Go to:
Gentoo Home
Documentation
Forums
Lists
Bugs
Planet
Store
Wiki
Get Gentoo!
Gentoo's Bugzilla – Attachment 93911 Details for
Bug 143465
kernel support for areca ARC-11xx Series (SATA ll RAID Controllers)
Home
|
New
–
[Ex]
|
Browse
|
Search
|
Privacy Policy
|
[?]
|
Reports
|
Requests
|
Help
|
New Account
|
Log In
[x]
|
Forgot Password
Login:
[x]
arcmsr-1.20.0X.13.patch
arcmsr-1.20.0X.13.patch (text/plain), 462.83 KB, created by
Christian Affolter
on 2006-08-10 07:13:20 UTC
(
hide
)
Description:
arcmsr-1.20.0X.13.patch
Filename:
MIME Type:
Creator:
Christian Affolter
Created:
2006-08-10 07:13:20 UTC
Size:
462.83 KB
patch
obsolete
>diff -urN linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/arcmsr.c linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/arcmsr.c >--- linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/arcmsr.c 1970-01-01 01:00:00.000000000 +0100 >+++ linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/arcmsr.c 2006-08-10 16:41:54.000000000 +0200 >@@ -0,0 +1,2764 @@ >+/* >+****************************************************************************************** >+** O.S : Linux >+** FILE NAME : arcmsr.c >+** BY : Erich Chen >+** Description: SCSI RAID Device Driver for >+** ARCMSR RAID Host adapter >+************************************************************************ >+** Copyright (C) 2002 - 2005, Areca Technology Corporation All rights reserved. >+** >+** Web site: www.areca.com.tw >+** E-mail: erich@areca.com.tw >+** >+** This program is free software; you can redistribute it and/or modify >+** it under the terms of the GNU General Public License version 2 as >+** published by the Free Software Foundation. >+** This program is distributed in the hope that it will be useful, >+** but WITHOUT ANY WARRANTY; without even the implied warranty of >+** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the >+** GNU General Public License for more details. >+************************************************************************ >+** Redistribution and use in source and binary forms,with or without >+** modification,are permitted provided that the following conditions >+** are met: >+** 1. Redistributions of source code must retain the above copyright >+** notice,this list of conditions and the following disclaimer. >+** 2. Redistributions in binary form must reproduce the above copyright >+** notice,this list of conditions and the following disclaimer in the >+** documentation and/or other materials provided with the distribution. >+** 3. The name of the author may not be used to endorse or promote products >+** derived from this software without specific prior written permission. >+** >+** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR >+** IMPLIED WARRANTIES,INCLUDING,BUT NOT LIMITED TO,THE IMPLIED WARRANTIES >+** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. >+** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT,INDIRECT, >+** INCIDENTAL,SPECIAL,EXEMPLARY,OR CONSEQUENTIAL DAMAGES(INCLUDING,BUT >+** NOT LIMITED TO,PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, >+** DATA,OR PROFITS; OR BUSINESS INTERRUPTION)HOWEVER CAUSED AND ON ANY >+** THEORY OF LIABILITY,WHETHER IN CONTRACT,STRICT LIABILITY,OR TORT >+**(INCLUDING NEGLIGENCE OR OTHERWISE)ARISING IN ANY WAY OUT OF THE USE OF >+** THIS SOFTWARE,EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. >+************************************************************************** >+** History >+** >+** REV# DATE NAME DESCRIPTION >+** 1.00.00.00 3/31/2004 Erich Chen First release >+** 1.10.00.04 7/28/2004 Erich Chen modify for ioctl >+** 1.10.00.06 8/28/2004 Erich Chen modify for 2.6.x >+** 1.10.00.08 9/28/2004 Erich Chen modify for x86_64 >+** 1.10.00.10 10/10/2004 Erich Chen bug fix for SMP & ioctl >+** 1.20.00.00 11/29/2004 Erich Chen bug fix with arcmsr_bus_reset when PHY error >+** 1.20.00.02 12/09/2004 Erich Chen bug fix with over 2T bytes RAID Volume >+** 1.20.00.04 1/09/2005 Erich Chen fits for Debian linux kernel version 2.2.xx >+** 1.20.0X.07 3/28/2005 Erich Chen sync for 1.20.00.07 (linux.org version) >+** remove some unused function >+** --.--.0X.-- is for old style kernel compatibility >+** 1.20.0X.08 6/23/2005 Erich Chen bug fix with abort command,in case of heavy loading when sata cable >+** working on low quality connection >+** 1.20.0X.09 9/12/2005 Erich Chen bug fix with abort command handling,and firmware version check >+** and firmware update notify for hardware bug fix >+** 1.20.0X.10 9/23/2005 Erich Chen enhance sysfs function for change driver's max tag Q number. >+** add DMA_64BIT_MASK for backward compatible with all 2.6.x >+** add some useful message for abort command >+** add ioctl code 'ARCMSR_MESSAGE_FLUSH_ADAPTER_CACHE' >+** customer can send this command for sync raid volume data >+** 1.20.0X.11 9/29/2005 Erich Chen by comment of Arjan van de Ven fix incorrect msleep redefine >+** cast off sizeof(dma_addr_t) condition for 64bit pci_set_dma_mask >+** 1.20.0X.12 9/30/2005 Erich Chen bug fix with 64bit platform's ccbs using if over 4G system memory >+** change 64bit pci_set_consistent_dma_mask into 32bit >+** increcct adapter count if adapter initialize fail. >+** miss edit at arcmsr_build_ccb.... >+** psge += sizeof(struct SG64ENTRY *) => psge += sizeof(struct SG64ENTRY) >+** 64 bits sg entry would be incorrectly calculated >+** thanks Kornel Wieliczek give me kindly notify and detail description >+** 1.20.0X.13 11/15/2005 Erich Chen scheduling pending ccb with 'first in first out' >+** new firmware update notify >+****************************************************************************************** >+*/ >+#define ARCMSR_DEBUG 0 >+/************************************/ >+#if defined __KERNEL__ >+ #include <linux/config.h> >+ #include <linux/version.h> >+ #if defined( CONFIG_MODVERSIONS ) && ! defined( MODVERSIONS ) >+ #define MODVERSIONS >+ #endif >+ /* modversions.h should be before should be before module.h */ >+ #if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,0) >+ #if defined( MODVERSIONS ) >+ #include <config/modversions.h> >+ #endif >+ #endif >+ #include <linux/module.h> >+ /* Now your module include files & source code follows */ >+ #include <asm/dma.h> >+ #include <asm/io.h> >+ #include <asm/system.h> >+ #include <asm/uaccess.h> >+ #include <linux/delay.h> >+ #include <linux/signal.h> >+ #include <linux/errno.h> >+ #include <linux/kernel.h> >+ #include <linux/ioport.h> >+ #include <linux/pci.h> >+ #include <linux/proc_fs.h> >+ #include <linux/string.h> >+ #include <linux/ctype.h> >+ #include <linux/interrupt.h> >+ #include <linux/smp_lock.h> >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,5,0) >+ #include <linux/moduleparam.h> >+ #include <linux/blkdev.h> >+ #else >+ #include <linux/blk.h> >+ #endif >+ #include <linux/timer.h> >+ #include <linux/devfs_fs_kernel.h> >+ #include <linux/reboot.h> >+ #include <linux/sched.h> >+ #include <linux/init.h> >+ >+ # if LINUX_VERSION_CODE >=KERNEL_VERSION(2,3,30) >+ # include <linux/spinlock.h> >+ # else >+ # include <asm/spinlock.h> >+ # endif /* 2,3,30 */ >+ >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,5,0) >+ #include <scsi/scsi.h> >+ #include <scsi/scsi_host.h> >+ #include <scsi/scsi_cmnd.h> >+ #include <scsi/scsi_tcq.h> >+ #include <scsi/scsi_device.h> >+ #include <scsi/scsicam.h> >+ #else >+ #include "/usr/src/linux/drivers/scsi/scsi.h" >+ #include "/usr/src/linux/drivers/scsi/hosts.h" >+ #include "/usr/src/linux/drivers/scsi/constants.h" >+ #include "/usr/src/linux/drivers/scsi/sd.h" >+ #endif >+ #include "arcmsr.h" >+#endif >+ >+MODULE_AUTHOR("Erich Chen <erich@areca.com.tw>"); >+MODULE_DESCRIPTION("ARECA (ARC11xx/12xx) SATA RAID HOST Adapter"); >+ >+#ifdef MODULE_LICENSE >+MODULE_LICENSE("Dual BSD/GPL"); >+#endif >+ >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static u_int8_t arcmsr_adapterCnt=0; >+static struct HCBARC arcmsr_host_control_block; >+static int arcmsr_fops_ioctl(struct inode *inode, struct file *filep, unsigned int ioctl_cmd, unsigned long arg); >+static int arcmsr_fops_close(struct inode *inode, struct file *filep); >+static int arcmsr_fops_open(struct inode *inode, struct file *filep); >+static int arcmsr_initialize(struct AdapterControlBlock *acb,struct pci_dev *pdev); >+static int arcmsr_iop_ioctlcmd(struct AdapterControlBlock *acb,int ioctl_cmd,void __user *arg); >+static void arcmsr_free_ccb_pool(struct AdapterControlBlock *acb); >+static void arcmsr_pcidev_disattach(struct AdapterControlBlock *acb); >+static void arcmsr_iop_init(struct AdapterControlBlock *acb); >+static void arcmsr_polling_ccbdone(struct AdapterControlBlock *acb); >+static u_int8_t arcmsr_wait_msgint_ready(struct AdapterControlBlock *acb); >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ #define arcmsr_detect NULL >+ static irqreturn_t arcmsr_interrupt(struct AdapterControlBlock *acb); >+ static int arcmsr_device_probe(struct pci_dev *pdev,const struct pci_device_id *id); >+ static void arcmsr_device_remove(struct pci_dev *pdev); >+#else >+ static void arcmsr_interrupt(struct AdapterControlBlock *acb); >+ int arcmsr_schedule_command(struct scsi_cmnd *pcmd); >+ int arcmsr_detect(Scsi_Host_Template *); >+#endif >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static struct file_operations arcmsr_file_operations = >+{ >+ ioctl: arcmsr_fops_ioctl, >+ open: arcmsr_fops_open, >+ release: arcmsr_fops_close >+}; >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+#if LINUX_VERSION_CODE < KERNEL_VERSION(2,3,30) >+ struct proc_dir_entry arcmsr_proc_scsi= >+ { >+ PROC_SCSI_ARCMSR, >+ 8, >+ "arcmsr", >+ S_IFDIR | S_IRUGO | S_IXUGO, >+ 2 >+ }; >+#endif >+ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ /* We do our own ID filtering. So, grab all SCSI storage class devices. */ >+ static struct pci_device_id arcmsr_device_id_table[] = >+ { >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1110)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1120)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1130)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1160)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1170)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1210)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1220)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1230)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1260)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1270)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1280)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1380)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1381)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1680)}, >+ {PCI_DEVICE(PCI_VENDOR_ID_ARECA, PCI_DEVICE_ID_ARECA_1681)}, >+ {0, 0}, /* Terminating entry */ >+ }; >+ MODULE_DEVICE_TABLE(pci, arcmsr_device_id_table); >+ struct pci_driver arcmsr_pci_driver = >+ { >+ .name = "arcmsr", >+ .id_table = arcmsr_device_id_table, >+ .probe = arcmsr_device_probe, >+ .remove = arcmsr_device_remove, >+ }; >+ /* >+ ********************************************************************* >+ ********************************************************************* >+ */ >+ static irqreturn_t arcmsr_do_interrupt(int irq,void *dev_id,struct pt_regs *regs) >+ { >+ irqreturn_t handle_state; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ struct AdapterControlBlock *acb; >+ struct AdapterControlBlock *acbtmp; >+ unsigned long flags; >+ int i=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_do_interrupt.................. \n"); >+ #endif >+ >+ acb=(struct AdapterControlBlock *)dev_id; >+ acbtmp=pHCBARC->acb[i]; >+ while((acb != acbtmp) && acbtmp && (i <ARCMSR_MAX_ADAPTER) ) >+ { >+ i++; >+ acbtmp=pHCBARC->acb[i]; >+ } >+ if(!acbtmp) >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_do_interrupt: Invalid acb=0x%p \n",acb); >+ #endif >+ return IRQ_NONE; >+ } >+ spin_lock_irqsave(acb->host->host_lock, flags); >+ handle_state=arcmsr_interrupt(acb); >+ spin_unlock_irqrestore(acb->host->host_lock, flags); >+ return(handle_state); >+ } >+ /* >+ ********************************************************************* >+ ********************************************************************* >+ */ >+ int arcmsr_bios_param(struct scsi_device *sdev, struct block_device *bdev,sector_t capacity, int *geom) >+ { >+ int ret,heads,sectors,cylinders; >+ unsigned char *buffer;/* return copy of block device's partition table */ >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_bios_param.................. \n"); >+ #endif >+ >+ buffer = scsi_bios_ptable(bdev); >+ if(buffer) >+ { >+ ret = scsi_partsize(buffer, capacity, &geom[2], &geom[0], &geom[1]); >+ kfree(buffer); >+ if (ret != -1) >+ { >+ return(ret); >+ } >+ } >+ heads=64; >+ sectors=32; >+ cylinders=sector_div(capacity, heads * sectors); >+ if(cylinders >= 1024) >+ { >+ heads=255; >+ sectors=63; >+ cylinders=sector_div(capacity, heads * sectors); >+ } >+ geom[0]=heads; >+ geom[1]=sectors; >+ geom[2]=cylinders; >+ return (0); >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ static int arcmsr_device_probe(struct pci_dev *pdev,const struct pci_device_id *id) >+ { >+ struct Scsi_Host *host; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ uint8_t bus,dev_fun; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_device_probe............................\n"); >+ #endif >+ if(pci_enable_device(pdev)) >+ { >+ printk("arcmsr%d: adapter probe: pci_enable_device error \n",arcmsr_adapterCnt); >+ return -ENODEV; >+ } >+ if((host=scsi_host_alloc(&arcmsr_scsi_host_template,sizeof(struct AdapterControlBlock)))==0) >+ { >+ printk("arcmsr%d: adapter probe: scsi_host_alloc error \n",arcmsr_adapterCnt); >+ return -ENODEV; >+ } >+ if(!pci_set_dma_mask(pdev, DMA_64BIT_MASK)) >+ { >+ printk("ARECA RAID ADAPTER%d: 64BITS PCI BUS DMA ADDRESSING SUPPORTED\n",arcmsr_adapterCnt); >+ } >+ else if(!pci_set_dma_mask(pdev, DMA_32BIT_MASK)) >+ { >+ printk("ARECA RAID ADAPTER%d: 32BITS PCI BUS DMA ADDRESSING SUPPORTED\n",arcmsr_adapterCnt); >+ } >+ else >+ { >+ printk("ARECA RAID ADAPTER%d: No suitable DMA available.\n",arcmsr_adapterCnt); >+ return -ENOMEM; >+ } >+ if (pci_set_consistent_dma_mask(pdev, DMA_32BIT_MASK)) >+ { >+ printk("ARECA RAID ADAPTER%d: No 32BIT coherent DMA adressing available.\n",arcmsr_adapterCnt); >+ return -ENOMEM; >+ } >+ bus = pdev->bus->number; >+ dev_fun = pdev->devfn; >+ acb=(struct AdapterControlBlock *) host->hostdata; >+ memset(acb,0,sizeof(struct AdapterControlBlock)); >+ acb->pdev=pdev; >+ acb->host=host; >+ host->max_sectors=ARCMSR_MAX_XFER_SECTORS; >+ host->max_lun=ARCMSR_MAX_TARGETLUN; >+ host->max_id=ARCMSR_MAX_TARGETID;/*16:8*/ >+ host->max_cmd_len=16; /*this is issue of 64bit LBA ,over 2T byte*/ >+ host->sg_tablesize=ARCMSR_MAX_SG_ENTRIES; >+ host->can_queue=ARCMSR_MAX_FREECCB_NUM; /* max simultaneous cmds */ >+ host->cmd_per_lun=ARCMSR_MAX_CMD_PERLUN; >+ host->this_id=ARCMSR_SCSI_INITIATOR_ID; >+ host->unique_id=(bus << 8) | dev_fun; >+ host->io_port=0; >+ host->n_io_port=0; >+ host->irq=pdev->irq; >+ pci_set_master(pdev); >+ if(arcmsr_initialize(acb,pdev)) >+ { >+ printk("arcmsr%d: initialize got error \n",arcmsr_adapterCnt); >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ pHCBARC->acb[arcmsr_adapterCnt]=NULL; >+ scsi_remove_host(host); >+ scsi_host_put(host); >+ return -ENODEV; >+ } >+ if (pci_request_regions(pdev, "arcmsr")) >+ { >+ printk("arcmsr%d: adapter probe: pci_request_regions failed \n",arcmsr_adapterCnt--); >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ arcmsr_pcidev_disattach(acb); >+ return -ENODEV; >+ } >+ #ifdef CONFIG_SCSI_ARCMSR_MSI >+ if(pci_enable_msi(pdev) == 0) >+ { >+ acb->acb_flags |= ACB_F_HAVE_MSI; >+ } >+ #endif >+ if(request_irq(pdev->irq,arcmsr_do_interrupt,SA_INTERRUPT | SA_SHIRQ,"arcmsr",acb)) >+ { >+ printk("arcmsr%d: request IRQ=%d failed !\n",arcmsr_adapterCnt--,pdev->irq); >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ arcmsr_pcidev_disattach(acb); >+ return -ENODEV; >+ } >+ arcmsr_iop_init(acb); >+ if(scsi_add_host(host, &pdev->dev)) >+ { >+ printk("arcmsr%d: scsi_add_host got error \n",arcmsr_adapterCnt--); >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ arcmsr_pcidev_disattach(acb); >+ return -ENODEV; >+ } >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ pci_set_drvdata(pdev, host); >+ scsi_scan_host(host); >+ return 0; >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ static void arcmsr_device_remove(struct pci_dev *pdev) >+ { >+ struct Scsi_Host *host=pci_get_drvdata(pdev); >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ struct AdapterControlBlock *acb=(struct AdapterControlBlock *) host->hostdata; >+ int i; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_device_remove............................\n"); >+ #endif >+ arcmsr_pcidev_disattach(acb); >+ /*if this is last acb */ >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ if(pHCBARC->acb[i]) >+ { >+ return;/* this is not last adapter's release */ >+ } >+ } >+ unregister_chrdev(pHCBARC->arcmsr_major_number, "arcmsr"); >+ return; >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ static int arcmsr_scsi_host_template_init(struct scsi_host_template * host_template) >+ { >+ int error; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_scsi_host_template_init..............\n"); >+ #endif >+ /* >+ ** register as a PCI hot-plug driver module >+ */ >+ memset(pHCBARC,0,sizeof(struct HCBARC)); >+ error=pci_module_init(&arcmsr_pci_driver); >+ if(pHCBARC->acb[0]) >+ { >+ host_template->proc_name="arcmsr"; >+ pHCBARC->arcmsr_major_number=register_chrdev(0, "arcmsr", &arcmsr_file_operations); >+ printk("arcmsr device major number %d \n",pHCBARC->arcmsr_major_number); >+ } >+ return(error); >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ static int arcmsr_module_init(void) >+ { >+ return (arcmsr_scsi_host_template_init(&arcmsr_scsi_host_template)); >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ static void arcmsr_module_exit(void) >+ { >+ pci_unregister_driver(&arcmsr_pci_driver); >+ return; >+ } >+ module_init(arcmsr_module_init); >+ module_exit(arcmsr_module_exit); >+#else >+ /* >+ ************************************************************************* >+ ************************************************************************* >+ */ >+ static void arcmsr_internal_done(struct scsi_cmnd *pcmd) >+ { >+ pcmd->SCp.Status++; >+ return; >+ } >+ /* >+ *************************************************************** >+ * arcmsr_schedule_command >+ * Description: Process a command from the SCSI manager(A.P) >+ * Parameters: cmd - Pointer to SCSI command structure. >+ * Returns: Status code. >+ *************************************************************** >+ */ >+ int arcmsr_schedule_command(struct scsi_cmnd *pcmd) >+ { >+ unsigned long timeout; >+ #if ARCMSR_DEBUG >+ printk(" arcmsr_schedule_command................ \n"); >+ #endif >+ pcmd->SCp.Status=0; >+ arcmsr_queue_command(pcmd,arcmsr_internal_done); >+ timeout=jiffies + 60 * HZ; >+ while(time_before(jiffies,timeout) && !pcmd->SCp.Status) >+ { >+ schedule(); >+ } >+ if(!pcmd->SCp.Status) >+ { >+ pcmd->result=(DID_ERROR<<16); >+ } >+ return pcmd->result; >+ } >+ /* >+ ********************************************************************* >+ ********************************************************************* >+ */ >+ void arcmsr_do_interrupt(int irq,void *dev_id,struct pt_regs *regs) >+ { >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ struct AdapterControlBlock *acb; >+ struct AdapterControlBlock *acbtmp; >+ int i=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_do_interrupt.................. \n"); >+ #endif >+ acb=(struct AdapterControlBlock *)dev_id; >+ acbtmp=pHCBARC->acb[i]; >+ while((acb != acbtmp) && acbtmp && (i <ARCMSR_MAX_ADAPTER) ) >+ { >+ i++; >+ acbtmp=pHCBARC->acb[i]; >+ } >+ if(!acbtmp) >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_do_interrupt: Invalid acb=0x%p \n",acb); >+ #endif >+ return; >+ } >+ spin_lock_irq(&acb->isr_lock); >+ arcmsr_interrupt(acb); >+ spin_unlock_irq(&acb->isr_lock); >+ return; >+ } >+ /* >+ ********************************************************************* >+ ********************************************************************* >+ */ >+ int arcmsr_bios_param(Disk *disk,kdev_t dev,int geom[]) >+ { >+ int heads,sectors,cylinders,total_capacity; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_bios_param.................. \n"); >+ #endif >+ total_capacity=disk->capacity; >+ heads=64; >+ sectors=32; >+ cylinders=total_capacity / (heads * sectors); >+ if(cylinders >= 1024) >+ { >+ heads=255; >+ sectors=63; >+ cylinders=total_capacity / (heads * sectors); >+ } >+ geom[0]=heads; >+ geom[1]=sectors; >+ geom[2]=cylinders; >+ return (0); >+ } >+ /* >+ ************************************************************************ >+ ************************************************************************ >+ */ >+ int arcmsr_detect(Scsi_Host_Template * host_template) >+ { >+ struct >+ { >+ unsigned int vendor_id; >+ unsigned int device_id; >+ } const arcmsr_devices[]={ >+ { PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1110 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1120 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1130 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1160 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1170 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1210 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1220 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1230 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1260 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1270 } >+ ,{ PCI_VENDOR_ID_ARECA,PCI_DEVICE_ID_ARECA_1280 } >+ }; >+ struct pci_dev *pdev=NULL; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ struct Scsi_Host *host; >+ static u_int8_t i; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_detect............................\n"); >+ #endif >+ memset(pHCBARC,0,sizeof(struct HCBARC)); >+ for(i=0; i < (sizeof(arcmsr_devices)/sizeof(arcmsr_devices[0])) ; ++i) >+ { >+ pdev=NULL; >+ while((pdev=pci_find_device(arcmsr_devices[i].vendor_id,arcmsr_devices[i].device_id,pdev))) >+ { >+ if((host=scsi_register(host_template,sizeof(struct AdapterControlBlock)))==0) >+ { >+ printk("arcmsr_detect: scsi_register error . . . . . . . . . . .\n"); >+ continue; >+ } >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ { >+ if(pci_enable_device(pdev)) >+ { >+ printk("arcmsr_detect: pci_enable_device ERROR..................................\n"); >+ scsi_unregister(host); >+ continue; >+ } >+ if(!pci_set_dma_mask(pdev,(dma_addr_t)0xffffffffffffffffULL))/*64bit*/ >+ { >+ printk("ARECA RAID: 64BITS PCI BUS DMA ADDRESSING SUPPORTED\n"); >+ } >+ else if(pci_set_dma_mask(pdev,(dma_addr_t)0x00000000ffffffffULL))/*32bit*/ >+ { >+ printk("ARECA RAID: 32BITS PCI BUS DMA ADDRESSING NOT SUPPORTED (ERROR)\n"); >+ scsi_unregister(host); >+ continue; >+ } >+ } >+ #endif >+ acb=(struct AdapterControlBlock *) host->hostdata; >+ memset(acb,0,sizeof(struct AdapterControlBlock)); >+ spin_lock_init(&acb->isr_lock); >+ acb->pdev=pdev; >+ acb->host=host; >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,4,7) >+ host->max_sectors=ARCMSR_MAX_XFER_SECTORS; >+ #endif >+ host->max_lun=ARCMSR_MAX_TARGETLUN; >+ host->max_id=ARCMSR_MAX_TARGETID;/*16:8*/ >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ host->max_cmd_len=16; /*this is issue of 64bit LBA ,over 2T byte*/ >+ #endif >+ host->sg_tablesize=ARCMSR_MAX_SG_ENTRIES; >+ host->can_queue=ARCMSR_MAX_FREECCB_NUM; /* max simultaneous cmds */ >+ host->cmd_per_lun=ARCMSR_MAX_CMD_PERLUN; >+ host->this_id=ARCMSR_SCSI_INITIATOR_ID; >+ host->io_port=0; >+ host->n_io_port=0; >+ host->irq=pdev->irq; >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,4,4) >+ scsi_set_pci_device(host,pdev); >+ #endif >+ if(!arcmsr_initialize(acb,pdev)) >+ { >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ pci_set_drvdata(pdev,acb); /*set driver_data*/ >+ #endif >+ pci_set_master(pdev); >+ if(request_irq(pdev->irq,arcmsr_do_interrupt,SA_INTERRUPT | SA_SHIRQ,"arcmsr",acb)) >+ { >+ printk("arcmsr_detect: request_irq got ERROR...................\n"); >+ arcmsr_adapterCnt--; >+ pHCBARC->acb[acb->adapter_index]=NULL; >+ iounmap(acb->pmu); >+ arcmsr_free_ccb_pool(acb); >+ scsi_unregister(host); >+ goto next_areca; >+ } >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ if (pci_request_regions(pdev, "arcmsr")) >+ { >+ printk("arcmsr_detect: pci_request_regions got ERROR...................\n"); >+ arcmsr_adapterCnt--; >+ pHCBARC->acb[acb->adapter_index]=NULL; >+ iounmap(acb->pmu); >+ arcmsr_free_ccb_pool(acb); >+ scsi_unregister(host); >+ goto next_areca; >+ } >+ #endif >+ arcmsr_iop_init(acb);/* on kernel 2.4.21 driver's iop read/write must after request_irq */ >+ } >+ else >+ { >+ printk("arcmsr: arcmsr_initialize got ERROR...................\n"); >+ scsi_unregister(host); >+ } >+ next_areca: ; >+ } >+ } >+ if(arcmsr_adapterCnt) >+ { >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,3,30) >+ host_template->proc_name="arcmsr"; >+ #else >+ host_template->proc_dir= &arcmsr_proc_scsi; >+ #endif >+ } >+ else >+ { >+ printk("arcmsr_detect:...............NO ARECA RAID ADAPTER FOUND...........\n"); >+ return(arcmsr_adapterCnt); >+ } >+ pHCBARC->adapterCnt=arcmsr_adapterCnt; >+ pHCBARC->arcmsr_major_number=register_chrdev(0, "arcmsr", &arcmsr_file_operations); >+ printk("arcmsr device major number %d \n",pHCBARC->arcmsr_major_number); >+ return(arcmsr_adapterCnt); >+ } >+#endif >+/* >+********************************************************************** >+********************************************************************** >+*/ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ void arcmsr_pci_unmap_dma(struct CommandControlBlock *ccb) >+ { >+ struct AdapterControlBlock *acb=ccb->acb; >+ struct scsi_cmnd *pcmd=ccb->pcmd; >+ >+ if(pcmd->use_sg != 0) >+ { >+ struct scatterlist *sl; >+ >+ sl = (struct scatterlist *)pcmd->request_buffer; >+ pci_unmap_sg(acb->pdev, sl, pcmd->use_sg, pcmd->sc_data_direction); >+ } >+ else if(pcmd->request_bufflen != 0) >+ { >+ pci_unmap_single(acb->pdev,(dma_addr_t)(unsigned long)pcmd->SCp.ptr,pcmd->request_bufflen, pcmd->sc_data_direction); >+ } >+ return; >+ } >+#endif >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static u32 arcmsr_disable_outbound_ints(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg = acb->pmu; >+ u32 orig_mask = readl(®->outbound_intmask); >+ >+ writel(orig_mask | ARCMSR_MU_OUTBOUND_ALL_INTMASKENABLE, >+ ®->outbound_intmask); >+ return orig_mask; >+} >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static void arcmsr_enable_outbound_ints(struct AdapterControlBlock *acb, >+ u32 orig_mask) >+{ >+ struct MessageUnit __iomem *reg = acb->pmu; >+ u32 mask; >+ >+ mask = orig_mask & ~(ARCMSR_MU_OUTBOUND_POSTQUEUE_INTMASKENABLE | >+ ARCMSR_MU_OUTBOUND_DOORBELL_INTMASKENABLE); >+ writel(mask, ®->outbound_intmask); >+} >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static int arcmsr_fops_open(struct inode *inode, struct file *filep) >+{ >+ int i,minor; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ >+ minor = MINOR(inode->i_rdev); >+ if(minor >= pHCBARC->adapterCnt) >+ { >+ return -ENODEV; >+ } >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ acb=pHCBARC->acb[i]; >+ if(acb) >+ { >+ if(acb->adapter_index==minor) >+ { >+ break; >+ } >+ } >+ } >+ if(i>=ARCMSR_MAX_ADAPTER) >+ { >+ return -ENODEV; >+ } >+ return 0; /* success */ >+} >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static int arcmsr_fops_close(struct inode *inode, struct file *filep) >+{ >+ int i,minor; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ >+ minor = MINOR(inode->i_rdev); >+ if(minor >= pHCBARC->adapterCnt) >+ { >+ return -ENODEV; >+ } >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ acb=pHCBARC->acb[i]; >+ if(acb) >+ { >+ if(acb->adapter_index==minor) >+ { >+ break; >+ } >+ } >+ } >+ if(i>=ARCMSR_MAX_ADAPTER) >+ { >+ return -ENODEV; >+ } >+ return 0; >+} >+/* >+********************************************************************************** >+********************************************************************************** >+*/ >+static int arcmsr_fops_ioctl(struct inode *inode, struct file *filep, unsigned int ioctl_cmd, unsigned long arg) >+{ >+ int i,minor; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ >+ minor = MINOR(inode->i_rdev); >+ if(minor >= pHCBARC->adapterCnt) >+ { >+ return -ENODEV; >+ } >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ acb=pHCBARC->acb[i]; >+ if(acb) >+ { >+ if(acb->adapter_index==minor) >+ { >+ break; >+ } >+ } >+ } >+ if(i>=ARCMSR_MAX_ADAPTER) >+ { >+ return -ENODEV; >+ } >+ return arcmsr_iop_ioctlcmd(acb,ioctl_cmd,(void __user *) arg); >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+void arcmsr_flush_adapter_cache(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_flush_adapter_cache..............\n"); >+ #endif >+ writel(ARCMSR_INBOUND_MESG0_FLUSH_CACHE,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: wait 'flush adapter cache' timeout \n",acb->adapter_index); >+ } >+ return; >+} >+/* >+********************************************************************** >+********************************************************************** >+*/ >+void arcmsr_ccb_complete(struct CommandControlBlock *ccb,int stand_flag) >+{ >+ struct AdapterControlBlock *acb=ccb->acb; >+ struct scsi_cmnd *pcmd=ccb->pcmd; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_ccb_complete:ccb=0x%p \n",ccb); >+ #endif >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ arcmsr_pci_unmap_dma(ccb); >+#endif >+ if(stand_flag==1) >+ { >+ atomic_dec(&acb->ccboutstandingcount); >+ } >+ ccb->startdone=ARCMSR_CCB_DONE; >+ ccb->ccb_flags=0; >+ list_add_tail(&ccb->list, &acb->ccb_free_list); >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ { >+ pcmd->scsi_done(pcmd); >+ } >+ #else >+ { >+ unsigned long flags; >+ spin_lock_irqsave(&io_request_lock, flags); >+ pcmd->scsi_done(pcmd); >+ spin_unlock_irqrestore(&io_request_lock, flags); >+ } >+ #endif >+ return; >+} >+/* >+********************************************************************** >+** if scsi error do auto request sense >+********************************************************************** >+*/ >+void arcmsr_report_sense_info(struct CommandControlBlock *ccb) >+{ >+ struct scsi_cmnd *pcmd=ccb->pcmd; >+ struct SENSE_DATA *psenseBuffer=(struct SENSE_DATA *)pcmd->sense_buffer; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_report_sense_info...........\n"); >+ #endif >+ pcmd->result=DID_OK << 16; >+ if(psenseBuffer) >+ { >+ int sense_data_length=sizeof(struct SENSE_DATA) < sizeof(pcmd->sense_buffer) ? sizeof(struct SENSE_DATA) : sizeof(pcmd->sense_buffer); >+ memset(psenseBuffer, 0, sizeof(pcmd->sense_buffer)); >+ memcpy(psenseBuffer,ccb->arcmsr_cdb.SenseData,sense_data_length); >+ psenseBuffer->ErrorCode=0x70; >+ psenseBuffer->Valid=1; >+ } >+ return; >+} >+/* >+********************************************************************* >+********************************************************************* >+*/ >+void arcmsr_abort_allcmd(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ >+ writel(ARCMSR_INBOUND_MESG0_ABORT_CMD,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: wait 'abort all outstanding command' timeout \n",acb->adapter_index); >+ } >+ return; >+} >+/* >+********************************************************************** >+********************************************************************** >+*/ >+static u_int8_t arcmsr_wait_msgint_ready(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ uint32_t Index; >+ uint8_t Retries=0x00; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_wait_msgint_ready: ...............................\n"); >+ #endif >+ do >+ { >+ for(Index=0; Index < 100; Index++) >+ { >+ if(readl(®->outbound_intstatus) & ARCMSR_MU_OUTBOUND_MESSAGE0_INT) >+ { >+ writel(ARCMSR_MU_OUTBOUND_MESSAGE0_INT,®->outbound_intstatus);/*clear interrupt*/ >+ return 0x00; >+ } >+ arc_mdelay_int(10); >+ }/*max 1 seconds*/ >+ }while(Retries++ < 20);/*max 20 sec*/ >+ return 0xff; >+} >+/* >+**************************************************************************** >+**************************************************************************** >+*/ >+static void arcmsr_iop_reset(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct CommandControlBlock *ccb; >+ uint32_t intmask_org; >+ int i=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_reset: reset iop controller......................................\n"); >+ #endif >+ if(atomic_read(&acb->ccboutstandingcount)!=0) >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_reset: ccboutstandingcount=%d ...\n",atomic_read(&acb->ccboutstandingcount)); >+ #endif >+ >+ /* talk to iop 331 outstanding command aborted*/ >+ arcmsr_abort_allcmd(acb); >+ arc_mdelay_int(3000);/*wait for 3 sec for all command aborted*/ >+ /* disable all outbound interrupt */ >+ intmask_org = arcmsr_disable_outbound_ints(acb); >+ /*clear all outbound posted Q*/ >+ for(i=0;i<ARCMSR_MAX_OUTSTANDING_CMD;i++) >+ { >+ readl(®->outbound_queueport); >+ } >+ for(i=0;i<ARCMSR_MAX_FREECCB_NUM;i++) >+ { >+ ccb=acb->pccb_pool[i]; >+ if((ccb->startdone==ARCMSR_CCB_START) || (ccb->startdone==ARCMSR_CCB_ABORTED)) >+ { >+ ccb->startdone=ARCMSR_CCB_ABORTED; >+ ccb->pcmd->result=DID_ABORT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ } >+ /* enable all outbound interrupt */ >+ arcmsr_enable_outbound_ints(acb, intmask_org); >+ } >+ atomic_set(&acb->ccboutstandingcount,0); >+ return; >+} >+/* >+********************************************************************** >+********************************************************************** >+*/ >+void arcmsr_build_ccb(struct AdapterControlBlock *acb,struct CommandControlBlock *ccb,struct scsi_cmnd *pcmd) >+{ >+ struct ARCMSR_CDB *arcmsr_cdb= &ccb->arcmsr_cdb; >+ uint8_t *psge=(uint8_t * )&arcmsr_cdb->u; >+ uint32_t address_lo,address_hi; >+ int arccdbsize=0x30,sgcount=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_build_ccb........................... \n"); >+ #endif >+ ccb->pcmd=pcmd; >+ memset(arcmsr_cdb,0,sizeof(struct ARCMSR_CDB)); >+ arcmsr_cdb->Bus=0; >+ arcmsr_cdb->TargetID=pcmd->device->id; >+ arcmsr_cdb->LUN=pcmd->device->lun; >+ arcmsr_cdb->Function=1; >+ arcmsr_cdb->CdbLength=(uint8_t)pcmd->cmd_len; >+ arcmsr_cdb->Context=(unsigned long)arcmsr_cdb; >+ memcpy(arcmsr_cdb->Cdb, pcmd->cmnd, pcmd->cmd_len); >+ if(pcmd->use_sg) >+ { >+ int length,i,cdb_sgcount=0; >+ struct scatterlist *sl; >+ >+ /* Get Scatter Gather List from scsiport. */ >+ sl=(struct scatterlist *) pcmd->request_buffer; >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,3,30) >+ sgcount=pci_map_sg(acb->pdev, sl, pcmd->use_sg, pcmd->sc_data_direction); >+ #else >+ sgcount=pcmd->use_sg; >+ #endif >+ /* map stor port SG list to our iop SG List.*/ >+ for(i=0;i<sgcount;i++) >+ { >+ /* Get the physical address of the current data pointer */ >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,3,30) >+ length=cpu_to_le32(sg_dma_len(sl)); >+ address_lo=cpu_to_le32(dma_addr_lo32(sg_dma_address(sl))); >+ address_hi=cpu_to_le32(dma_addr_hi32(sg_dma_address(sl))); >+ #else >+ length=cpu_to_le32(sl->length); >+ address_lo=cpu_to_le32(virt_to_bus(sl->address)); >+ address_hi=0; >+ #endif >+ if(address_hi==0) >+ { >+ struct SG32ENTRY* pdma_sg=(struct SG32ENTRY*)psge; >+ >+ pdma_sg->address=address_lo; >+ pdma_sg->length=length; >+ psge += sizeof(struct SG32ENTRY); >+ arccdbsize += sizeof(struct SG32ENTRY); >+ } >+ else >+ { >+ struct SG64ENTRY *pdma_sg=(struct SG64ENTRY *)psge; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_build_ccb: ..........address_hi=0x%x.... \n",address_hi); >+ #endif >+ >+ pdma_sg->addresshigh=address_hi; >+ pdma_sg->address=address_lo; >+ pdma_sg->length=length|IS_SG64_ADDR; >+ psge +=sizeof(struct SG64ENTRY); >+ arccdbsize +=sizeof(struct SG64ENTRY); >+ } >+ sl++; >+ cdb_sgcount++; >+ } >+ arcmsr_cdb->sgcount=(uint8_t)cdb_sgcount; >+ arcmsr_cdb->DataLength=pcmd->request_bufflen; >+ if( arccdbsize > 256) >+ { >+ arcmsr_cdb->Flags|=ARCMSR_CDB_FLAG_SGL_BSIZE; >+ } >+ } >+ else if(pcmd->request_bufflen) >+ { >+ #if LINUX_VERSION_CODE >=KERNEL_VERSION(2,3,30) >+ dma_addr_t dma_addr; >+ dma_addr=pci_map_single(acb->pdev, pcmd->request_buffer, pcmd->request_bufflen, pcmd->sc_data_direction); >+ pcmd->SCp.ptr = (char *)(unsigned long) dma_addr; >+ address_lo=cpu_to_le32(dma_addr_lo32(dma_addr)); >+ address_hi=cpu_to_le32(dma_addr_hi32(dma_addr)); >+ #else >+ address_lo=cpu_to_le32(virt_to_bus(pcmd->request_buffer));/* Actual requested buffer */ >+ address_hi=0; >+ #endif >+ if(address_hi==0) >+ { >+ struct SG32ENTRY* pdma_sg=(struct SG32ENTRY*)psge; >+ pdma_sg->address=address_lo; >+ pdma_sg->length=pcmd->request_bufflen; >+ } >+ else >+ { >+ struct SG64ENTRY* pdma_sg=(struct SG64ENTRY*)psge; >+ pdma_sg->addresshigh=address_hi; >+ pdma_sg->address=address_lo; >+ pdma_sg->length=pcmd->request_bufflen|IS_SG64_ADDR; >+ } >+ arcmsr_cdb->sgcount=1; >+ arcmsr_cdb->DataLength=pcmd->request_bufflen; >+ } >+ if (pcmd->cmnd[0]|WRITE_6 || pcmd->cmnd[0]|WRITE_10 || pcmd->cmnd[0]|WRITE_12 ) >+ { >+ arcmsr_cdb->Flags |= ARCMSR_CDB_FLAG_WRITE; >+ ccb->ccb_flags |= CCB_FLAG_WRITE; >+ } >+ #if ARCMSR_DEBUG >+ printk("arcmsr_build_ccb: ccb=0x%p cmd=0x%x xferlength=%d arccdbsize=%d sgcount=%d\n",ccb,pcmd->cmnd[0],arcmsr_cdb->DataLength,arccdbsize,arcmsr_cdb->sgcount); >+ #endif >+ return; >+} >+/* >+************************************************************************** >+** arcmsr_post_ccb - Send a protocol specific ARC send postcard to a AIOC . >+** handle: Handle of registered ARC protocol driver >+** adapter_id: AIOC unique identifier(integer) >+** pPOSTCARD_SEND: Pointer to ARC send postcard >+** >+** This routine posts a ARC send postcard to the request post FIFO of a >+** specific ARC adapter. >+************************************************************************** >+*/ >+static void arcmsr_post_ccb(struct AdapterControlBlock *acb,struct CommandControlBlock *ccb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ uint32_t cdb_shifted_phyaddr=ccb->cdb_shifted_phyaddr; >+ struct ARCMSR_CDB *arcmsr_cdb=(struct ARCMSR_CDB *)&ccb->arcmsr_cdb; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_post_ccb: ccb=0x%p cdb_shifted_phyaddr=0x%x ccb->acb=0x%p \n",ccb,cdb_shifted_phyaddr,ccb->acb); >+ #endif >+ atomic_inc(&acb->ccboutstandingcount); >+ ccb->startdone=ARCMSR_CCB_START; >+ if(arcmsr_cdb->Flags & ARCMSR_CDB_FLAG_SGL_BSIZE) >+ { >+ writel(cdb_shifted_phyaddr|ARCMSR_CCBPOST_FLAG_SGL_BSIZE,®->inbound_queueport); >+ } >+ else >+ { >+ writel(cdb_shifted_phyaddr,®->inbound_queueport); >+ } >+ return; >+} >+/* >+********************************************************************** >+** Function: arcmsr_post_Qbuffer >+** Output: >+********************************************************************** >+*/ >+static void arcmsr_post_Qbuffer(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct QBUFFER __iomem *pwbuffer=(struct QBUFFER __iomem *)®->message_wbuffer; >+ uint8_t __iomem *iop_data=(uint8_t __iomem *)pwbuffer->data; >+ int32_t allxfer_len=0; >+ >+ if(acb->acb_flags & ACB_F_MESSAGE_WQBUFFER_READED) >+ { >+ acb->acb_flags &= (~ACB_F_MESSAGE_WQBUFFER_READED); >+ while((acb->wqbuf_firstindex!=acb->wqbuf_lastindex) && (allxfer_len<124)) >+ { >+ writeb(acb->wqbuffer[acb->wqbuf_firstindex], iop_data); >+ acb->wqbuf_firstindex++; >+ acb->wqbuf_firstindex %= ARCMSR_MAX_QBUFFER; /*if last index number set it to 0 */ >+ iop_data++; >+ allxfer_len++; >+ } >+ writel(allxfer_len, &pwbuffer->data_len); >+ /* >+ ** push inbound doorbell and wait reply at hwinterrupt routine for next Qbuffer post >+ */ >+ writel(ARCMSR_INBOUND_DRIVER_DATA_WRITE_OK,®->inbound_doorbell); >+ } >+ return; >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+static void arcmsr_stop_adapter_bgrb(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_stop_adapter_bgrb..............\n"); >+ #endif >+ >+ acb->acb_flags &= ~ACB_F_MSG_START_BGRB; >+ writel(ARCMSR_INBOUND_MESG0_STOP_BGRB,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: wait 'stop adapter background rebulid' timeout \n",acb->adapter_index); >+ } >+ return; >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+static void arcmsr_free_ccb_pool(struct AdapterControlBlock *acb) >+{ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ { >+ dma_free_coherent(&acb->pdev->dev,((sizeof(struct CommandControlBlock) * ARCMSR_MAX_FREECCB_NUM)+0x20),acb->dma_coherent,acb->dma_coherent_handle); >+ } >+#elif LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ { >+ pci_free_consistent(acb->pdev, ((sizeof(struct CommandControlBlock) * ARCMSR_MAX_FREECCB_NUM)+0x20), acb->dma_coherent, acb->dma_coherent_handle); >+ } >+#else >+ { >+ kfree(acb->dma_coherent); >+ } >+#endif >+ return; >+} >+/* >+********************************************************************** >+** Function: arcmsr_interrupt >+** Output: void >+** DID_OK 0x00 // NO error >+** DID_NO_CONNECT 0x01 // Couldn't connect before timeout period >+** DID_BUS_BUSY 0x02 // BUS stayed busy through time out period >+** DID_TIME_OUT 0x03 // TIMED OUT for other reason >+** DID_BAD_TARGET 0x04 // BAD target. >+** DID_ABORT 0x05 // Told to abort for some other reason >+** DID_PARITY 0x06 // Parity error >+** DID_ERROR 0x07 // Internal error >+** DID_RESET 0x08 // Reset by somebody. >+** DID_BAD_INTR 0x09 // Got an interrupt we weren't expecting. >+** DID_PASSTHROUGH 0x0a // Force command past mid-layer >+** DID_SOFT_ERROR 0x0b // The low level driver just wish a retry >+** DRIVER_OK 0x00 // Driver status >+********************************************************************** >+*/ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ static irqreturn_t arcmsr_interrupt(struct AdapterControlBlock *acb) >+#else >+ static void arcmsr_interrupt(struct AdapterControlBlock *acb) >+#endif >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct CommandControlBlock *ccb; >+ uint32_t flag_ccb,outbound_intstatus,outbound_doorbell; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_interrupt...................................\n"); >+ #endif >+ >+ outbound_intstatus=readl(®->outbound_intstatus) & acb->outbound_int_enable; >+ writel(outbound_intstatus,®->outbound_intstatus);/*clear interrupt*/ >+ if(outbound_intstatus & ARCMSR_MU_OUTBOUND_DOORBELL_INT) >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_interrupt:..........ARCMSR_MU_OUTBOUND_DOORBELL_INT \n"); >+ #endif >+ >+ outbound_doorbell=readl(®->outbound_doorbell); >+ writel(outbound_doorbell,®->outbound_doorbell);/*clear interrupt */ >+ if(outbound_doorbell & ARCMSR_OUTBOUND_IOP331_DATA_WRITE_OK) >+ { >+ struct QBUFFER __iomem *prbuffer=(struct QBUFFER __iomem *)®->message_rbuffer; >+ uint8_t __iomem *iop_data=(uint8_t __iomem *)prbuffer->data; >+ int32_t my_empty_len,iop_len,rqbuf_firstindex,rqbuf_lastindex; >+ >+ /*check this iop data if overflow my rqbuffer*/ >+ rqbuf_lastindex=acb->rqbuf_lastindex; >+ rqbuf_firstindex=acb->rqbuf_firstindex; >+ iop_len=prbuffer->data_len; >+ my_empty_len=(rqbuf_firstindex-rqbuf_lastindex-1)&(ARCMSR_MAX_QBUFFER-1); >+ if(my_empty_len>=iop_len) >+ { >+ while(iop_len > 0) >+ { >+ acb->rqbuffer[acb->rqbuf_lastindex] = readb(iop_data); >+ acb->rqbuf_lastindex++; >+ acb->rqbuf_lastindex %= ARCMSR_MAX_QBUFFER;/*if last index number set it to 0 */ >+ iop_data++; >+ iop_len--; >+ } >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell);/*signature, let IOP331 know data has been readed */ >+ } >+ else >+ { >+ acb->acb_flags|=ACB_F_IOPDATA_OVERFLOW; >+ } >+ } >+ if(outbound_doorbell & ARCMSR_OUTBOUND_IOP331_DATA_READ_OK) >+ { >+ acb->acb_flags |= ACB_F_MESSAGE_WQBUFFER_READED; >+ >+ if(acb->wqbuf_firstindex!=acb->wqbuf_lastindex) >+ { >+ struct QBUFFER __iomem *pwbuffer=(struct QBUFFER __iomem *)®->message_wbuffer; >+ uint8_t __iomem * iop_data=(uint8_t __iomem *)pwbuffer->data; >+ int32_t allxfer_len=0; >+ >+ acb->acb_flags &= (~ACB_F_MESSAGE_WQBUFFER_READED); >+ while((acb->wqbuf_firstindex!=acb->wqbuf_lastindex) && (allxfer_len<124)) >+ { >+ writeb(acb->wqbuffer[acb->wqbuf_firstindex], iop_data); >+ acb->wqbuf_firstindex++; >+ acb->wqbuf_firstindex %= ARCMSR_MAX_QBUFFER; /*if last index number set it to 0 */ >+ iop_data++; >+ allxfer_len++; >+ } >+ writel(allxfer_len, &pwbuffer->data_len); >+ /* >+ ** push inbound doorbell tell iop driver data write ok and wait reply on next hwinterrupt for next Qbuffer post >+ */ >+ writel(ARCMSR_INBOUND_DRIVER_DATA_WRITE_OK,®->inbound_doorbell); >+ } >+ if(acb->wqbuf_firstindex==acb->wqbuf_lastindex) >+ { >+ acb->acb_flags |= ACB_F_MESSAGE_WQBUFFER_CLEARED; >+ } >+ } >+ } >+ if(outbound_intstatus & ARCMSR_MU_OUTBOUND_POSTQUEUE_INT) >+ { >+ int id,lun; >+ /* >+ ***************************************************************************** >+ ** areca cdb command done >+ ***************************************************************************** >+ */ >+ while(1) >+ { >+ if((flag_ccb=readl(®->outbound_queueport)) == 0xFFFFFFFF) >+ { >+ break;/*chip FIFO no ccb for completion already*/ >+ } >+ /* check if command done with no error*/ >+ ccb=(struct CommandControlBlock *)(acb->vir2phy_offset+(flag_ccb << 5));/*frame must be 32 bytes aligned*/ >+ if((ccb->acb!=acb) || (ccb->startdone!=ARCMSR_CCB_START)) >+ { >+ if(ccb->startdone==ARCMSR_CCB_ABORTED) >+ { >+ struct scsi_cmnd *abortcmd=ccb->pcmd; >+ printk("arcmsr%d: ccb='0x%p' isr command abort successfully \n",acb->adapter_index,ccb); >+ if(abortcmd) >+ { >+ id=abortcmd->device->id; >+ lun=abortcmd->device->lun; >+ if(acb->dev_aborts[id][lun] >= 4) >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ abortcmd->result = DID_NO_CONNECT << 16; >+ } >+ abortcmd->result |= DID_ABORT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ continue; >+ } >+ printk("arcmsr%d: isr get an illegal ccb command done acb='0x%p' ccb='0x%p' ccbacb='0x%p' startdone=0x%x ccboutstandingcount=%d \n",acb->adapter_index,acb,ccb,ccb->acb,ccb->startdone,atomic_read(&acb->ccboutstandingcount)); >+ continue; >+ } >+ id=ccb->pcmd->device->id; >+ lun=ccb->pcmd->device->lun; >+ if((flag_ccb & ARCMSR_CCBREPLY_FLAG_ERROR)==0) >+ { >+ #if ARCMSR_DEBUG >+ printk("ccb=0x%p scsi cmd=0x%x................... GOOD ..............done\n",ccb,ccb->pcmd->cmnd[0]); >+ #endif >+ >+ if(acb->devstate[id][lun]==ARECA_RAID_GONE) >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GOOD; >+ acb->dev_aborts[id][lun]=0; >+ } >+ ccb->pcmd->result=DID_OK << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ else >+ { >+ switch(ccb->arcmsr_cdb.DeviceStatus) >+ { >+ case ARCMSR_DEV_SELECT_TIMEOUT: >+ { >+ #if ARCMSR_DEBUG >+ printk("ccb=0x%p ......ARCMSR_DEV_SELECT_TIMEOUT\n",ccb); >+ #endif >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_TIME_OUT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ case ARCMSR_DEV_ABORTED: >+ case ARCMSR_DEV_INIT_FAIL: >+ { >+ #if ARCMSR_DEBUG >+ printk("ccb=0x%p .....ARCMSR_DEV_INIT_FAIL\n",ccb); >+ #endif >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_BAD_TARGET << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ case SCSISTAT_CHECK_CONDITION: >+ { >+ #if ARCMSR_DEBUG >+ printk("ccb=0x%p .....SCSISTAT_CHECK_CONDITION\n",ccb); >+ #endif >+ acb->devstate[id][lun]=ARECA_RAID_GOOD; >+ arcmsr_report_sense_info(ccb); >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ default: >+ /* error occur Q all error ccb to errorccbpending Q*/ >+ printk("arcmsr%d: scsi id=%d lun=%d isr get command error done, but got unknow DeviceStatus=0x%x \n",acb->adapter_index,id,lun,ccb->arcmsr_cdb.DeviceStatus); >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_BAD_TARGET << 16;/*unknow error or crc error just for retry*/ >+ arcmsr_ccb_complete(ccb,1); >+ break; >+ } >+ } >+ } /*drain reply FIFO*/ >+ } >+ if(!(outbound_intstatus & ARCMSR_MU_OUTBOUND_HANDLE_INT)) >+ { >+ /*it must be share irq*/ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_interrupt..........FALSE....................share irq.....\n"); >+ #endif >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ return IRQ_NONE; >+ #else >+ return; >+ #endif >+ } >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ return IRQ_HANDLED; >+#else >+ return; >+#endif >+} >+/* >+******************************************************************************* >+******************************************************************************* >+*/ >+static void arcmsr_iop_parking(struct AdapterControlBlock *acb) >+{ >+ if(acb) >+ { >+ /* stop adapter background rebuild */ >+ if(acb->acb_flags & ACB_F_MSG_START_BGRB) >+ { >+ acb->acb_flags &= ~ACB_F_MSG_START_BGRB; >+ arcmsr_stop_adapter_bgrb(acb); >+ arcmsr_flush_adapter_cache(acb); >+ } >+ } >+} >+/* >+*********************************************************************** >+************************************************************************ >+*/ >+static int arcmsr_iop_ioctlcmd(struct AdapterControlBlock *acb,int ioctl_cmd,void __user *arg) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct CMD_MESSAGE_FIELD *pcmdmessagefld; >+ dma_addr_t cmd_handle; >+ int retvalue=0; >+ /* Only let one of these through at a time */ >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd.......................................\n"); >+ #endif >+ pcmdmessagefld=pci_alloc_consistent(acb->pdev, sizeof (struct CMD_MESSAGE_FIELD), &cmd_handle); >+ if(!pcmdmessagefld) >+ { >+ return -ENOMEM; >+ } >+ if(copy_from_user(pcmdmessagefld, arg, sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue = -EFAULT; >+ goto ioctl_out; >+ } >+ if(memcmp(pcmdmessagefld->cmdmessage.Signature,"ARCMSR",6)!=0) >+ { >+ retvalue = -EINVAL; >+ goto ioctl_out; >+ } >+ switch(ioctl_cmd) >+ { >+ case ARCMSR_MESSAGE_READ_RQBUFFER: >+ { >+ unsigned long *ver_addr; >+ dma_addr_t buf_handle; >+ uint8_t *pQbuffer,*ptmpQbuffer; >+ int32_t allxfer_len=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_READ_RQBUFFER..... \n"); >+ #endif >+ ver_addr=pci_alloc_consistent(acb->pdev, 1032, &buf_handle); >+ if(!ver_addr) >+ { >+ retvalue = -ENOMEM; >+ goto ioctl_out; >+ } >+ ptmpQbuffer=(uint8_t *)ver_addr; >+ while((acb->rqbuf_firstindex!=acb->rqbuf_lastindex) && (allxfer_len<1031)) >+ { >+ /*copy READ QBUFFER to srb*/ >+ pQbuffer= &acb->rqbuffer[acb->rqbuf_firstindex]; >+ memcpy(ptmpQbuffer,pQbuffer,1); >+ acb->rqbuf_firstindex++; >+ acb->rqbuf_firstindex %= ARCMSR_MAX_QBUFFER; /*if last index number set it to 0 */ >+ ptmpQbuffer++; >+ allxfer_len++; >+ } >+ if(acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) >+ { >+ struct QBUFFER* prbuffer=(struct QBUFFER*)®->message_rbuffer; >+ uint8_t __iomem * iop_data=(uint8_t __iomem *)prbuffer->data; >+ int32_t iop_len; >+ >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ iop_len=readl(&prbuffer->data_len); >+ /*this iop data does no chance to make me overflow again here, so just do it*/ >+ while(iop_len>0) >+ { >+ acb->rqbuffer[acb->rqbuf_lastindex] = readb(iop_data); >+ acb->rqbuf_lastindex++; >+ acb->rqbuf_lastindex %= ARCMSR_MAX_QBUFFER;/*if last index number set it to 0 */ >+ iop_data++; >+ iop_len--; >+ } >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell);/*signature, let IOP331 know data has been readed */ >+ } >+ memcpy(pcmdmessagefld->messagedatabuffer,(uint8_t *)ver_addr,allxfer_len); >+ pcmdmessagefld->cmdmessage.Length=allxfer_len; >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ pci_free_consistent(acb->pdev, 1032, ver_addr, buf_handle); >+ } >+ break; >+ case ARCMSR_MESSAGE_WRITE_WQBUFFER: >+ { >+ unsigned long *ver_addr; >+ dma_addr_t buf_handle; >+ int32_t my_empty_len,user_len,wqbuf_firstindex,wqbuf_lastindex; >+ uint8_t *pQbuffer,*ptmpuserbuffer; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_WRITE_WQBUFFER..... \n"); >+ #endif >+ ver_addr=pci_alloc_consistent(acb->pdev, 1032, &buf_handle); >+ if(!ver_addr) >+ { >+ retvalue= -ENOMEM; >+ goto ioctl_out; >+ } >+ ptmpuserbuffer=(uint8_t *)ver_addr; >+ user_len=pcmdmessagefld->cmdmessage.Length; >+ memcpy(ptmpuserbuffer,pcmdmessagefld->messagedatabuffer,user_len); >+ /*check if data xfer length of this request will overflow my array qbuffer */ >+ wqbuf_lastindex=acb->wqbuf_lastindex; >+ wqbuf_firstindex=acb->wqbuf_firstindex; >+ if(wqbuf_lastindex!=wqbuf_firstindex) >+ { >+ arcmsr_post_Qbuffer(acb); >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_ERROR; >+ } >+ else >+ { >+ my_empty_len=(wqbuf_firstindex-wqbuf_lastindex-1)&(ARCMSR_MAX_QBUFFER-1); >+ if(my_empty_len>=user_len) >+ { >+ while(user_len>0) >+ { >+ /*copy srb data to wqbuffer*/ >+ pQbuffer= &acb->wqbuffer[acb->wqbuf_lastindex]; >+ memcpy(pQbuffer,ptmpuserbuffer,1); >+ acb->wqbuf_lastindex++; >+ acb->wqbuf_lastindex %= ARCMSR_MAX_QBUFFER;/*if last index number set it to 0 */ >+ ptmpuserbuffer++; >+ user_len--; >+ } >+ /*post fist Qbuffer*/ >+ if(acb->acb_flags & ACB_F_MESSAGE_WQBUFFER_CLEARED) >+ { >+ acb->acb_flags &=~ACB_F_MESSAGE_WQBUFFER_CLEARED; >+ arcmsr_post_Qbuffer(acb); >+ } >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ } >+ else >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd:invalid data xfer ............qbuffer full............ \n"); >+ #endif >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_ERROR; >+ } >+ } >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ pci_free_consistent(acb->pdev, 1032, ver_addr, buf_handle); >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_RQBUFFER: >+ { >+ uint8_t * pQbuffer=acb->rqbuffer; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_CLEAR_RQBUFFER..... \n"); >+ #endif >+ if(acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) >+ { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell);/*signature, let IOP331 know data has been readed */ >+ } >+ acb->acb_flags |= ACB_F_MESSAGE_RQBUFFER_CLEARED; >+ acb->rqbuf_firstindex=0; >+ acb->rqbuf_lastindex=0; >+ memset(pQbuffer, 0, ARCMSR_MAX_QBUFFER); >+ /*report success*/ >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_WQBUFFER: >+ { >+ uint8_t * pQbuffer=acb->wqbuffer; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_CLEAR_WQBUFFER..... \n"); >+ #endif >+ >+ if(acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) >+ { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell);/*signature, let IOP331 know data has been readed */ >+ } >+ acb->acb_flags |= (ACB_F_MESSAGE_WQBUFFER_CLEARED|ACB_F_MESSAGE_WQBUFFER_READED); >+ acb->wqbuf_firstindex=0; >+ acb->wqbuf_lastindex=0; >+ memset(pQbuffer, 0, ARCMSR_MAX_QBUFFER); >+ /*report success*/ >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_ALLQBUFFER: >+ { >+ uint8_t * pQbuffer; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_CLEAR_ALLQBUFFER..... \n"); >+ #endif >+ if(acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) >+ { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell);/*signature, let IOP331 know data has been readed */ >+ } >+ acb->acb_flags |= (ACB_F_MESSAGE_WQBUFFER_CLEARED|ACB_F_MESSAGE_RQBUFFER_CLEARED|ACB_F_MESSAGE_WQBUFFER_READED); >+ acb->rqbuf_firstindex=0; >+ acb->rqbuf_lastindex=0; >+ acb->wqbuf_firstindex=0; >+ acb->wqbuf_lastindex=0; >+ pQbuffer=acb->rqbuffer; >+ memset(pQbuffer, 0, sizeof(struct QBUFFER)); >+ pQbuffer=acb->wqbuffer; >+ memset(pQbuffer, 0, sizeof(struct QBUFFER)); >+ /*report success*/ >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ } >+ break; >+ case ARCMSR_MESSAGE_RETURN_CODE_3F: >+ { >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_RETURNCODE_3F..... \n"); >+ #endif >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_3F; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ } >+ break; >+ case ARCMSR_MESSAGE_SAY_HELLO: >+ { >+ int8_t * hello_string="Hello! I am ARCMSR"; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_ioctlcmd: ARCMSR_MESSAGE_SAY_HELLO..... \n"); >+ #endif >+ memcpy(pcmdmessagefld->messagedatabuffer,hello_string,(int16_t)strlen(hello_string)); >+ pcmdmessagefld->cmdmessage.ReturnCode=ARCMSR_MESSAGE_RETURNCODE_OK; >+ if(copy_to_user(arg,pcmdmessagefld,sizeof (struct CMD_MESSAGE_FIELD))!=0) >+ { >+ retvalue= -EFAULT; >+ } >+ } >+ break; >+ case ARCMSR_MESSAGE_SAY_GOODBYE: >+ { >+ arcmsr_iop_parking(acb); >+ } >+ break; >+ case ARCMSR_MESSAGE_FLUSH_ADAPTER_CACHE: >+ { >+ arcmsr_flush_adapter_cache(acb); >+ } >+ break; >+ default: >+ retvalue= -EFAULT; >+ } >+ioctl_out: >+ pci_free_consistent(acb->pdev, sizeof (struct CMD_MESSAGE_FIELD), pcmdmessagefld, cmd_handle); >+ return retvalue; >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+int arcmsr_ioctl(struct scsi_device *dev,int ioctl_cmd,void __user *arg) >+{ >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ int32_t match=0x55AA,i; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_ioctl..................................................... \n"); >+ #endif >+ >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ acb=pHCBARC->acb[i]; >+ if(acb) >+ { >+ if(acb->host==dev->host) >+ { >+ match=i; >+ break; >+ } >+ } >+ } >+ if(match==0x55AA) >+ { >+ return -ENODEV; >+ } >+ if(!arg) >+ { >+ return -EINVAL; >+ } >+ return(arcmsr_iop_ioctlcmd(acb,ioctl_cmd,arg)); >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+static int arcmsr_iop_message_xfer(struct AdapterControlBlock *acb, struct scsi_cmnd *cmd) >+{ >+ struct MessageUnit __iomem *reg = acb->pmu; >+ struct CMD_MESSAGE_FIELD *pcmdmessagefld; >+ int retvalue = 0, transfer_len = 0; >+ char *buffer; >+ uint32_t controlcode = (uint32_t ) cmd->cmnd[5] << 24 | >+ (uint32_t ) cmd->cmnd[6] << 16 | >+ (uint32_t ) cmd->cmnd[7] << 8 | >+ (uint32_t ) cmd->cmnd[8]; >+ /* 4 bytes: Areca io control code */ >+ if (cmd->use_sg) { >+ struct scatterlist *sg = (struct scatterlist *)cmd->request_buffer; >+ >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ buffer = kmap_atomic(sg->page, KM_IRQ0) + sg->offset; >+ #else >+ buffer = sg->address; >+ #endif >+ if (cmd->use_sg > 1) { >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ goto message_out; >+ } >+ transfer_len += sg->length; >+ } else { >+ buffer = cmd->request_buffer; >+ transfer_len = cmd->request_bufflen; >+ } >+ if (transfer_len > sizeof(struct CMD_MESSAGE_FIELD)) { >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ goto message_out; >+ } >+ pcmdmessagefld = (struct CMD_MESSAGE_FIELD *) buffer; >+ switch(controlcode) { >+ case ARCMSR_MESSAGE_READ_RQBUFFER: { >+ unsigned long *ver_addr; >+ dma_addr_t buf_handle; >+ uint8_t *pQbuffer, *ptmpQbuffer; >+ int32_t allxfer_len = 0; >+ >+ ver_addr = pci_alloc_consistent(acb->pdev, 1032, &buf_handle); >+ if (!ver_addr) { >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ goto message_out; >+ } >+ ptmpQbuffer = (uint8_t *) ver_addr; >+ while ((acb->rqbuf_firstindex != acb->rqbuf_lastindex) >+ && (allxfer_len < 1031)) { >+ pQbuffer = &acb->rqbuffer[acb->rqbuf_firstindex]; >+ memcpy(ptmpQbuffer, pQbuffer, 1); >+ acb->rqbuf_firstindex++; >+ acb->rqbuf_firstindex %= ARCMSR_MAX_QBUFFER; >+ ptmpQbuffer++; >+ allxfer_len++; >+ } >+ if (acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) { >+ struct QBUFFER __iomem * prbuffer = (struct QBUFFER __iomem *) >+ ®->message_rbuffer; >+ uint8_t __iomem * iop_data = (uint8_t __iomem *)prbuffer->data; >+ int32_t iop_len; >+ >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ iop_len = readl(&prbuffer->data_len); >+ while (iop_len > 0) { >+ acb->rqbuffer[acb->rqbuf_lastindex] = readb(iop_data); >+ acb->rqbuf_lastindex++; >+ acb->rqbuf_lastindex %= ARCMSR_MAX_QBUFFER; >+ iop_data++; >+ iop_len--; >+ } >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK, >+ ®->inbound_doorbell); >+ } >+ memcpy(pcmdmessagefld->messagedatabuffer, >+ (uint8_t *)ver_addr, allxfer_len); >+ pcmdmessagefld->cmdmessage.Length = allxfer_len; >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_OK; >+ pci_free_consistent(acb->pdev, 1032, ver_addr, buf_handle); >+ } >+ break; >+ case ARCMSR_MESSAGE_WRITE_WQBUFFER: { >+ unsigned long *ver_addr; >+ dma_addr_t buf_handle; >+ int32_t my_empty_len, user_len, wqbuf_firstindex, wqbuf_lastindex; >+ uint8_t *pQbuffer, *ptmpuserbuffer; >+ >+ ver_addr = pci_alloc_consistent(acb->pdev, 1032, &buf_handle); >+ if (!ver_addr) { >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ goto message_out; >+ } >+ ptmpuserbuffer = (uint8_t *)ver_addr; >+ user_len = pcmdmessagefld->cmdmessage.Length; >+ memcpy(ptmpuserbuffer, pcmdmessagefld->messagedatabuffer, user_len); >+ wqbuf_lastindex = acb->wqbuf_lastindex; >+ wqbuf_firstindex = acb->wqbuf_firstindex; >+ if (wqbuf_lastindex != wqbuf_firstindex) { >+ struct SENSE_DATA *sensebuffer = >+ (struct SENSE_DATA *)cmd->sense_buffer; >+ arcmsr_post_Qbuffer(acb); >+ /* has error report sensedata */ >+ sensebuffer->ErrorCode = 0x70; >+ sensebuffer->SenseKey = ILLEGAL_REQUEST; >+ sensebuffer->AdditionalSenseLength = 0x0A; >+ sensebuffer->AdditionalSenseCode = 0x20; >+ sensebuffer->Valid = 1; >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ } else { >+ my_empty_len = (wqbuf_firstindex-wqbuf_lastindex - 1) >+ &(ARCMSR_MAX_QBUFFER - 1); >+ if (my_empty_len >= user_len) { >+ while (user_len > 0) { >+ pQbuffer = >+ &acb->wqbuffer[acb->wqbuf_lastindex]; >+ memcpy(pQbuffer, ptmpuserbuffer, 1); >+ acb->wqbuf_lastindex++; >+ acb->wqbuf_lastindex %= ARCMSR_MAX_QBUFFER; >+ ptmpuserbuffer++; >+ user_len--; >+ } >+ if (acb->acb_flags & ACB_F_MESSAGE_WQBUFFER_CLEARED) { >+ acb->acb_flags &= >+ ~ACB_F_MESSAGE_WQBUFFER_CLEARED; >+ arcmsr_post_Qbuffer(acb); >+ } >+ } else { >+ /* has error report sensedata */ >+ struct SENSE_DATA *sensebuffer = >+ (struct SENSE_DATA *)cmd->sense_buffer; >+ sensebuffer->ErrorCode = 0x70; >+ sensebuffer->SenseKey = ILLEGAL_REQUEST; >+ sensebuffer->AdditionalSenseLength = 0x0A; >+ sensebuffer->AdditionalSenseCode = 0x20; >+ sensebuffer->Valid = 1; >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ } >+ } >+ pci_free_consistent(acb->pdev, 1032, ver_addr, buf_handle); >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_RQBUFFER: { >+ uint8_t *pQbuffer = acb->rqbuffer; >+ >+ if (acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK, >+ ®->inbound_doorbell); >+ } >+ acb->acb_flags |= ACB_F_MESSAGE_RQBUFFER_CLEARED; >+ acb->rqbuf_firstindex = 0; >+ acb->rqbuf_lastindex = 0; >+ memset(pQbuffer, 0, ARCMSR_MAX_QBUFFER); >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_OK; >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_WQBUFFER: { >+ uint8_t *pQbuffer = acb->wqbuffer; >+ >+ if (acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK >+ , ®->inbound_doorbell); >+ } >+ acb->acb_flags |= >+ (ACB_F_MESSAGE_WQBUFFER_CLEARED | ACB_F_MESSAGE_WQBUFFER_READED); >+ acb->wqbuf_firstindex = 0; >+ acb->wqbuf_lastindex = 0; >+ memset(pQbuffer, 0, ARCMSR_MAX_QBUFFER); >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_OK; >+ } >+ break; >+ case ARCMSR_MESSAGE_CLEAR_ALLQBUFFER: { >+ uint8_t *pQbuffer; >+ >+ if (acb->acb_flags & ACB_F_IOPDATA_OVERFLOW) { >+ acb->acb_flags &= ~ACB_F_IOPDATA_OVERFLOW; >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK >+ , ®->inbound_doorbell); >+ } >+ acb->acb_flags |= >+ (ACB_F_MESSAGE_WQBUFFER_CLEARED >+ | ACB_F_MESSAGE_RQBUFFER_CLEARED >+ | ACB_F_MESSAGE_WQBUFFER_READED); >+ acb->rqbuf_firstindex = 0; >+ acb->rqbuf_lastindex = 0; >+ acb->wqbuf_firstindex = 0; >+ acb->wqbuf_lastindex = 0; >+ pQbuffer = acb->rqbuffer; >+ memset(pQbuffer, 0, sizeof (struct QBUFFER)); >+ pQbuffer = acb->wqbuffer; >+ memset(pQbuffer, 0, sizeof (struct QBUFFER)); >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_OK; >+ } >+ break; >+ case ARCMSR_MESSAGE_RETURN_CODE_3F: { >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_3F; >+ } >+ break; >+ case ARCMSR_MESSAGE_SAY_HELLO: { >+ int8_t * hello_string = "Hello! I am ARCMSR"; >+ >+ memcpy(pcmdmessagefld->messagedatabuffer, hello_string >+ , (int16_t)strlen(hello_string)); >+ pcmdmessagefld->cmdmessage.ReturnCode = ARCMSR_MESSAGE_RETURNCODE_OK; >+ } >+ break; >+ case ARCMSR_MESSAGE_SAY_GOODBYE: >+ arcmsr_iop_parking(acb); >+ break; >+ case ARCMSR_MESSAGE_FLUSH_ADAPTER_CACHE: >+ arcmsr_flush_adapter_cache(acb); >+ break; >+ default: >+ retvalue = ARCMSR_MESSAGE_FAIL; >+ } >+message_out: >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ if (cmd->use_sg) { >+ struct scatterlist *sg; >+ >+ sg = (struct scatterlist *) cmd->request_buffer; >+ kunmap_atomic(buffer - sg->offset, KM_IRQ0); >+ } >+ #endif >+ return retvalue; >+} >+/* >+************************************************************************** >+************************************************************************** >+*/ >+static struct CommandControlBlock * arcmsr_get_freeccb(struct AdapterControlBlock *acb) >+{ >+ struct list_head *head = &acb->ccb_free_list; >+ struct CommandControlBlock *ccb=NULL; >+ >+ if (!list_empty(head)) >+ { >+ ccb = list_entry(head->next, struct CommandControlBlock, list); >+ list_del(head->next); >+ } >+ return(ccb); >+} >+/* >+*********************************************************************** >+*********************************************************************** >+*/ >+int arcmsr_queue_command(struct scsi_cmnd *cmd,void (* done)(struct scsi_cmnd *)) >+{ >+ struct Scsi_Host *host = cmd->device->host; >+ struct AdapterControlBlock *acb=(struct AdapterControlBlock *) host->hostdata; >+ struct CommandControlBlock *ccb; >+ int target=cmd->device->id; >+ int lun=cmd->device->lun; >+ uint8_t scsicmd = cmd->cmnd[0]; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_queue_command:Cmd=%2x,TargetId=%d,Lun=%d \n",scsicmd,target,lun); >+ #endif >+ cmd->scsi_done=done; >+ cmd->host_scribble=NULL; >+ cmd->result=0; >+ if(scsicmd==SYNCHRONIZE_CACHE) >+ { >+ if(acb->devstate[target][lun]==ARECA_RAID_GONE) >+ { >+ cmd->result=(DID_NO_CONNECT << 16); >+ } >+ cmd->scsi_done(cmd); >+ return(0); >+ } >+ if (acb->acb_flags & ACB_F_BUS_RESET) { >+ printk(KERN_NOTICE "arcmsr%d: bus reset" >+ " and return busy \n" >+ , acb->host->host_no); >+ return SCSI_MLQUEUE_HOST_BUSY; >+ } >+ if(target == 16) { >+ /* virtual device for iop message transfer */ >+ switch(scsicmd) { >+ case INQUIRY: { >+ unsigned char inqdata[36]; >+ char *buffer; >+ >+ if(lun != 0) { >+ cmd->result = (DID_TIME_OUT << 16); >+ cmd->scsi_done(cmd); >+ return 0; >+ } >+ inqdata[0] = TYPE_PROCESSOR; >+ /* Periph Qualifier & Periph Dev Type */ >+ inqdata[1] = 0; >+ /* rem media bit & Dev Type Modifier */ >+ inqdata[2] = 0; >+ /* ISO,ECMA,& ANSI versions */ >+ inqdata[4] = 31; >+ /* length of additional data */ >+ strncpy(&inqdata[8], "Areca ", 8); >+ /* Vendor Identification */ >+ strncpy(&inqdata[16], "RAID controller ", 16); >+ /* Product Identification */ >+ strncpy(&inqdata[32], "R001", 4); /* Product Revision */ >+ if (cmd->use_sg) { >+ struct scatterlist *sg; >+ >+ sg = (struct scatterlist *) cmd->request_buffer; >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ buffer = kmap_atomic(sg->page, KM_IRQ0) + sg->offset; >+ #else >+ buffer = sg->address; >+ #endif >+ } else { >+ buffer = cmd->request_buffer; >+ } >+ memcpy(buffer, inqdata, sizeof(inqdata)); >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ if (cmd->use_sg) { >+ struct scatterlist *sg; >+ >+ sg = (struct scatterlist *) cmd->request_buffer; >+ kunmap_atomic(buffer - sg->offset, KM_IRQ0); >+ } >+ #endif >+ cmd->scsi_done(cmd); >+ return 0; >+ } >+ case WRITE_BUFFER: >+ case READ_BUFFER: { >+ if (arcmsr_iop_message_xfer(acb, cmd)) { >+ cmd->result = (DID_ERROR << 16); >+ } >+ cmd->scsi_done(cmd); >+ return 0; >+ } >+ default: >+ cmd->scsi_done(cmd); >+ return 0; >+ } >+ } >+ if(acb->devstate[target][lun]==ARECA_RAID_GONE) >+ { >+ uint8_t block_cmd; >+ >+ block_cmd=scsicmd & 0x0f; >+ if(block_cmd==0x08 || block_cmd==0x0a) >+ { >+ printk("arcmsr%d: block 'read/write' command with gone raid volume Cmd=%2x,TargetId=%d,Lun=%d \n",acb->adapter_index,scsicmd,target,lun); >+ cmd->result=(DID_NO_CONNECT << 16); >+ cmd->scsi_done(cmd); >+ return(0); >+ } >+ } >+ if (atomic_read(&acb->ccboutstandingcount) >= >+ ARCMSR_MAX_OUTSTANDING_CMD) >+ return SCSI_MLQUEUE_HOST_BUSY; >+ >+ ccb=arcmsr_get_freeccb(acb); >+ if (!ccb) >+ return SCSI_MLQUEUE_HOST_BUSY; >+ arcmsr_build_ccb(acb, ccb, cmd); >+ arcmsr_post_ccb(acb, ccb); >+ return 0; >+} >+/* >+********************************************************************** >+** get firmware miscellaneous data >+********************************************************************** >+*/ >+static void arcmsr_get_firmware_spec(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ char *acb_firm_model=acb->firm_model; >+ char *acb_firm_version=acb->firm_version; >+ char *iop_firm_model=(char *) (®->message_rwbuffer[15]); /*firm_model,15,60-67*/ >+ char *iop_firm_version=(char *) (®->message_rwbuffer[17]); /*firm_version,17,68-83*/ >+ int count; >+ >+ writel(ARCMSR_INBOUND_MESG0_GET_CONFIG,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: wait 'get adapter firmware miscellaneous data' timeout \n",acb->adapter_index); >+ } >+ count=8; >+ while(count) >+ { >+ *acb_firm_model=readb(iop_firm_model); >+ acb_firm_model++; >+ iop_firm_model++; >+ count--; >+ } >+ count=16; >+ while(count) >+ { >+ *acb_firm_version=readb(iop_firm_version); >+ acb_firm_version++; >+ iop_firm_version++; >+ count--; >+ } >+ printk("ARECA RAID ADAPTER%d: FIRMWARE VERSION %s \n",acb->adapter_index,acb->firm_version); >+ acb->firm_request_len=readl(®->message_rwbuffer[1]); /*firm_request_len,1,04-07*/ >+ acb->firm_numbers_queue=readl(®->message_rwbuffer[2]); /*firm_numbers_queue,2,08-11*/ >+ acb->firm_sdram_size=readl(®->message_rwbuffer[3]); /*firm_sdram_size,3,12-15*/ >+ acb->firm_ide_channels=readl(®->message_rwbuffer[4]); /*firm_ide_channels,4,16-19*/ >+ return; >+} >+/* >+********************************************************************** >+** start background rebulid >+********************************************************************** >+*/ >+static void arcmsr_start_adapter_bgrb(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_start_adapter_bgrb.................................. \n"); >+ #endif >+ >+ acb->acb_flags |= ACB_F_MSG_START_BGRB; >+ writel(ARCMSR_INBOUND_MESG0_START_BGRB,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: wait 'start adapter background rebulid' timeout \n",acb->adapter_index); >+ } >+ return; >+} >+/* >+********************************************************************** >+********************************************************************** >+*/ >+static void arcmsr_polling_ccbdone(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct CommandControlBlock *ccb; >+ uint32_t flag_ccb,outbound_intstatus,poll_ccb_done=0,poll_count=0; >+ int id,lun; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_polling_ccbdone.................................. \n"); >+ #endif >+polling_ccb_retry: >+ poll_count++; >+ outbound_intstatus=readl(®->outbound_intstatus) & acb->outbound_int_enable; >+ writel(outbound_intstatus,®->outbound_intstatus);/*clear interrupt*/ >+ while(1) >+ { >+ if((flag_ccb=readl(®->outbound_queueport))==0xFFFFFFFF) >+ { >+ if(poll_ccb_done) >+ { >+ break;/*chip FIFO no ccb for completion already*/ >+ } >+ else >+ { >+ arc_mdelay(25); >+ if(poll_count > 100) >+ { >+ break; >+ } >+ goto polling_ccb_retry; >+ } >+ } >+ /* check if command done with no error*/ >+ ccb=(struct CommandControlBlock *)(acb->vir2phy_offset+(flag_ccb << 5));/*frame must be 32 bytes aligned*/ >+ if((ccb->acb!=acb) || (ccb->startdone!=ARCMSR_CCB_START)) >+ { >+ if(ccb->startdone==ARCMSR_CCB_ABORTED) >+ { >+ id=ccb->pcmd->device->id; >+ lun=ccb->pcmd->device->lun; >+ printk("arcmsr%d: scsi id=%d lun=%d ccb='0x%p' poll command abort successfully \n",acb->adapter_index,id,lun,ccb); >+ if(acb->dev_aborts[id][lun] >= 4) >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result = DID_NO_CONNECT << 16; >+ } >+ ccb->pcmd->result |= DID_ABORT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ poll_ccb_done=1; >+ continue; >+ } >+ printk("arcmsr%d: polling get an illegal ccb command done ccb='0x%p' ccboutstandingcount=%d \n",acb->adapter_index,ccb,atomic_read(&acb->ccboutstandingcount)); >+ continue; >+ } >+ id=ccb->pcmd->device->id; >+ lun=ccb->pcmd->device->lun; >+ if((flag_ccb & ARCMSR_CCBREPLY_FLAG_ERROR)==0) >+ { >+ if(acb->devstate[id][lun]==ARECA_RAID_GONE) >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GOOD; >+ } >+ ccb->pcmd->result=DID_OK << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ else >+ { >+ switch(ccb->arcmsr_cdb.DeviceStatus) >+ { >+ case ARCMSR_DEV_SELECT_TIMEOUT: >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_TIME_OUT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ case ARCMSR_DEV_ABORTED: >+ case ARCMSR_DEV_INIT_FAIL: >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_BAD_TARGET << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ case SCSISTAT_CHECK_CONDITION: >+ { >+ acb->devstate[id][lun]=ARECA_RAID_GOOD; >+ arcmsr_report_sense_info(ccb); >+ arcmsr_ccb_complete(ccb,1); >+ } >+ break; >+ default: >+ /* error occur Q all error ccb to errorccbpending Q*/ >+ printk("arcmsr%d: scsi id=%d lun=%d polling and getting command error done, but got unknow DeviceStatus=0x%x \n",acb->adapter_index,id,lun,ccb->arcmsr_cdb.DeviceStatus); >+ acb->devstate[id][lun]=ARECA_RAID_GONE; >+ ccb->pcmd->result=DID_BAD_TARGET << 16;/*unknow error or crc error just for retry*/ >+ arcmsr_ccb_complete(ccb,1); >+ break; >+ } >+ } >+ } /*drain reply FIFO*/ >+ return; >+} >+/* >+********************************************************************** >+** start background rebulid >+********************************************************************** >+*/ >+static void arcmsr_iop_init(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ uint32_t intmask_org,mask,outbound_doorbell,firmware_state=0; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_iop_init.................................. \n"); >+ #endif >+ do >+ { >+ firmware_state=readl(®->outbound_msgaddr1); >+ }while((firmware_state & ARCMSR_OUTBOUND_MESG1_FIRMWARE_OK)==0); >+ intmask_org=readl(®->outbound_intmask)|ARCMSR_MU_OUTBOUND_MESSAGE0_INTMASKENABLE;/*change "disable iop interrupt" to arcmsr_initialize*/ >+ arcmsr_get_firmware_spec(acb); >+ /*start background rebuild*/ >+ arcmsr_start_adapter_bgrb(acb); >+ /* clear Qbuffer if door bell ringed */ >+ outbound_doorbell=readl(®->outbound_doorbell); >+ writel(outbound_doorbell,®->outbound_doorbell);/*clear interrupt */ >+ writel(ARCMSR_INBOUND_DRIVER_DATA_READ_OK,®->inbound_doorbell); >+ /* enable outbound Post Queue,outbound message0,outbell doorbell Interrupt */ >+ mask=~(ARCMSR_MU_OUTBOUND_POSTQUEUE_INTMASKENABLE|ARCMSR_MU_OUTBOUND_DOORBELL_INTMASKENABLE); >+ writel(intmask_org & mask,®->outbound_intmask); >+ acb->outbound_int_enable = ~(intmask_org & mask) & 0x000000ff; >+ acb->acb_flags |=ACB_F_IOP_INITED; >+ return; >+} >+/* >+**************************************************************************** >+**************************************************************************** >+*/ >+int arcmsr_bus_reset(struct scsi_cmnd *cmd) >+{ >+ struct AdapterControlBlock *acb; >+ int retry=0; >+ >+ acb=(struct AdapterControlBlock *) cmd->device->host->hostdata; >+ printk("arcmsr%d: bus reset ..... \n",acb->adapter_index); >+ acb->num_resets++; >+ acb->acb_flags |= ACB_F_BUS_RESET; >+ while(atomic_read(&acb->ccboutstandingcount)!=0 && retry < 400) >+ { >+ arcmsr_interrupt(acb); >+ arc_mdelay(25); >+ retry++; >+ } >+ arcmsr_iop_reset(acb); >+ acb->acb_flags &= ~ACB_F_BUS_RESET; >+ return SUCCESS; >+} >+ >+/* >+***************************************************************************************** >+***************************************************************************************** >+*/ >+static void arcmsr_abort_one_cmd(struct AdapterControlBlock *acb, >+ struct CommandControlBlock *ccb) >+{ >+ u32 intmask; >+ >+ ccb->startdone = ARCMSR_CCB_ABORTED; >+ >+ /* >+ ** Wait for 3 sec for all command done. >+ */ >+ arc_mdelay_int(3000); >+ >+ intmask = arcmsr_disable_outbound_ints(acb); >+ arcmsr_polling_ccbdone(acb); >+ arcmsr_enable_outbound_ints(acb, intmask); >+} >+/* >+***************************************************************************************** >+***************************************************************************************** >+*/ >+int arcmsr_abort(struct scsi_cmnd *cmd) >+{ >+ struct AdapterControlBlock *acb = >+ (struct AdapterControlBlock *)cmd->device->host->hostdata; >+ int i = 0; >+ >+ printk(KERN_NOTICE >+ "arcmsr%d: abort device command of scsi id=%d lun=%d \n", >+ acb->host->host_no, cmd->device->id, cmd->device->lun); >+ acb->num_aborts++; >+ >+ /* >+ ************************************************ >+ ** the all interrupt service routine is locked >+ ** we need to handle it as soon as possible and exit >+ ************************************************ >+ */ >+ if (!atomic_read(&acb->ccboutstandingcount)) >+ return SUCCESS; >+ >+ for (i = 0; i < ARCMSR_MAX_FREECCB_NUM; i++) { >+ struct CommandControlBlock *ccb = acb->pccb_pool[i]; >+ if (ccb->startdone == ARCMSR_CCB_START && ccb->pcmd == cmd) { >+ arcmsr_abort_one_cmd(acb, ccb); >+ break; >+ } >+ } >+ return SUCCESS; >+} >+/* >+********************************************************************* >+********************************************************************* >+*/ >+const char *arcmsr_info(struct Scsi_Host *host) >+{ >+ struct AdapterControlBlock *acb = >+ (struct AdapterControlBlock *) host->hostdata; >+ static char buf[256]; >+ char *type; >+ int raid6 = 1; >+ >+ switch (acb->pdev->device) { >+ case PCI_DEVICE_ID_ARECA_1110: >+ case PCI_DEVICE_ID_ARECA_1210: >+ raid6 = 0; >+ /*FALLTHRU*/ >+ case PCI_DEVICE_ID_ARECA_1120: >+ case PCI_DEVICE_ID_ARECA_1130: >+ case PCI_DEVICE_ID_ARECA_1160: >+ case PCI_DEVICE_ID_ARECA_1170: >+ case PCI_DEVICE_ID_ARECA_1220: >+ case PCI_DEVICE_ID_ARECA_1230: >+ case PCI_DEVICE_ID_ARECA_1260: >+ case PCI_DEVICE_ID_ARECA_1270: >+ case PCI_DEVICE_ID_ARECA_1280: >+ type = "SATA"; >+ break; >+ case PCI_DEVICE_ID_ARECA_1380: >+ case PCI_DEVICE_ID_ARECA_1381: >+ case PCI_DEVICE_ID_ARECA_1680: >+ case PCI_DEVICE_ID_ARECA_1681: >+ type = "SAS"; >+ break; >+ default: >+ type = "X-TYPE"; >+ break; >+ } >+ sprintf(buf, "Areca %s Host Adapter RAID Controller%s\n %s", >+ type, raid6 ? "( RAID6 capable)" : "", >+ ARCMSR_DRIVER_VERSION); >+ return buf; >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+static int arcmsr_initialize(struct AdapterControlBlock *acb,struct pci_dev *pdev) >+{ >+ struct MessageUnit __iomem *reg; >+ uint32_t intmask_org,page_base,page_offset,mem_base_start,ccb_phyaddr_hi32; >+ dma_addr_t dma_coherent_handle,dma_addr; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ uint8_t pcicmd; >+ void *dma_coherent; >+ void __iomem *page_remapped; >+ int i,j; >+ struct CommandControlBlock *pccb_tmp; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_initialize....................................\n"); >+ #endif >+ /* Enable Busmaster/Mem */ >+ pci_read_config_byte(pdev,PCI_COMMAND,&pcicmd); >+ pci_write_config_byte(pdev,PCI_COMMAND,pcicmd|PCI_COMMAND_INVALIDATE|PCI_COMMAND_MASTER|PCI_COMMAND_MEMORY); >+ mem_base_start=(uint32_t)arcget_pcicfg_base(pdev,0); >+ page_base=mem_base_start & PAGE_MASK; >+ page_offset=mem_base_start - page_base; >+ page_remapped=ioremap(page_base,page_offset + 0x1FFF); >+ if(!page_remapped) >+ { >+ printk("arcmsr%d: memory mapping region fail \n",arcmsr_adapterCnt); >+ return -ENXIO; >+ } >+ acb->pmu=(struct MessageUnit __iomem *)(page_remapped+page_offset); >+ acb->acb_flags |= (ACB_F_MESSAGE_WQBUFFER_CLEARED|ACB_F_MESSAGE_RQBUFFER_CLEARED|ACB_F_MESSAGE_WQBUFFER_READED); >+ acb->acb_flags &= ~ACB_F_SCSISTOPADAPTER; >+ acb->irq=pdev->irq; >+ INIT_LIST_HEAD(&acb->ccb_free_list); >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ dma_coherent = dma_alloc_coherent(&pdev->dev, ARCMSR_MAX_FREECCB_NUM * sizeof(struct CommandControlBlock) + 0x20, &dma_coherent_handle, GFP_KERNEL); >+#else >+ dma_coherent = pci_alloc_consistent(pdev, ARCMSR_MAX_FREECCB_NUM * sizeof(struct CommandControlBlock) + 0x20, &dma_coherent_handle); >+#endif >+ if (!dma_coherent) >+ { >+ printk("arcmsr%d: dma_alloc_coherent got error \n",arcmsr_adapterCnt); >+ return -ENOMEM; >+ } >+ acb->dma_coherent=dma_coherent; >+ acb->dma_coherent_handle=dma_coherent_handle; >+ memset(dma_coherent, 0, ARCMSR_MAX_FREECCB_NUM * sizeof(struct CommandControlBlock)+0x20); >+ if(((unsigned long)dma_coherent & 0x1F)!=0) /*ccb address must 32 (0x20) boundary*/ >+ { >+ dma_coherent=dma_coherent+(0x20-((unsigned long)dma_coherent & 0x1F)); >+ dma_coherent_handle=dma_coherent_handle+(0x20-((unsigned long)dma_coherent_handle & 0x1F)); >+ } >+ dma_addr=dma_coherent_handle; >+ pccb_tmp=(struct CommandControlBlock *)dma_coherent; >+ for(i = 0; i < ARCMSR_MAX_FREECCB_NUM; i++) >+ { >+ pccb_tmp->cdb_shifted_phyaddr=dma_addr >> 5; >+ pccb_tmp->acb=acb; >+ acb->pccb_pool[i]=pccb_tmp; >+ list_add_tail(&pccb_tmp->list, &acb->ccb_free_list); >+ dma_addr=dma_addr+sizeof(struct CommandControlBlock); >+ pccb_tmp++; >+ } >+ acb->vir2phy_offset=(unsigned long)pccb_tmp-(unsigned long)dma_addr; >+ for(i=0;i<ARCMSR_MAX_TARGETID;i++) >+ { >+ for(j=0;j<ARCMSR_MAX_TARGETLUN;j++) >+ { >+ acb->devstate[i][j]=ARECA_RAID_GOOD; >+ } >+ } >+ reg = acb->pmu; >+ /* >+ ******************************************************************** >+ ** here we need to tell iop 331 our pccb_tmp.HighPart >+ ** if pccb_tmp.HighPart is not zero >+ ******************************************************************** >+ */ >+ ccb_phyaddr_hi32=(uint32_t) ((dma_coherent_handle>>16)>>16); >+ if(ccb_phyaddr_hi32!=0) >+ { >+ writel(ARCMSR_SIGNATURE_SET_CONFIG,®->message_rwbuffer[0]); >+ writel(ccb_phyaddr_hi32,®->message_rwbuffer[1]); >+ writel(ARCMSR_INBOUND_MESG0_SET_CONFIG,®->inbound_msgaddr0); >+ if(arcmsr_wait_msgint_ready(acb)) >+ { >+ printk("arcmsr%d: 'set ccb high part physical address' timeout \n",arcmsr_adapterCnt); >+ } >+ } >+ acb->adapter_index=arcmsr_adapterCnt; >+ pHCBARC->acb[arcmsr_adapterCnt]=acb; >+ /* disable iop all outbound interrupt */ >+ intmask_org=readl(®->outbound_intmask); >+ writel(intmask_org|ARCMSR_MU_OUTBOUND_ALL_INTMASKENABLE,®->outbound_intmask); >+ arcmsr_adapterCnt++; >+ return(0); >+} >+/* >+********************************************************************* >+********************************************************************* >+*/ >+static int arcmsr_set_info(char *buffer,int length) >+{ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_set_info.............\n"); >+ #endif >+ return (0); >+} >+/* >+********************************************************************* >+********************************************************************* >+*/ >+static void arcmsr_pcidev_disattach(struct AdapterControlBlock *acb) >+{ >+ struct MessageUnit __iomem *reg=acb->pmu; >+ struct pci_dev *pdev; >+ struct CommandControlBlock *ccb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ struct Scsi_Host *host; >+ uint32_t intmask_org; >+ int i=0,poll_count=0,have_msi=0; >+ #if ARCMSR_DEBUG >+ printk("arcmsr_pcidev_disattach.................. \n"); >+ #endif >+ >+ arcmsr_stop_adapter_bgrb(acb); >+ arcmsr_flush_adapter_cache(acb); >+ intmask_org=readl(®->outbound_intmask); >+ writel(intmask_org|ARCMSR_MU_OUTBOUND_ALL_INTMASKENABLE,®->outbound_intmask); >+ acb->acb_flags |= ACB_F_SCSISTOPADAPTER; >+ acb->acb_flags &= ~ACB_F_IOP_INITED; >+ if(atomic_read(&acb->ccboutstandingcount)!=0) >+ { >+ while(atomic_read(&acb->ccboutstandingcount)!=0 && (poll_count < 256)) >+ { >+ arcmsr_interrupt(acb); >+ arc_mdelay(25); >+ poll_count++; >+ } >+ if(atomic_read(&acb->ccboutstandingcount)!=0) >+ { >+ arcmsr_abort_allcmd(acb); >+ for(i=0;i<ARCMSR_MAX_OUTSTANDING_CMD;i++) >+ { >+ readl(®->outbound_queueport); >+ } >+ for(i=0;i<ARCMSR_MAX_FREECCB_NUM;i++) >+ { >+ ccb=acb->pccb_pool[i]; >+ if(ccb->startdone==ARCMSR_CCB_START) >+ { >+ ccb->startdone=ARCMSR_CCB_ABORTED; >+ ccb->pcmd->result=DID_ABORT << 16; >+ arcmsr_ccb_complete(ccb,1); >+ } >+ } >+ } >+ } >+ if((acb->acb_flags & ACB_F_HAVE_MSI) != 0) >+ { >+ have_msi=1; >+ } >+ host=acb->host; >+ pdev=acb->pdev; >+ iounmap(acb->pmu); >+ arcmsr_free_ccb_pool(acb); >+ pHCBARC->acb[acb->adapter_index]=NULL; /* clear record */ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ scsi_remove_host(host); >+ scsi_host_put(host); >+#else >+ scsi_unregister(host); >+#endif >+ free_irq(pdev->irq,acb); >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ #ifdef CONFIG_PCI_MSI >+ if(have_msi==1) >+ { >+ pci_disable_msi(pdev); >+ } >+ #endif >+ pci_release_regions(pdev); >+ pci_disable_device(pdev); >+ pci_set_drvdata(pdev, NULL); >+#endif >+ return; >+} >+/* >+********************************************************************* >+********************************************************************* >+*/ >+#undef SPRINTF >+#define SPRINTF(args...) pos +=sprintf(pos,## args) >+#define YESNO(YN)\ >+if(YN) SPRINTF(" Yes ");\ >+else SPRINTF(" No ") >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ int arcmsr_proc_info(struct Scsi_Host *host, char *buffer, char **start, off_t offset, int length, int inout) >+#else >+ int arcmsr_proc_info(char * buffer,char ** start,off_t offset,int length,int hostno,int inout) >+#endif >+{ >+ uint8_t i; >+ char * pos=buffer; >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_proc_info.............\n"); >+ #endif >+ if(inout) >+ { >+ return(arcmsr_set_info(buffer,length)); >+ } >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ acb=pHCBARC->acb[i]; >+ if(!acb) >+ continue; >+ SPRINTF("ARECA SATA RAID Mass Storage Host Adadpter \n"); >+ SPRINTF("Driver Version %s ",ARCMSR_DRIVER_VERSION); >+ SPRINTF("IRQ%d \n",acb->pdev->irq); >+ SPRINTF("===========================\n"); >+ } >+ *start=buffer + offset; >+ if(pos - buffer < offset) >+ { >+ return 0; >+ } >+ else if(pos - buffer - offset < length) >+ { >+ return (pos - buffer - offset); >+ } >+ else >+ { >+ return length; >+ } >+} >+/* >+************************************************************************ >+************************************************************************ >+*/ >+int arcmsr_release(struct Scsi_Host *host) >+{ >+ struct AdapterControlBlock *acb; >+ struct HCBARC *pHCBARC= &arcmsr_host_control_block; >+ uint8_t match=0xff,i; >+ >+ #if ARCMSR_DEBUG >+ printk("arcmsr_release...........................\n"); >+ #endif >+ if(!host) >+ { >+ return -ENXIO; >+ } >+ acb=(struct AdapterControlBlock *)host->hostdata; >+ if(!acb) >+ { >+ return -ENXIO; >+ } >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ if(pHCBARC->acb[i]==acb) >+ { >+ match=i; >+ } >+ } >+ if(match==0xff) >+ { >+ return -ENODEV; >+ } >+ arcmsr_pcidev_disattach(acb); >+ for(i=0;i<ARCMSR_MAX_ADAPTER;i++) >+ { >+ if(pHCBARC->acb[i]) >+ { >+ return(0); >+ } >+ } >+ unregister_chrdev(pHCBARC->arcmsr_major_number, "arcmsr"); >+ return(0); >+} >+ >diff -urN linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/arcmsr.h linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/arcmsr.h >--- linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/arcmsr.h 1970-01-01 01:00:00.000000000 +0100 >+++ linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/arcmsr.h 2006-08-10 16:41:54.000000000 +0200 >@@ -0,0 +1,5019 @@ >+/* >+*********************************************************************************************** >+** O.S : Linux >+** FILE NAME : arcmsr.h >+** BY : Erich Chen >+** Description: SCSI RAID Device Driver for >+** ARCMSR RAID Host adapter >+*********************************************************************************************** >+** Copyright (C) 2002 - 2005, Areca Technology Corporation All rights reserved. >+** >+** Web site: www.areca.com.tw >+** E-mail: erich@areca.com.tw >+** >+** This program is free software; you can redistribute it and/or modify >+** it under the terms of the GNU General Public License version 2 as >+** published by the Free Software Foundation. >+** This program is distributed in the hope that it will be useful, >+** but WITHOUT ANY WARRANTY; without even the implied warranty of >+** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the >+** GNU General Public License for more details. >+************************************************************************ >+** Redistribution and use in source and binary forms,with or without >+** modification,are permitted provided that the following conditions >+** are met: >+** 1. Redistributions of source code must retain the above copyright >+** notice,this list of conditions and the following disclaimer. >+** 2. Redistributions in binary form must reproduce the above copyright >+** notice,this list of conditions and the following disclaimer in the >+** documentation and/or other materials provided with the distribution. >+** 3. The name of the author may not be used to endorse or promote products >+** derived from this software without specific prior written permission. >+** >+** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR >+** IMPLIED WARRANTIES,INCLUDING,BUT NOT LIMITED TO,THE IMPLIED WARRANTIES >+** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. >+** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT,INDIRECT, >+** INCIDENTAL,SPECIAL,EXEMPLARY,OR CONSEQUENTIAL DAMAGES(INCLUDING,BUT >+** NOT LIMITED TO,PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, >+** DATA,OR PROFITS; OR BUSINESS INTERRUPTION)HOWEVER CAUSED AND ON ANY >+** THEORY OF LIABILITY,WHETHER IN CONTRACT,STRICT LIABILITY,OR TORT >+**(INCLUDING NEGLIGENCE OR OTHERWISE)ARISING IN ANY WAY OUT OF THE USE OF >+** THIS SOFTWARE,EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. >+************************************************************************** >+*/ >+#include <linux/config.h> >+#include <linux/version.h> >+#ifndef KERNEL_VERSION >+ #define KERNEL_VERSION(V, P, S) (((V) << 16) + ((P) << 8) + (S)) >+#endif >+#if defined(__SMP__) && !defined(CONFIG_SMP) >+ #define CONFIG_SMP >+#endif >+/* >+********************************************************************************** >+** >+********************************************************************************** >+*/ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ #define ARCMSR_MAX_OUTSTANDING_CMD 256 >+ #define ARCMSR_MAX_FREECCB_NUM 288 >+#else >+ #define ARCMSR_MAX_OUTSTANDING_CMD 230 >+ #define ARCMSR_MAX_FREECCB_NUM 240 >+#endif >+#ifndef __user >+ #define __user >+#endif >+#ifndef __iomem >+ #define __iomem >+#endif >+#define ARCMSR_DRIVER_VERSION "Driver Version 1.20.0X.13" >+#define ARCMSR_SCSI_INITIATOR_ID 255 >+#define ARCMSR_MAX_XFER_SECTORS 512 >+#define ARCMSR_MAX_TARGETID 17 /*17 max target id + 1*/ >+#define ARCMSR_MAX_TARGETLUN 8 /*8*/ >+#define ARCMSR_MAX_CMD_PERLUN ARCMSR_MAX_OUTSTANDING_CMD /* ARCMSR_MAX_FREECCB_NUM if eq. 256 will kernel panic at 2.2.x */ >+#define ARCMSR_MAX_QBUFFER 4096 /* ioctl QBUFFER */ >+#define ARCMSR_MAX_SG_ENTRIES 38 /* max 38*/ >+#define ARCMSR_MAX_ADAPTER 4 >+/* >+********************************************************************************** >+** >+********************************************************************************** >+*/ >+#ifndef PCI_VENDOR_ID_ARECA >+ #define PCI_VENDOR_ID_ARECA 0x17d3 /* Vendor ID */ >+ #define PCI_DEVICE_ID_ARECA_1110 0x1110 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1120 0x1120 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1130 0x1130 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1160 0x1160 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1170 0x1170 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1210 0x1210 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1220 0x1220 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1230 0x1230 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1260 0x1260 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1270 0x1270 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1280 0x1280 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1380 0x1380 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1381 0x1381 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1680 0x1680 /* Device ID */ >+ #define PCI_DEVICE_ID_ARECA_1681 0x1681 /* Device ID */ >+#endif >+ >+#ifndef PCI_ANY_ID >+ #define PCI_ANY_ID (~0) >+#endif >+/* >+********************************************************************************** >+** >+********************************************************************************** >+*/ >+#define dma_addr_hi32(addr) (uint32_t) ((addr>>16)>>16) >+#define dma_addr_lo32(addr) (uint32_t) (addr & 0xffffffff) >+ >+#ifndef DMA_64BIT_MASK >+ #define DMA_64BIT_MASK 0xffffffffffffffffULL >+ #define DMA_32BIT_MASK 0x00000000ffffffffULL >+#endif >+ >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,10) >+ #define arcget_pcicfg_base(pdev,n) pci_resource_start(pdev,n) >+#else >+ #define arcget_pcicfg_base(pdev,n) pdev->base_address[n] & PCI_BASE_ADDRESS_MEM_MASK >+#endif >+#if LINUX_VERSION_CODE < KERNEL_VERSION(2,3,30) >+ >+ #if (BITS_PER_LONG == 64) >+ typedef u64 dma_addr_t; >+ #else >+ typedef u32 dma_addr_t; >+ #endif >+ >+ static inline void *pci_alloc_consistent(struct pci_dev *hwdev, size_t size, dma_addr_t *dma_handle) >+ { >+ void *virt_ptr; >+ >+ virt_ptr = kmalloc(size, GFP_KERNEL); >+ *dma_handle = virt_to_bus(virt_ptr); >+ return virt_ptr; >+ } >+ #define pci_free_consistent(cookie, size, ptr, dma_ptr) kfree(ptr) >+ #define pci_map_single(cookie, address, size, dir) virt_to_bus(address) >+ #define pci_unmap_single(cookie, address, size, dir) >+#endif >+#if LINUX_VERSION_CODE >=KERNEL_VERSION(2,6,9) >+ #define arc_mdelay(msec) msleep(msec) >+ #define arc_mdelay_int(msec) msleep_interruptible(msec) >+#else >+ #define arc_mdelay(msec) mdelay(msec) >+ #define arc_mdelay_int(msec) mdelay(msec) >+#endif >+#ifndef spin_trylock_irqsave >+ #define spin_trylock_irqsave(lock, flags) \ >+ ({ \ >+ local_irq_save(flags); \ >+ spin_trylock(lock) ? \ >+ 1 : ({local_irq_restore(flags); 0;}); \ >+ }) >+#endif /* if not spin_trylock_irqsave */ >+/* >+************************************************************************ >+** MESSAGE CONTROL CODE >+************************************************************************ >+*/ >+struct CMD_MESSAGE >+{ >+ uint32_t HeaderLength; >+ uint8_t Signature[8]; >+ uint32_t Timeout; >+ uint32_t ControlCode; >+ uint32_t ReturnCode; >+ uint32_t Length; >+}; >+/* >+************************************************************************************************************ >+** IOP Message Transfer Data for user space >+************************************************************************************************************ >+*/ >+struct CMD_MESSAGE_FIELD >+{ >+ struct CMD_MESSAGE cmdmessage; /*ioctl header*/ >+ uint8_t messagedatabuffer[1032];/*areca gui program does not accept more than 1031 byte*/ >+}; >+/* IOP message transfer */ >+#define ARCMSR_MESSAGE_FAIL 0x0001 >+/*error code for StorPortLogError,ScsiPortLogError*/ >+#define ARCMSR_IOP_ERROR_ILLEGALPCI 0x0001 >+#define ARCMSR_IOP_ERROR_VENDORID 0x0002 >+#define ARCMSR_IOP_ERROR_DEVICEID 0x0002 >+#define ARCMSR_IOP_ERROR_ILLEGALCDB 0x0003 >+#define ARCMSR_IOP_ERROR_UNKNOW_CDBERR 0x0004 >+#define ARCMSR_SYS_ERROR_MEMORY_ALLOCATE 0x0005 >+#define ARCMSR_SYS_ERROR_MEMORY_CROSS4G 0x0006 >+#define ARCMSR_SYS_ERROR_MEMORY_LACK 0x0007 >+#define ARCMSR_SYS_ERROR_MEMORY_RANGE 0x0008 >+#define ARCMSR_SYS_ERROR_DEVICE_BASE 0x0009 >+#define ARCMSR_SYS_ERROR_PORT_VALIDATE 0x000A >+/*DeviceType*/ >+#define ARECA_SATA_RAID 0x90000000 >+/*FunctionCode*/ >+#define FUNCTION_READ_RQBUFFER 0x0801 >+#define FUNCTION_WRITE_WQBUFFER 0x0802 >+#define FUNCTION_CLEAR_RQBUFFER 0x0803 >+#define FUNCTION_CLEAR_WQBUFFER 0x0804 >+#define FUNCTION_CLEAR_ALLQBUFFER 0x0805 >+#define FUNCTION_RETURN_CODE_3F 0x0806 >+#define FUNCTION_SAY_HELLO 0x0807 >+#define FUNCTION_SAY_GOODBYE 0x0808 >+#define FUNCTION_FLUSH_ADAPTER_CACHE 0x0809 >+/* ARECA IO CONTROL CODE*/ >+#define ARCMSR_MESSAGE_READ_RQBUFFER ARECA_SATA_RAID | FUNCTION_READ_RQBUFFER >+#define ARCMSR_MESSAGE_WRITE_WQBUFFER ARECA_SATA_RAID | FUNCTION_WRITE_WQBUFFER >+#define ARCMSR_MESSAGE_CLEAR_RQBUFFER ARECA_SATA_RAID | FUNCTION_CLEAR_RQBUFFER >+#define ARCMSR_MESSAGE_CLEAR_WQBUFFER ARECA_SATA_RAID | FUNCTION_CLEAR_WQBUFFER >+#define ARCMSR_MESSAGE_CLEAR_ALLQBUFFER ARECA_SATA_RAID | FUNCTION_CLEAR_ALLQBUFFER >+#define ARCMSR_MESSAGE_RETURN_CODE_3F ARECA_SATA_RAID | FUNCTION_RETURN_CODE_3F >+#define ARCMSR_MESSAGE_SAY_HELLO ARECA_SATA_RAID | FUNCTION_SAY_HELLO >+#define ARCMSR_MESSAGE_SAY_GOODBYE ARECA_SATA_RAID | FUNCTION_SAY_GOODBYE >+#define ARCMSR_MESSAGE_FLUSH_ADAPTER_CACHE ARECA_SATA_RAID | FUNCTION_FLUSH_ADAPTER_CACHE >+/* ARECA IOCTL ReturnCode */ >+#define ARCMSR_MESSAGE_RETURNCODE_OK 0x00000001 >+#define ARCMSR_MESSAGE_RETURNCODE_ERROR 0x00000006 >+#define ARCMSR_MESSAGE_RETURNCODE_3F 0x0000003F >+/* >+************************************************************* >+** structure for holding DMA address data >+************************************************************* >+*/ >+#define IS_SG64_ADDR 0x01000000 /* bit24 */ >+struct SG32ENTRY /* size 8 bytes */ >+{ /* length bit 24 == 0 */ >+ uint32_t length; /* high 8 bit == flag,low 24 bit == length */ >+ uint32_t address; >+}; >+struct SG64ENTRY /* size 12 bytes */ >+{ /* length bit 24 == 1 */ >+ uint32_t length; /* high 8 bit == flag,low 24 bit == length */ >+ uint32_t address; >+ uint32_t addresshigh; >+}; >+struct SGENTRY_UNION >+{ >+ union >+ { >+ struct SG32ENTRY sg32entry; /* 30h Scatter gather address */ >+ struct SG64ENTRY sg64entry; /* 30h */ >+ }u; >+}; >+/* >+************************************************************* >+** >+************************************************************* >+*/ >+struct ARCMSR_PCIINFO >+{ >+ uint16_t vendor_id; >+ uint16_t device_id; >+ uint16_t irq; >+ uint16_t reserved; >+}; >+/* >+********************************** >+** Inquiry Data format >+** typedef struct _INQUIRYDATA >+** { >+** uint8_t DeviceType : 5; >+** uint8_t DeviceTypeQualifier : 3; >+** uint8_t DeviceTypeModifier : 7; >+** uint8_t RemovableMedia : 1; >+** uint8_t Versions; >+** uint8_t ResponseDataFormat : 4; >+** uint8_t HiSupport : 1; >+** uint8_t NormACA : 1; >+** uint8_t ReservedBit : 1; >+** uint8_t AERC : 1; >+** uint8_t AdditionalLength; >+** uint8_t Reserved[2]; >+** uint8_t SoftReset : 1; >+** uint8_t CommandQueue : 1; >+** uint8_t Reserved2 : 1; >+** uint8_t LinkedCommands : 1; >+** uint8_t Synchronous : 1; >+** uint8_t Wide16Bit : 1; >+** uint8_t Wide32Bit : 1; >+** uint8_t RelativeAddressing : 1; >+** uint8_t VendorId[8]; >+** uint8_t ProductId[16]; >+** uint8_t ProductRevisionLevel[4]; >+** uint8_t VendorSpecific[20]; >+** uint8_t Reserved3[40]; >+** } INQUIRYDATA, *PINQUIRYDATA; >+********************************** >+*/ >+struct QBUFFER >+{ >+ uint32_t data_len; >+ uint8_t data[124]; >+}; >+/* >+************************************************************************************************ >+** FIRMWARE INFO >+************************************************************************************************ >+*/ >+struct FIRMWARE_INFO >+{ >+ uint32_t signature; /*0,00-03*/ >+ uint32_t request_len; /*1,04-07*/ >+ uint32_t numbers_queue; /*2,08-11*/ >+ uint32_t sdram_size; /*3,12-15*/ >+ uint32_t ide_channels; /*4,16-19*/ >+ char vendor[40]; /*5,20-59*/ >+ char model[8]; /*15,60-67*/ >+ char firmware_ver[16]; /*17,68-83*/ >+ char device_map[16]; /*21,84-99*/ >+}; >+/* >+************************************************************************************************ >+** ARECA FIRMWARE SPEC >+************************************************************************************************ >+** Usage of IOP331 adapter >+** (All In/Out is in IOP331's view) >+** 1. Message 0 --> InitThread message and retrun code >+** 2. Doorbell is used for RS-232 emulation >+** inDoorBell : bit0 -- data in ready (DRIVER DATA WRITE OK) >+** bit1 -- data out has been read (DRIVER DATA READ OK) >+** outDooeBell: bit0 -- data out ready (IOP331 DATA WRITE OK) >+** bit1 -- data in has been read (IOP331 DATA READ OK) >+** 3. Index Memory Usage >+** offset 0xf00 : for RS232 out (request buffer) >+** offset 0xe00 : for RS232 in (scratch buffer) >+** offset 0xa00 : for inbound message code message_rwbuffer (driver to IOP331) >+** offset 0xa00 : for outbound message code message_rwbuffer (IOP331 to driver) >+** 4. RS-232 emulation >+** Currently 128 byte buffer is used >+** 1st uint32_t : Data length (1--124) >+** Byte 4--127 : Max 124 bytes of data >+** 5. PostQ >+** All SCSI Command must be sent through postQ: >+** (inbound queue port) Request frame must be 32 bytes aligned >+** # bit27--bit31 => flag for post ccb >+** # bit0--bit26 => real address (bit27--bit31) of post arcmsr_cdb >+** bit31 : 0 : 256 bytes frame >+** 1 : 512 bytes frame >+** bit30 : 0 : normal request >+** 1 : BIOS request >+** bit29 : reserved >+** bit28 : reserved >+** bit27 : reserved >+** ------------------------------------------------------------------------------- >+** (outbount queue port) Request reply >+** # bit27--bit31 => flag for reply >+** # bit0--bit26 => real address (bit27--bit31) of reply arcmsr_cdb >+** bit31 : must be 0 (for this type of reply) >+** bit30 : reserved for BIOS handshake >+** bit29 : reserved >+** bit28 : 0 : no error, ignore AdapStatus/DevStatus/SenseData >+** 1 : Error, error code in AdapStatus/DevStatus/SenseData >+** bit27 : reserved >+** 6. BIOS request >+** All BIOS request is the same with request from PostQ >+** Except : >+** Request frame is sent from configuration space >+** offset: 0x78 : Request Frame (bit30 == 1) >+** offset: 0x18 : writeonly to generate IRQ to IOP331 >+** Completion of request: >+** (bit30 == 0, bit28==err flag) >+** 7. Definition of SGL entry (structure) >+** 8. Message1 Out - Diag Status Code (????) >+** 9. Message0 message code : >+** 0x00 : NOP >+** 0x01 : Get Config ->offset 0xa00 :for outbound message code message_rwbuffer (IOP331 to driver) >+** Signature 0x87974060(4) >+** Request len 0x00000200(4) >+** # of queue 0x00000100(4) >+** SDRAM Size 0x00000100(4)-->256 MB >+** IDE Channels 0x00000008(4) >+** vendor 40 bytes char >+** model 8 bytes char >+** FirmVer 16 bytes char >+** Device Map 16 Bytes >+** FirmwareVersion DWORD <== Added for checking of new firmware capability >+** 0x02 : Set Config ->offset 0xa00 : for inbound message code message_rwbuffer (driver to IOP331) >+** Signature 0x87974063(4) >+** UPPER32 of Request Frame (4)-->Driver Only >+** 0x03 : Reset (Abort all queued Command) >+** 0x04 : Stop Background Activity >+** 0x05 : Flush Cache >+** 0x06 : Start Background Activity (re-start if background is halted) >+** 0x07 : Check If Host Command Pending (Novell May Need This Function) >+** 0x08 : Set controller time ->offset 0xa00 : for inbound message code message_rwbuffer (driver to IOP331) >+** byte 0 : 0xaa <-- signature >+** byte 1 : 0x55 <-- signature >+** byte 2 : year (04) >+** byte 3 : month (1..12) >+** byte 4 : date (1..31) >+** byte 5 : hour (0..23) >+** byte 6 : minute (0..59) >+** byte 7 : second (0..59) >+************************************************************************************************ >+*/ >+/* signature of set and get firmware config */ >+#define ARCMSR_SIGNATURE_GET_CONFIG 0x87974060 >+#define ARCMSR_SIGNATURE_SET_CONFIG 0x87974063 >+/* message code of inbound message register */ >+#define ARCMSR_INBOUND_MESG0_NOP 0x00000000 >+#define ARCMSR_INBOUND_MESG0_GET_CONFIG 0x00000001 >+#define ARCMSR_INBOUND_MESG0_SET_CONFIG 0x00000002 >+#define ARCMSR_INBOUND_MESG0_ABORT_CMD 0x00000003 >+#define ARCMSR_INBOUND_MESG0_STOP_BGRB 0x00000004 >+#define ARCMSR_INBOUND_MESG0_FLUSH_CACHE 0x00000005 >+#define ARCMSR_INBOUND_MESG0_START_BGRB 0x00000006 >+#define ARCMSR_INBOUND_MESG0_CHK331PENDING 0x00000007 >+#define ARCMSR_INBOUND_MESG0_SYNC_TIMER 0x00000008 >+/* doorbell interrupt generator */ >+#define ARCMSR_INBOUND_DRIVER_DATA_WRITE_OK 0x00000001 >+#define ARCMSR_INBOUND_DRIVER_DATA_READ_OK 0x00000002 >+#define ARCMSR_OUTBOUND_IOP331_DATA_WRITE_OK 0x00000001 >+#define ARCMSR_OUTBOUND_IOP331_DATA_READ_OK 0x00000002 >+/* ccb areca cdb flag */ >+#define ARCMSR_CCBPOST_FLAG_SGL_BSIZE 0x80000000 >+#define ARCMSR_CCBPOST_FLAG_IAM_BIOS 0x40000000 >+#define ARCMSR_CCBREPLY_FLAG_IAM_BIOS 0x40000000 >+#define ARCMSR_CCBREPLY_FLAG_ERROR 0x10000000 >+/* outbound firmware ok */ >+#define ARCMSR_OUTBOUND_MESG1_FIRMWARE_OK 0x80000000 >+/* >+****************************************************************************************************** >+** Messaging Unit (MU) of the Intel R 80331 I/O processor (80331) >+** ================================================================================================== >+** The Messaging Unit (MU) transfers data between the PCI system and the 80331 >+** notifies the respective system when new data arrives. >+** The PCI window for messaging transactions is always the first 4 Kbytes of the inbound translation. >+** window defined by: >+** 1.Inbound ATU Base Address Register 0 (IABAR0) >+** 2.Inbound ATU Limit Register 0 (IALR0) >+** All of the Messaging Unit errors are reported in the same manner as ATU errors. >+** Error conditions and status can be found in : >+** 1.ATUSR >+** 2.ATUISR >+**==================================================================================================== >+** Mechanism Quantity Assert PCI Interrupt Signals Generate I/O Processor Interrupt >+**---------------------------------------------------------------------------------------------------- >+** Message Registers 2 Inbound Optional Optional >+** 2 Outbound >+**---------------------------------------------------------------------------------------------------- >+** Doorbell Registers 1 Inbound Optional Optional >+** 1 Outbound >+**---------------------------------------------------------------------------------------------------- >+** Circular Queues 4 Circular Queues Under certain conditions Under certain conditions >+**---------------------------------------------------------------------------------------------------- >+** Index Registers 1004 32-bit Memory Locations No Optional >+**==================================================================================================== >+** PCI Memory Map: First 4 Kbytes of the ATU Inbound PCI Address Space >+**==================================================================================================== >+** 0000H Reserved >+** 0004H Reserved >+** 0008H Reserved >+** 000CH Reserved >+**------------------------------------------------------------------------ >+** 0010H Inbound Message Register 0 ] >+** 0014H Inbound Message Register 1 ] >+** 0018H Outbound Message Register 0 ] >+** 001CH Outbound Message Register 1 ] 4 Message Registers >+**------------------------------------------------------------------------ >+** 0020H Inbound Doorbell Register ] >+** 0024H Inbound Interrupt Status Register ] >+** 0028H Inbound Interrupt Mask Register ] >+** 002CH Outbound Doorbell Register ] >+** 0030H Outbound Interrupt Status Register ] >+** 0034H Outbound Interrupt Mask Register ] 2 Doorbell Registers and 4 Interrupt Registers >+**------------------------------------------------------------------------ >+** 0038H Reserved >+** 003CH Reserved >+**------------------------------------------------------------------------ >+** 0040H Inbound Queue Port ] >+** 0044H Outbound Queue Port ] 2 Queue Ports >+**------------------------------------------------------------------------ >+** 0048H Reserved >+** 004CH Reserved >+**------------------------------------------------------------------------ >+** 0050H ] >+** : ] >+** : Intel Xscale Microarchitecture Local Memory ] >+** : ] >+** 0FFCH ] 1004 Index Registers >+******************************************************************************* >+*/ >+struct MessageUnit >+{ >+ uint32_t resrved0[4]; /*0000 000F*/ >+ uint32_t inbound_msgaddr0; /*0010 0013*/ >+ uint32_t inbound_msgaddr1; /*0014 0017*/ >+ uint32_t outbound_msgaddr0; /*0018 001B*/ >+ uint32_t outbound_msgaddr1; /*001C 001F*/ >+ uint32_t inbound_doorbell; /*0020 0023*/ >+ uint32_t inbound_intstatus; /*0024 0027*/ >+ uint32_t inbound_intmask; /*0028 002B*/ >+ uint32_t outbound_doorbell; /*002C 002F*/ >+ uint32_t outbound_intstatus; /*0030 0033*/ >+ uint32_t outbound_intmask; /*0034 0037*/ >+ uint32_t reserved1[2]; /*0038 003F*/ >+ uint32_t inbound_queueport; /*0040 0043*/ >+ uint32_t outbound_queueport; /*0044 0047*/ >+ uint32_t reserved2[2]; /*0048 004F*/ >+ uint32_t reserved3[492]; /*0050 07FF ......local_buffer 492*/ >+ uint32_t reserved4[128]; /*0800 09FF 128*/ >+ uint32_t message_rwbuffer[256]; /*0a00 0DFF 256*/ >+ uint32_t message_wbuffer[32]; /*0E00 0E7F 32*/ >+ uint32_t reserved5[32]; /*0E80 0EFF 32*/ >+ uint32_t message_rbuffer[32]; /*0F00 0F7F 32*/ >+ uint32_t reserved6[32]; /*0F80 0FFF 32*/ >+}; >+/* >+************************************************************************************************ >+** size 0x1F8 (504) >+************************************************************************************************ >+*/ >+struct ARCMSR_CDB >+{ >+ uint8_t Bus; /* 00h should be 0 */ >+ uint8_t TargetID; /* 01h should be 0--15 */ >+ uint8_t LUN; /* 02h should be 0--7 */ >+ uint8_t Function; /* 03h should be 1 */ >+ >+ uint8_t CdbLength; /* 04h not used now */ >+ uint8_t sgcount; /* 05h */ >+ uint8_t Flags; /* 06h */ >+#define ARCMSR_CDB_FLAG_SGL_BSIZE 0x01 /* bit 0: 0(256) / 1(512) bytes */ >+#define ARCMSR_CDB_FLAG_BIOS 0x02 /* bit 1: 0(from driver) / 1(from BIOS) */ >+#define ARCMSR_CDB_FLAG_WRITE 0x04 /* bit 2: 0(Data in) / 1(Data out) */ >+#define ARCMSR_CDB_FLAG_SIMPLEQ 0x00 /* bit 4/3 ,00 : simple Q,01 : head of Q,10 : ordered Q */ >+#define ARCMSR_CDB_FLAG_HEADQ 0x08 >+#define ARCMSR_CDB_FLAG_ORDEREDQ 0x10 >+ uint8_t Reserved1; /* 07h */ >+ >+ uint32_t Context; /* 08h Address of this request */ >+ uint32_t DataLength; /* 0ch not used now */ >+ >+ uint8_t Cdb[16]; /* 10h SCSI CDB */ >+ /* >+ ******************************************************** >+ **Device Status : the same from SCSI bus if error occur >+ ** SCSI bus status codes. >+ ******************************************************** >+ */ >+ uint8_t DeviceStatus; /* 20h if error */ >+#define SCSISTAT_GOOD 0x00 >+#define SCSISTAT_CHECK_CONDITION 0x02 >+#define SCSISTAT_CONDITION_MET 0x04 >+#define SCSISTAT_BUSY 0x08 >+#define SCSISTAT_INTERMEDIATE 0x10 >+#define SCSISTAT_INTERMEDIATE_COND_MET 0x14 >+#define SCSISTAT_RESERVATION_CONFLICT 0x18 >+#define SCSISTAT_COMMAND_TERMINATED 0x22 >+#define SCSISTAT_QUEUE_FULL 0x28 >+#define ARCMSR_DEV_SELECT_TIMEOUT 0xF0 >+#define ARCMSR_DEV_ABORTED 0xF1 >+#define ARCMSR_DEV_INIT_FAIL 0xF2 >+ >+ uint8_t SenseData[15]; /* 21h output */ >+ >+ union >+ { >+ struct SG32ENTRY sg32entry[ARCMSR_MAX_SG_ENTRIES]; /* 30h Scatter gather address */ >+ struct SG64ENTRY sg64entry[ARCMSR_MAX_SG_ENTRIES]; /* 30h */ >+ } u; >+}; >+/* >+********************************************************************* >+** Command Control Block (SrbExtension) >+** CCB must be not cross page boundary,and the order from offset 0 >+** structure describing an ATA disk request >+** this CCB length must be 32 bytes boundary >+********************************************************************* >+*/ >+struct CommandControlBlock >+{ >+ struct ARCMSR_CDB arcmsr_cdb; /* 0-503 (size of CDB=504): arcmsr messenger scsi command descriptor size 504 bytes */ >+ uint32_t cdb_shifted_phyaddr; /* 504-507 */ >+ uint32_t reserved1; /* 508-511 */ >+#if BITS_PER_LONG == 64 >+ /* ======================512+64 bytes======================== */ >+ struct list_head list; /* 512-527 16 bytes next/prev ptrs for ccb lists */ >+ struct scsi_cmnd * pcmd; /* 528-535 8 bytes pointer of linux scsi command */ >+ struct AdapterControlBlock * acb; /* 536-543 8 bytes pointer of acb */ >+ >+ uint16_t ccb_flags; /* 544-545 */ >+ #define CCB_FLAG_READ 0x0000 >+ #define CCB_FLAG_WRITE 0x0001 >+ #define CCB_FLAG_ERROR 0x0002 >+ #define CCB_FLAG_FLUSHCACHE 0x0004 >+ #define CCB_FLAG_MASTER_ABORTED 0x0008 >+ uint16_t startdone; /* 546-547 */ >+ #define ARCMSR_CCB_DONE 0x0000 >+ #define ARCMSR_CCB_START 0x55AA >+ #define ARCMSR_CCB_ABORTED 0xAA55 >+ #define ARCMSR_CCB_ILLEGAL 0xFFFF >+ uint32_t reserved2[7]; /* 548-551 552-555 556-559 560-563 564-567 568-571 572-575 */ >+#else >+ /* ======================512+32 bytes======================== */ >+ struct list_head list; /* 512-519 8 bytes next/prev ptrs for ccb lists */ >+ struct scsi_cmnd * pcmd; /* 520-523 4 bytes pointer of linux scsi command */ >+ struct AdapterControlBlock * acb; /* 524-527 4 bytes pointer of acb */ >+ >+ uint16_t ccb_flags; /* 528-529 */ >+ #define CCB_FLAG_READ 0x0000 >+ #define CCB_FLAG_WRITE 0x0001 >+ #define CCB_FLAG_ERROR 0x0002 >+ #define CCB_FLAG_FLUSHCACHE 0x0004 >+ #define CCB_FLAG_MASTER_ABORTED 0x0008 >+ uint16_t startdone; /* 530-531 */ >+ #define ARCMSR_CCB_DONE 0x0000 >+ #define ARCMSR_CCB_START 0x55AA >+ #define ARCMSR_CCB_ABORTED 0xAA55 >+ #define ARCMSR_CCB_ILLEGAL 0xFFFF >+ uint32_t reserved2[3]; /* 532-535 536-539 540-543 */ >+#endif >+ /* ========================================================== */ >+}; >+/* >+********************************************************************* >+** Adapter Control Block >+********************************************************************* >+*/ >+struct AdapterControlBlock >+{ >+ struct pci_dev * pdev; >+ struct Scsi_Host * host; >+ unsigned long vir2phy_offset; /* Offset is used in making arc cdb physical to virtual calculations */ >+ uint32_t outbound_int_enable; >+ >+ struct MessageUnit __iomem * pmu; /* message unit ATU inbound base address0 */ >+ >+ uint8_t adapter_index; /* */ >+ uint8_t irq; >+ uint16_t acb_flags; /* */ >+#define ACB_F_SCSISTOPADAPTER 0x0001 >+#define ACB_F_MSG_STOP_BGRB 0x0002 /* stop RAID background rebuild */ >+#define ACB_F_MSG_START_BGRB 0x0004 /* stop RAID background rebuild */ >+#define ACB_F_IOPDATA_OVERFLOW 0x0008 /* iop ioctl data rqbuffer overflow */ >+#define ACB_F_MESSAGE_WQBUFFER_CLEARED 0x0010 /* ioctl clear wqbuffer */ >+#define ACB_F_MESSAGE_RQBUFFER_CLEARED 0x0020 /* ioctl clear rqbuffer */ >+#define ACB_F_MESSAGE_WQBUFFER_READED 0x0040 >+#define ACB_F_BUS_RESET 0x0080 >+#define ACB_F_IOP_INITED 0x0100 /* iop init */ >+#define ACB_F_HAVE_MSI 0x0200 >+ >+ struct CommandControlBlock * pccb_pool[ARCMSR_MAX_FREECCB_NUM]; /* used for memory free */ >+ struct list_head ccb_free_list; /* head of free ccb list */ >+ atomic_t ccboutstandingcount; >+ >+ void * dma_coherent; /* dma_coherent used for memory free */ >+ dma_addr_t dma_coherent_handle; /* dma_coherent_handle used for memory free */ >+ >+ uint8_t rqbuffer[ARCMSR_MAX_QBUFFER]; /* data collection buffer for read from 80331 */ >+ int32_t rqbuf_firstindex; /* first of read buffer */ >+ int32_t rqbuf_lastindex; /* last of read buffer */ >+ >+ uint8_t wqbuffer[ARCMSR_MAX_QBUFFER]; /* data collection buffer for write to 80331 */ >+ int32_t wqbuf_firstindex; /* first of write buffer */ >+ int32_t wqbuf_lastindex; /* last of write buffer */ >+ >+#if LINUX_VERSION_CODE < KERNEL_VERSION(2,5,0) >+ spinlock_t isr_lock; >+#endif >+ >+ uint8_t devstate[ARCMSR_MAX_TARGETID][ARCMSR_MAX_TARGETLUN]; /* id0 ..... id15,lun0...lun7 */ >+#define ARECA_RAID_GONE 0x55 >+#define ARECA_RAID_GOOD 0xaa >+ uint8_t dev_aborts[ARCMSR_MAX_TARGETID][ARCMSR_MAX_TARGETLUN]; /* id0 ..... id15,lun0...lun7 */; >+ uint32_t num_aborts; >+ uint32_t num_resets; >+ uint32_t firm_request_len; /*1,04-07*/ >+ uint32_t firm_numbers_queue; /*2,08-11*/ >+ uint32_t firm_sdram_size; /*3,12-15*/ >+ uint32_t firm_ide_channels; /*4,16-19*/ >+ char firm_model[12]; /*15,60-67*/ >+ char firm_version[20]; >+}; >+/* >+********************************************************************* >+** >+********************************************************************* >+*/ >+struct HCBARC >+{ >+ struct AdapterControlBlock * acb[ARCMSR_MAX_ADAPTER]; >+ >+ int32_t arcmsr_major_number; >+ >+ uint8_t adapterCnt; >+ uint8_t reserved[3]; >+}; >+/* >+************************************************************* >+************************************************************* >+*/ >+struct SENSE_DATA >+{ >+ uint8_t ErrorCode:7; >+#define SCSI_SENSE_CURRENT_ERRORS 0x70 >+#define SCSI_SENSE_DEFERRED_ERRORS 0x71 >+ uint8_t Valid:1; >+ uint8_t SegmentNumber; >+ uint8_t SenseKey:4; >+ uint8_t Reserved:1; >+ uint8_t IncorrectLength:1; >+ uint8_t EndOfMedia:1; >+ uint8_t FileMark:1; >+ uint8_t Information[4]; >+ uint8_t AdditionalSenseLength; >+ uint8_t CommandSpecificInformation[4]; >+ uint8_t AdditionalSenseCode; >+ uint8_t AdditionalSenseCodeQualifier; >+ uint8_t FieldReplaceableUnitCode; >+ uint8_t SenseKeySpecific[3]; >+}; >+/* >+********************************** >+** Peripheral Device Type definitions >+********************************** >+*/ >+#define SCSI_DASD 0x00 /* Direct-access Device */ >+#define SCSI_SEQACESS 0x01 /* Sequential-access device */ >+#define SCSI_PRINTER 0x02 /* Printer device */ >+#define SCSI_PROCESSOR 0x03 /* Processor device */ >+#define SCSI_WRITEONCE 0x04 /* Write-once device */ >+#define SCSI_CDROM 0x05 /* CD-ROM device */ >+#define SCSI_SCANNER 0x06 /* Scanner device */ >+#define SCSI_OPTICAL 0x07 /* Optical memory device */ >+#define SCSI_MEDCHGR 0x08 /* Medium changer device */ >+#define SCSI_COMM 0x09 /* Communications device */ >+#define SCSI_NODEV 0x1F /* Unknown or no device type*/ >+/* >+************************************************************************************************************ >+** @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ >+** 80331 PCI-to-PCI Bridge >+** PCI Configuration Space >+** >+** @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ >+** Programming Interface >+** ======================== >+** Configuration Register Address Space Groupings and Ranges >+** ============================================================= >+** Register Group Configuration Offset >+** ------------------------------------------------------------- >+** Standard PCI Configuration 00-3Fh >+** ------------------------------------------------------------- >+** Device Specific Registers 40-A7h >+** ------------------------------------------------------------- >+** Reserved A8-CBh >+** ------------------------------------------------------------- >+** Enhanced Capability List CC-FFh >+** ========================================================================================================== >+** Standard PCI [Type 1] Configuration Space Address Map >+** ********************************************************************************************************** >+** | Byte 3 | Byte 2 | Byte 1 | Byte 0 | Configu-ration Byte Offset >+** ---------------------------------------------------------------------------------------------------------- >+** | Device ID | Vendor ID | 00h >+** ---------------------------------------------------------------------------------------------------------- >+** | Primary Status | Primary Command | 04h >+** ---------------------------------------------------------------------------------------------------------- >+** | Class Code | RevID | 08h >+** ---------------------------------------------------------------------------------------------------------- >+** | reserved | Header Type | Primary MLT | Primary CLS | 0Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 10h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 14h >+** ---------------------------------------------------------------------------------------------------------- >+** | Secondary MLT | Subordinate Bus Number | Secondary Bus Number | Primary Bus Number | 18h >+** ---------------------------------------------------------------------------------------------------------- >+** | Secondary Status | I/O Limit | I/O Base | 1Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | Non-prefetchable Memory Limit Address | Non-prefetchable Memory Base Address | 20h >+** ---------------------------------------------------------------------------------------------------------- >+** | Prefetchable Memory Limit Address | Prefetchable Memory Base Address | 24h >+** ---------------------------------------------------------------------------------------------------------- >+** | Prefetchable Memory Base Address Upper 32 Bits | 28h >+** ---------------------------------------------------------------------------------------------------------- >+** | Prefetchable Memory Limit Address Upper 32 Bits | 2Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | I/O Limit Upper 16 Bits | I/O Base Upper 16 | 30h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Capabilities Pointer | 34h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 38h >+** ---------------------------------------------------------------------------------------------------------- >+** | Bridge Control | Primary Interrupt Pin | Primary Interrupt Line | 3Ch >+**============================================================================================================= >+*/ >+/* >+**============================================================================================================= >+** 0x03-0x00 : >+** Bit Default Description >+**31:16 0335h Device ID (DID): Indicates the unique device ID that is assigned to bridge by the PCI SIG. >+** ID is unique per product speed as indicated. >+**15:00 8086h Vendor ID (VID): 16-bit field which indicates that Intel is the vendor. >+**============================================================================================================= >+*/ >+#define ARCMSR_PCI2PCI_VENDORID_REG 0x00 /*word*/ >+#define ARCMSR_PCI2PCI_DEVICEID_REG 0x02 /*word*/ >+/* >+**============================================================================== >+** 0x05-0x04 : command register >+** Bit Default Description >+**15:11 00h Reserved >+** 10 0 Interrupt Disable: Disables/Enables the generation of Interrupts on the primary bus. >+** The bridge does not support interrupts. >+** 09 0 FB2B Enable: Enables/Disables the generation of fast back to back transactions on the primary bus. >+** The bridge does not generate fast back to back transactions on the primary bus. >+** 08 0 SERR# Enable (SEE): Enables primary bus SERR# assertions. >+** 0=The bridge does not assert P_SERR#. >+** 1=The bridge may assert P_SERR#, subject to other programmable criteria. >+** 07 0 Wait Cycle Control (WCC): Always returns 0bzero indicating that bridge does not perform address or data stepping, >+** 06 0 Parity Error Response (PER): Controls bridge response to a detected primary bus parity error. >+** 0=When a data parity error is detected bridge does not assert S_PERR#. >+** Also bridge does not assert P_SERR# in response to a detected address or attribute parity error. >+** 1=When a data parity error is detected bridge asserts S_PERR#. >+** The bridge also asserts P_SERR# (when enabled globally via bit(8) of this register) in response to a detected address or attribute parity error. >+** 05 0 VGA Palette Snoop Enable (VGA_PSE): Controls bridge response to VGA-compatible palette write transactions. >+** VGA palette write transactions are I/O transactions whose address bits are: P_AD[9:0] equal to 3C6h, 3C8h or 3C9h >+** P_AD[15:10] are not decoded (i.e. aliases are claimed), or are fully decoding (i.e., must be all 0's depending upon the VGA aliasing bit in the Bridge Control Register, offset 3Eh. >+** P_AD[31:16] equal to 0000h >+** 0=The bridge ignores VGA palette write transactions, unless decoded by the standard I/O address range window. >+** 1=The bridge responds to VGA palette write transactions with medium DEVSEL# timing and forwards them to the secondary bus. >+** 04 0 Memory Write and Invalidate Enable (MWIE): The bridge does not promote MW transactions to MWI transactions. >+** MWI transactions targeting resources on the opposite side of the bridge, however, are forwarded as MWI transactions. >+** 03 0 Special Cycle Enable (SCE): The bridge ignores special cycle transactions. >+** This bit is read only and always returns 0 when read >+** 02 0 Bus Master Enable (BME): Enables bridge to initiate memory and I/O transactions on the primary interface. >+** Initiation of configuration transactions is not affected by the state of this bit. >+** 0=The bridge does not initiate memory or I/O transactions on the primary interface. >+** 1=The bridge is enabled to function as an initiator on the primary interface. >+** 01 0 Memory Space Enable (MSE): Controls target response to memory transactions on the primary interface. >+** 0=The bridge target response to memory transactions on the primary interface is disabled. >+** 1=The bridge target response to memory transactions on the primary interface is enabled. >+** 00 0 I/O Space Enable (IOSE): Controls target response to I/O transactions on the primary interface. >+** 0=The bridge target response to I/O transactions on the primary interface is disabled. >+** 1=The bridge target response to I/O transactions on the primary interface is enabled. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_COMMAND_REG 0x04 /*word*/ >+#define PCI_DISABLE_INTERRUPT 0x0400 >+/* >+**============================================================================== >+** 0x07-0x06 : status register >+** Bit Default Description >+** 15 0 Detected Parity Error: The bridge sets this bit to a 1b whenever it detects an address, attribute or data parity error. >+** This bit is set regardless of the state of the PER bit in the command register. >+** 14 0 Signaled System Error: The bridge sets this bit to a 1b whenever it asserts SERR# on the primary bus. >+** 13 0 Received Master Abort: The bridge sets this bit to a 1b when, acting as the initiator on the primary bus, its transaction (with the exception of special cycles) has been terminated with a Master Abort. >+** 12 0 Received Target Abort: The bridge sets this bit to a 1b when, acting as the initiator on the primary bus, its transaction has been terminated with a Target Abort. >+** 11 0 Signaled Target Abort: The bridge sets this bit to a 1b when it, as the target of a transaction, terminates it with a Target Abort. >+** In PCI-X mode this bit is also set when it forwards a SCM with a target abort error code. >+** 10:09 01 DEVSEL# Timing: Indicates slowest response to a non-configuration command on the primary interface. >+** Returns ¡§01b¡¨ when read, indicating that bridge responds no slower than with medium timing. >+** 08 0 Master Data Parity Error: The bridge sets this bit to a 1b when all of the following conditions are true: The bridge is the current master on the primary bus >+** S_PERR# is detected asserted or is asserted by bridge >+** The Parity Error Response bit is set in the Command register >+** 07 1 Fast Back to Back Capable: Returns a 1b when read indicating that bridge is able to respond to fast back to back transactions on its primary interface. >+** 06 0 Reserved >+** 05 1 66 MHz Capable Indication: Returns a 1b when read indicating that bridge primary interface is 66 MHz capable. >+** 1 = >+** 04 1 Capabilities List Enable: Returns 1b when read indicating that bridge supports PCI standard enhanced capabilities. >+** Offset 34h (Capability Pointer register) provides the offset for the first entry in the linked list of enhanced capabilities. >+** 03 0 Interrupt Status: Reflects the state of the interrupt in the device/function. >+** The bridge does not support interrupts. >+** 02:00 000 Reserved >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_STATUS_REG 0x06 /*word: 06,07 */ >+#define ARCMSR_ADAP_66MHZ 0x20 >+/* >+**============================================================================== >+** 0x08 : revision ID >+** Bit Default Description >+** 07:00 00000000 Revision ID (RID): '00h' indicating bridge A-0 stepping. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_REVISIONID_REG 0x08 /*byte*/ >+/* >+**============================================================================== >+** 0x0b-0x09 : 0180_00 (class code 1,native pci mode ) >+** Bit Default Description >+** 23:16 06h Base Class Code (BCC): Indicates that this is a bridge device. >+** 15:08 04h Sub Class Code (SCC): Indicates this is of type PCI-to-PCI bridge. >+** 07:00 00h Programming Interface (PIF): Indicates that this is standard (non-subtractive) PCI-PCI bridge. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_CLASSCODE_REG 0x09 /*3bytes*/ >+/* >+**============================================================================== >+** 0x0c : cache line size >+** Bit Default Description >+** 07:00 00h Cache Line Size (CLS): Designates the cache line size in 32-bit dword units. >+** The contents of this register are factored into internal policy decisions associated with memory read prefetching, and the promotion of Memory Write transactions to MWI transactions. >+** Valid cache line sizes are 8 and 16 dwords. >+** When the cache line size is set to an invalid value, bridge behaves as though the cache line size was set to 00h. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_CACHELINESIZE_REG 0x0C /*byte*/ >+/* >+**============================================================================== >+** 0x0d : latency timer (number of pci clock 00-ff ) >+** Bit Default Description >+** Primary Latency Timer (PTV): >+** 07:00 00h (Conventional PCI) Conventional PCI Mode: Primary bus Master latency timer. Indicates the number of PCI clock cycles, >+** referenced from the assertion of FRAME# to the expiration of the timer, >+** when bridge may continue as master of the current transaction. All bits are writable, >+** resulting in a granularity of 1 PCI clock cycle. >+** When the timer expires (i.e., equals 00h) bridge relinquishes the bus after the first data transfer when its PCI bus grant has been deasserted. >+** or 40h (PCI-X) PCI-X Mode: Primary bus Master latency timer. >+** Indicates the number of PCI clock cycles, >+** referenced from the assertion of FRAME# to the expiration of the timer, >+** when bridge may continue as master of the current transaction. >+** All bits are writable, resulting in a granularity of 1 PCI clock cycle. >+** When the timer expires (i.e., equals 00h) bridge relinquishes the bus at the next ADB. >+** (Except in the case where MLT expires within 3 data phases of an ADB.In this case bridge continues on until it reaches the next ADB before relinquishing the bus.) >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_LATENCYTIMER_REG 0x0D /*byte*/ >+/* >+**============================================================================== >+** 0x0e : (header type,single function ) >+** Bit Default Description >+** 07 0 Multi-function device (MVD): 80331 is a single-function device. >+** 06:00 01h Header Type (HTYPE): Defines the layout of addresses 10h through 3Fh in configuration space. >+** Returns ¡§01h¡¨ when read indicating that the register layout conforms to the standard PCI-to-PCI bridge layout. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_HEADERTYPE_REG 0x0E /*byte*/ >+/* >+**============================================================================== >+** 0x0f : >+**============================================================================== >+*/ >+/* >+**============================================================================== >+** 0x13-0x10 : >+** PCI CFG Base Address #0 (0x10) >+**============================================================================== >+*/ >+/* >+**============================================================================== >+** 0x17-0x14 : >+** PCI CFG Base Address #1 (0x14) >+**============================================================================== >+*/ >+/* >+**============================================================================== >+** 0x1b-0x18 : >+** PCI CFG Base Address #2 (0x18) >+**-----------------0x1A,0x19,0x18--Bus Number Register - BNR >+** Bit Default Description >+** 23:16 00h Subordinate Bus Number (SBBN): Indicates the highest PCI bus number below this bridge. >+** Any Type 1 configuration cycle on the primary bus whose bus number is greater than the secondary bus number, >+** and less than or equal to the subordinate bus number is forwarded unaltered as a Type 1 configuration cycle on the secondary PCI bus. >+** 15:08 00h Secondary Bus Number (SCBN): Indicates the bus number of PCI to which the secondary interface is connected. >+** Any Type 1 configuration cycle matching this bus number is translated to a Type 0 configuration cycle (or a Special Cycle) before being executed on bridge's secondary PCI bus. >+** 07:00 00h Primary Bus Number (PBN): Indicates bridge primary bus number. >+** Any Type 1 configuration cycle on the primary interface with a bus number that is less than the contents of this register field does not be claimed by bridge. >+**-----------------0x1B--Secondary Latency Timer Register - SLTR >+** Bit Default Description >+** Secondary Latency Timer (STV): >+** 07:00 00h (Conventional PCI) Conventional PCI Mode: Secondary bus Master latency timer. >+** Indicates the number of PCI clock cycles,referenced from the assertion of FRAME# to the expiration of the timer, >+** when bridge may continue as master of the current transaction. All bits are writable, >+** resulting in a granularity of 1 PCI clock cycle. >+** When the timer expires (i.e., equals 00h) bridge relinquishes the bus after the first data transfer when its PCI bus grant has been deasserted. >+** or 40h (PCI-X) PCI-X Mode: Secondary bus Master latency timer. >+** Indicates the number of PCI clock cycles,referenced from the assertion of FRAME# to the expiration of the timer, >+** when bridge may continue as master of the current transaction. All bits are writable, >+** resulting in a granularity of 1 PCI clock cycle. >+** When the timer expires (i.e., equals 00h) bridge relinquishes the bus at the next ADB. >+** (Except in the case where MLT expires within 3 data phases of an ADB. In this case bridge continues on until it reaches the next ADB before relinquishing the bus) >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_BUSNUMBER_REG 0x18 /*3byte 0x1A,0x19,0x18*/ >+#define ARCMSR_PCI2PCI_SECONDARY_BUSNUMBER_REG 0x19 /*byte*/ >+#define ARCMSR_PCI2PCI_SUBORDINATE_BUSNUMBER_REG 0x1A /*byte*/ >+#define ARCMSR_PCI2PCI_SECONDARY_LATENCYTIMER_REG 0x1B /*byte*/ >+/* >+**============================================================================== >+** 0x1f-0x1c : >+** PCI CFG Base Address #3 (0x1C) >+**-----------------0x1D,0x1C--I/O Base and Limit Register - IOBL >+** Bit Default Description >+** 15:12 0h I/O Limit Address Bits [15:12]: Defines the top address of an address range to determine when to forward I/O transactions from one interface to the other. >+** These bits correspond to address lines 15:12 for 4KB alignment. >+** Bits 11:0 are assumed to be FFFh. >+** 11:08 1h I/O Limit Addressing Capability: This field is hard-wired to 1h, indicating support 32-bit I/O addressing. >+** 07:04 0h I/O Base Address Bits [15:12]: Defines the bottom address of an address range to determine when to forward I/O transactions from one interface to the other. >+** These bits correspond to address lines 15:12 for 4KB alignment. Bits 11:0 are assumed to be 000h. >+** 03:00 1h I/O Base Addressing Capability: This is hard-wired to 1h, indicating support for 32-bit I/O addressing. >+**-----------------0x1F,0x1E--Secondary Status Register - SSR >+** Bit Default Description >+** 15 0b Detected Parity Error: The bridge sets this bit to a 1b whenever it detects an address, attribute or data parity error on its secondary interface. >+** 14 0b Received System Error: The bridge sets this bit when it samples SERR# asserted on its secondary bus interface. >+** 13 0b Received Master Abort: The bridge sets this bit to a 1b when, acting as the initiator on the secondary bus, it's transaction (with the exception of special cycles) has been terminated with a Master Abort. >+** 12 0b Received Target Abort: The bridge sets this bit to a 1b when, acting as the initiator on the secondary bus, it's transaction has been terminated with a Target Abort. >+** 11 0b Signaled Target Abort: The bridge sets this bit to a 1b when it, as the target of a transaction, terminates it with a Target Abort. >+** In PCI-X mode this bit is also set when it forwards a SCM with a target abort error code. >+** 10:09 01b DEVSEL# Timing: Indicates slowest response to a non-configuration command on the secondary interface. >+** Returns ¡§01b¡¨ when read, indicating that bridge responds no slower than with medium timing. >+** 08 0b Master Data Parity Error: The bridge sets this bit to a 1b when all of the following conditions are true: >+** The bridge is the current master on the secondary bus >+** S_PERR# is detected asserted or is asserted by bridge >+** The Parity Error Response bit is set in the Command register >+** 07 1b Fast Back-to-Back Capable (FBC): Indicates that the secondary interface of bridge can receive fast back-to-back cycles. >+** 06 0b Reserved >+** 05 1b 66 MHz Capable (C66): Indicates the secondary interface of the bridge is 66 MHz capable. >+** 1 = >+** 04:00 00h Reserved >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_IO_BASE_REG 0x1C /*byte*/ >+#define ARCMSR_PCI2PCI_IO_LIMIT_REG 0x1D /*byte*/ >+#define ARCMSR_PCI2PCI_SECONDARY_STATUS_REG 0x1E /*word: 0x1F,0x1E */ >+/* >+**============================================================================== >+** 0x23-0x20 : >+** PCI CFG Base Address #4 (0x20) >+**-----------------0x23,0x22,0x21,0x20--Memory Base and Limit Register - MBL >+** Bit Default Description >+** 31:20 000h Memory Limit: These 12 bits are compared with P_AD[31:20] of the incoming address to determine >+** the upper 1MB aligned value (exclusive) of the range. >+** The incoming address must be less than or equal to this value. >+** For the purposes of address decoding the lower 20 address bits (P_AD[19:0] are assumed to be F FFFFh. >+** 19:16 0h Reserved. >+** 15:04 000h Memory Base: These 12 bits are compared with bits P_AD[31:20] of the incoming address to determine the lower 1MB aligned value (inclusive) of the range. >+** The incoming address must be greater than or equal to this value. >+** For the purposes of address decoding the lower 20 address bits (P_AD[19:0]) are assumed to be 0 0000h. >+** 03:00 0h Reserved. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_NONPREFETCHABLE_MEMORY_BASE_REG 0x20 /*word: 0x21,0x20 */ >+#define ARCMSR_PCI2PCI_NONPREFETCHABLE_MEMORY_LIMIT_REG 0x22 /*word: 0x23,0x22 */ >+/* >+**============================================================================== >+** 0x27-0x24 : >+** PCI CFG Base Address #5 (0x24) >+**-----------------0x27,0x26,0x25,0x24--Prefetchable Memory Base and Limit Register - PMBL >+** Bit Default Description >+** 31:20 000h Prefetchable Memory Limit: These 12 bits are compared with P_AD[31:20] of the incoming address to determine >+** the upper 1MB aligned value (exclusive) of the range. >+** The incoming address must be less than or equal to this value. >+** For the purposes of address decoding the lower 20 address bits (P_AD[19:0] are assumed to be F FFFFh. >+** 19:16 1h 64-bit Indicator: Indicates that 64-bit addressing is supported. >+** 15:04 000h Prefetchable Memory Base: These 12 bits are compared with bits P_AD[31:20] of the incoming address to determine the lower 1MB aligned value (inclusive) of the range. >+** The incoming address must be greater than or equal to this value. >+** For the purposes of address decoding the lower 20 address bits (P_AD[19:0]) are assumed to be 0 0000h. >+** 03:00 1h 64-bit Indicator: Indicates that 64-bit addressing is supported. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PREFETCHABLE_MEMORY_BASE_REG 0x24 /*word: 0x25,0x24 */ >+#define ARCMSR_PCI2PCI_PREFETCHABLE_MEMORY_LIMIT_REG 0x26 /*word: 0x27,0x26 */ >+/* >+**============================================================================== >+** 0x2b-0x28 : >+** Bit Default Description >+** 31:00 00000000h Prefetchable Memory Base Upper Portion: All bits are read/writable >+** bridge supports full 64-bit addressing. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PREFETCHABLE_MEMORY_BASE_UPPER32_REG 0x28 /*dword: 0x2b,0x2a,0x29,0x28 */ >+/* >+**============================================================================== >+** 0x2f-0x2c : >+** Bit Default Description >+** 31:00 00000000h Prefetchable Memory Limit Upper Portion: All bits are read/writable >+** bridge supports full 64-bit addressing. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PREFETCHABLE_MEMORY_LIMIT_UPPER32_REG 0x2C /*dword: 0x2f,0x2e,0x2d,0x2c */ >+/* >+**============================================================================== >+** 0x33-0x30 : >+** Bit Default Description >+** 07:00 DCh Capabilities Pointer: Pointer to the first CAP ID entry in the capabilities list is at DCh in PCI configuration >+** space. (Power Management Capability Registers) >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_CAPABILITIES_POINTER_REG 0x34 /*byte*/ >+/* >+**============================================================================== >+** 0x3b-0x35 : reserved >+**============================================================================== >+*/ >+/* >+**============================================================================== >+** 0x3d-0x3c : >+** >+** Bit Default Description >+** 15:08 00h Interrupt Pin (PIN): Bridges do not support the generation of interrupts. >+** 07:00 00h Interrupt Line (LINE): The bridge does not generate interrupts, so this is reserved as '00h'. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_PRIMARY_INTERRUPT_LINE_REG 0x3C /*byte*/ >+#define ARCMSR_PCI2PCI_PRIMARY_INTERRUPT_PIN_REG 0x3D /*byte*/ >+/* >+**============================================================================== >+** 0x3f-0x3e : >+** Bit Default Description >+** 15:12 0h Reserved >+** 11 0b Discard Timer SERR# Enable: Controls the generation of SERR# on the primary interface (P_SERR#) in response >+** to a timer discard on either the primary or secondary interface. >+** 0b=SERR# is not asserted. >+** 1b=SERR# is asserted. >+** 10 0b Discard Timer Status (DTS): This bit is set to a '1b' when either the primary or secondary discard timer expires. >+** The delayed completion is then discarded. >+** 09 0b Secondary Discard Timer (SDT): Sets the maximum number of PCI clock cycles that bridge waits for an initiator on the secondary bus to repeat a delayed transaction request. >+** The counter starts when the delayed transaction completion is ready to be returned to the initiator. >+** When the initiator has not repeated the transaction at least once before the counter expires,bridge discards the delayed transaction from its queues. >+** 0b=The secondary master time-out counter is 2 15 PCI clock cycles. >+** 1b=The secondary master time-out counter is 2 10 PCI clock cycles. >+** 08 0b Primary Discard Timer (PDT): Sets the maximum number of PCI clock cycles that bridge waits for an initiator on the primary bus to repeat a delayed transaction request. >+** The counter starts when the delayed transaction completion is ready to be returned to the initiator. >+** When the initiator has not repeated the transaction at least once before the counter expires, bridge discards the delayed transaction from its queues. >+** 0b=The primary master time-out counter is 2 15 PCI clock cycles. >+** 1b=The primary master time-out counter is 2 10 PCI clock cycles. >+** 07 0b Fast Back-to-Back Enable (FBE): The bridge does not initiate back to back transactions. >+** 06 0b Secondary Bus Reset (SBR): >+** When cleared to 0b: The bridge deasserts S_RST#, when it had been asserted by writing this bit to a 1b. >+** When set to 1b: The bridge asserts S_RST#. >+** 05 0b Master Abort Mode (MAM): Dictates bridge behavior on the initiator bus when a master abort termination occurs in response to a delayed transaction initiated by bridge on the target bus. >+** 0b=The bridge asserts TRDY# in response to a non-locked delayed transaction,and returns FFFF FFFFh when a read. >+** 1b=When the transaction had not yet been completed on the initiator bus (e.g.,delayed reads, or non-posted writes), >+** then bridge returns a Target Abort in response to the original requester >+** when it returns looking for its delayed completion on the initiator bus. >+** When the transaction had completed on the initiator bus (e.g., a PMW), then bridge asserts P_SERR# (when enabled). >+** For PCI-X transactions this bit is an enable for the assertion of P_SERR# due to a master abort while attempting to deliver a posted memory write on the destination bus. >+** 04 0b VGA Alias Filter Enable: This bit dictates bridge behavior in conjunction with the VGA enable bit (also of this register), >+** and the VGA Palette Snoop Enable bit (Command Register). >+** When the VGA enable, or VGA Palette Snoop enable bits are on (i.e., 1b) the VGA Aliasing bit for the corresponding enabled functionality,: >+** 0b=Ignores address bits AD[15:10] when decoding VGA I/O addresses. >+** 1b=Ensures that address bits AD[15:10] equal 000000b when decoding VGA I/O addresses. >+** When all VGA cycle forwarding is disabled, (i.e., VGA Enable bit =0b and VGA Palette Snoop bit =0b), then this bit has no impact on bridge behavior. >+** 03 0b VGA Enable: Setting this bit enables address decoding and transaction forwarding of the following VGA transactions from the primary bus to the secondary bus: >+** frame buffer memory addresses 000A0000h:000BFFFFh, VGA I/O addresses 3B0:3BBh and 3C0h:3DFh, where AD[31:16]=¡§0000h¡¨ and AD[15:10] are either not decoded (i.e., don't cares), or must be ¡§000000b¡¨ >+** depending upon the state of the VGA Alias Filter Enable bit. (bit(4) of this register) >+** I/O and Memory Enable bits must be set in the Command register to enable forwarding of VGA cycles. >+** 02 0b ISA Enable: Setting this bit enables special handling for the forwarding of ISA I/O transactions that fall within the address range specified by the I/O Base and Limit registers, and are within the lowest 64Kbyte of the I/O address map (i.e., 0000 0000h - 0000 FFFFh). >+** 0b=All I/O transactions that fall within the I/O Base and Limit registers' specified range are forwarded from primary to secondary unfiltered. >+** 1b=Blocks the forwarding from primary to secondary of the top 768 bytes of each 1Kbyte alias. On the secondary the top 768 bytes of each 1K alias are inversely decoded and forwarded from secondary to primary. >+** 01 0b SERR# Forward Enable: 0b=The bridge does not assert P_SERR# as a result of an S_SERR# assertion. >+** 1b=The bridge asserts P_SERR# whenever S_SERR# is detected asserted provided the SERR# Enable bit is set (PCI Command Register bit(8)=1b). >+** 00 0b Parity Error Response: This bit controls bridge response to a parity error that is detected on its secondary interface. >+** 0b=When a data parity error is detected bridge does not assert S_PERR#. >+** Also bridge does not assert P_SERR# in response to a detected address or attribute parity error. >+** 1b=When a data parity error is detected bridge asserts S_PERR#. The bridge also asserts P_SERR# (when enabled globally via bit(8) of the Command register) >+** in response to a detected address or attribute parity error. >+**============================================================================== >+*/ >+#define ARCMSR_PCI2PCI_BRIDGE_CONTROL_REG 0x3E /*word*/ >+/* >+************************************************************************** >+** Device Specific Registers 40-A7h >+************************************************************************** >+** ---------------------------------------------------------------------------------------------------------- >+** | Byte 3 | Byte 2 | Byte 1 | Byte 0 | Configu-ration Byte Offset >+** ---------------------------------------------------------------------------------------------------------- >+** | Bridge Control 0 | Arbiter Control/Status | Reserved | 40h >+** ---------------------------------------------------------------------------------------------------------- >+** | Bridge Control 2 | Bridge Control 1 | 44h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Bridge Status | 48h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 4Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | Prefetch Policy | Multi-Transaction Timer | 50h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Pre-boot Status | P_SERR# Assertion Control | 54h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Reserved | Secondary Decode Enable | 58h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Secondary IDSEL | 5Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 5Ch >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 68h:CBh >+** ---------------------------------------------------------------------------------------------------------- >+************************************************************************** >+**============================================================================== >+** 0x42-0x41: Secondary Arbiter Control/Status Register - SACSR >+** Bit Default Description >+** 15:12 1111b Grant Time-out Violator: This field indicates the agent that violated the Grant Time-out rule (PCI=16 clocks,PCI-X=6 clocks). >+** Note that this field is only meaningful when: >+** # Bit[11] of this register is set to 1b, indicating that a Grant Time-out violation had occurred. >+** # bridge internal arbiter is enabled. >+** Bits[15:12] Violating Agent (REQ#/GNT# pair number) >+** 0000b REQ#/GNT#[0] >+** 0001b REQ#/GNT#[1] >+** 0010b REQ#/GNT#[2] >+** 0011b REQ#/GNT#[3] >+** 1111b Default Value (no violation detected) >+** When bit[11] is cleared by software, this field reverts back to its default value. >+** All other values are Reserved >+** 11 0b Grant Time-out Occurred: When set to 1b, >+** this indicates that a Grant Time-out error had occurred involving one of the secondary bus agents. >+** Software clears this bit by writing a 1b to it. >+** 10 0b Bus Parking Control: 0=During bus idle, bridge parks the bus on the last master to use the bus. >+** 1=During bus idle, bridge parks the bus on itself. The bus grant is removed from the last master and internally asserted to bridge. >+** 09:08 00b Reserved >+** 07:00 0000 0000b Secondary Bus Arbiter Priority Configuration: The bridge secondary arbiter provides two rings of arbitration priority. >+** Each bit of this field assigns its corresponding secondary bus master to either the high priority arbiter ring (1b) or to the low priority arbiter ring (0b). >+** Bits [3:0] correspond to request inputs S_REQ#[3:0], respectively. >+** Bit [6] corresponds to the bridge internal secondary bus request while Bit [7] corresponds to the SATU secondary bus request. >+** Bits [5:4] are unused. >+** 0b=Indicates that the master belongs to the low priority group. >+** 1b=Indicates that the master belongs to the high priority group >+**================================================================================= >+** 0x43: Bridge Control Register 0 - BCR0 >+** Bit Default Description >+** 07 0b Fully Dynamic Queue Mode: 0=The number of Posted write transactions is limited to eight and the Posted Write data is limited to 4KB. >+** 1=Operation in fully dynamic queue mode. The bridge enqueues up to 14 Posted Memory Write transactions and 8KB of posted write data. >+** 06:03 0H Reserved. >+** 02 0b Upstream Prefetch Disable: This bit disables bridge ability to perform upstream prefetch operations for Memory Read requests received on its secondary interface. >+** This bit also controls the bridge's ability to generate advanced read commands when forwarding a Memory Read Block transaction request upstream from a PCI-X bus to a Conventional PCI bus. >+** 0b=bridge treats all upstream Memory Read requests as though they target prefetchable memory. The use of Memory Read Line and Memory Read >+** Multiple is enabled when forwarding a PCI-X Memory Read Block request to an upstream bus operating in Conventional PCI mode. >+** 1b=bridge treats upstream PCI Memory Read requests as though they target non-prefetchable memory and forwards upstream PCI-X Memory Read Block commands as Memory Read when the primary bus is operating in Conventional PCI mode. >+** NOTE: This bit does not affect bridge ability to perform read prefetching when the received command is Memory Read Line or Memory Read Multiple. >+**================================================================================= >+** 0x45-0x44: Bridge Control Register 1 - BCR1 (Sheet 2 of 2) >+** Bit Default Description >+** 15:08 0000000b Reserved >+** 07:06 00b Alias Command Mapping: This two bit field determines how bridge handles PCI-X ¡§Alias¡¨ commands, specifically the Alias to Memory Read Block and Alias to Memory Write Block commands. >+** The three options for handling these alias commands are to either pass it as is, re-map to the actual block memory read/write command encoding, or ignore >+** the transaction forcing a Master Abort to occur on the Origination Bus. >+** Bit (7:6) Handling of command >+** 0 0 Re-map to Memory Read/Write Block before forwarding >+** 0 1 Enqueue and forward the alias command code unaltered >+** 1 0 Ignore the transaction, forcing Master Abort >+** 1 1 Reserved >+** 05 1b Watchdog Timers Disable: Disables or enables all 2 24 Watchdog Timers in both directions. >+** The watchdog timers are used to detect prohibitively long latencies in the system. >+** The watchdog timer expires when any Posted Memory Write (PMW), Delayed Request, >+** or Split Requests (PCI-X mode) is not completed within 2 24 events >+** (¡§events¡¨ are defined as PCI Clocks when operating in PCI-X mode, and as the number of times being retried when operating in Conventional PCI mode) >+** 0b=All 2 24 watchdog timers are enabled. >+** 1b=All 2 24 watchdog timers are disabled and there is no limits to the number of attempts bridge makes when initiating a PMW, >+** transacting a Delayed Transaction, or how long it waits for a split completion corresponding to one of its requests. >+** 04 0b GRANT# time-out disable: This bit enables/disables the GNT# time-out mechanism. >+** Grant time-out is 16 clocks for conventional PCI, and 6 clocks for PCI-X. >+** 0b=The Secondary bus arbiter times out an agent that does not assert FRAME# within 16/6 clocks of receiving its grant, once the bus has gone idle. >+** The time-out counter begins as soon as the bus goes idle with the new GNT# asserted. >+** An infringing agent does not receive a subsequent GNT# until it de-asserts its REQ# for at least one clock cycle. >+** 1b=GNT# time-out mechanism is disabled. >+** 03 00b Reserved. >+** 02 0b Secondary Discard Timer Disable: This bit enables/disables bridge secondary delayed transaction discard mechanism. >+** The time out mechanism is used to ensure that initiators of delayed transactions return for their delayed completion data/status within a reasonable amount of time after it is available from bridge. >+** 0b=The secondary master time-out counter is enabled and uses the value specified by the Secondary Discard Timer bit (see Bridge Control Register). >+** 1b=The secondary master time-out counter is disabled. The bridge waits indefinitely for a secondary bus master to repeat a delayed transaction. >+** 01 0b Primary Discard Timer Disable: This bit enables/disables bridge primary delayed transaction discard mechanism. The time out mechanism is used to ensure that initiators of delayed transactions return for their delayed completion data/status within a reasonable amount of time after it is available from bridge. >+** 0b=The primary master time-out counter is enabled and uses the value specified by the Primary Discard Timer bit (see Bridge Control Register). >+** 1b=The secondary master time-out counter is disabled. The bridge waits indefinitely for a secondary bus master to repeat a delayed transaction. >+** 00 0b Reserved >+**================================================================================= >+** 0x47-0x46: Bridge Control Register 2 - BCR2 >+** Bit Default Description >+** 15:07 0000b Reserved. >+** 06 0b Global Clock Out Disable (External Secondary Bus Clock Source Enable): This bit disables all of the secondary PCI clock outputs including the feedback clock S_CLKOUT. >+** This means that the user is required to provide an S_CLKIN input source. >+** 05:04 11 (66 MHz) Preserved. >+** 01 (100 MHz) >+** 00 (133 MHz) >+** 03:00 Fh (100 MHz & 66 MHz) >+** 7h (133 MHz) >+** This 4 bit field provides individual enable/disable mask bits for each of bridge >+** secondary PCI clock outputs. Some, or all secondary clock outputs (S_CLKO[3:0]) >+** default to being enabled following the rising edge of P_RST#, depending on the >+** frequency of the secondary bus clock: >+** ¡E Designs with 100 MHz (or lower) Secondary PCI clock power up with all four S_CLKOs enabled by default. (SCLKO[3:0])¡P >+** ¡E Designs with 133 MHz Secondary PCI clock power up with the lower order 3 S_CLKOs enabled by default. (S_CLKO[2:0]) Only those SCLKs that power up enabled by can be connected to downstream device clock inputs. >+**================================================================================= >+** 0x49-0x48: Bridge Status Register - BSR >+** Bit Default Description >+** 15 0b Upstream Delayed Transaction Discard Timer Expired: This bit is set to a 1b and P_SERR# is conditionally asserted when the secondary discard timer expires. >+** 14 0b Upstream Delayed/Split Read Watchdog Timer Expired: >+** Conventional PCI Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards an upstream delayed read transaction request after 2 24 retries following the initial retry. >+** PCI-X Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards an upstream split read request after waiting in excess of 2 24 clocks for the corresponding Split Completion to arrive. >+** 13 0b Upstream Delayed/Split Write Watchdog Timer Expired: >+** Conventional PCI Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards an upstream delayed write transaction request after 2 24 retries following the initial retry. >+** PCI-X Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards an upstream split write request after waiting in excess of 2 24 clocks for the corresponding Split Completion to arrive. >+** 12 0b Master Abort during Upstream Posted Write: This bit is set to a 1b and P_SERR# is conditionally asserted when a Master Abort occurs as a result of an attempt, by bridge, to retire a PMW upstream. >+** 11 0b Target Abort during Upstream Posted Write: This bit is set to a 1b and P_SERR# is conditionally asserted when a Target Abort occurs as a result of an attempt, by bridge, to retire a PMW upstream. >+** 10 0b Upstream Posted Write Data Discarded: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards an upstream PMW transaction after receiving 2 24 target retries from the primary bus target >+** 09 0b Upstream Posted Write Data Parity Error: This bit is set to a 1b and P_SERR# is conditionally asserted when a data parity error is detected by bridge while attempting to retire a PMW upstream >+** 08 0b Secondary Bus Address Parity Error: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge detects an address parity error on the secondary bus. >+** 07 0b Downstream Delayed Transaction Discard Timer Expired: This bit is set to a 1b and P_SERR# is conditionally asserted when the primary bus discard timer expires. >+** 06 0b Downstream Delayed/Split Read Watchdog Timer Expired: >+** Conventional PCI Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards a downstream delayed read transaction request after receiving 2 24 target retries from the secondary bus target. >+** PCI-X Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards a downstream split read request after waiting in excess of 2 24 clocks for the corresponding Split Completion to arrive. >+** 05 0b Downstream Delayed Write/Split Watchdog Timer Expired: >+** Conventional PCI Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards a downstream delayed write transaction request after receiving 2 24 target retries from the secondary bus target. >+** PCI-X Mode: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards a downstream split write request after waiting in excess of 2 24 clocks for the corresponding Split Completion to arrive. >+** 04 0b Master Abort during Downstream Posted Write: This bit is set to a 1b and P_SERR# is conditionally asserted when a Master Abort occurs as a result of an attempt, by bridge, to retire a PMW downstream. >+** 03 0b Target Abort during Downstream Posted Write: This bit is set to a 1b and P_SERR# is conditionally asserted when a Target Abort occurs as a result of an attempt, by bridge, to retire a PMW downstream. >+** 02 0b Downstream Posted Write Data Discarded: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge discards a downstream PMW transaction after receiving 2 24 target retries from the secondary bus target >+** 01 0b Downstream Posted Write Data Parity Error: This bit is set to a 1b and P_SERR# is conditionally asserted when a data parity error is detected by bridge while attempting to retire a PMW downstream. >+** 00 0b Primary Bus Address Parity Error: This bit is set to a 1b and P_SERR# is conditionally asserted when bridge detects an address parity error on the primary bus. >+**================================================================================== >+** 0x51-0x50: Bridge Multi-Transaction Timer Register - BMTTR >+** Bit Default Description >+** 15:13 000b Reserved >+** 12:10 000b GRANT# Duration: This field specifies the count (PCI clocks) that a secondary bus master has its grant maintained in order to enable multiple transactions to execute within the same arbitration cycle. >+** Bit[02:00] GNT# Extended Duration >+** 000 MTT Disabled (Default=no GNT# extension) >+** 001 16 clocks >+** 010 32 clocks >+** 011 64 clocks >+** 100 128 clocks >+** 101 256 clocks >+** 110 Invalid (treated as 000) >+** 111 Invalid (treated as 000) >+** 09:08 00b Reserved >+** 07:00 FFh MTT Mask: This field enables/disables MTT usage for each REQ#/GNT# pair supported by bridge secondary arbiter. >+** Bit(7) corresponds to SATU internal REQ#/GNT# pair, >+** bit(6) corresponds to bridge internal REQ#/GNT# pair, >+** bit(5) corresponds to REQ#/GNT#(5) pair, etc. >+** When a given bit is set to 1b, its corresponding REQ#/GNT# pair is enabled for MTT functionality as determined by bits(12:10) of this register. >+** When a given bit is cleared to 0b, its corresponding REQ#/GNT# pair is disabled from using the MTT. >+**================================================================================== >+** 0x53-0x52: Read Prefetch Policy Register - RPPR >+** Bit Default Description >+** 15:13 000b ReRead_Primary Bus: 3-bit field indicating the multiplication factor to be used in calculating the number of bytes to prefetch from the secondary bus interface on subsequent PreFetch operations given that the read demands were not satisfied using the FirstRead parameter. >+** The default value of 000b correlates to: Command Type Hardwired pre-fetch amount Memory Read 4 DWORDs Memory Read Line 1 cache lines Memory Read Multiple 2 cache lines >+** 12:10 000b FirstRead_Primary Bus: 3-bit field indicating the multiplication factor to be used in calculating the number of bytes to prefetch from the secondary bus interface on the initial PreFetch operation. >+** The default value of 000b correlates to: Command Type Hardwired pre-fetch amount Memory Read 4 DWORDs Memory Read Line 1 cache line Memory Read Multiple 2 cache lines >+** 09:07 010b ReRead_Secondary Bus: 3-bit field indicating the multiplication factor to be used in calculating the number of bytes to prefetch from the primary bus interface on subsequent PreFetch operations given that the read demands were not satisfied using the FirstRead parameter. >+** The default value of 010b correlates to: Command Type Hardwired pre-fetch amount Memory Read 3 cache lines Memory Read Line 3 cache lines Memory Read Multiple 6 cache lines >+** 06:04 000b FirstRead_Secondary Bus: 3-bit field indicating the multiplication factor to be used in calculating the number of bytes to prefetch from the primary bus interface on the initial PreFetch operation. >+** The default value of 000b correlates to: Command Type Hardwired pre-fetch amount Memory Read 4 DWORDs Memory Read Line 1 cache line Memory Read Multiple 2 cache lines >+** 03:00 1111b Staged Prefetch Enable: This field enables/disables the FirstRead/ReRead pre-fetch algorithm for the secondary and the primary bus interfaces. >+** Bit(3) is a ganged enable bit for REQ#/GNT#[7:3], and bits(2:0) provide individual >+** enable bits for REQ#/GNT#[2:0]. (bit(2) is the enable bit for REQ#/GNT#[2], etc...) >+** 1b: enables the staged pre-fetch feature >+** 0b: disables staged pre-fetch, >+** and hardwires read pre-fetch policy to the following for >+** Memory Read, >+** Memory Read Line, >+** and Memory Read Multiple commands: >+** Command Type Hardwired Pre-Fetch Amount... >+** Memory Read 4 DWORDs >+** Memory Read Line 1 cache line >+** Memory Read Multiple 2 cache lines >+** NOTE: When the starting address is not cache line aligned, bridge pre-fetches Memory Read line commands only to the next higher cache line boundary.For non-cache line aligned Memory Read Multiple commands bridge pre-fetches only to the second cache line boundary encountered. >+**================================================================================== >+** 0x55-0x54: P_SERR# Assertion Control - SERR_CTL >+** Bit Default Description >+** 15 0b Upstream Delayed Transaction Discard Timer Expired: Dictates the bridge behavior in response to its discarding of a delayed transaction that was initiated from the primary bus. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 14 0b Upstream Delayed/Split Read Watchdog Timer Expired: Dictates bridge behavior following expiration of the subject watchdog timer. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 13 0b Upstream Delayed/Split Write Watchdog Timer Expired: Dictates bridge behavior following expiration of the subject watchdog timer. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 12 0b Master Abort during Upstream Posted Write: Dictates bridge behavior following its having detected a Master Abort while attempting to retire one of its PMWs upstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 11 0b Target Abort during Upstream Posted Write: Dictates bridge behavior following its having been terminated with Target Abort while attempting to retire one of its PMWs upstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 10 0b Upstream Posted Write Data Discarded: Dictates bridge behavior in the event that it discards an upstream posted write transaction. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 09 0b Upstream Posted Write Data Parity Error: Dictates bridge behavior when a data parity error is detected while attempting to retire on of its PMWs upstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 08 0b Secondary Bus Address Parity Error: This bit dictates bridge behavior when it detects an address parity error on the secondary bus. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 07 0b Downstream Delayed Transaction Discard Timer Expired: Dictates bridge behavior in response to its discarding of a delayed transaction that was initiated on the secondary bus. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 06 0b Downstream Delayed/Split Read Watchdog Timer Expired: Dictates bridge behavior following expiration of the subject watchdog timer. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 05 0b Downstream Delayed/Split Write Watchdog Timer Expired: Dictates bridge behavior following expiration of the subject watchdog timer. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 04 0b Master Abort during Downstream Posted Write: Dictates bridge behavior following its having detected a Master Abort while attempting to retire one of its PMWs downstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 03 0b Target Abort during Downstream Posted Write: Dictates bridge behavior following its having been terminated with Target Abort while attempting to retire one of its PMWs downstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 02 0b Downstream Posted Write Data Discarded: Dictates bridge behavior in the event that it discards a downstream posted write transaction. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 01 0b Downstream Posted Write Data Parity Error: Dictates bridge behavior when a data parity error is detected while attempting to retire on of its PMWs downstream. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+** 00 0b Primary Bus Address Parity Error: This bit dictates bridge behavior when it detects an address parity error on the primary bus. >+** 0b=bridge asserts P_SERR#. >+** 1b=bridge does not assert P_SERR# >+**=============================================================================== >+** 0x56: Pre-Boot Status Register - PBSR >+** Bit Default Description >+** 07 1 Reserved >+** 06 - Reserved - value indeterminate >+** 05:02 0 Reserved >+** 01 Varies with External State of S_133EN at PCI Bus Reset Secondary Bus Max Frequency Setting: This bit reflect captured S_133EN strap, indicating the maximum secondary bus clock frequency when in PCI-X mode. >+** Max Allowable Secondary Bus Frequency >+** S_133EN PCI-X Mode >+** 0 100 MHz >+** 1 133 MH >+** 00 0b Reserved >+**=============================================================================== >+** 0x59-0x58: Secondary Decode Enable Register - SDER >+** Bit Default Description >+** 15:03 FFF1h Preserved. >+** 02 Varies with External State of PRIVMEM at PCI Bus Reset Private Memory Space Enable - when set, bridge overrides its secondary inverse decode logic and not >+** forward upstream any secondary bus initiated DAC Memory transactions with AD(63)=1b. >+** This creates a private memory space on the Secondary PCI bus that allows peer-to-peer transactions. >+** 01:00 10 2 Preserved. >+**=============================================================================== >+** 0x5D-0x5C: Secondary IDSEL Select Register - SISR >+** Bit Default Description >+** 15:10 000000 2 Reserved. >+** 09 Varies with External State of PRIVDEV at PCI Bus Reset AD25- IDSEL Disable - When this bit is set, AD25 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD25 is asserted when Primary addresses AD[15:11]=01001 2 during a Type 1 to Type 0 conversion. >+** 08 Varies with External State of PRIVDEV at PCI Bus Reset AD24- IDSEL Disable - When this bit is set, AD24 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD24 is asserted when Primary addresses AD[15:11]=01000 2 during a Type 1 to Type 0 conversion. >+** 07 Varies with External State of PRIVDEV at PCI Bus Reset AD23- IDSEL Disable - When this bit is set, AD23 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD23 is asserted when Primary addresses AD[15:11]=00111 2 during a Type 1 to Type 0 conversion. >+** 06 Varies with External State of PRIVDEV at PCI Bus Reset AD22- IDSEL Disable - When this bit is set, AD22 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD22 is asserted when Primary addresses AD[15:11]=00110 2 during a Type 1 to Type 0 conversion. >+** 05 Varies with External State of PRIVDEV at PCI Bus Reset AD21- IDSEL Disable - When this bit is set, AD21 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD21 is asserted when Primary addresses AD[15:11]=00101 2 during a Type 1 to Type 0 conversion. >+** 04 Varies with External State of PRIVDEV at PCI Bus Reset AD20- IDSEL Disable - When this bit is set, AD20 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD20 is asserted when Primary addresses AD[15:11]=00100 2 during a Type 1 to Type 0 conversion. >+** 03 Varies with External State of PRIVDEV at PCI Bus Reset AD19- IDSEL Disable - When this bit is set, AD19 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD19 is asserted when Primary addresses AD[15:11]=00011 2 during a Type 1 to Type 0 conversion. >+** 02 Varies with External State of PRIVDEV at PCI Bus Reset AD18- IDSEL Disable - When this bit is set, AD18 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD18 is asserted when Primary addresses AD[15:11]=00010 2 during a Type 1 to Type 0 conversion. >+** 01 Varies with External State of PRIVDEV at PCI Bus Reset AD17- IDSEL Disable - When this bit is set, AD17 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD17 is asserted when Primary addresses AD[15:11]=00001 2 during a Type 1 to Type 0 conversion. >+** 00 Varies with External State of PRIVDEV at PCI Bus Reset AD16- IDSEL Disable - When this bit is set, AD16 is deasserted for any possible Type 1 to Type 0 conversion. >+** When this bit is clear, AD16 is asserted when Primary addresses AD[15:11]=00000 2 during a Type 1 to Type 0 conversion. >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** Reserved A8-CBh >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** PCI Extended Enhanced Capabilities List CC-FFh >+************************************************************************** >+** ---------------------------------------------------------------------------------------------------------- >+** | Byte 3 | Byte 2 | Byte 1 | Byte 0 | Configu-ration Byte Offset >+** ---------------------------------------------------------------------------------------------------------- >+** | Power Management Capabilities | Next Item Ptr | Capability ID | DCh >+** ---------------------------------------------------------------------------------------------------------- >+** | PM Data | PPB Support | Extensions Power Management CSR | E0h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Reserved | Reserved | E4h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | E8h >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | Reserved | Reserved | Reserved | ECh >+** ---------------------------------------------------------------------------------------------------------- >+** | PCI-X Secondary Status | Next Item Ptr | Capability ID | F0h >+** ---------------------------------------------------------------------------------------------------------- >+** | PCI-X Bridge Status | F4h >+** ---------------------------------------------------------------------------------------------------------- >+** | PCI-X Upstream Split Transaction Control | F8h >+** ---------------------------------------------------------------------------------------------------------- >+** | PCI-X Downstream Split Transaction Control | FCh >+** ---------------------------------------------------------------------------------------------------------- >+**=============================================================================== >+** 0xDC: Power Management Capabilities Identifier - PM_CAPID >+** Bit Default Description >+** 07:00 01h Identifier (ID): PCI SIG assigned ID for PCI-PM register block >+**=============================================================================== >+** 0xDD: Next Item Pointer - PM_NXTP >+** Bit Default Description >+** 07:00 F0H Next Capabilities Pointer (PTR): The register defaults to F0H pointing to the PCI-X Extended Capability Header. >+**=============================================================================== >+** 0xDF-0xDE: Power Management Capabilities Register - PMCR >+** Bit Default Description >+** 15:11 00h PME Supported (PME): PME# cannot be asserted by bridge. >+** 10 0h State D2 Supported (D2): Indicates no support for state D2. No power management action in this state. >+** 09 1h State D1 Supported (D1): Indicates support for state D1. No power management action in this state. >+** 08:06 0h Auxiliary Current (AUXC): This 3 bit field reports the 3.3Vaux auxiliary current requirements for the PCI function. >+** This returns 000b as PME# wake-up for bridge is not implemented. >+** 05 0 Special Initialization Required (SINT): Special initialization is not required for bridge. >+** 04:03 00 Reserved >+** 02:00 010 Version (VS): Indicates that this supports PCI Bus Power Management Interface Specification, Revision 1.1. >+**=============================================================================== >+** 0xE1-0xE0: Power Management Control / Status - Register - PMCSR >+** Bit Default Description >+** 15:09 00h Reserved >+** 08 0b PME_Enable: This bit, when set to 1b enables bridge to assert PME#. Note that bridge never has occasion to assert PME# and implements this dummy R/W bit only for the purpose of working around an OS PCI-PM bug. >+** 07:02 00h Reserved >+** 01:00 00 Power State (PSTATE): This 2-bit field is used both to determine the current power state of a function and to set the Function into a new power state. >+** 00 - D0 state >+** 01 - D1 state >+** 10 - D2 state >+** 11 - D3 hot state >+**=============================================================================== >+** 0xE2: Power Management Control / Status PCI to PCI Bridge Support - PMCSR_BSE >+** Bit Default Description >+** 07 0 Bus Power/Clock Control Enable (BPCC_En): Indicates that the bus power/clock control policies have been disabled. >+** 06 0 B2/B3 support for D3 Hot (B2_B3#): The state of this bit determines the action that is to occur as a direct result of programming the function to D3 hot. >+** This bit is only meaningful when bit 7 (BPCC_En) is a ¡§1¡¨. >+** 05:00 00h Reserved >+**=============================================================================== >+** 0xE3: Power Management Data Register - PMDR >+** Bit Default Description >+** 07:00 00h Reserved >+**=============================================================================== >+** 0xF0: PCI-X Capabilities Identifier - PX_CAPID >+** Bit Default Description >+** 07:00 07h Identifier (ID): Indicates this is a PCI-X capabilities list. >+**=============================================================================== >+** 0xF1: Next Item Pointer - PX_NXTP >+** Bit Default Description >+** 07:00 00h Next Item Pointer: Points to the next capability in the linked list The power on default value of this >+** register is 00h indicating that this is the last entry in the linked list of capabilities. >+**=============================================================================== >+** 0xF3-0xF2: PCI-X Secondary Status - PX_SSTS >+** Bit Default Description >+** 15:09 00h Reserved >+** 08:06 Xxx Secondary Clock Frequency (SCF): This field is set with the frequency of the secondary bus. >+** The values are: >+** BitsMax FrequencyClock Period >+** 000PCI ModeN/A >+** 00166 15 >+** 01010010 >+** 0111337.5 >+** 1xxreservedreserved >+** The default value for this register is the operating frequency of the secondary bus >+** 05 0b Split Request Delayed. (SRD): This bit is supposed to be set by a bridge when it cannot forward a transaction on the >+** secondary bus to the primary bus because there is not enough room within the limit >+** specified in the Split Transaction Commitment Limit field in the Downstream Split >+** Transaction Control register. The bridge does not set this bit. >+** 04 0b Split Completion Overrun (SCO): This bit is supposed to be set when a bridge terminates a Split Completion on the secondary bus with retry or Disconnect at next ADB because its buffers are full. The bridge does not set this bit. >+** 03 0b Unexpected Split Completion (USC): This bit is set when an unexpected split completion with a requester ID equal to bridge secondary bus number, device number 00h, and function number 0 is received on the secondary interface. This bit is cleared by software writing a '1'. >+** 02 0b Split Completion Discarded (SCD): This bit is set when bridge discards a split completion moving toward the secondary bus because the requester would not accept it. This bit cleared by software writing a '1'. >+** 01 1b 133 MHz Capable: Indicates that bridge is capable of running its secondary bus at 133 MHz >+** 00 1b 64-bit Device (D64): Indicates the width of the secondary bus as 64-bits. >+**=============================================================================== >+** 0xF7-0xF6-0xf5-0xF4: PCI-X Bridge Status - PX_BSTS >+** Bit Default Description >+** 31:22 0 Reserved >+** 21 0 Split Request Delayed (SRD): This bit does not be set by bridge. >+** 20 0 Split Completion Overrun (SCO): This bit does not be set by bridge because bridge throttles traffic on the completion side. >+** 19 0 Unexpected Split Completion (USC): The bridge sets this bit to 1b when it encounters a corrupted Split Completion, possibly with an inconsistent remaining byte count.Software clears this bit by writing a 1b to it. >+** 18 0 Split Completion Discarded (SCD): The bridge sets this bit to 1b when it has discarded a Split Completion.Software clears this bit by writing a 1b to it. >+** 17 1 133 MHz Capable: This bit indicates that the bridge primary interface is capable of 133 MHz operation in PCI-X mode. >+** 0=The maximum operating frequency is 66 MHz. >+** 1=The maximum operating frequency is 133 MHz. >+** 16 Varies with the external state of P_32BITPCI# at PCI Bus Reset 64-bit Device (D64): Indicates bus width of the Primary PCI bus interface. >+** 0=Primary Interface is connected as a 32-bit PCI bus. >+** 1=Primary Interface is connected as a 64-bit PCI bus. >+** 15:08 00h Bus Number (BNUM): This field is simply an alias to the PBN field of the BNUM register at offset 18h. >+** Apparently it was deemed necessary reflect it here for diagnostic purposes. >+** 07:03 1fh Device Number (DNUM): Indicates which IDSEL bridge consumes. May be updated whenever a PCI-X >+** configuration write cycle that targets bridge scores a hit. >+** 02:00 0h Function Number (FNUM): The bridge Function # >+**=============================================================================== >+** 0xFB-0xFA-0xF9-0xF8: PCI-X Upstream Split Transaction Control - PX_USTC >+** Bit Default Description >+** 31:16 003Eh Split Transaction Limit (STL): This register indicates the size of the commitment limit in units of ADQs. >+** Software is permitted to program this register to any value greater than or equal to >+** the contents of the Split Transaction Capacity register. A value less than the contents >+** of the Split Transaction Capacity register causes unspecified results. >+** A value of 003Eh or greater enables the bridge to forward all Split Requests of any >+** size regardless of the amount of buffer space available. >+** 15:00 003Eh Split Transaction Capacity (STC): This read-only field indicates the size of the buffer (number of ADQs) for storing >+** split completions. This register controls behavior of the bridge buffers for forwarding >+** Split Transactions from a primary bus requester to a secondary bus completer. >+** The default value of 003Eh indicates there is available buffer space for 62 ADQs (7936 bytes). >+**=============================================================================== >+** 0xFF-0xFE-0xFD-0xFC: PCI-X Downstream Split Transaction Control - PX_DSTC >+** Bit Default Description >+** 31:16 003Eh Split Transaction Limit (STL): This register indicates the size of the commitment limit in units of ADQs. >+** Software is permitted to program this register to any value greater than or equal to >+** the contents of the Split Transaction Capacity register. A value less than the contents >+** of the Split Transaction Capacity register causes unspecified results. >+** A value of 003Eh or greater enables the bridge to forward all Split Requests of any >+** size regardless of the amount of buffer space available. >+** 15:00 003Eh Split Transaction Capacity (STC): This read-only field indicates the size of the buffer (number of ADQs) for storing >+** split completions. This register controls behavior of the bridge buffers for forwarding >+** Split Transactions from a primary bus requester to a secondary bus completer. >+** The default value of 003Eh indicates there is available buffer space for 62 ADQs (7936 bytes). >+************************************************************************** >+*/ >+ >+ >+ >+ >+/* >+************************************************************************************************************************************* >+** 80331 Address Translation Unit Register Definitions >+** ATU Interface Configuration Header Format >+** The ATU is programmed via a [Type 0] configuration command on the PCI interface. >+************************************************************************************************************************************* >+** | Byte 3 | Byte 2 | Byte 1 | Byte 0 | Configuration Byte Offset >+**=================================================================================================================================== >+** | ATU Device ID | Vendor ID | 00h >+** ---------------------------------------------------------------------------------------------------------- >+** | Status | Command | 04H >+** ---------------------------------------------------------------------------------------------------------- >+** | ATU Class Code | Revision ID | 08H >+** ---------------------------------------------------------------------------------------------------------- >+** | ATUBISTR | Header Type | Latency Timer | Cacheline Size | 0CH >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Base Address 0 | 10H >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Upper Base Address 0 | 14H >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Base Address 1 | 18H >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Upper Base Address 1 | 1CH >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Base Address 2 | 20H >+** ---------------------------------------------------------------------------------------------------------- >+** | Inbound ATU Upper Base Address 2 | 24H >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 28H >+** ---------------------------------------------------------------------------------------------------------- >+** | ATU Subsystem ID | ATU Subsystem Vendor ID | 2CH >+** ---------------------------------------------------------------------------------------------------------- >+** | Expansion ROM Base Address | 30H >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved Capabilities Pointer | 34H >+** ---------------------------------------------------------------------------------------------------------- >+** | Reserved | 38H >+** ---------------------------------------------------------------------------------------------------------- >+** | Maximum Latency | Minimum Grant | Interrupt Pin | Interrupt Line | 3CH >+** ---------------------------------------------------------------------------------------------------------- >+********************************************************************************************************************* >+*/ >+/* >+*********************************************************************************** >+** ATU Vendor ID Register - ATUVID >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:00 8086H (0x17D3) ATU Vendor ID - This is a 16-bit value assigned to Intel. This register, combined with the DID, uniquely identify the PCI device. >+** Access type is Read/Write to allow the 80331 to configure the register as a different vendor ID to simulate the interface of a standard mechanism currently used by existing application software. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_VENDOR_ID_REG 0x00 /*word*/ >+/* >+*********************************************************************************** >+** ATU Device ID Register - ATUDID >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:00 0336H (0x1110) ATU Device ID - This is a 16-bit value assigned to the ATU. This ID, combined with the VID, uniquely identify any PCI device. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_DEVICE_ID_REG 0x02 /*word*/ >+/* >+*********************************************************************************** >+** ATU Command Register - ATUCMD >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:11 000000 2 Reserved >+** 10 0 Interrupt Disable - This bit disables 80331 from asserting the ATU interrupt signal. >+** 0=enables the assertion of interrupt signal. >+** 1=disables the assertion of its interrupt signal. >+** 09 0 2 Fast Back to Back Enable - When cleared, the ATU interface is not allowed to generate fast back-to-back cycles on its bus. Ignored when operating in the PCI-X mode. >+** 08 0 2 SERR# Enable - When cleared, the ATU interface is not allowed to assert SERR# on the PCI interface. >+** 07 1 2 Address/Data Stepping Control - Address stepping is implemented for configuration transactions. The >+** ATU inserts 2 clock cycles of address stepping for Conventional Mode and 4 clock cycles of address stepping for PCI-X mode. >+** 06 0 2 Parity Error Response - When set, the ATU takes normal action when a parity error is detected. When cleared, parity checking is disabled. >+** 05 0 2 VGA Palette Snoop Enable - The ATU interface does not support I/O writes and therefore, does not perform VGA palette snooping. >+** 04 0 2 Memory Write and Invalidate Enable - When set, ATU may generate MWI commands. When clear, ATU use Memory Write commands instead of MWI. Ignored when operating in the PCI-X mode. >+** 03 0 2 Special Cycle Enable - The ATU interface does not respond to special cycle commands in any way. Not implemented and a reserved bit field. >+** 02 0 2 Bus Master Enable - The ATU interface can act as a master on the PCI bus. When cleared, disables the device from generating PCI accesses. When set, allows the device to behave as a PCI bus master. >+** When operating in the PCI-X mode, ATU initiates a split completion transaction regardless of the state of this bit. >+** 01 0 2 Memory Enable - Controls the ATU interface¡¦s response to PCI memory addresses. When cleared, the ATU interface does not respond to any memory access on the PCI bus. >+** 00 0 2 I/O Space Enable - Controls the ATU interface response to I/O transactions. Not implemented and a reserved bit field. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_COMMAND_REG 0x04 /*word*/ >+/* >+*********************************************************************************** >+** ATU Status Register - ATUSR (Sheet 1 of 2) >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15 0 2 Detected Parity Error - set when a parity error is detected in data received by the ATU on the PCI bus even >+** when the ATUCMD register¡¦s Parity Error Response bit is cleared. Set under the following conditions: >+** ¡E Write Data Parity Error when the ATU is a target (inbound write). >+** ¡E Read Data Parity Error when the ATU is a requester (outbound read). >+** ¡E Any Address or Attribute (PCI-X Only) Parity Error on the Bus (including one generated by the ATU). >+** 14 0 2 SERR# Asserted - set when SERR# is asserted on the PCI bus by the ATU. >+** 13 0 2 Master Abort - set when a transaction initiated by the ATU PCI master interface, ends in a Master-Abort >+** or when the ATU receives a Master Abort Split Completion Error Message in PCI-X mode. >+** 12 0 2 Target Abort (master) - set when a transaction initiated by the ATU PCI master interface, ends in a target >+** abort or when the ATU receives a Target Abort Split Completion Error Message in PCI-X mode. >+** 11 0 2 Target Abort (target) - set when the ATU interface, acting as a target, terminates the transaction on the PCI bus with a target abort. >+** 10:09 01 2 DEVSEL# Timing - These bits are read-only and define the slowest DEVSEL# timing for a target device in Conventional PCI Mode regardless of the operating mode (except configuration accesses). >+** 00 2=Fast >+** 01 2=Medium >+** 10 2=Slow >+** 11 2=Reserved >+** The ATU interface uses Medium timing. >+** 08 0 2 Master Parity Error - The ATU interface sets this bit under the following conditions: >+** ¡E The ATU asserted PERR# itself or the ATU observed PERR# asserted. >+** ¡E And the ATU acted as the requester for the operation in which the error occurred. >+** ¡E And the ATUCMD register¡¦s Parity Error Response bit is set >+** ¡E Or (PCI-X Mode Only) the ATU received a Write Data Parity Error Message >+** ¡E And the ATUCMD register¡¦s Parity Error Response bit is set >+** 07 1 2 (Conventional mode) >+** 0 2 (PCI-X mode) >+** Fast Back-to-Back - The ATU/Messaging Unit interface is capable of accepting fast back-to-back >+** transactions in Conventional PCI mode when the transactions are not to the same target. Since fast >+** back-to-back transactions do not exist in PCI-X mode, this bit is forced to 0 in the PCI-X mode. >+** 06 0 2 UDF Supported - User Definable Features are not supported >+** 05 1 2 66 MHz. Capable - 66 MHz operation is supported. >+** 04 1 2 Capabilities - When set, this function implements extended capabilities. >+** 03 0 Interrupt Status - reflects the state of the ATU interrupt when the Interrupt Disable bit in the command register is a 0. >+** 0=ATU interrupt signal deasserted. >+** 1=ATU interrupt signal asserted. >+** NOTE: Setting the Interrupt Disable bit to a 1 has no effect on the state of this bit. Refer to >+** Section 3.10.23, ¡§ATU Interrupt Pin Register - ATUIPR¡¨ on page 236 for details on the ATU >+** interrupt signal. >+** 02:00 00000 2 Reserved. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_STATUS_REG 0x06 /*word*/ >+/* >+*********************************************************************************** >+** ATU Revision ID Register - ATURID >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 00H ATU Revision - identifies the 80331 revision number. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_REVISION_REG 0x08 /*byte*/ >+/* >+*********************************************************************************** >+** ATU Class Code Register - ATUCCR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 23:16 05H Base Class - Memory Controller >+** 15:08 80H Sub Class - Other Memory Controller >+** 07:00 00H Programming Interface - None defined >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_CLASS_CODE_REG 0x09 /*3bytes 0x0B,0x0A,0x09*/ >+/* >+*********************************************************************************** >+** ATU Cacheline Size Register - ATUCLSR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 00H ATU Cacheline Size - specifies the system cacheline size in DWORDs. Cacheline size is restricted to either 0, 8 or 16 DWORDs. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_CACHELINE_SIZE_REG 0x0C /*byte*/ >+/* >+*********************************************************************************** >+** ATU Latency Timer Register - ATULT >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:03 00000 2 (for Conventional mode) >+** 01000 2 (for PCI-X mode) >+** Programmable Latency Timer - This field varies the latency timer for the interface from 0 to 248 clocks. >+** The default value is 0 clocks for Conventional PCI mode, and 64 clocks for PCI-X mode. >+** 02:00 000 2 Latency Timer Granularity - These Bits are read only giving a programmable granularity of 8 clocks for the latency timer. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_LATENCY_TIMER_REG 0x0D /*byte*/ >+/* >+*********************************************************************************** >+** ATU Header Type Register - ATUHTR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07 0 2 Single Function/Multi-Function Device - Identifies the 80331 as a single-function PCI device. >+** 06:00 000000 2 PCI Header Type - This bit field indicates the type of PCI header implemented. The ATU interface >+** header conforms to PCI Local Bus Specification, Revision 2.3. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_HEADER_TYPE_REG 0x0E /*byte*/ >+/* >+*********************************************************************************** >+** ATU BIST Register - ATUBISTR >+** >+** The ATU BIST Register controls the functions the Intel XScale core performs when BIST is >+** initiated. This register is the interface between the host processor requesting BIST functions and >+** the 80331 replying with the results from the software implementation of the BIST functionality. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07 0 2 BIST Capable - This bit value is always equal to the ATUCR ATU BIST Interrupt Enable bit. >+** 06 0 2 Start BIST - When the ATUCR BIST Interrupt Enable bit is set: >+** Setting this bit generates an interrupt to the Intel XScale core to perform a software BIST function. >+** The Intel XScale core clears this bit when the BIST software has completed with the BIST results >+** found in ATUBISTR register bits [3:0]. >+** When the ATUCR BIST Interrupt Enable bit is clear: >+** Setting this bit does not generate an interrupt to the Intel XScale core and no BIST functions is performed. >+** The Intel XScale core does not clear this bit. >+** 05:04 00 2 Reserved >+** 03:00 0000 2 BIST Completion Code - when the ATUCR BIST Interrupt Enable bit is set and the ATUBISTR Start BIST bit is set (bit 6): >+** The Intel XScale core places the results of the software BIST in these bits. A nonzero value indicates a device-specific error. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_BIST_REG 0x0F /*byte*/ >+ >+/* >+*************************************************************************************** >+** ATU Base Registers and Associated Limit Registers >+*************************************************************************************** >+** Base Address Register Limit Register Description >+** Inbound ATU Base Address Register 0 Inbound ATU Limit Register 0 Defines the inbound translation window 0 from the PCI bus. >+** Inbound ATU Upper Base Address Register 0 N/A Together with ATU Base Address Register 0 defines the inbound translation window 0 from the PCI bus for DACs. >+** Inbound ATU Base Address Register 1 Inbound ATU Limit Register 1 Defines inbound window 1 from the PCI bus. >+** Inbound ATU Upper Base Address Register 1 N/A Together with ATU Base Address Register 1 defines inbound window 1 from the PCI bus for DACs. >+** Inbound ATU Base Address Register 2 Inbound ATU Limit Register 2 Defines the inbound translation window 2 from the PCI bus. >+** Inbound ATU Upper Base Address Register 2 N/A Together with ATU Base Address Register 2 defines the inbound translation window 2 from the PCI bus for DACs. >+** Inbound ATU Base Address Register 3 Inbound ATU Limit Register 3 Defines the inbound translation window 3 from the PCI bus. >+** Inbound ATU Upper Base Address Register 3 N/A Together with ATU Base Address Register 3 defines the inbound translation window 3 from the PCI bus for DACs. >+** NOTE: This is a private BAR that resides outside of the standard PCI configuration header space (offsets 00H-3FH). >+** Expansion ROM Base Address Register Expansion ROM Limit Register Defines the window of addresses used by a bus master for reading from an Expansion ROM. >+**-------------------------------------------------------------------------------------- >+** ATU Inbound Window 1 is not a translate window. >+** The ATU does not claim any PCI accesses that fall within this range. >+** This window is used to allocate host memory for use by Private Devices. >+** When enabled, the ATU interrupts the Intel XScale core when either the IABAR1 register or the IAUBAR1 register is written from the PCI bus. >+*********************************************************************************** >+*/ >+ >+/* >+*********************************************************************************** >+** Inbound ATU Base Address Register 0 - IABAR0 >+** >+** . The Inbound ATU Base Address Register 0 (IABAR0) together with the Inbound ATU Upper Base Address Register 0 (IAUBAR0) defines the block of memory addresses where the inbound translation window 0 begins. >+** . The inbound ATU decodes and forwards the bus request to the 80331 internal bus with a translated address to map into 80331 local memory. >+** . The IABAR0 and IAUBAR0 define the base address and describes the required memory block size. >+** . Bits 31 through 12 of the IABAR0 is either read/write bits or read only with a value of 0 >+** depending on the value located within the IALR0. >+** This configuration allows the IABAR0 to be programmed per PCI Local Bus Specification. >+** The first 4 Kbytes of memory defined by the IABAR0, IAUBAR0 and the IALR0 is reserved for the Messaging Unit. >+** The programmed value within the base address register must comply with the PCI programming requirements for address alignment. >+** Warning: >+** When IALR0 is cleared prior to host configuration: >+** the user should also clear the Prefetchable Indicator and the Type Indicator. >+** Assuming IALR0 is not cleared: >+** a. Since non prefetchable memory windows can never be placed above the 4 Gbyte address boundary, >+** when the Prefetchable Indicator is cleared prior to host configuration, >+** the user should also set the Type Indicator for 32 bit addressability. >+** b. For compliance to the PCI-X Addendum to the PCI Local Bus Specification, >+** when the Prefetchable Indicator is set prior to host configuration, the user >+** should also set the Type Indicator for 64 bit addressability. >+** This is the default for IABAR0. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Translation Base Address 0 - These bits define the actual location the translation function is to respond to when addressed from the PCI bus. >+** 11:04 00H Reserved. >+** 03 1 2 Prefetchable Indicator - When set, defines the memory space as prefetchable. >+** 02:01 10 2 Type Indicator - Defines the width of the addressability for this memory window: >+** 00 - Memory Window is locatable anywhere in 32 bit address space >+** 10 - Memory Window is locatable anywhere in 64 bit address space >+** 00 0 2 Memory Space Indicator - This bit field describes memory or I/O space base address. >+** The ATU does not occupy I/O space, >+** thus this bit must be zero. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_BASE_ADDRESS0_REG 0x10 /*dword 0x13,0x12,0x11,0x10*/ >+#define ARCMSR_INBOUND_ATU_MEMORY_PREFETCHABLE 0x08 >+#define ARCMSR_INBOUND_ATU_MEMORY_WINDOW64 0x04 >+/* >+*********************************************************************************** >+** Inbound ATU Upper Base Address Register 0 - IAUBAR0 >+** >+** This register contains the upper base address when decoding PCI addresses beyond 4 GBytes. >+** Together with the Translation Base Address this register defines the actual location the translation >+** function is to respond to when addressed from the PCI bus for addresses > 4GBytes (for DACs). >+** The programmed value within the base address register must comply with the PCI programming requirements for address alignment. >+** Note: >+** When the Type indicator of IABAR0 is set to indicate 32 bit addressability, >+** the IAUBAR0 register attributes are read-only. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:0 00000H Translation Upper Base Address 0 - Together with the Translation Base Address 0 these bits define the >+** actual location the translation function is to respond to when addressed from the PCI bus for addresses > 4GBytes. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_UPPER_BASE_ADDRESS0_REG 0x14 /*dword 0x17,0x16,0x15,0x14*/ >+/* >+*********************************************************************************** >+** Inbound ATU Base Address Register 1 - IABAR1 >+** >+** . The Inbound ATU Base Address Register (IABAR1) together with the Inbound ATU Upper Base Address Register 1 (IAUBAR1) defines the block of memory addresses where the inbound translation window 1 begins. >+** . This window is used merely to allocate memory on the PCI bus and, the ATU does not process any PCI bus transactions to this memory range. >+** . The programmed value within the base address register must comply with the PCI programming requirements for address alignment. >+** . When enabled, the ATU interrupts the Intel XScale core when the IABAR1 register is written from the PCI bus. >+** Warning: >+** When a non-zero value is not written to IALR1 prior to host configuration, >+** the user should not set either the Prefetchable Indicator or the Type Indicator for 64 bit addressability. >+** This is the default for IABAR1. >+** Assuming a non-zero value is written to IALR1, >+** the user may set the Prefetchable Indicator >+** or the Type Indicator: >+** a. Since non prefetchable memory windows can never be placed above the 4 Gbyte address >+** boundary, when the Prefetchable Indicator is not set prior to host configuration, >+** the user should also leave the Type Indicator set for 32 bit addressability. >+** This is the default for IABAR1. >+** b. when the Prefetchable Indicator is set prior to host configuration, >+** the user should also set the Type Indicator for 64 bit addressability. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Translation Base Address 1 - These bits define the actual location of window 1 on the PCI bus. >+** 11:04 00H Reserved. >+** 03 0 2 Prefetchable Indicator - When set, defines the memory space as prefetchable. >+** 02:01 00 2 Type Indicator - Defines the width of the addressability for this memory window: >+** 00 - Memory Window is locatable anywhere in 32 bit address space >+** 10 - Memory Window is locatable anywhere in 64 bit address space >+** 00 0 2 Memory Space Indicator - This bit field describes memory or I/O space base address. >+** The ATU does not occupy I/O space, >+** thus this bit must be zero. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_BASE_ADDRESS1_REG 0x18 /*dword 0x1B,0x1A,0x19,0x18*/ >+/* >+*********************************************************************************** >+** Inbound ATU Upper Base Address Register 1 - IAUBAR1 >+** >+** This register contains the upper base address when locating this window for PCI addresses beyond 4 GBytes. >+** Together with the IABAR1 this register defines the actual location for this memory window for addresses > 4GBytes (for DACs). >+** This window is used merely to allocate memory on the PCI bus and, the ATU does not process any PCI bus transactions to this memory range. >+** The programmed value within the base address register must comply with the PCI programming >+** requirements for address alignment. >+** When enabled, the ATU interrupts the Intel XScale core when the IAUBAR1 register is written >+** from the PCI bus. >+** Note: >+** When the Type indicator of IABAR1 is set to indicate 32 bit addressability, >+** the IAUBAR1 register attributes are read-only. >+** This is the default for IABAR1. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:0 00000H Translation Upper Base Address 1 - Together with the Translation Base Address 1 these bits define the actual location for this memory window on the PCI bus for addresses > 4GBytes. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_UPPER_BASE_ADDRESS1_REG 0x1C /*dword 0x1F,0x1E,0x1D,0x1C*/ >+/* >+*********************************************************************************** >+** Inbound ATU Base Address Register 2 - IABAR2 >+** >+** . The Inbound ATU Base Address Register 2 (IABAR2) together with the Inbound ATU Upper Base Address Register 2 (IAUBAR2) defines the block of memory addresses where the inbound translation window 2 begins. >+** . The inbound ATU decodes and forwards the bus request to the 80331 internal bus with a translated address to map into 80331 local memory. >+** . The IABAR2 and IAUBAR2 define the base address and describes the required memory block size >+** . Bits 31 through 12 of the IABAR2 is either read/write bits or read only with a value of 0 depending on the value located within the IALR2. >+** The programmed value within the base address register must comply with the PCI programming requirements for address alignment. >+** Warning: >+** When a non-zero value is not written to IALR2 prior to host configuration, >+** the user should not set either the Prefetchable Indicator >+** or the Type Indicator for 64 bit addressability. >+** This is the default for IABAR2. >+** Assuming a non-zero value is written to IALR2, >+** the user may set the Prefetchable Indicator >+** or the Type Indicator: >+** a. Since non prefetchable memory windows can never be placed above the 4 Gbyte address boundary, >+** when the Prefetchable Indicator is not set prior to host configuration, >+** the user should also leave the Type Indicator set for 32 bit addressability. >+** This is the default for IABAR2. >+** b. when the Prefetchable Indicator is set prior to host configuration, >+** the user should also set the Type Indicator for 64 bit addressability. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Translation Base Address 2 - These bits define the actual location the translation function is to respond to when addressed from the PCI bus. >+** 11:04 00H Reserved. >+** 03 0 2 Prefetchable Indicator - When set, defines the memory space as prefetchable. >+** 02:01 00 2 Type Indicator - Defines the width of the addressability for this memory window: >+** 00 - Memory Window is locatable anywhere in 32 bit address space >+** 10 - Memory Window is locatable anywhere in 64 bit address space >+** 00 0 2 Memory Space Indicator - This bit field describes memory or I/O space base address. >+** The ATU does not occupy I/O space, >+** thus this bit must be zero. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_BASE_ADDRESS2_REG 0x20 /*dword 0x23,0x22,0x21,0x20*/ >+/* >+*********************************************************************************** >+** Inbound ATU Upper Base Address Register 2 - IAUBAR2 >+** >+** This register contains the upper base address when decoding PCI addresses beyond 4 GBytes. >+** Together with the Translation Base Address this register defines the actual location the translation function is to respond to when addressed from the PCI bus for addresses > 4GBytes (for DACs). >+** The programmed value within the base address register must comply with the PCI programming >+** requirements for address alignment. >+** Note: >+** When the Type indicator of IABAR2 is set to indicate 32 bit addressability, >+** the IAUBAR2 register attributes are read-only. >+** This is the default for IABAR2. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:0 00000H Translation Upper Base Address 2 - Together with the Translation Base Address 2 these bits define the actual location the translation function is to respond to when addressed from the PCI bus for addresses > 4GBytes. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_UPPER_BASE_ADDRESS2_REG 0x24 /*dword 0x27,0x26,0x25,0x24*/ >+/* >+*********************************************************************************** >+** ATU Subsystem Vendor ID Register - ASVIR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:0 0000H Subsystem Vendor ID - This register uniquely identifies the add-in board or subsystem vendor. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_SUBSYSTEM_VENDOR_ID_REG 0x2C /*word 0x2D,0x2C*/ >+/* >+*********************************************************************************** >+** ATU Subsystem ID Register - ASIR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:0 0000H Subsystem ID - uniquely identifies the add-in board or subsystem. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_SUBSYSTEM_ID_REG 0x2E /*word 0x2F,0x2E*/ >+/* >+*********************************************************************************** >+** Expansion ROM Base Address Register -ERBAR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Expansion ROM Base Address - These bits define the actual location where the Expansion ROM address window resides when addressed from the PCI bus on any 4 Kbyte boundary. >+** 11:01 000H Reserved >+** 00 0 2 Address Decode Enable - This bit field shows the ROM address decoder is enabled or disabled. When cleared, indicates the address decoder is disabled. >+*********************************************************************************** >+*/ >+#define ARCMSR_EXPANSION_ROM_BASE_ADDRESS_REG 0x30 /*dword 0x33,0x32,0v31,0x30*/ >+#define ARCMSR_EXPANSION_ROM_ADDRESS_DECODE_ENABLE 0x01 >+/* >+*********************************************************************************** >+** ATU Capabilities Pointer Register - ATU_CAP_PTR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 C0H Capability List Pointer - This provides an offset in this function¡¦s configuration space that points to the 80331 PCl Bus Power Management extended capability. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_CAPABILITY_PTR_REG 0x34 /*byte*/ >+/* >+*********************************************************************************** >+** Determining Block Sizes for Base Address Registers >+** The required address size and type can be determined by writing ones to a base address register and >+** reading from the registers. By scanning the returned value from the least-significant bit of the base >+** address registers upwards, the programmer can determine the required address space size. The >+** binary-weighted value of the first non-zero bit found indicates the required amount of space. >+** Table 105 describes the relationship between the values read back and the byte sizes the base >+** address register requires. >+** As an example, assume that FFFF.FFFFH is written to the ATU Inbound Base Address Register 0 >+** (IABAR0) and the value read back is FFF0.0008H. Bit zero is a zero, so the device requires >+** memory address space. Bit three is one, so the memory does supports prefetching. Scanning >+** upwards starting at bit four, bit twenty is the first one bit found. The binary-weighted value of this >+** bit is 1,048,576, indicated that the device requires 1 Mbyte of memory space. >+** The ATU Base Address Registers and the Expansion ROM Base Address Register use their >+** associated limit registers to enable which bits within the base address register are read/write and >+** which bits are read only (0). This allows the programming of these registers in a manner similar to >+** other PCI devices even though the limit is variable. >+** Table 105. Memory Block Size Read Response >+** Response After Writing all 1s >+** to the Base Address Register >+** Size >+** (Bytes) >+** Response After Writing all 1s >+** to the Base Address Register >+** Size >+** (Bytes) >+** FFFFFFF0H 16 FFF00000H 1 M >+** FFFFFFE0H 32 FFE00000H 2 M >+** FFFFFFC0H 64 FFC00000H 4 M >+** FFFFFF80H 128 FF800000H 8 M >+** FFFFFF00H 256 FF000000H 16 M >+** FFFFFE00H 512 FE000000H 32 M >+** FFFFFC00H 1K FC000000H 64 M >+** FFFFF800H 2K F8000000H 128 M >+** FFFFF000H 4K F0000000H 256 M >+** FFFFE000H 8K E0000000H 512 M >+** FFFFC000H 16K C0000000H 1 G >+** FFFF8000H 32K 80000000H 2 G >+** FFFF0000H 64K >+** 00000000H >+** Register not >+** imple-mented, >+** no >+** address >+** space >+** required. >+** FFFE0000H 128K >+** FFFC0000H 256K >+** FFF80000H 512K >+** >+*************************************************************************************** >+*/ >+ >+ >+ >+/* >+*********************************************************************************** >+** ATU Interrupt Line Register - ATUILR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 FFH Interrupt Assigned - system-assigned value identifies which system interrupt controller¡¦s interrupt >+** request line connects to the device's PCI interrupt request lines (as specified in the interrupt pin register). >+** A value of FFH signifies ¡§no connection¡¨ or ¡§unknown¡¨. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_INTERRUPT_LINE_REG 0x3C /*byte*/ >+/* >+*********************************************************************************** >+** ATU Interrupt Pin Register - ATUIPR >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 01H Interrupt Used - A value of 01H signifies that the ATU interface unit uses INTA# as the interrupt pin. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_INTERRUPT_PIN_REG 0x3D /*byte*/ >+/* >+*********************************************************************************** >+** ATU Minimum Grant Register - ATUMGNT >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 80H This register specifies how long a burst period the device needs in increments of 8 PCI clocks. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_MINIMUM_GRANT_REG 0x3E /*byte*/ >+/* >+*********************************************************************************** >+** ATU Maximum Latency Register - ATUMLAT >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 00H Specifies frequency (how often) the device needs to access the PCI bus in increments of 8 PCI clocks. A zero value indicates the device has no stringent requirement. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_MAXIMUM_LATENCY_REG 0x3F /*byte*/ >+/* >+*********************************************************************************** >+** Inbound Address Translation >+** >+** The ATU allows external PCI bus initiators to directly access the internal bus. >+** These PCI bus initiators can read or write 80331 memory-mapped registers or 80331 local memory space. >+** The process of inbound address translation involves two steps: >+** 1. Address Detection. >+** ¡E Determine when the 32-bit PCI address (64-bit PCI address during DACs) is >+** within the address windows defined for the inbound ATU. >+** ¡E Claim the PCI transaction with medium DEVSEL# timing in the conventional PCI >+** mode and with Decode A DEVSEL# timing in the PCI-X mode. >+** 2. Address Translation. >+** ¡E Translate the 32-bit PCI address (lower 32-bit PCI address during DACs) to a 32-bit 80331 internal bus address. >+** The ATU uses the following registers in inbound address window 0 translation: >+** ¡E Inbound ATU Base Address Register 0 >+** ¡E Inbound ATU Limit Register 0 >+** ¡E Inbound ATU Translate Value Register 0 >+** The ATU uses the following registers in inbound address window 2 translation: >+** ¡E Inbound ATU Base Address Register 2 >+** ¡E Inbound ATU Limit Register 2 >+** ¡E Inbound ATU Translate Value Register 2 >+** The ATU uses the following registers in inbound address window 3 translation: >+** ¡E Inbound ATU Base Address Register 3 >+** ¡E Inbound ATU Limit Register 3 >+** ¡E Inbound ATU Translate Value Register 3 >+** Note: Inbound Address window 1 is not a translate window. >+** Instead, window 1 may be used to allocate host memory for Private Devices. >+** Inbound Address window 3 does not reside in the standard section of the configuration header (offsets 00H - 3CH), >+** thus the host BIOS does not configure window 3. >+** Window 3 is intended to be used as a special window into local memory for private PCI >+** agents controlled by the 80331 in conjunction with the Private Memory Space of the bridge. >+** PCI-to-PCI Bridge in 80331 or >+** Inbound address detection is determined from the 32-bit PCI address, >+** (64-bit PCI address during DACs) the base address register and the limit register. >+** In the case of DACs none of the upper 32-bits of the address is masked during address comparison. >+** >+** The algorithm for detection is: >+** >+** Equation 1. Inbound Address Detection >+** When (PCI_Address [31:0] & Limit_Register[31:0]) == (Base_Register[31:0] & PCI_Address [63:32]) == Base_Register[63:32] (for DACs only) >+** the PCI Address is claimed by the Inbound ATU. >+** >+** The incoming 32-bit PCI address (lower 32-bits of the address in case of DACs) is bitwise ANDed >+** with the associated inbound limit register. >+** When the result matches the base register (and upper base address matches upper PCI address in case of DACs), >+** the inbound PCI address is detected as being within the inbound translation window and is claimed by the ATU. >+** >+** Note: The first 4 Kbytes of the ATU inbound address translation window 0 are reserved for the Messaging Unit. >+** Once the transaction is claimed, the address must be translated from a PCI address to a 32-bit >+** internal bus address. In case of DACs upper 32-bits of the address is simply discarded and only the >+** lower 32-bits are used during address translation. >+** The algorithm is: >+** >+** >+** Equation 2. Inbound Translation >+** Intel I/O processor Internal Bus Address=(PCI_Address[31:0] & ~Limit_Register[31:0]) | ATU_Translate_Value_Register[31:0]. >+** >+** The incoming 32-bit PCI address (lower 32-bits in case of DACs) is first bitwise ANDed with the >+** bitwise inverse of the limit register. This result is bitwise ORed with the ATU Translate Value and >+** the result is the internal bus address. This translation mechanism is used for all inbound memory >+** read and write commands excluding inbound configuration read and writes. >+** In the PCI mode for inbound memory transactions, the only burst order supported is Linear >+** Incrementing. For any other burst order, the ATU signals a Disconnect after the first data phase. >+** The PCI-X supports linear incrementing only, and hence above situation is not encountered in the PCI-X mode. >+** example: >+** Register Values >+** Base_Register=3A00 0000H >+** Limit_Register=FF80 0000H (8 Mbyte limit value) >+** Value_Register=B100 0000H >+** Inbound Translation Window ranges from 3A00 0000H to 3A7F FFFFH (8 Mbytes) >+** >+** Address Detection (32-bit address) >+** >+** PCI_Address & Limit_Register == Base_Register >+** 3A45 012CH & FF80 0000H == 3A00 0000H >+** >+** ANS: PCI_Address is in the Inbound Translation Window >+** Address Translation (to get internal bus address) >+** >+** IB_Address=(PCI_Address & ~Limit_Register) | Value_Reg >+** IB_Address=(3A45 012CH & 007F FFFFH) | B100 0000H >+** >+** ANS:IB_Address=B145 012CH >+*********************************************************************************** >+*/ >+ >+ >+ >+/* >+*********************************************************************************** >+** Inbound ATU Limit Register 0 - IALR0 >+** >+** Inbound address translation for memory window 0 occurs for data transfers occurring from the PCI >+** bus (originated from the PCI bus) to the 80331 internal bus. The address translation block converts >+** PCI addresses to internal bus addresses. >+** The 80331 translate value register¡¦s programmed value must be naturally aligned with the base >+** address register¡¦s programmed value. The limit register is used as a mask; thus, the lower address >+** bits programmed into the 80331 translate value register are invalid. Refer to the PCI Local Bus >+** Specification, Revision 2.3 for additional information on programming base address registers. >+** Bits 31 to 12 within the IALR0 have a direct effect on the IABAR0 register, bits 31 to 12, with a >+** one to one correspondence. A value of 0 in a bit within the IALR0 makes the corresponding bit >+** within the IABAR0 a read only bit which always returns 0. A value of 1 in a bit within the IALR0 >+** makes the corresponding bit within the IABAR0 read/write from PCI. Note that a consequence of >+** this programming scheme is that unless a valid value exists within the IALR0, all writes to the >+** IABAR0 has no effect since a value of all zeros within the IALR0 makes the IABAR0 a read only register. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 FF000H Inbound Translation Limit 0 - This readback value determines the memory block size required for >+** inbound memory window 0 of the address translation unit. This defaults to an inbound window of 16MB. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_LIMIT0_REG 0x40 /*dword 0x43,0x42,0x41,0x40*/ >+/* >+*********************************************************************************** >+** Inbound ATU Translate Value Register 0 - IATVR0 >+** >+** The Inbound ATU Translate Value Register 0 (IATVR0) contains the internal bus address used to >+** convert PCI bus addresses. The converted address is driven on the internal bus as a result of the >+** inbound ATU address translation. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 FF000H Inbound ATU Translation Value 0 - This value is used to convert the PCI address to internal bus addresses. >+** This value must be 64-bit aligned on the internal bus. The default address allows the ATU to access the internal 80331 memory-mapped registers. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_TRANSLATE_VALUE0_REG 0x44 /*dword 0x47,0x46,0x45,0x44*/ >+/* >+*********************************************************************************** >+** Expansion ROM Limit Register - ERLR >+** >+** The Expansion ROM Limit Register (ERLR) defines the block size of addresses the ATU defines >+** as Expansion ROM address space. The block size is programmed by writing a value into the ERLR. >+** Bits 31 to 12 within the ERLR have a direct effect on the ERBAR register, bits 31 to 12, with a one >+** to one correspondence. A value of 0 in a bit within the ERLR makes the corresponding bit within >+** the ERBAR a read only bit which always returns 0. A value of 1 in a bit within the ERLR makes >+** the corresponding bit within the ERBAR read/write from PCI. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 000000H Expansion ROM Limit - Block size of memory required for the Expansion ROM translation unit. Default >+** value is 0, which indicates no Expansion ROM address space and all bits within the ERBAR are read only with a value of 0. >+** 11:00 000H Reserved. >+*********************************************************************************** >+*/ >+#define ARCMSR_EXPANSION_ROM_LIMIT_REG 0x48 /*dword 0x4B,0x4A,0x49,0x48*/ >+/* >+*********************************************************************************** >+** Expansion ROM Translate Value Register - ERTVR >+** >+** The Expansion ROM Translate Value Register contains the 80331 internal bus address which the >+** ATU converts the PCI bus access. This address is driven on the internal bus as a result of the >+** Expansion ROM address translation. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Expansion ROM Translation Value - Used to convert PCI addresses to 80331 internal bus addresses >+** for Expansion ROM accesses. The Expansion ROM address translation value must be word aligned on the internal bus. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_EXPANSION_ROM_TRANSLATE_VALUE_REG 0x4C /*dword 0x4F,0x4E,0x4D,0x4C*/ >+/* >+*********************************************************************************** >+** Inbound ATU Limit Register 1 - IALR1 >+** >+** Bits 31 to 12 within the IALR1 have a direct effect on the IABAR1 register, bits 31 to 12, with a >+** one to one correspondence. A value of 0 in a bit within the IALR1 makes the corresponding bit >+** within the IABAR1 a read only bit which always returns 0. A value of 1 in a bit within the IALR1 >+** makes the corresponding bit within the IABAR1 read/write from PCI. Note that a consequence of >+** this programming scheme is that unless a valid value exists within the IALR1, all writes to the >+** IABAR1 has no effect since a value of all zeros within the IALR1 makes the IABAR1 a read only >+** register. >+** The inbound memory window 1 is used merely to allocate memory on the PCI bus. The ATU does >+** not process any PCI bus transactions to this memory range. >+** Warning: The ATU does not claim any PCI accesses that fall within the range defined by IABAR1, >+** IAUBAR1, and IALR1. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Inbound Translation Limit 1 - This readback value determines the memory block size required for the ATUs memory window 1. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_LIMIT1_REG 0x50 /*dword 0x53,0x52,0x51,0x50*/ >+/* >+*********************************************************************************** >+** Inbound ATU Limit Register 2 - IALR2 >+** >+** Inbound address translation for memory window 2 occurs for data transfers occurring from the PCI >+** bus (originated from the PCI bus) to the 80331 internal bus. The address translation block converts >+** PCI addresses to internal bus addresses. >+** The inbound translation base address for inbound window 2 is specified in Section 3.10.15. When >+** determining block size requirements ¡X as described in Section 3.10.21 ¡X the translation limit >+** register provides the block size requirements for the base address register. The remaining registers >+** used for performing address translation are discussed in Section 3.2.1.1. >+** The 80331 translate value register¡¦s programmed value must be naturally aligned with the base >+** address register¡¦s programmed value. The limit register is used as a mask; thus, the lower address >+** bits programmed into the 80331 translate value register are invalid. Refer to the PCI Local Bus >+** Specification, Revision 2.3 for additional information on programming base address registers. >+** Bits 31 to 12 within the IALR2 have a direct effect on the IABAR2 register, bits 31 to 12, with a >+** one to one correspondence. A value of 0 in a bit within the IALR2 makes the corresponding bit >+** within the IABAR2 a read only bit which always returns 0. A value of 1 in a bit within the IALR2 >+** makes the corresponding bit within the IABAR2 read/write from PCI. Note that a consequence of >+** this programming scheme is that unless a valid value exists within the IALR2, all writes to the >+** IABAR2 has no effect since a value of all zeros within the IALR2 makes the IABAR2 a read only >+** register. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Inbound Translation Limit 2 - This readback value determines the memory block size required for the ATUs memory window 2. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_LIMIT2_REG 0x54 /*dword 0x57,0x56,0x55,0x54*/ >+/* >+*********************************************************************************** >+** Inbound ATU Translate Value Register 2 - IATVR2 >+** >+** The Inbound ATU Translate Value Register 2 (IATVR2) contains the internal bus address used to >+** convert PCI bus addresses. The converted address is driven on the internal bus as a result of the >+** inbound ATU address translation. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Inbound ATU Translation Value 2 - This value is used to convert the PCI address to internal bus addresses. >+** This value must be 64-bit aligned on the internal bus. The default address allows the ATU to access the internal 80331 memory-mapped registers. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_TRANSLATE_VALUE2_REG 0x58 /*dword 0x5B,0x5A,0x59,0x58*/ >+/* >+*********************************************************************************** >+** Outbound I/O Window Translate Value Register - OIOWTVR >+** >+** The Outbound I/O Window Translate Value Register (OIOWTVR) contains the PCI I/O address >+** used to convert the internal bus access to a PCI address. This address is driven on the PCI bus as a >+** result of the outbound ATU address translation. >+** The I/O window is from 80331 internal bus address 9000 000H to 9000 FFFFH with the fixed >+** length of 64 Kbytes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:16 0000H Outbound I/O Window Translate Value - Used to convert internal bus addresses to PCI addresses. >+** 15:00 0000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_IO_WINDOW_TRANSLATE_VALUE_REG 0x5C /*dword 0x5F,0x5E,0x5D,0x5C*/ >+/* >+*********************************************************************************** >+** Outbound Memory Window Translate Value Register 0 -OMWTVR0 >+** >+** The Outbound Memory Window Translate Value Register 0 (OMWTVR0) contains the PCI >+** address used to convert 80331 internal bus addresses for outbound transactions. This address is >+** driven on the PCI bus as a result of the outbound ATU address translation. >+** The memory window is from internal bus address 8000 000H to 83FF FFFFH with the fixed length >+** of 64 Mbytes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:26 00H Outbound MW Translate Value - Used to convert 80331 internal bus addresses to PCI addresses. >+** 25:02 00 0000H Reserved >+** 01:00 00 2 Burst Order - This bit field shows the address sequence during a memory burst. Only linear incrementing mode is supported. >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_MEMORY_WINDOW_TRANSLATE_VALUE0_REG 0x60 /*dword 0x63,0x62,0x61,0x60*/ >+/* >+*********************************************************************************** >+** Outbound Upper 32-bit Memory Window Translate Value Register 0 - OUMWTVR0 >+** >+** The Outbound Upper 32-bit Memory Window Translate Value Register 0 (OUMWTVR0) defines >+** the upper 32-bits of address used during a dual address cycle. This enables the outbound ATU to >+** directly address anywhere within the 64-bit host address space. When this register is all-zero, then >+** a SAC is generated on the PCI bus. >+** The memory window is from internal bus address 8000 000H to 83FF FFFFH with the fixed >+** length of 64 Mbytes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H These bits define the upper 32-bits of address driven during the dual address cycle (DAC). >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_UPPER32_MEMORY_WINDOW_TRANSLATE_VALUE0_REG 0x64 /*dword 0x67,0x66,0x65,0x64*/ >+/* >+*********************************************************************************** >+** Outbound Memory Window Translate Value Register 1 -OMWTVR1 >+** >+** The Outbound Memory Window Translate Value Register 1 (OMWTVR1) contains the PCI >+** address used to convert 80331 internal bus addresses for outbound transactions. This address is >+** driven on the PCI bus as a result of the outbound ATU address translation. >+** The memory window is from internal bus address 8400 000H to 87FF FFFFH with the fixed length >+** of 64 Mbytes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:26 00H Outbound MW Translate Value - Used to convert 80331 internal bus addresses to PCI addresses. >+** 25:02 00 0000H Reserved >+** 01:00 00 2 Burst Order - This bit field shows the address sequence during a memory burst. Only linear incrementing mode is supported. >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_MEMORY_WINDOW_TRANSLATE_VALUE1_REG 0x68 /*dword 0x6B,0x6A,0x69,0x68*/ >+/* >+*********************************************************************************** >+** Outbound Upper 32-bit Memory Window Translate Value Register 1 - OUMWTVR1 >+** >+** The Outbound Upper 32-bit Memory Window Translate Value Register 1 (OUMWTVR1) defines >+** the upper 32-bits of address used during a dual address cycle. This enables the outbound ATU to >+** directly address anywhere within the 64-bit host address space. When this register is all-zero, then >+** a SAC is generated on the PCI bus. >+** The memory window is from internal bus address 8400 000H to 87FF FFFFH with the fixed length >+** of 64 Mbytes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H These bits define the upper 32-bits of address driven during the dual address cycle (DAC). >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_UPPER32_MEMORY_WINDOW_TRANSLATE_VALUE1_REG 0x6C /*dword 0x6F,0x6E,0x6D,0x6C*/ >+/* >+*********************************************************************************** >+** Outbound Upper 32-bit Direct Window Translate Value Register - OUDWTVR >+** >+** The Outbound Upper 32-bit Direct Window Translate Value Register (OUDWTVR) defines the >+** upper 32-bits of address used during a dual address cycle for the transactions via Direct Addressing >+** Window. This enables the outbound ATU to directly address anywhere within the 64-bit host >+** address space. When this register is all-zero, then a SAC is generated on the PCI bus. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H These bits define the upper 32-bits of address driven during the dual address cycle (DAC). >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_UPPER32_DIRECT_WINDOW_TRANSLATE_VALUE_REG 0x78 /*dword 0x7B,0x7A,0x79,0x78*/ >+/* >+*********************************************************************************** >+** ATU Configuration Register - ATUCR >+** >+** The ATU Configuration Register controls the outbound address translation for address translation >+** unit. It also contains bits for Conventional PCI Delayed Read Command (DRC) aliasing, discard >+** timer status, SERR# manual assertion, SERR# detection interrupt masking, and ATU BIST >+** interrupt enabling. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:20 00H Reserved >+** 19 0 2 ATU DRC Alias - when set, the ATU does not distinguish read commands when attempting to match a >+** current PCI read transaction with read data enqueued within the DRC buffer. When clear, a current read >+** transaction must have the exact same read command as the DRR for the ATU to deliver DRC data. Not >+** applicable in the PCI-X mode. >+** 18 0 2 Direct Addressing Upper 2Gbytes Translation Enable - When set, with Direct Addressing enabled (bit 7 of the ATUCR set), the ATU forwards internal bus cycles with an address between 0000.0040H and >+** 7FFF.FFFFH to the PCI bus with bit 31 of the address set (8000.0000H - FFFF.FFFFH). When clear, no translation occurs. >+** 17 0 2 Reserved >+** 16 0 2 SERR# Manual Assertion - when set, the ATU asserts SERR# for one clock on the PCI interface. Until >+** cleared, SERR# may not be manually asserted again. Once cleared, operation proceeds as specified. >+** 15 0 2 ATU Discard Timer Status - when set, one of the 4 discard timers within the ATU has expired and >+** discarded the delayed completion transaction within the queue. When clear, no timer has expired. >+** 14:10 00000 2 Reserved >+** 09 0 2 SERR# Detected Interrupt Enable - When set, the Intel XScale core is signalled an HPI# interrupt >+** when the ATU detects that SERR# was asserted. When clear, the Intel XScale core is not interrupted when SERR# is detected. >+** 08 0 2 Direct Addressing Enable - Setting this bit enables direct outbound addressing through the ATU. >+** Internal bus cycles with an address between 0000.0040H and 7FFF.FFFFH automatically forwards to >+** the PCI bus with or without translation of address bit 31 based on the setting of bit 18 of the ATUCR. >+** 07:04 0000 2 Reserved >+** 03 0 2 ATU BIST Interrupt Enable - When set, enables an interrupt to the Intel XScale core when the start >+** BIST bit is set in the ATUBISTR register. This bit is also reflected as the BIST Capable bit 7 in the ATUBISTR register. >+** 02 0 2 Reserved >+** 01 0 2 Outbound ATU Enable - When set, enables the outbound address translation unit. When cleared, disables the outbound ATU. >+** 00 0 2 Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_CONFIGURATION_REG 0x80 /*dword 0x83,0x82,0x81,0x80*/ >+/* >+*********************************************************************************** >+** PCI Configuration and Status Register - PCSR >+** >+** The PCI Configuration and Status Register has additional bits for controlling and monitoring >+** various features of the PCI bus interface. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:19 0000H Reserved >+** 18 0 2 Detected Address or Attribute Parity Error - set when a parity error is detected during either the address >+** or attribute phase of a transaction on the PCI bus even when the ATUCMD register Parity Error >+** Response bit is cleared. Set under the following conditions: >+** ¡E Any Address or Attribute (PCI-X Only) Parity Error on the Bus (including one generated by the ATU). >+** 17:16 Varies with >+** external state >+** of DEVSEL#, >+** STOP#, and >+** TRDY#, >+** during >+** P_RST# >+** PCI-X capability - These two bits define the mode of the PCI bus (conventional or PCI-X) as well as the >+** operating frequency in the case of PCI-X mode. >+** 00 - Conventional PCI mode >+** 01 - PCI-X 66 >+** 10 - PCI-X 100 >+** 11 - PCI-X 133 >+** As defined by the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a, the operating >+** mode is determined by an initialization pattern on the PCI bus during P_RST# assertion: >+** DEVSEL# STOP# TRDY# Mode >+** Deasserted Deasserted Deasserted Conventional >+** Deasserted Deasserted Asserted PCI-X 66 >+** Deasserted Asserted Deasserted PCI-X 100 >+** Deasserted Asserted Asserted PCI-X 133 >+** All other patterns are reserved. >+** 15 0 2 >+** Outbound Transaction Queue Busy: >+** 0=Outbound Transaction Queue Empty >+** 1=Outbound Transaction Queue Busy >+** 14 0 2 >+** Inbound Transaction Queue Busy: >+** 0=Inbound Transaction Queue Empty >+** 1=Inbound Transaction Queue Busy >+** 13 0 2 Reserved. >+** 12 0 2 >+** Discard Timer Value - This bit controls the time-out value for the four discard timers attached to the queues holding read data. >+** A value of 0 indicates the time-out value is 2 15 clocks. >+** A value of 1 indicates the time-out value is 2 10 clocks. >+** 11 0 2 Reserved. >+** 10 Varies with >+** external state >+** of M66EN >+** during >+** P_RST# >+** Bus Operating at 66 MHz - When set, the interface has been initialized to function at 66 MHz in >+** Conventional PCI mode by the assertion of M66EN during bus initialization. When clear, the interface >+** has been initialized as a 33 MHz bus. >+** NOTE: When PCSR bits 17:16 are not equal to zero, then this bit is meaningless since the 80331 is >+** operating in PCI-X mode. >+** 09 0 2 Reserved >+** 08 Varies with >+** external state >+** of REQ64# >+** during >+** P_RST# >+** PCI Bus 64-Bit Capable - When clear, the PCI bus interface has been configured as 64-bit capable by >+** the assertion of REQ64# on the rising edge of P_RST#. When set, the PCI interface is configured as >+** 32-bit only. >+** 07:06 00 2 Reserved. >+** 05 0 2 Reset Internal Bus - This bit controls the reset of the Intel XScale core and all units on the internal >+** bus. In addition to the internal bus initialization, this bit triggers the assertion of the M_RST# pin for >+** initialization of registered DIMMs. When set: >+** When operating in the conventional PCI mode: >+** ¡E All current PCI transactions being mastered by the ATU completes, and the ATU master interfaces >+** proceeds to an idle state. No additional transactions is mastered by these units until the internal bus >+** reset is complete. >+** ¡E All current transactions being slaved by the ATU on either the PCI bus or the internal bus >+** completes, and the ATU target interfaces proceeds to an idle state. All future slave transactions >+** master aborts, with the exception of the completion cycle for the transaction that set the Reset >+** Internal Bus bit in the PCSR. >+** ¡E When the value of the Core Processor Reset bit in the PCSR (upon P_RST# assertion) is set, the >+** Intel XScale core is held in reset when the internal bus reset is complete. >+** ¡E The ATU ignores configuration cycles, and they appears as master aborts for: 32 Internal Bus clocks. >+** ¡E The 80331 hardware clears this bit after the reset operation completes. >+** When operating in the PCI-X mode: >+** The ATU hardware responds the same as in Conventional PCI-X mode. However, this may create a >+** problem in PCI-X mode for split requests in that there may still be an outstanding split completion that the >+** ATU is either waiting to receive (Outbound Request) or initiate (Inbound Read Request). For a cleaner >+** internal bus reset, host software can take the following steps prior to asserting Reset Internal bus: >+** 1. Clear the Bus Master (bit 2 of the ATUCMD) and the Memory Enable (bit 1 of the ATUCMD) bits in >+** the ATUCMD. This ensures that no new transactions, either outbound or inbound are enqueued. >+** 2. Wait for both the Outbound (bit 15 of the PCSR) and Inbound Read (bit 14 of the PCSR) Transaction >+** queue busy bits to be clear. >+** 3. Set the Reset Internal Bus bit >+** As a result, the ATU hardware resets the internal bus using the same logic as in conventional mode, >+** however the user is now assured that the ATU no longer has any pending inbound or outbound split >+** completion transactions. >+** NOTE: Since the Reset Internal Bus bit is set using an inbound configuration cycle, the user is >+** guaranteed that any prior configuration cycles have properly completed since there is only a one >+** deep transaction queue for configuration transaction requests. The ATU sends the appropriate >+** Split Write Completion Message to the Requester prior to the onset of Internal Bus Reset. >+** 04 0 2 Bus Master Indicator Enable: Provides software control for the Bus Master Indicator signal P_BMI used >+** for external RAIDIOS logic control of private devices. Only valid when operating with the bridge and >+** central resource/arbiter disabled (BRG_EN =low, ARB_EN=low). >+** 03 Varies with >+** external state >+** of PRIVDEV >+** during >+** P_RST# >+** Private Device Enable - This bit indicates the state of the reset strap which enables the private device >+** control mechanism within the PCI-to-PCI Bridge SISR configuration register. >+** 0=Private Device control Disabled - SISR register bits default to zero >+** 1=Private Device control Enabled - SISR register bits default to one >+** 02 Varies with >+** external state >+** of RETRY >+** during >+** P_RST# >+** Configuration Cycle Retry - When this bit is set, the PCI interface of the 80331 responds to all >+** configuration cycles with a Retry condition. When clear, the 80331 responds to the appropriate >+** configuration cycles. >+** The default condition for this bit is based on the external state of the RETRY pin at the rising edge of >+** P_RST#. When the external state of the pin is high, the bit is set. When the external state of the pin is >+** low, the bit is cleared. >+** 01 Varies with >+** external state >+** of >+** CORE_RST# >+** during >+** P_RST# >+** Core Processor Reset - This bit is set to its default value by the hardware when either P_RST# is >+** asserted or the Reset Internal Bus bit in PCSR is set. When this bit is set, the Intel XScale core is >+** being held in reset. Software cannot set this bit. Software is required to clear this bit to deassert Intel >+** XScale core reset. >+** The default condition for this bit is based on the external state of the CORE_RST# pin at the rising edge >+** of P_RST#. When the external state of the pin is low, the bit is set. When the external state of the pin is >+** high, the bit is clear. >+** 00 Varies with >+** external state >+** of PRIVMEM >+** during >+** P_RST# >+** Private Memory Enable - This bit indicates the state of the reset strap which enables the private device >+** control mechanism within the PCI-to-PCI Bridge SDER configuration register. >+** 0=Private Memory control Disabled - SDER register bit 2 default to zero >+** 1=Private Memory control Enabled - SDER register bits 2 default to one >+*********************************************************************************** >+*/ >+#define ARCMSR_PCI_CONFIGURATION_STATUS_REG 0x84 /*dword 0x87,0x86,0x85,0x84*/ >+/* >+*********************************************************************************** >+** ATU Interrupt Status Register - ATUISR >+** >+** The ATU Interrupt Status Register is used to notify the core processor of the source of an ATU >+** interrupt. In addition, this register is written to clear the source of the interrupt to the interrupt unit >+** of the 80331. All bits in this register are Read/Clear. >+** Bits 4:0 are a direct reflection of bits 14:11 and bit 8 (respectively) of the ATU Status Register >+** (these bits are set at the same time by hardware but need to be cleared independently). Bit 7 is set >+** by an error associated with the internal bus of the 80331. Bit 8 is for software BIST. The >+** conditions that result in an ATU interrupt are cleared by writing a 1 to the appropriate bits in this >+** register. >+** Note: Bits 4:0, and bits 15 and 13:7 can result in an interrupt being driven to the Intel XScale core. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:18 0000H Reserved >+** 17 0 2 VPD Address Register Updated - This bit is set when a PCI bus configuration write occurs to the VPDAR >+** register. Configuration register writes to the VPDAR does NOT result in bit 15 also being set. When set, >+** this bit results in the assertion of the ATU Configure Register Write Interrupt. >+** 16 0 2 Reserved >+** 15 0 2 ATU Configuration Write - This bit is set when a PCI bus configuration write occurs to any ATU register. >+** When set, this bit results in the assertion of the ATU Configure Register Write Interrupt. >+** 14 0 2 ATU Inbound Memory Window 1 Base Updated - This bit is set when a PCI bus configuration write >+** occurs to either the IABAR1 register or the IAUBAR1 register. Configuration register writes to these >+** registers deos NOT result in bit 15 also being set. When set, this bit results in the assertion of the ATU >+** Configure Register Write Interrupt. >+** 13 0 2 Initiated Split Completion Error Message - This bit is set when the device initiates a Split Completion >+** Message on the PCI Bus with the Split Completion Error attribute bit set. >+** 12 0 2 Received Split Completion Error Message - This bit is set when the device receives a Split Completion >+** Message from the PCI Bus with the Split Completion Error attribute bit set. >+** 11 0 2 Power State Transition - When the Power State Field of the ATU Power Management Control/Status >+** Register is written to transition the ATU function Power State from D0 to D3, D0 to D1, or D3 to D0 and >+** the ATU Power State Transition Interrupt mask bit is cleared, this bit is set. >+** 10 0 2 P_SERR# Asserted - set when P_SERR# is asserted on the PCI bus by the ATU. >+** 09 0 2 Detected Parity Error - set when a parity error is detected on the PCI bus even when the ATUCMD >+** register¡¦s Parity Error Response bit is cleared. Set under the following conditions: >+** ¡E Write Data Parity Error when the ATU is a target (inbound write). >+** ¡E Read Data Parity Error when the ATU is an initiator (outbound read). >+** ¡E Any Address or Attribute (PCI-X Only) Parity Error on the Bus. >+** 08 0 2 ATU BIST Interrupt - When set, generates the ATU BIST Start Interrupt and indicates the host processor >+** has set the Start BIST bit (ATUBISTR register bit 6), when the ATU BIST interrupt is enabled (ATUCR >+** register bit 3). The Intel XScale core can initiate the software BIST and store the result in ATUBISTR >+** register bits 3:0. >+** Configuration register writes to the ATUBISTR does NOT result in bit 15 also being set or the assertion >+** of the ATU Configure Register Write Interrupt. >+** 07 0 2 Internal Bus Master Abort - set when a transaction initiated by the ATU internal bus initiator interface ends in a Master-abort. >+** 06:05 00 2 Reserved. >+** 04 0 2 P_SERR# Detected - set when P_SERR# is detected on the PCI bus by the ATU. >+** 03 0 2 PCI Master Abort - set when a transaction initiated by the ATU PCI initiator interface ends in a Master-abort. >+** 02 0 2 PCI Target Abort (master) - set when a transaction initiated by the ATU PCI master interface ends in a Target-abort. >+** 01 0 2 PCI Target Abort (target) - set when the ATU interface, acting as a target, terminates the transaction on the PCI bus with a target abort. >+** 00 0 2 PCI Master Parity Error - Master Parity Error - The ATU interface sets this bit under the following >+** conditions: >+** ¡E The ATU asserted PERR# itself or the ATU observed PERR# asserted. >+** ¡E And the ATU acted as the requester for the operation in which the error occurred. >+** ¡E And the ATUCMD register¡¦s Parity Error Response bit is set >+** ¡E Or (PCI-X Mode Only) the ATU received a Write Data Parity Error Message >+** ¡E And the ATUCMD register¡¦s Parity Error Response bit is set >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_INTERRUPT_STATUS_REG 0x88 /*dword 0x8B,0x8A,0x89,0x88*/ >+/* >+*********************************************************************************** >+** ATU Interrupt Mask Register - ATUIMR >+** >+** The ATU Interrupt Mask Register contains the control bit to enable and disable interrupts >+** generated by the ATU. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:15 0 0000H Reserved >+** 14 0 2 VPD Address Register Updated Mask - Controls the setting of bit 17 of the ATUISR and generation of the >+** ATU Configuration Register Write interrupt when a PCI bus write occurs to the VPDAR register. >+** 0=Not Masked >+** 1=Masked >+** 13 0 2 Reserved >+** 12 0 2 Configuration Register Write Mask - Controls the setting of bit 15 of the ATUISR and generation of the >+** ATU Configuration Register Write interrupt when a PCI bus write occurs to any ATU configuration register >+** except those covered by mask bit 11 and bit 14 of this register, and ATU BIST enable bit 3 of the ATUCR. >+** 0=Not Masked >+** 1=Masked >+** 11 1 2 ATU Inbound Memory Window 1 Base Updated Mask - Controls the setting of bit 14 of the ATUISR and >+** generation of the ATU Configuration Register Write interrupt when a PCI bus write occurs to either the >+** IABAR1 register or the IAUBAR1 register. >+** 0=Not Masked >+** 1=Masked >+** 10 0 2 Initiated Split Completion Error Message Interrupt Mask - Controls the setting of bit 13 of the ATUISR and >+** generation of the ATU Error interrupt when the ATU initiates a Split Completion Error Message. >+** 0=Not Masked >+** 1=Masked >+** 09 0 2 Received Split Completion Error Message Interrupt Mask- Controls the setting of bit 12 of the ATUISR >+** and generation of the ATU Error interrupt when a Split Completion Error Message results in bit 29 of the >+** PCIXSR being set. >+** 0=Not Masked >+** 1=Masked >+** 08 1 2 Power State Transition Interrupt Mask - Controls the setting of bit 12 of the ATUISR and generation of the >+** ATU Error interrupt when ATU Power Management Control/Status Register is written to transition the >+** ATU Function Power State from D0 to D3, D0 to D1, D1 to D3 or D3 to D0. >+** 0=Not Masked >+** 1=Masked >+** 07 0 2 ATU Detected Parity Error Interrupt Mask - Controls the setting of bit 9 of the ATUISR and generation of >+** the ATU Error interrupt when a parity error detected on the PCI bus that sets bit 15 of the ATUSR. >+** 0=Not Masked >+** 1=Masked >+** 06 0 2 ATU SERR# Asserted Interrupt Mask - Controls the setting of bit 10 of the ATUISR and generation of the >+** ATU Error interrupt when SERR# is asserted on the PCI interface resulting in bit 14 of the ATUSR being set. >+** 0=Not Masked >+** 1=Masked >+** NOTE: This bit is specific to the ATU asserting SERR# and not detecting SERR# from another master. >+** 05 0 2 ATU PCI Master Abort Interrupt Mask - Controls the setting of bit 3 of the ATUISR and generation of the >+** ATU Error interrupt when a master abort error resulting in bit 13 of the ATUSR being set. >+** 0=Not Masked >+** 1=Masked >+** 04 0 2 ATU PCI Target Abort (Master) Interrupt Mask- Controls the setting of bit 12 of the ATUISR and ATU Error >+** generation of the interrupt when a target abort error resulting in bit 12 of the ATUSR being set >+** 0=Not Masked >+** 1=Masked >+** 03 0 2 ATU PCI Target Abort (Target) Interrupt Mask- Controls the setting of bit 1 of the ATUISR and generation >+** of the ATU Error interrupt when a target abort error resulting in bit 11 of the ATUSR being set. >+** 0=Not Masked >+** 1=Masked >+** 02 0 2 ATU PCI Master Parity Error Interrupt Mask - Controls the setting of bit 0 of the ATUISR and generation >+** of the ATU Error interrupt when a parity error resulting in bit 8 of the ATUSR being set. >+** 0=Not Masked >+** 1=Masked >+** 01 0 2 ATU Inbound Error SERR# Enable - Controls when the ATU asserts (when enabled through the >+** ATUCMD) SERR# on the PCI interface in response to a master abort on the internal bus during an >+** inbound write transaction. >+** 0=SERR# Not Asserted due to error >+** 1=SERR# Asserted due to error >+** 00 0 2 ATU ECC Target Abort Enable - Controls the ATU response on the PCI interface to a target abort (ECC >+** error) from the memory controller on the internal bus. In conventional mode, this action only occurs >+** during an inbound read transaction where the data phase that was target aborted on the internal bus is >+** actually requested from the inbound read queue. >+** 0=Disconnect with data (the data being up to 64 bits of 1¡¦s) >+** 1=Target Abort >+** NOTE: In PCI-X Mode, The ATU initiates a Split Completion Error Message (with message class=2h - >+** completer error and message index=81h - 80331 internal bus target abort) on the PCI bus, >+** independent of the setting of this bit. >+*********************************************************************************** >+*/ >+#define ARCMSR_ATU_INTERRUPT_MASK_REG 0x8C /*dword 0x8F,0x8E,0x8D,0x8C*/ >+/* >+*********************************************************************************** >+** Inbound ATU Base Address Register 3 - IABAR3 >+** >+** . The Inbound ATU Base Address Register 3 (IABAR3) together with the Inbound ATU Upper Base Address Register 3 (IAUBAR3) defines the block of memory addresses where the inbound translation window 3 begins. >+** . The inbound ATU decodes and forwards the bus request to the 80331 internal bus with a translated address to map into 80331 local memory. >+** . The IABAR3 and IAUBAR3 define the base address and describes the required memory block size. >+** . Bits 31 through 12 of the IABAR3 is either read/write bits or read only with a value of 0 depending on the value located within the IALR3. >+** The programmed value within the base address register must comply with the PCI programming requirements for address alignment. >+** Note: >+** Since IABAR3 does not appear in the standard PCI configuration header space (offsets 00H - 3CH), >+** IABAR3 is not configured by the host during normal system initialization. >+** Warning: >+** When a non-zero value is not written to IALR3, >+** the user should not set either the Prefetchable Indicator >+** or the Type Indicator for 64 bit addressability. >+** This is the default for IABAR3. >+** Assuming a non-zero value is written to IALR3, >+** the user may set the Prefetchable Indicator >+** or the Type Indicator: >+** a. Since non prefetchable memory windows can never be placed above the 4 Gbyte address boundary, >+** when the Prefetchable Indicator is not set, >+** the user should also leave the Type Indicator set for 32 bit addressability. >+** This is the default for IABAR3. >+** b. when the Prefetchable Indicator is set, >+** the user should also set the Type Indicator for 64 bit addressability. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Translation Base Address 3 - These bits define the actual location the translation function is to respond to when addressed from the PCI bus. >+** 11:04 00H Reserved. >+** 03 0 2 Prefetchable Indicator - When set, defines the memory space as prefetchable. >+** 02:01 00 2 Type Indicator - Defines the width of the addressability for this memory window: >+** 00 - Memory Window is locatable anywhere in 32 bit address space >+** 10 - Memory Window is locatable anywhere in 64 bit address space >+** 00 0 2 Memory Space Indicator - This bit field describes memory or I/O space base address. >+** The ATU does not occupy I/O space, >+** thus this bit must be zero. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_BASE_ADDRESS3_REG 0x90 /*dword 0x93,0x92,0x91,0x90*/ >+/* >+*********************************************************************************** >+** Inbound ATU Upper Base Address Register 3 - IAUBAR3 >+** >+** This register contains the upper base address when decoding PCI addresses beyond 4 GBytes. >+** Together with the Translation Base Address this register defines the actual location the translation function is to respond to when addressed from the PCI bus for addresses > 4GBytes (for DACs). >+** The programmed value within the base address register must comply with the PCI programming >+** requirements for address alignment. >+** Note: >+** When the Type indicator of IABAR3 is set to indicate 32 bit addressability, >+** the IAUBAR3 register attributes are read-only. >+** This is the default for IABAR3. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:0 00000H Translation Upper Base Address 3 - Together with the Translation Base Address 3 these bits define the actual location the translation function is to respond to when addressed from the PCI bus for addresses > 4GBytes. >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_UPPER_BASE_ADDRESS3_REG 0x94 /*dword 0x97,0x96,0x95,0x94*/ >+/* >+*********************************************************************************** >+** Inbound ATU Limit Register 3 - IALR3 >+** >+** Inbound address translation for memory window 3 occurs for data transfers occurring from the PCI >+** bus (originated from the PCI bus) to the 80331 internal bus. The address translation block converts >+** PCI addresses to internal bus addresses. >+** The inbound translation base address for inbound window 3 is specified in Section 3.10.15. When >+** determining block size requirements ¡X as described in Section 3.10.21 ¡X the translation limit >+** register provides the block size requirements for the base address register. The remaining registers >+** used for performing address translation are discussed in Section 3.2.1.1. >+** The 80331 translate value register¡¦s programmed value must be naturally aligned with the base >+** address register¡¦s programmed value. The limit register is used as a mask; thus, the lower address >+** bits programmed into the 80331 translate value register are invalid. Refer to the PCI Local Bus >+** Specification, Revision 2.3 for additional information on programming base address registers. >+** Bits 31 to 12 within the IALR3 have a direct effect on the IABAR3 register, bits 31 to 12, with a >+** one to one correspondence. A value of 0 in a bit within the IALR3 makes the corresponding bit >+** within the IABAR3 a read only bit which always returns 0. A value of 1 in a bit within the IALR3 >+** makes the corresponding bit within the IABAR3 read/write from PCI. Note that a consequence of >+** this programming scheme is that unless a valid value exists within the IALR3, all writes to the >+** IABAR3 has no effect since a value of all zeros within the IALR3 makes the IABAR3 a read only >+** register. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Inbound Translation Limit 3 - This readback value determines the memory block size required for the ATUs memory window 3. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_LIMIT3_REG 0x98 /*dword 0x9B,0x9A,0x99,0x98*/ >+/* >+*********************************************************************************** >+** Inbound ATU Translate Value Register 3 - IATVR3 >+** >+** The Inbound ATU Translate Value Register 3 (IATVR3) contains the internal bus address used to >+** convert PCI bus addresses. The converted address is driven on the internal bus as a result of the >+** inbound ATU address translation. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:12 00000H Inbound ATU Translation Value 3 - This value is used to convert the PCI address to internal bus addresses. >+** This value must be 64-bit aligned on the internal bus. The default address allows the ATU to >+** access the internal 80331 memory-mapped registers. >+** 11:00 000H Reserved >+*********************************************************************************** >+*/ >+#define ARCMSR_INBOUND_ATU_TRANSLATE_VALUE3_REG 0x9C /*dword 0x9F,0x9E,0x9D,0x9C*/ >+/* >+*********************************************************************************** >+** Outbound Configuration Cycle Address Register - OCCAR >+** >+** The Outbound Configuration Cycle Address Register is used to hold the 32-bit PCI configuration >+** cycle address. The Intel XScale core writes the PCI configuration cycles address which then >+** enables the outbound configuration read or write. The Intel XScale core then performs a read or >+** write to the Outbound Configuration Cycle Data Register to initiate the configuration cycle on the >+** PCI bus. >+** Note: Bits 15:11 of the configuration cycle address for Type 0 configuration cycles are defined differently >+** for Conventional versus PCI-X modes. When 80331 software programs the OCCAR to initiate a >+** Type 0 configuration cycle, the OCCAR should always be loaded based on the PCI-X definition for >+** the Type 0 configuration cycle address. When operating in Conventional mode, the 80331 clears >+** bits 15:11 of the OCCAR prior to initiating an outbound Type 0 configuration cycle. See the PCI-X >+** Addendum to the PCI Local Bus Specification, Revision 1.0a for details on the two formats. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H Configuration Cycle Address - These bits define the 32-bit PCI address used during an outbound configuration read or write cycle. >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_CONFIGURATION_CYCLE_ADDRESS_REG 0xA4 /*dword 0xA7,0xA6,0xA5,0xA4*/ >+/* >+*********************************************************************************** >+** Outbound Configuration Cycle Data Register - OCCDR >+** >+** The Outbound Configuration Cycle Data Register is used to initiate a configuration read or write >+** on the PCI bus. The register is logical rather than physical meaning that it is an address not a >+** register. The Intel XScale core reads or writes the data registers memory-mapped address to >+** initiate the configuration cycle on the PCI bus with the address found in the OCCAR. For a >+** configuration write, the data is latched from the internal bus and forwarded directly to the OWQ. >+** For a read, the data is returned directly from the ORQ to the Intel XScale core and is never >+** actually entered into the data register (which does not physically exist). >+** The OCCDR is only visible from 80331 internal bus address space and appears as a reserved value >+** within the ATU configuration space. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H Configuration Cycle Data - These bits define the data used during an outbound configuration read or write cycle. >+*********************************************************************************** >+*/ >+#define ARCMSR_OUTBOUND_CONFIGURATION_CYCLE_DATA_REG 0xAC /*dword 0xAF,0xAE,0xAD,0xAC*/ >+/* >+*********************************************************************************** >+** VPD Capability Identifier Register - VPD_CAPID >+** >+** The Capability Identifier Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register in the PCI Extended Capability header identifies the type of Extended >+** Capability contained in that header. In the case of the 80331, this is the VPD extended capability >+** with an ID of 03H as defined by the PCI Local Bus Specification, Revision 2.3. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 03H Cap_Id - This field with its¡¦ 03H value identifies this item in the linked list of Extended Capability Headers as being the VPD capability registers. >+*********************************************************************************** >+*/ >+#define ARCMSR_VPD_CAPABILITY_IDENTIFIER_REG 0xB8 /*byte*/ >+/* >+*********************************************************************************** >+** VPD Next Item Pointer Register - VPD_NXTP >+** >+** The Next Item Pointer Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register describes the location of the next item in the function¡¦s capability list. >+** For the 80331, this the final capability list, and hence, this register is set to 00H. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 00H Next_ Item_ Pointer - This field provides an offset into the function¡¦s configuration space pointing to the >+** next item in the function¡¦s capability list. Since the VPD capabilities are the last in the linked list of >+** extended capabilities in the 80331, the register is set to 00H. >+*********************************************************************************** >+*/ >+#define ARCMSR_VPD_NEXT_ITEM_PTR_REG 0xB9 /*byte*/ >+/* >+*********************************************************************************** >+** VPD Address Register - VPD_AR >+** >+** The VPD Address register (VPDAR) contains the DWORD-aligned byte address of the VPD to be >+** accessed. The register is read/write and the initial value at power-up is indeterminate. >+** A PCI Configuration Write to the VPDAR interrupts the Intel XScale core. Software can use >+** the Flag setting to determine whether the configuration write was intended to initiate a read or >+** write of the VPD through the VPD Data Register. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15 0 2 Flag - A flag is used to indicate when a transfer of data between the VPD Data Register and the storage >+** component has completed. Please see Section 3.9, ¡§Vital Product Data¡¨ on page 201 for more details on >+** how the 80331 handles the data transfer. >+** 14:0 0000H VPD Address - This register is written to set the DWORD-aligned byte address used to read or write >+** Vital Product Data from the VPD storage component. >+*********************************************************************************** >+*/ >+#define ARCMSR_VPD_ADDRESS_REG 0xBA /*word 0xBB,0xBA*/ >+/* >+*********************************************************************************** >+** VPD Data Register - VPD_DR >+** >+** This register is used to transfer data between the 80331 and the VPD storage component. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000H VPD Data - Four bytes are always read or written through this register to/from the VPD storage component. >+*********************************************************************************** >+*/ >+#define ARCMSR_VPD_DATA_REG 0xBC /*dword 0xBF,0xBE,0xBD,0xBC*/ >+/* >+*********************************************************************************** >+** Power Management Capability Identifier Register -PM_CAPID >+** >+** The Capability Identifier Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register in the PCI Extended Capability header identifies the type of Extended >+** Capability contained in that header. In the case of the 80331, this is the PCI Bus Power >+** Management extended capability with an ID of 01H as defined by the PCI Bus Power Management >+** Interface Specification, Revision 1.1. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 01H Cap_Id - This field with its¡¦ 01H value identifies this item in the linked list of Extended Capability Headers as being the PCI Power Management Registers. >+*********************************************************************************** >+*/ >+#define ARCMSR_POWER_MANAGEMENT_CAPABILITY_IDENTIFIER_REG 0xC0 /*byte*/ >+/* >+*********************************************************************************** >+** Power Management Next Item Pointer Register - PM_NXTP >+** >+** The Next Item Pointer Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register describes the location of the next item in the function¡¦s capability list. >+** For the 80331, the next capability (MSI capability list) is located at off-set D0H. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 D0H Next_ Item_ Pointer - This field provides an offset into the function¡¦s configuration space pointing to the >+** next item in the function¡¦s capability list which in the 80331 is the MSI extended capabilities header. >+*********************************************************************************** >+*/ >+#define ARCMSR_POWER_NEXT_ITEM_PTR_REG 0xC1 /*byte*/ >+/* >+*********************************************************************************** >+** Power Management Capabilities Register - PM_CAP >+** >+** Power Management Capabilities bits adhere to the definitions in the PCI Bus Power Management >+** Interface Specification, Revision 1.1. This register is a 16-bit read-only register which provides >+** information on the capabilities of the ATU function related to power management. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:11 00000 2 PME_Support - This function is not capable of asserting the PME# signal in any state, since PME# is not supported by the 80331. >+** 10 0 2 D2_Support - This bit is set to 0 2 indicating that the 80331 does not support the D2 Power Management State >+** 9 1 2 D1_Support - This bit is set to 1 2 indicating that the 80331 supports the D1 Power Management State >+** 8:6 000 2 Aux_Current - This field is set to 000 2 indicating that the 80331 has no current requirements for the >+** 3.3Vaux signal as defined in the PCI Bus Power Management Interface Specification, Revision 1.1 >+** 5 0 2 DSI - This field is set to 0 2 meaning that this function requires a device specific initialization sequence >+** following the transition to the D0 uninitialized state. >+** 4 0 2 Reserved. >+** 3 0 2 PME Clock - Since the 80331 does not support PME# signal generation this bit is cleared to 0 2 . >+** 2:0 010 2 Version - Setting these bits to 010 2 means that this function complies with PCI Bus Power Management Interface Specification, Revision 1.1 >+*********************************************************************************** >+*/ >+#define ARCMSR_POWER_MANAGEMENT_CAPABILITY_REG 0xC2 /*word 0xC3,0xC2*/ >+/* >+*********************************************************************************** >+** Power Management Control/Status Register - PM_CSR >+** >+** Power Management Control/Status bits adhere to the definitions in the PCI Bus Power >+** Management Interface Specification, Revision 1.1. This 16-bit register is the control and status >+** interface for the power management extended capability. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15 0 2 PME_Status - This function is not capable of asserting the PME# signal in any state, since PME## is not supported by the 80331. >+** 14:9 00H Reserved >+** 8 0 2 PME_En - This bit is hardwired to read-only 0 2 since this function does not support PME# generation from any power state. >+** 7:2 000000 2 Reserved >+** 1:0 00 2 Power State - This 2-bit field is used both to determine the current power state of a function and to set the function into a new power state. The definition of the values is: >+** 00 2 - D0 >+** 01 2 - D1 >+** 10 2 - D2 (Unsupported) >+** 11 2 - D3 hot >+** The 80331 supports only the D0 and D3 hot states. >+** >+*********************************************************************************** >+*/ >+#define ARCMSR_POWER_MANAGEMENT_CONTROL_STATUS_REG 0xC4 /*word 0xC5,0xC4*/ >+/* >+*********************************************************************************** >+** PCI-X Capability Identifier Register - PX_CAPID >+** >+** The Capability Identifier Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register in the PCI Extended Capability header identifies the type of Extended >+** Capability contained in that header. In the case of the 80331, this is the PCI-X extended capability with >+** an ID of 07H as defined by the PCI-X Addendum to the PCI Local Bus Specification, Revision 1.0a. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 07H Cap_Id - This field with its¡¦ 07H value identifies this item in the linked list of Extended Capability Headers as being the PCI-X capability registers. >+*********************************************************************************** >+*/ >+#define ARCMSR_PCIX_CAPABILITY_IDENTIFIER_REG 0xE0 /*byte*/ >+/* >+*********************************************************************************** >+** PCI-X Next Item Pointer Register - PX_NXTP >+** >+** The Next Item Pointer Register bits adhere to the definitions in the PCI Local Bus Specification, >+** Revision 2.3. This register describes the location of the next item in the function¡¦s capability list. >+** By default, the PCI-X capability is the last capabilities list for the 80331, thus this register defaults >+** to 00H. >+** However, this register may be written to B8H prior to host configuration to include the VPD >+** capability located at off-set B8H. >+** Warning: Writing this register to any value other than 00H (default) or B8H is not supported and may >+** produce unpredictable system behavior. >+** In order to guarantee that this register is written prior to host configuration, the 80331 must be >+** initialized at P_RST# assertion to Retry Type 0 configuration cycles (bit 2 of PCSR). Typically, >+** the Intel XScale core would be enabled to boot immediately following P_RST# assertion in >+** this case (bit 1 of PCSR), as well. Please see Table 125, ¡§PCI Configuration and Status Register - >+** PCSR¡¨ on page 253 for more details on the 80331 initialization modes. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 07:00 00H Next_ Item_ Pointer - This field provides an offset into the function¡¦s configuration space pointing to the >+** next item in the function¡¦s capability list. Since the PCI-X capabilities are the last in the linked list of >+** extended capabilities in the 80331, the register is set to 00H. >+** However, this field may be written prior to host configuration with B8H to extend the list to include the >+** VPD extended capabilities header. >+*********************************************************************************** >+*/ >+#define ARCMSR_PCIX_NEXT_ITEM_PTR_REG 0xE1 /*byte*/ >+/* >+*********************************************************************************** >+** PCI-X Command Register - PX_CMD >+** >+** This register controls various modes and features of ATU and Message Unit when operating in the >+** PCI-X mode. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 15:7 000000000 2 Reserved. >+** 6:4 011 2 Maximum Outstanding Split Transactions - This register sets the maximum number of Split Transactions >+** the device is permitted to have outstanding at one time. >+** Register Maximum Outstanding >+** 0 1 >+** 1 2 >+** 2 3 >+** 3 4 >+** 4 8 >+** 5 12 >+** 6 16 >+** 7 32 >+** 3:2 00 2 Maximum Memory Read Byte Count - This register sets the maximum byte count the device uses when >+** initiating a Sequence with one of the burst memory read commands. >+** Register Maximum Byte Count >+** 0 512 >+** 1 1024 >+** 2 2048 >+** 3 4096 >+** 1 0 2 >+** Enable Relaxed Ordering - The 80331 does not set the relaxed ordering bit in the Requester Attributes >+** of Transactions. >+** 0 0 2 Data Parity Error Recovery Enable - The device driver sets this bit to enable the device to attempt to >+** recover from data parity errors. When this bit is 0 and the device is in PCI-X mode, the device asserts >+** SERR# (when enabled) whenever the Master Data Parity Error bit (Status register, bit 8) is set. >+*********************************************************************************** >+*/ >+#define ARCMSR_PCIX_COMMAND_REG 0xE2 /*word 0xE3,0xE2*/ >+/* >+*********************************************************************************** >+** PCI-X Status Register - PX_SR >+** >+** This register identifies the capabilities and current operating mode of ATU, DMAs and Message >+** Unit when operating in the PCI-X mode. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:30 00 2 Reserved >+** 29 0 2 Received Split Completion Error Message - This bit is set when the device receives a Split Completion >+** Message with the Split Completion Error attribute bit set. Once set, this bit remains set until software >+** writes a 1 to this location. >+** 0=no Split Completion error message received. >+** 1=a Split Completion error message has been received. >+** 28:26 001 2 Designed Maximum Cumulative Read Size (DMCRS) - The value of this register depends on the setting >+** of the Maximum Memory Read Byte Count field of the PCIXCMD register: >+** DMCRS Max ADQs Maximum Memory Read Byte Count Register Setting >+** 1 16 512 (Default) >+** 2 32 1024 >+** 2 32 2048 >+** 2 32 4096 >+** 25:23 011 2 Designed Maximum Outstanding Split Transactions - The 80331 can have up to four outstanding split transactions. >+** 22:21 01 2 Designed Maximum Memory Read Byte Count - The 80331 can generate memory reads with byte counts up to 1024 bytes. >+** 20 1 2 80331 is a complex device. >+** 19 0 2 Unexpected Split Completion - This bit is set when an unexpected Split Completion with this device¡¦s >+** Requester ID is received. Once set, this bit remains set until software writes a 1 to this location. >+** 0=no unexpected Split Completion has been received. >+** 1=an unexpected Split Completion has been received. >+** 18 0 2 Split Completion Discarded - This bit is set when the device discards a Split Completion because the >+** requester would not accept it. See Section 5.4.4 of the PCI-X Addendum to the PCI Local Bus >+** Specification, Revision 1.0a for details. Once set, this bit remains set until software writes a 1 to this >+** location. >+** 0=no Split Completion has been discarded. >+** 1=a Split Completion has been discarded. >+** NOTE: The 80331 does not set this bit since there is no Inbound address responding to Inbound Read >+** Requests with Split Responses (Memory or Register) that has ¡§read side effects.¡¨ >+** 17 1 2 80331 is a 133 MHz capable device. >+** 16 1 2 or P_32BITPCI# 80331 with bridge enabled (BRG_EN=1) implements the ATU with a 64-bit interface on the secondary PCI bus, therefore this bit is always set. >+** 80331 with no bridge and central resource disabled (BRG_EN=0, ARB_EN=0), use this bit to identify the add-in card to the system as 64-bit or 32-bit wide via a user-configurable strap (P_32BITPCI#). >+** This strap, by default, identifies the add in card based on 80331 with bridge disabled as 64-bit unless the user attaches the appropriate pull-down resistor to the strap. >+** 0=The bus is 32 bits wide. >+** 1=The bus is 64 bits wide. >+** 15:8 FFH Bus Number - This register is read for diagnostic purposes only. It indicates the number of the bus >+** segment for the device containing this function. The function uses this number as part of its Requester >+** ID and Completer ID. For all devices other than the source bridge, each time the function is addressed >+** by a Configuration Write transaction, the function must update this register with the contents of AD[7::0] >+** of the attribute phase of the Configuration Write, regardless of which register in the function is >+** addressed by the transaction. The function is addressed by a Configuration Write transaction when all of >+** the following are true: >+** 1. The transaction uses a Configuration Write command. >+** 2. IDSEL is asserted during the address phase. >+** 3. AD[1::0] are 00b (Type 0 configuration transaction). >+** 4. AD[10::08] of the configuration address contain the appropriate function number. >+** 7:3 1FH Device Number - This register is read for diagnostic purposes only. It indicates the number of the device >+** containing this function, i.e., the number in the Device Number field (AD[15::11]) of the address of a >+** Type 0 configuration transaction that is assigned to the device containing this function by the connection >+** of the system hardware. The system must assign a device number other than 00h (00h is reserved for >+** the source bridge). The function uses this number as part of its Requester ID and Completer ID. Each >+** time the function is addressed by a Configuration Write transaction, the device must update this register >+** with the contents of AD[15::11] of the address phase of the Configuration Write, regardless of which >+** register in the function is addressed by the transaction. The function is addressed by a Configuration >+** Write transaction when all of the following are true: >+** 1. The transaction uses a Configuration Write command. >+** 2. IDSEL is asserted during the address phase. >+** 3. AD[1::0] are 00b (Type 0 configuration transaction). >+** 4. AD[10::08] of the configuration address contain the appropriate function number. >+** 2:0 000 2 Function Number - This register is read for diagnostic purposes only. It indicates the number of this >+** function; i.e., the number in the Function Number field (AD[10::08]) of the address of a Type 0 >+** configuration transaction to which this function responds. The function uses this number as part of its >+** Requester ID and Completer ID. >+** >+************************************************************************** >+*/ >+#define ARCMSR_PCIX_STATUS_REG 0xE4 /*dword 0xE7,0xE6,0xE5,0xE4*/ >+ >+/* >+************************************************************************** >+** Inbound Read Transaction >+** ======================================================================== >+** An inbound read transaction is initiated by a PCI initiator and is targeted at either 80331 local >+** memory or a 80331 memory-mapped register space. The read transaction is propagated through >+** the inbound transaction queue (ITQ) and read data is returned through the inbound read queue >+** (IRQ). >+** When operating in the conventional PCI mode, all inbound read transactions are processed as >+** delayed read transactions. When operating in the PCI-X mode, all inbound read transactions are >+** processed as split transactions. The ATUs PCI interface claims the read transaction and forwards >+** the read request through to the internal bus and returns the read data to the PCI bus. Data flow for >+** an inbound read transaction on the PCI bus is summarized in the following statements: >+** ¡E The ATU claims the PCI read transaction when the PCI address is within the inbound >+** translation window defined by ATU Inbound Base Address Register (and Inbound Upper Base >+** Address Register during DACs) and Inbound Limit Register. >+** ¡E When operating in the conventional PCI mode, when the ITQ is currently holding transaction >+** information from a previous delayed read, the current transaction information is compared to >+** the previous transaction information (based on the setting of the DRC Alias bit in >+** Section 3.10.39, ¡§ATU Configuration Register - ATUCR¡¨ on page 252). When there is a >+** match and the data is in the IRQ, return the data to the master on the PCI bus. When there is a >+** match and the data is not available, a Retry is signaled with no other action taken. When there >+** is not a match and when the ITQ has less than eight entries, capture the transaction >+** information, signal a Retry and initiate a delayed transaction. When there is not a match and >+** when the ITQ is full, then signal a Retry with no other action taken. >+** ¡X When an address parity error is detected, the address parity response defined in >+** Section 3.7 is used. >+** ¡E When operating in the conventional PCI mode, once read data is driven onto the PCI bus from >+** the IRQ, it continues until one of the following is true: >+** ¡X The initiator completes the PCI transaction. When there is data left unread in the IRQ, the >+** data is flushed. >+** ¡X An internal bus Target Abort was detected. In this case, the QWORD associated with the >+** Target Abort is never entered into the IRQ, and therefore is never returned. >+** ¡X Target Abort or a Disconnect with Data is returned in response to the Internal Bus Error. >+** ¡X The IRQ becomes empty. In this case, the PCI interface signals a Disconnect with data to >+** the initiator on the last data word available. >+** ¡E When operating in the PCI-X mode, when ITQ is not full, the PCI address, attribute and >+** command are latched into the available ITQ and a Split Response Termination is signalled to >+** the initiator. >+** ¡E When operating in the PCI-X mode, when the transaction does not cross a 1024 byte aligned >+** boundary, then the ATU waits until it receives the full byte count from the internal bus target >+** before returning read data by generating the split completion transaction on the PCI-X bus. >+** When the read requested crosses at least one 1024 byte boundary, then ATU completes the >+** transfer by returning data in 1024 byte aligned chunks. >+** ¡E When operating in the PCI-X mode, once a split completion transaction has started, it >+** continues until one of the following is true: >+** ¡X The requester (now the target) generates a Retry Termination, or a Disconnection at Next >+** ADB (when the requester is a bridge) >+** ¡X The byte count is satisfied. >+** ¡X An internal bus Target Abort was detected. The ATU generates a Split Completion >+** Message (message class=2h - completer error, and message index=81h - target abort) to >+** inform the requester about the abnormal condition. The ITQ for this transaction is flushed. >+** Refer to Section 3.7.1. >+** ¡X An internal bus Master Abort was detected. The ATU generates a Split Completion >+** Message (message class=2h - completer error, and message index=80h - Master abort) to >+** inform the requester about the abnormal condition. The ITQ for this transaction is flushed. >+** Refer to Section 3.7.1 >+** ¡E When operating in the conventional PCI mode, when the master inserts wait states on the PCI >+** bus, the ATU PCI slave interface waits with no premature disconnects. >+** ¡E When a data parity error occurs signified by PERR# asserted from the initiator, no action is >+** taken by the target interface. Refer to Section 3.7.2.5. >+** ¡E When operating in the conventional PCI mode, when the read on the internal bus is >+** target-aborted, either a target-abort or a disconnect with data is signaled to the initiator. This is >+** based on the ATU ECC Target Abort Enable bit (bit 0 of the ATUIMR for ATU). When set, a >+** target abort is used, when clear, a disconnect is used. >+** ¡E When operating in the PCI-X mode (with the exception of the MU queue ports at offsets 40h >+** and 44h), when the transaction on the internal bus resulted in a target abort, the ATU generates >+** a Split Completion Message (message class=2h - completer error, and message index=81h - >+** internal bus target abort) to inform the requester about the abnormal condition. For the MU >+** queue ports, the ATU returns either a target abort or a single data phase disconnect depending >+** on the ATU ECC Target Abort Enable bit (bit 0 of the ATUIMR for ATU). The ITQ for this >+** transaction is flushed. Refer to Section 3.7.1. >+** ¡E When operating in the conventional PCI mode, when the transaction on the internal bus >+** resulted in a master abort, the ATU returns a target abort to inform the requester about the >+** abnormal condition. The ITQ for this transaction is flushed. Refer to Section 3.7.1 >+** ¡E When operating in the PCI-X mode, when the transaction on the internal bus resulted in a >+** master abort, the ATU generates a Split Completion Message (message class=2h - completer >+** error, and message index=80h - internal bus master abort) to inform the requester about the >+** abnormal condition. The ITQ for this transaction is flushed. Refer to Section 3.7.1. >+** ¡E When operating in the PCI-X mode, when the Split Completion transaction completes with >+** either Master-Abort or Target-Abort, the requester is indicating a failure condition that >+** prevents it from accepting the completion it requested. In this case, since the Split Request >+** addresses a location that has no read side effects, the completer must discard the Split >+** Completion and take no further action. >+** The data flow for an inbound read transaction on the internal bus is summarized in the following >+** statements: >+** ¡E The ATU internal bus master interface requests the internal bus when a PCI address appears in >+** an ITQ and transaction ordering has been satisfied. When operating in the PCI-X mode the >+** ATU does not use the information provided by the Relax Ordering Attribute bit. That is, ATU >+** always uses conventional PCI ordering rules. >+** ¡E Once the internal bus is granted, the internal bus master interface drives the translated address >+** onto the bus and wait for IB_DEVSEL#. When a Retry is signaled, the request is repeated. >+** When a master abort occurs, the transaction is considered complete and a target abort is loaded >+** into the associated IRQ for return to the PCI initiator (transaction is flushed once the PCI >+** master has been delivered the target abort). >+** ¡E Once the translated address is on the bus and the transaction has been accepted, the internal >+** bus target starts returning data with the assertion of IB_TRDY#. Read data is continuously >+** received by the IRQ until one of the following is true: >+** ¡X The full byte count requested by the ATU read request is received. The ATU internal bus >+** initiator interface performs a initiator completion in this case. >+** ¡X When operating in the conventional PCI mode, a Target Abort is received on the internal >+** bus from the internal bus target. In this case, the transaction is aborted and the PCI side is >+** informed. >+** ¡X When operating in the PCI-X mode, a Target Abort is received on the internal bus from >+** the internal bus target. In this case, the transaction is aborted. The ATU generates a Split >+** Completion Message (message class=2h - completer error, and message index=81h - >+** target abort) on the PCI bus to inform the requester about the abnormal condition. The >+** ITQ for this transaction is flushed. >+** ¡X When operating in the conventional PCI mode, a single data phase disconnection is >+** received from the internal bus target. When the data has not been received up to the next >+** QWORD boundary, the ATU internal bus master interface attempts to reacquire the bus. >+** When not, the bus returns to idle. >+** ¡X When operating in the PCI-X mode, a single data phase disconnection is received from >+** the internal bus target. The ATU IB initiator interface attempts to reacquire the bus to >+** obtain remaining data. >+** ¡X When operating in the conventional PCI mode, a disconnection at Next ADB is received >+** from the internal bus target. The bus returns to idle. >+** ¡X When operating in the PCI-X mode, a disconnection at Next ADB is received from the >+** internal bus target. The ATU IB initiator interface attempts to reacquire the bus to obtain >+** remaining data. >+** To support PCI Local Bus Specification, Revision 2.0 devices, the ATU can be programmed to >+** ignore the memory read command (Memory Read, Memory Read Line, and Memory Read >+** Multiple) when trying to match the current inbound read transaction with data in a DRC queue >+** which was read previously (DRC on target bus). When the Read Command Alias Bit in the >+** ATUCR register is set, the ATU does not distinguish the read commands on transactions. For >+** example, the ATU enqueues a DRR with a Memory Read Multiple command and performs the read >+** on the internal bus. Some time later, a PCI master attempts a Memory Read with the same address >+** as the previous Memory Read Multiple. When the Read Command Bit is set, the ATU would return >+** the read data from the DRC queue and consider the Delayed Read transaction complete. When the >+** Read Command bit in the ATUCR was clear, the ATU would not return data since the PCI read >+** commands did not match, only the address. >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** Inbound Write Transaction >+**======================================================================== >+** An inbound write transaction is initiated by a PCI master and is targeted at either 80331 local >+** memory or a 80331 memory-mapped register. >+** Data flow for an inbound write transaction on the PCI bus is summarized as: >+** ¡E The ATU claims the PCI write transaction when the PCI address is within the inbound >+** translation window defined by the ATU Inbound Base Address Register (and Inbound Upper >+** Base Address Register during DACs) and Inbound Limit Register. >+** ¡E When the IWADQ has at least one address entry available and the IWQ has at least one buffer >+** available, the address is captured and the first data phase is accepted. >+** ¡E The PCI interface continues to accept write data until one of the following is true: >+** ¡X The initiator performs a disconnect. >+** ¡X The transaction crosses a buffer boundary. >+** ¡E When an address parity error is detected during the address phase of the transaction, the >+** address parity error mechanisms are used. Refer to Section 3.7.1 for details of the address >+** parity error response. >+** ¡E When operating in the PCI-X mode when an attribute parity error is detected, the attribute >+** parity error mechanism described in Section 3.7.1 is used. >+** ¡E When a data parity error is detected while accepting data, the slave interface sets the >+** appropriate bits based on PCI specifications. No other action is taken. Refer to Section 3.7.2.6 >+** for details of the inbound write data parity error response. >+** Once the PCI interface places a PCI address in the IWADQ, when IWQ has received data sufficient >+** to cross a buffer boundary or the master disconnects on the PCI bus, the ATUs internal bus >+** interface becomes aware of the inbound write. When there are additional write transactions ahead >+** in the IWQ/IWADQ, the current transaction remains posted until ordering and priority have been >+** satisfied (Refer to Section 3.5.3) and the transaction is attempted on the internal bus by the ATU >+** internal master interface. The ATU does not insert target wait states nor do data merging on the PCI >+** interface, when operating in the PCI mode. >+** In the PCI-X mode memory writes are always executed as immediate transactions, while >+** configuration write transactions are processed as split transactions. The ATU generates a Split >+** Completion Message, (with Message class=0h - Write Completion Class and Message index = >+** 00h - Write Completion Message) once a configuration write is successfully executed. >+** Also, when operating in the PCI-X mode a write sequence may contain multiple write transactions. >+** The ATU handles such transactions as independent transactions. >+** Data flow for the inbound write transaction on the internal bus is summarized as: >+** ¡E The ATU internal bus master requests the internal bus when IWADQ has at least one entry >+** with associated data in the IWQ. >+** ¡E When the internal bus is granted, the internal bus master interface initiates the write >+** transaction by driving the translated address onto the internal bus. For details on inbound >+** address translation. >+** ¡E When IB_DEVSEL# is not returned, a master abort condition is signaled on the internal bus. >+** The current transaction is flushed from the queue and SERR# may be asserted on the PCI >+** interface. >+** ¡E The ATU initiator interface asserts IB_REQ64# to attempt a 64-bit transfer. When >+** IB_ACK64# is not returned, a 32-bit transfer is used. Transfers of less than 64-bits use the >+** IB_C/BE[7:0]# to mask the bytes not written in the 64-bit data phase. Write data is transferred >+** from the IWQ to the internal bus when data is available and the internal bus interface retains >+** internal bus ownership. >+** ¡E The internal bus interface stops transferring data from the current transaction to the internal >+** bus when one of the following conditions becomes true: >+** ¡X The internal bus initiator interface loses bus ownership. The ATU internal initiator >+** terminates the transfer (initiator disconnection) at the next ADB (for the internal bus ADB >+** is defined as a naturally aligned 128-byte boundary) and attempt to reacquire the bus to >+** complete the delivery of remaining data using the same sequence ID but with the >+** modified starting address and byte count. >+** ¡X A Disconnect at Next ADB is signaled on the internal bus from the internal target. When >+** the transaction in the IWQ completes at that ADB, the initiator returns to idle. When the >+** transaction in the IWQ is not complete, the initiator attempts to reacquire the bus to >+** complete the delivery of remaining data using the same sequence ID but with the >+** modified starting address and byte count. >+** ¡X A Single Data Phase Disconnect is signaled on the internal bus from the internal target. >+** When the transaction in the IWQ needs only a single data phase, the master returns to idle. >+** When the transaction in the IWQ is not complete, the initiator attempts to reacquire the >+** bus to complete the delivery of remaining data using the same sequence ID but with the >+** modified starting address and byte count. >+** ¡X The data from the current transaction has completed (satisfaction of byte count). An >+** initiator termination is performed and the bus returns to idle. >+** ¡X A Master Abort is signaled on the internal bus. SERR# may be asserted on the PCI bus. >+** Data is flushed from the IWQ. >+***************************************************************** >+*/ >+ >+ >+ >+/* >+************************************************************************** >+** Inbound Read Completions Data Parity Errors >+**======================================================================== >+** As an initiator, the ATU may encounter this error condition when operating in the PCI-X mode. >+** When as the completer of a Split Read Request the ATU observes PERR# assertion during the split >+** completion transaction, the ATU attempts to complete the transaction normally and no further >+** action is taken. >+************************************************************************** >+*/ >+ >+/* >+************************************************************************** >+** Inbound Configuration Write Completion Message Data Parity Errors >+**======================================================================== >+** As an initiator, the ATU may encounter this error condition when operating in the PCI-X mode. >+** When as the completer of a Configuration (Split) Write Request the ATU observes PERR# >+** assertion during the split completion transaction, the ATU attempts to complete the transaction >+** normally and no further action is taken. >+************************************************************************** >+*/ >+ >+/* >+************************************************************************** >+** Inbound Read Request Data Parity Errors >+**===================== Immediate Data Transfer ========================== >+** As a target, the ATU may encounter this error when operating in the Conventional PCI or PCI-X modes. >+** Inbound read data parity errors occur when read data delivered from the IRQ is detected as having >+** bad parity by the initiator of the transaction who is receiving the data. The initiator may optionally >+** report the error to the system by asserting PERR#. As a target device in this scenario, no action is >+** required and no error bits are set. >+**=====================Split Response Termination========================= >+** As a target, the ATU may encounter this error when operating in the PCI-X mode. >+** Inbound read data parity errors occur during the Split Response Termination. The initiator may >+** optionally report the error to the system by asserting PERR#. As a target device in this scenario, no >+** action is required and no error bits are set. >+************************************************************************** >+*/ >+ >+/* >+************************************************************************** >+** Inbound Write Request Data Parity Errors >+**======================================================================== >+** As a target, the ATU may encounter this error when operating in the Conventional or PCI-X modes. >+** Data parity errors occurring during write operations received by the ATU may assert PERR# on >+** the PCI Bus. When an error occurs, the ATU continues accepting data until the initiator of the write >+** transaction completes or a queue fill condition is reached. Specifically, the following actions with >+** the given constraints are taken by the ATU: >+** ¡E PERR# is asserted two clocks cycles (three clock cycles when operating in the PCI-X mode) >+** following the data phase in which the data parity error is detected on the bus. This is only >+** done when the Parity Error Response bit in the ATUCMD is set. >+** ¡E The Detected Parity Error bit in the ATUSR is set. When the ATU sets this bit, additional >+** actions is taken: >+** ¡X When the ATU Detected Parity Error Interrupt Mask bit in the ATUIMR is clear, set the >+** Detected Parity Error bit in the ATUISR. When set, no action. >+*************************************************************************** >+*/ >+ >+ >+/* >+*************************************************************************** >+** Inbound Configuration Write Request >+** ===================================================================== >+** As a target, the ATU may encounter this error when operating in the Conventional or PCI-X modes. >+** =============================================== >+** Conventional PCI Mode >+** =============================================== >+** To allow for correct data parity calculations for delayed write transactions, the ATU delays the >+** assertion of STOP# (signalling a Retry) until PAR is driven by the master. A parity error during a >+** delayed write transaction (inbound configuration write cycle) can occur in any of the following >+** parts of the transactions: >+** ¡E During the initial Delayed Write Request cycle on the PCI bus when the ATU latches the >+** address/command and data for delayed delivery to the internal configuration register. >+** ¡E During the Delayed Write Completion cycle on the PCI bus when the ATU delivers the status >+** of the operation back to the original master. >+** The 80331 ATU PCI interface has the following responses to a delayed write parity error for >+** inbound transactions during Delayed Write Request cycles with the given constraints: >+** ¡E When the Parity Error Response bit in the ATUCMD is set, the ATU asserts TRDY# >+** (disconnects with data) and two clock cycles later asserts PERR# notifying the initiator of the >+** parity error. The delayed write cycle is not enqueued and forwarded to the internal bus. >+** When the Parity Error Response bit in the ATUCMD is cleared, the ATU retries the >+** transaction by asserting STOP# and enqueues the Delayed Write Request cycle to be >+** forwarded to the internal bus. PERR# is not asserted. >+** ¡E The Detected Parity Error bit in the ATUSR is set. When the ATU sets this bit, additional >+** actions is taken: >+** ¡X When the ATU Detected Parity Error Interrupt Mask bit in the ATUIMR is clear, set the >+** Detected Parity Error bit in the ATUISR. When set, no action. >+** For the original write transaction to be completed, the initiator retries the transaction on the PCI >+** bus and the ATU returns the status from the internal bus, completing the transaction. >+** For the Delayed Write Completion transaction on the PCI bus where a data parity error occurs and >+** therefore does not agree with the status being returned from the internal bus (i.e. status being >+** returned is normal completion) the ATU performs the following actions with the given constraints: >+** ¡E When the Parity Error Response Bit is set in the ATUCMD, the ATU asserts TRDY# >+** (disconnects with data) and two clocks later asserts PERR#. The Delayed Completion cycle in >+** the IDWQ remains since the data of retried command did not match the data within the queue. >+** ¡E The Detected Parity Error bit in the ATUSR is set. When the ATU sets this bit, additional >+** actions is taken: >+** ¡X When the ATU Detected Parity Error Interrupt Mask bit in the ATUIMR is clear, set the >+** Detected Parity Error bit in the ATUISR. When set, no action. >+** =================================================== >+** PCI-X Mode >+** =================================================== >+** Data parity errors occurring during configuration write operations received by the ATU may cause >+** PERR# assertion and delivery of a Split Completion Error Message on the PCI Bus. When an error >+** occurs, the ATU accepts the write data and complete with a Split Response Termination. >+** Specifically, the following actions with the given constraints are then taken by the ATU: >+** ¡E When the Parity Error Response bit in the ATUCMD is set, PERR# is asserted three clocks >+** cycles following the Split Response Termination in which the data parity error is detected on >+** the bus. When the ATU asserts PERR#, additional actions is taken: >+** ¡X A Split Write Data Parity Error message (with message class=2h - completer error and >+** message index=01h - Split Write Data Parity Error) is initiated by the ATU on the PCI bus >+** that addresses the requester of the configuration write. >+** ¡X When the Initiated Split Completion Error Message Interrupt Mask in the ATUIMR is >+** clear, set the Initiated Split Completion Error Message bit in the ATUISR. When set, no >+** action. >+** ¡X The Split Write Request is not enqueued and forwarded to the internal bus. >+** ¡E The Detected Parity Error bit in the ATUSR is set. When the ATU sets this bit, additional >+** actions is taken: >+** ¡X When the ATU Detected Parity Error Interrupt Mask bit in the ATUIMR is clear, set the >+** Detected Parity Error bit in the ATUISR. When set, no action. >+** >+*************************************************************************** >+*/ >+ >+/* >+*************************************************************************** >+** Split Completion Messages >+** ======================================================================= >+** As a target, the ATU may encounter this error when operating in the PCI-X mode. >+** Data parity errors occurring during Split Completion Messages claimed by the ATU may assert >+** PERR# (when enabled) or SERR# (when enabled) on the PCI Bus. When an error occurs, the >+** ATU accepts the data and complete normally. Specifically, the following actions with the given >+** constraints are taken by the ATU: >+** ¡E PERR# is asserted three clocks cycles following the data phase in which the data parity error >+** is detected on the bus. This is only done when the Parity Error Response bit in the ATUCMD >+** is set. When the ATU asserts PERR#, additional actions is taken: >+** ¡X The Master Parity Error bit in the ATUSR is set. >+** ¡X When the ATU PCI Master Parity Error Interrupt Mask Bit in the ATUIMR is clear, set the >+** PCI Master Parity Error bit in the ATUISR. When set, no action. >+** ¡X When the SERR# Enable bit in the ATUCMD is set, and the Data Parity Error Recover >+** Enable bit in the PCIXCMD register is clear, assert SERR#; otherwise no action is taken. >+** When the ATU asserts SERR#, additional actions is taken: >+** Set the SERR# Asserted bit in the ATUSR. >+** When the ATU SERR# Asserted Interrupt Mask Bit in the ATUIMR is clear, set the >+** SERR# Asserted bit in the ATUISR. When set, no action. >+** When the ATU SERR# Detected Interrupt Enable Bit in the ATUCR is set, set the >+** SERR# Detected bit in the ATUISR. When clear, no action. >+** ¡E When the SCE bit (Split Completion Error -- bit 30 of the Completer Attributes) is set during >+** the Attribute phase, the Received Split Completion Error Message bit in the PCIXSR is set. >+** When the ATU sets this bit, additional actions is taken: >+** ¡X When the ATU Received Split Completion Error Message Interrupt Mask bit in the >+** ATUIMR is clear, set the Received Split Completion Error Message bit in the ATUISR. >+** When set, no action. >+** ¡E The Detected Parity Error bit in the ATUSR is set. When the ATU sets this bit, additional >+** actions is taken: >+** ¡X When the ATU Detected Parity Error Interrupt Mask bit in the ATUIMR is clear, set the >+** Detected Parity Error bit in the ATUISR. When set, no action. >+** ¡E The transaction associated with the Split Completion Message is discarded. >+** ¡E When the discarded transaction was a read, a completion error message (with message >+** class=2h - completer error and message index=82h - PCI bus read parity error) is generated on >+** the internal bus of the 80331. >+***************************************************************************** >+*/ >+ >+ >+ >+/* >+***************************************************************************** >+** Theory of MU Operation >+***************************************************************************** >+**-------------------- >+** inbound_msgaddr0: >+** inbound_msgaddr1: >+** outbound_msgaddr0: >+** outbound_msgaddr1: >+** . The MU has four independent messaging mechanisms. >+** There are four Message Registers that are similar to a combination of mailbox and doorbell registers. >+** Each holds a 32-bit value and generates an interrupt when written. >+**-------------------- >+** inbound_doorbell: >+** outbound_doorbell: >+** . The two Doorbell Registers support software interrupts. >+** When a bit is set in a Doorbell Register, an interrupt is generated. >+**-------------------- >+** inbound_queueport: >+** outbound_queueport: >+** >+** >+** . The Circular Queues support a message passing scheme that uses 4 circular queues. >+** The 4 circular queues are implemented in 80331 local memory. >+** Two queues are used for inbound messages and two are used for outbound messages. >+** Interrupts may be generated when the queue is written. >+**-------------------- >+** local_buffer 0x0050 ....0x0FFF >+** . The Index Registers use a portion of the 80331 local memory to implement a large set of message registers. >+** When one of the Index Registers is written, an interrupt is generated and the address of the register written is captured. >+** Interrupt status for all interrupts is recorded in the Inbound Interrupt Status Register and the Outbound Interrupt Status Register. >+** Each interrupt generated by the Messaging Unit can be masked. >+**-------------------- >+** . Multi-DWORD PCI burst accesses are not supported by the Messaging Unit, >+** with the exception of Multi-DWORD reads to the index registers. >+** In Conventional mode: the MU terminates Multi-DWORD PCI transactions (other than index register reads) with a disconnect at the next Qword boundary, with the exception of queue ports. >+** In PCI-X mode : the MU terminates a Multi-DWORD PCI read transaction with a Split Response and the data is returned through split completion transaction(s). >+** however, when the burst request crosses into or through the range of offsets 40h to 4Ch (e.g., this includes the queue ports) the transaction is signaled target-abort immediately on the PCI bus. >+** In PCI-X mode, Multi-DWORD PCI writes is signaled a Single-Data-Phase Disconnect which means that no data beyond the first Qword (Dword when the MU does not assert P_ACK64#) is written. >+**-------------------- >+** . All registers needed to configure and control the Messaging Unit are memory-mapped registers. >+** The MU uses the first 4 Kbytes of the inbound translation window in the Address Translation Unit (ATU). >+** This PCI address window is used for PCI transactions that access the 80331 local memory. >+** The PCI address of the inbound translation window is contained in the Inbound ATU Base Address Register. >+**-------------------- >+** . From the PCI perspective, the Messaging Unit is part of the Address Translation Unit. >+** The Messaging Unit uses the PCI configuration registers of the ATU for control and status information. >+** The Messaging Unit must observe all PCI control bits in the ATU Command Register and ATU Configuration Register. >+** The Messaging Unit reports all PCI errors in the ATU Status Register. >+**-------------------- >+** . Parts of the Messaging Unit can be accessed as a 64-bit PCI device. >+** The register interface, message registers, doorbell registers, and index registers returns a P_ACK64# in response to a P_REQ64# on the PCI interface. >+** Up to 1 Qword of data can be read or written per transaction (except Index Register reads). >+** The Inbound and Outbound Queue Ports are always 32-bit addresses and the MU does not assert P_ACK64# to offsets 40H and 44H. >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** Message Registers >+** ============================== >+** . Messages can be sent and received by the 80331 through the use of the Message Registers. >+** . When written, the message registers may cause an interrupt to be generated to either the Intel XScale core or the host processor. >+** . Inbound messages are sent by the host processor and received by the 80331. >+** Outbound messages are sent by the 80331 and received by the host processor. >+** . The interrupt status for outbound messages is recorded in the Outbound Interrupt Status Register. >+** Interrupt status for inbound messages is recorded in the Inbound Interrupt Status Register. >+** >+** Inbound Messages: >+** ----------------- >+** . When an inbound message register is written by an external PCI agent, an interrupt may be generated to the Intel XScale core. >+** . The interrupt may be masked by the mask bits in the Inbound Interrupt Mask Register. >+** . The Intel XScale core interrupt is recorded in the Inbound Interrupt Status Register. >+** The interrupt causes the Inbound Message Interrupt bit to be set in the Inbound Interrupt Status Register. >+** This is a Read/Clear bit that is set by the MU hardware and cleared by software. >+** The interrupt is cleared when the Intel XScale core writes a value of 1 to the Inbound Message Interrupt bit in the Inbound Interrupt Status Register. >+** ------------------------------------------------------------------------ >+** Inbound Message Register - IMRx >+** >+** . There are two Inbound Message Registers: IMR0 and IMR1. >+** . When the IMR register is written, an interrupt to the Intel XScale core may be generated. >+** The interrupt is recorded in the Inbound Interrupt Status Register and may be masked by the Inbound Message Interrupt Mask bit in the Inbound Interrupt Mask Register. >+** ----------------------------------------------------------------- >+** Bit Default Description >+** 31:00 0000 0000H Inbound Message - This is a 32-bit message written by an external PCI agent. >+** When written, an interrupt to the Intel XScale core may be generated. >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_MESSAGE_REG0 0x10 /*dword 0x13,0x12,0x11,0x10*/ >+#define ARCMSR_MU_INBOUND_MESSAGE_REG1 0x14 /*dword 0x17,0x16,0x15,0x14*/ >+/* >+************************************************************************** >+** Outbound Message Register - OMRx >+** -------------------------------- >+** There are two Outbound Message Registers: OMR0 and OMR1. When the OMR register is >+** written, a PCI interrupt may be generated. The interrupt is recorded in the Outbound Interrupt >+** Status Register and may be masked by the Outbound Message Interrupt Mask bit in the Outbound >+** Interrupt Mask Register. >+** >+** Bit Default Description >+** 31:00 00000000H Outbound Message - This is 32-bit message written by the Intel XScale core. When written, an >+** interrupt may be generated on the PCI Interrupt pin determined by the ATU Interrupt Pin Register. >+************************************************************************** >+*/ >+#define ARCMSR_MU_OUTBOUND_MESSAGE_REG0 0x18 /*dword 0x1B,0x1A,0x19,0x18*/ >+#define ARCMSR_MU_OUTBOUND_MESSAGE_REG1 0x1C /*dword 0x1F,0x1E,0x1D,0x1C*/ >+/* >+************************************************************************** >+** Doorbell Registers >+** ============================== >+** There are two Doorbell Registers: >+** Inbound Doorbell Register >+** Outbound Doorbell Register >+** The Inbound Doorbell Register allows external PCI agents to generate interrupts to the Intel R XScale core. >+** The Outbound Doorbell Register allows the Intel R XScale core to generate a PCI interrupt. >+** Both Doorbell Registers may generate interrupts whenever a bit in the register is set. >+** >+** Inbound Doorbells: >+** ------------------ >+** . When the Inbound Doorbell Register is written by an external PCI agent, an interrupt may be generated to the Intel R XScale core. >+** An interrupt is generated when any of the bits in the doorbell register is written to a value of 1. >+** Writing a value of 0 to any bit does not change the value of that bit and does not cause an interrupt to be generated. >+** . Once a bit is set in the Inbound Doorbell Register, it cannot be cleared by any external PCI agent. >+** The interrupt is recorded in the Inbound Interrupt Status Register. >+** . The interrupt may be masked by the Inbound Doorbell Interrupt mask bit in the Inbound Interrupt Mask Register. >+** When the mask bit is set for a particular bit, no interrupt is generated for that bit. >+** The Inbound Interrupt Mask Register affects only the generation of the normal messaging unit interrupt and not the values written to the Inbound Doorbell Register. >+** One bit in the Inbound Doorbell Register is reserved for an Error Doorbell interrupt. >+** . The interrupt is cleared when the Intel R XScale core writes a value of 1 to the bits in the Inbound Doorbell Register that are set. >+** Writing a value of 0 to any bit does not change the value of that bit and does not clear the interrupt. >+** ------------------------------------------------------------------------ >+** Inbound Doorbell Register - IDR >+** >+** . The Inbound Doorbell Register (IDR) is used to generate interrupts to the Intel XScale core. >+** . Bit 31 is reserved for generating an Error Doorbell interrupt. >+** When bit 31 is set, an Error interrupt may be generated to the Intel XScale core. >+** All other bits, when set, cause the Normal Messaging Unit interrupt line of the Intel XScale core to be asserted, >+** when the interrupt is not masked by the Inbound Doorbell Interrupt Mask bit in the Inbound Interrupt Mask Register. >+** The bits in the IDR register can only be set by an external PCI agent and can only be cleared by the Intel XScale core. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31 0 2 Error Interrupt - Generate an Error Interrupt to the Intel XScale core. >+** 30:00 00000000H Normal Interrupt - When any bit is set, generate a Normal interrupt to the Intel XScale core. >+** When all bits are clear, do not generate a Normal Interrupt. >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_DOORBELL_REG 0x20 /*dword 0x23,0x22,0x21,0x20*/ >+/* >+************************************************************************** >+** Inbound Interrupt Status Register - IISR >+** >+** . The Inbound Interrupt Status Register (IISR) contains hardware interrupt status. >+** It records the status of Intel XScale core interrupts generated by the Message Registers, Doorbell Registers, and the Circular Queues. >+** All interrupts are routed to the Normal Messaging Unit interrupt input of the Intel XScale core, >+** except for the Error Doorbell Interrupt and the Outbound Free Queue Full interrupt; >+** these two are routed to the Messaging Unit Error interrupt input. >+** The generation of interrupts recorded in the Inbound Interrupt Status Register may be masked by setting the corresponding bit in the Inbound Interrupt Mask Register. >+** Some of the bits in this register are Read Only. >+** For those bits, the interrupt must be cleared through another register. >+** >+** Bit Default Description >+** 31:07 0000000H 0 2 Reserved >+** 06 0 2 Index Register Interrupt - This bit is set by the MU hardware when an Index Register has been written after a PCI transaction. >+** 05 0 2 Outbound Free Queue Full Interrupt - This bit is set when the Outbound Free Head Pointer becomes equal to the Tail Pointer and the queue is full. >+** An Error interrupt is generated for this condition. >+** 04 0 2 Inbound Post Queue Interrupt - This bit is set by the MU hardware when the Inbound Post Queue has been written. >+** Once cleared, an interrupt does NOT be generated when the head and tail pointers remain unequal (i.e. queue status is Not Empty). >+** Therefore, when software leaves any unprocessed messages in the post queue when the interrupt is cleared, >+** software must retain the information that the Inbound Post queue status is not empty. >+** NOTE: >+** This interrupt is provided with dedicated support in the 80331 Interrupt Controller. >+** 03 0 2 Error Doorbell Interrupt - This bit is set when the Error Interrupt of the Inbound Doorbell Register is set. >+** To clear this bit (and the interrupt), the Error Interrupt bit of the Inbound Doorbell Register must be clear. >+** 02 0 2 Inbound Doorbell Interrupt - This bit is set when at least one Normal Interrupt bit in the Inbound Doorbell Register is set. >+** To clear this bit (and the interrupt), the Normal Interrupt bits in the Inbound Doorbell Register must all be clear. >+** 01 0 2 Inbound Message 1 Interrupt - This bit is set by the MU hardware when the Inbound Message 1 Register has been written. >+** 00 0 2 Inbound Message 0 Interrupt - This bit is set by the MU hardware when the Inbound Message 0 Register has been written. >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_INTERRUPT_STATUS_REG 0x24 /*dword 0x27,0x26,0x25,0x24*/ >+#define ARCMSR_MU_INBOUND_INDEX_INT 0x40 >+#define ARCMSR_MU_INBOUND_QUEUEFULL_INT 0x20 >+#define ARCMSR_MU_INBOUND_POSTQUEUE_INT 0x10 >+#define ARCMSR_MU_INBOUND_ERROR_DOORBELL_INT 0x08 >+#define ARCMSR_MU_INBOUND_DOORBELL_INT 0x04 >+#define ARCMSR_MU_INBOUND_MESSAGE1_INT 0x02 >+#define ARCMSR_MU_INBOUND_MESSAGE0_INT 0x01 >+/* >+************************************************************************** >+** Inbound Interrupt Mask Register - IIMR >+** >+** . The Inbound Interrupt Mask Register (IIMR) provides the ability to mask Intel XScale core interrupts generated by the Messaging Unit. >+** Each bit in the Mask register corresponds to an interrupt bit in the Inbound Interrupt Status Register. >+** Setting or clearing bits in this register does not affect the Inbound Interrupt Status Register. >+** They only affect the generation of the Intel XScale core interrupt. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:07 000000H 0 2 Reserved >+** 06 0 2 Index Register Interrupt Mask - When set, this bit masks the interrupt generated by the MU hardware when an Index Register has been written after a PCI transaction. >+** 05 0 2 Outbound Free Queue Full Interrupt Mask - When set, this bit masks the Error interrupt generated when the Outbound Free Head Pointer becomes equal to the Tail Pointer and the queue is full. >+** 04 0 2 Inbound Post Queue Interrupt Mask - When set, this bit masks the interrupt generated by the MU hardware when the Inbound Post Queue has been written. >+** 03 0 2 Error Doorbell Interrupt Mask - When set, this bit masks the Error Interrupt when the Error Interrupt bit of the Inbound Doorbell Register is set. >+** 02 0 2 Inbound Doorbell Interrupt Mask - When set, this bit masks the interrupt generated when at least one Normal Interrupt bit in the Inbound Doorbell Register is set. >+** 01 0 2 Inbound Message 1 Interrupt Mask - When set, this bit masks the Inbound Message 1 Interrupt generated by a write to the Inbound Message 1 Register. >+** 00 0 2 Inbound Message 0 Interrupt Mask - When set, this bit masks the Inbound Message 0 Interrupt generated by a write to the Inbound Message 0 Register. >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_INTERRUPT_MASK_REG 0x28 /*dword 0x2B,0x2A,0x29,0x28*/ >+#define ARCMSR_MU_INBOUND_INDEX_INTMASKENABLE 0x40 >+#define ARCMSR_MU_INBOUND_QUEUEFULL_INTMASKENABLE 0x20 >+#define ARCMSR_MU_INBOUND_POSTQUEUE_INTMASKENABLE 0x10 >+#define ARCMSR_MU_INBOUND_DOORBELL_ERROR_INTMASKENABLE 0x08 >+#define ARCMSR_MU_INBOUND_DOORBELL_INTMASKENABLE 0x04 >+#define ARCMSR_MU_INBOUND_MESSAGE1_INTMASKENABLE 0x02 >+#define ARCMSR_MU_INBOUND_MESSAGE0_INTMASKENABLE 0x01 >+/* >+************************************************************************** >+** Outbound Doorbell Register - ODR >+** >+** The Outbound Doorbell Register (ODR) allows software interrupt generation. It allows the Intel >+** XScale core to generate PCI interrupts to the host processor by writing to this register. The >+** generation of PCI interrupts through the Outbound Doorbell Register may be masked by setting the >+** Outbound Doorbell Interrupt Mask bit in the Outbound Interrupt Mask Register. >+** The Software Interrupt bits in this register can only be set by the Intel XScale core and can only >+** be cleared by an external PCI agent. >+** ---------------------------------------------------------------------- >+** Bit Default Description >+** 31 0 2 Reserved >+** 30 0 2 Reserved. >+** 29 0 2 Reserved >+** 28 0000 0000H PCI Interrupt - When set, this bit causes the P_INTC# interrupt output (P_INTA# with BRG_EN and ARB_EN straps low) >+** signal to be asserted or a Message-signaled Interrupt is generated (when enabled). >+** When this bit is cleared, the P_INTC# interrupt output (P_INTA# with BRG_EN and ARB_EN straps low) >+** signal is deasserted. >+** 27:00 000 0000H Software Interrupts - When any bit is set the P_INTC# interrupt output (P_INTA# with BRG_EN and ARB_EN straps low) >+** signal is asserted or a Message-signaled Interrupt is generated (when enabled). >+** When all bits are cleared, the P_INTC# interrupt output (P_INTA# with BRG_EN and ARB_EN straps low) >+** signal is deasserted. >+************************************************************************** >+*/ >+#define ARCMSR_MU_OUTBOUND_DOORBELL_REG 0x2C //dword 0x2F,0x2E,0x2D,0x2C// >+/* >+************************************************************************** >+** Outbound Interrupt Status Register - OISR >+** >+** The Outbound Interrupt Status Register (OISR) contains hardware interrupt status. It records the >+** status of PCI interrupts generated by the Message Registers, Doorbell Registers, and the Circular >+** Queues. The generation of PCI interrupts recorded in the Outbound Interrupt Status Register may >+** be masked by setting the corresponding bit in the Outbound Interrupt Mask Register. Some of the >+** bits in this register are Read Only. For those bits, the interrupt must be cleared through another >+** register. >+** ---------------------------------------------------------------------- >+** Bit Default Description >+** 31:05 000000H 000 2 Reserved >+** 04 0 2 PCI Interrupt - This bit is set when the PCI Interrupt bit (bit 28) is set in the Outbound Doorbell Register. >+** To clear this bit (and the interrupt), the PCI Interrupt bit must be cleared. >+** 03 0 2 Outbound Post Queue Interrupt - This bit is set when data in the prefetch buffer is valid. This bit is >+** cleared when any prefetch data has been read from the Outbound Queue Port. >+** 02 0 2 Outbound Doorbell Interrupt - This bit is set when at least one Software Interrupt bit in the Outbound >+** Doorbell Register is set. To clear this bit (and the interrupt), the Software Interrupt bits in the Outbound >+** Doorbell Register must all be clear. >+** 01 0 2 Outbound Message 1 Interrupt - This bit is set by the MU when the Outbound Message 1 Register is >+** written. Clearing this bit clears the interrupt. >+** 00 0 2 Outbound Message 0 Interrupt - This bit is set by the MU when the Outbound Message 0 Register is >+** written. Clearing this bit clears the interrupt. >+************************************************************************** >+*/ >+#define ARCMSR_MU_OUTBOUND_INTERRUPT_STATUS_REG 0x30 //dword 0x33,0x32,0x31,0x30// >+#define ARCMSR_MU_OUTBOUND_PCI_INT 0x10 >+#define ARCMSR_MU_OUTBOUND_POSTQUEUE_INT 0x08 >+#define ARCMSR_MU_OUTBOUND_DOORBELL_INT 0x04 >+#define ARCMSR_MU_OUTBOUND_MESSAGE1_INT 0x02 >+#define ARCMSR_MU_OUTBOUND_MESSAGE0_INT 0x01 >+#define ARCMSR_MU_OUTBOUND_HANDLE_INT (ARCMSR_MU_OUTBOUND_MESSAGE0_INT|ARCMSR_MU_OUTBOUND_MESSAGE1_INT|ARCMSR_MU_OUTBOUND_DOORBELL_INT|ARCMSR_MU_OUTBOUND_POSTQUEUE_INT|ARCMSR_MU_OUTBOUND_PCI_INT) >+/* >+************************************************************************** >+** Outbound Interrupt Mask Register - OIMR >+** The Outbound Interrupt Mask Register (OIMR) provides the ability to mask outbound PCI >+** interrupts generated by the Messaging Unit. Each bit in the mask register corresponds to a >+** hardware interrupt bit in the Outbound Interrupt Status Register. When the bit is set, the PCI >+** interrupt is not generated. When the bit is clear, the interrupt is allowed to be generated. >+** Setting or clearing bits in this register does not affect the Outbound Interrupt Status Register. They >+** only affect the generation of the PCI interrupt. >+** ---------------------------------------------------------------------- >+** Bit Default Description >+** 31:05 000000H Reserved >+** 04 0 2 PCI Interrupt Mask - When set, this bit masks the interrupt generation when the PCI Interrupt bit (bit 28) >+** in the Outbound Doorbell Register is set. >+** 03 0 2 Outbound Post Queue Interrupt Mask - When set, this bit masks the interrupt generated when data in >+** the prefetch buffer is valid. >+** 02 0 2 Outbound Doorbell Interrupt Mask - When set, this bit masks the interrupt generated by the Outbound >+** Doorbell Register. >+** 01 0 2 Outbound Message 1 Interrupt Mask - When set, this bit masks the Outbound Message 1 Interrupt >+** generated by a write to the Outbound Message 1 Register. >+** 00 0 2 Outbound Message 0 Interrupt Mask- When set, this bit masks the Outbound Message 0 Interrupt >+** generated by a write to the Outbound Message 0 Register. >+************************************************************************** >+*/ >+#define ARCMSR_MU_OUTBOUND_INTERRUPT_MASK_REG 0x34 //dword 0x37,0x36,0x35,0x34// >+#define ARCMSR_MU_OUTBOUND_PCI_INTMASKENABLE 0x10 >+#define ARCMSR_MU_OUTBOUND_POSTQUEUE_INTMASKENABLE 0x08 >+#define ARCMSR_MU_OUTBOUND_DOORBELL_INTMASKENABLE 0x04 >+#define ARCMSR_MU_OUTBOUND_MESSAGE1_INTMASKENABLE 0x02 >+#define ARCMSR_MU_OUTBOUND_MESSAGE0_INTMASKENABLE 0x01 >+#define ARCMSR_MU_OUTBOUND_ALL_INTMASKENABLE 0x1F >+/* >+************************************************************************** >+** >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_QUEUE_PORT_REG 0x40 //dword 0x43,0x42,0x41,0x40// >+#define ARCMSR_MU_OUTBOUND_QUEUE_PORT_REG 0x44 //dword 0x47,0x46,0x45,0x44// >+/* >+************************************************************************** >+** Circular Queues >+** ====================================================================== >+** The MU implements four circular queues. There are 2 inbound queues and 2 outbound queues. In >+** this case, inbound and outbound refer to the direction of the flow of posted messages. >+** Inbound messages are either: >+** ¡E posted messages by other processors for the Intel XScale core to process or >+** ¡E free (or empty) messages that can be reused by other processors. >+** Outbound messages are either: >+** ¡E posted messages by the Intel XScale core for other processors to process or >+** ¡E free (or empty) messages that can be reused by the Intel XScale core. >+** Therefore, free inbound messages flow away from the 80331 and free outbound messages flow toward the 80331. >+** The four Circular Queues are used to pass messages in the following manner. >+** . The two inbound queues are used to handle inbound messages >+** and the two outbound queues are used to handle outbound messages. >+** . One of the inbound queues is designated the Free queue and it contains inbound free messages. >+** The other inbound queue is designated the Post queue and it contains inbound posted messages. >+** Similarly, one of the outbound queues is designated the Free queue and the other outbound queue is designated the Post queue. >+** >+** ============================================================================================================= >+** Circular Queue Summary >+** _____________________________________________________________________________________________________________ >+** | Queue Name | Purpose | Action on PCI Interface| >+** |______________________|____________________________________________________________|_________________________| >+** |Inbound Post Queue | Queue for inbound messages from other processors | Written | >+** | | waiting to be processed by the 80331 | | >+** |Inbound Free Queue | Queue for empty inbound messages from the 80331 | Read | >+** | | available for use by other processors | | >+** |Outbound Post Queue | Queue for outbound messages from the 80331 | Read | >+** | | that are being posted to the other processors | | >+** |Outbound Free Queue | Queue for empty outbound messages from other processors | Written | >+** | | available for use by the 80331 | | >+** |______________________|____________________________________________________________|_________________________| >+** >+** . The two inbound queues allow the host processor to post inbound messages for the 80331 in one >+** queue and to receive free messages returning from the 80331. >+** The host processor posts inbound messages, >+** the Intel XScale core receives the posted message and when it is finished with the message, >+** places it back on the inbound free queue for reuse by the host processor. >+** >+** The circular queues are accessed by external PCI agents through two port locations in the PCI >+** address space: >+** Inbound Queue Port >+** and Outbound Queue Port. >+** The Inbound Queue Port is used by external PCI agents to read the Inbound Free Queue and write the Inbound Post Queue. >+** The Outbound Queue Port is used by external PCI agents to read the Outbound Post Queue and write the Outbound Free Queue. >+** Note that a PCI transaction to the inbound or outbound queue ports with null byte enables (P_C/BE[3:0]#=1111 2 ) >+** does not cause the MU hardware to increment the queue pointers. >+** This is treated as when the PCI transaction did not occur. >+** The Inbound and Outbound Queue Ports never respond with P_ACK64# on the PCI interface. >+** ====================================================================================== >+** Overview of Circular Queue Operation >+** ====================================================================================== >+** . The data storage for the circular queues must be provided by the 80331 local memory. >+** . The base address of the circular queues is contained in the Queue Base Address Register. >+** Each entry in the queue is a 32-bit data value. >+** . Each read from or write to the queue may access only one queue entry. >+** . Multi-DWORD accesses to the circular queues are not allowed. >+** Sub-DWORD accesses are promoted to DWORD accesses. >+** . Each circular queue has a head pointer and a tail pointer. >+** The pointers are offsets from the Queue Base Address. >+** . Writes to a queue occur at the head of the queue and reads occur from the tail. >+** The head and tail pointers are incremented by either the Intel XScale core or the Messaging Unit hardware. >+** Which unit maintains the pointer is determined by the writer of the queue. >+** More details about the pointers are given in the queue descriptions below. >+** The pointers are incremented after the queue access. >+** Both pointers wrap around to the first address of the circular queue when they reach the circular queue size. >+** >+** Messaging Unit... >+** >+** The Messaging Unit generates an interrupt to the Intel XScale core or generate a PCI interrupt under certain conditions. >+** . In general, when a Post queue is written, an interrupt is generated to notify the receiver that a message was posted. >+** The size of each circular queue can range from 4K entries (16 Kbytes) to 64K entries (256 Kbytes). >+** . All four queues must be the same size and may be contiguous. >+** Therefore, the total amount of local memory needed by the circular queues ranges from 64 Kbytes to 1 Mbytes. >+** The Queue size is determined by the Queue Size field in the MU Configuration Register. >+** . There is one base address for all four queues. >+** It is stored in the Queue Base Address Register (QBAR). >+** The starting addresses of each queue is based on the Queue Base Address and the Queue Size field. >+** here shows an example of how the circular queues should be set up based on the >+** Intelligent I/O (I 2 O) Architecture Specification. >+** Other ordering of the circular queues is possible. >+** >+** Queue Starting Address >+** Inbound Free Queue QBAR >+** Inbound Post Queue QBAR + Queue Size >+** Outbound Post Queue QBAR + 2 * Queue Size >+** Outbound Free Queue QBAR + 3 * Queue Size >+** =================================================================================== >+** Inbound Post Queue >+** ------------------ >+** The Inbound Post Queue holds posted messages placed there by other processors for the Intel XScale core to process. >+** This queue is read from the queue tail by the Intel XScale core. It is written to the queue head by external PCI agents. >+** The tail pointer is maintained by the Intel XScale core. The head pointer is maintained by the MU hardware. >+** For a PCI write transaction that accesses the Inbound Queue Port, the MU writes the data to the local memory location address in the Inbound Post Head Pointer Register. >+** When the data written to the Inbound Queue Port is written to local memory, the MU hardware increments the Inbound Post Head Pointer Register. >+** An Intel XScale core interrupt may be generated when the Inbound Post Queue is written. >+** The Inbound Post Queue Interrupt bit in the Inbound Interrupt Status Register indicates the interrupt status. >+** The interrupt is cleared when the Inbound Post Queue Interrupt bit is cleared. >+** The interrupt can be masked by the Inbound Interrupt Mask Register. >+** Software must be aware of the state of the Inbound Post Queue Interrupt Mask bit to guarantee that the full condition is recognized by the core processor. >+** In addition, to guarantee that the queue does not get overwritten, software must process messages from the tail of the queue before incrementing the tail pointer and clearing this interrupt. >+** Once cleared, an interrupt is NOT generated when the head and tail pointers remain unequal (i.e. queue status is Not Empty). >+** Only a new message posting the in the inbound queue generates a new interrupt. >+** Therefore, when software leaves any unprocessed messages in the post queue when the interrupt is cleared, software must retain the information that the Inbound Post queue status. >+** From the time that the PCI write transaction is received until the data is written in local memory and the Inbound Post Head Pointer Register is incremented, any PCI transaction that attempts to access the Inbound Post Queue Port is signalled a Retry. >+** The Intel XScale core may read messages from the Inbound Post Queue by reading the data from the local memory location pointed to by the Inbound Post Tail Pointer Register. >+** The Intel XScale core must then increment the Inbound Post Tail Pointer Register. >+** When the Inbound Post Queue is full (head and tail pointers are equal and the head pointer was last updated by hardware), the hardware retries any PCI writes until a slot in the queue becomes available. >+** A slot in the post queue becomes available by the Intel XScale core incrementing the tail pointer. >+** =================================================================================== >+** Inbound Free Queue >+** ------------------ >+** The Inbound Free Queue holds free inbound messages placed there by the Intel XScale core for other processors to use. >+** This queue is read from the queue tail by external PCI agents. >+** It is written to the queue head by the Intel XScale core. >+** The tail pointer is maintained by the MU hardware. >+** The head pointer is maintained by the Intel XScale core. >+** For a PCI read transaction that accesses the Inbound Queue Port, >+** the MU attempts to read the data at the local memory address in the Inbound Free Tail Pointer. >+** When the queue is not empty (head and tail pointers are not equal) or full (head and tail pointers are equal but the head pointer was last written by software), the data is returned. >+** When the queue is empty (head and tail pointers are equal and the head pointer was last updated by hardware), the value of -1 (FFFF.FFFFH) is returned. >+** When the queue was not empty and the MU succeeded in returning the data at the tail, >+** the MU hardware must increment the value in the Inbound Free Tail Pointer Register. >+** To reduce latency for the PCI read access, the MU implements a prefetch mechanism to anticipate accesses to the Inbound Free Queue. >+** The MU hardware prefetches the data at the tail of the Inbound Free Queue and load it into an internal prefetch register. >+** When the PCI read access occurs, the data is read directly from the prefetch register. >+** The prefetch mechanism loads a value of -1 (FFFF.FFFFH) into the prefetch register >+** when the head and tail pointers are equal and the queue is empty. >+** In order to update the prefetch register when messages are added to the queue and it becomes non-empty, >+** the prefetch mechanism automatically starts a prefetch when the prefetch register contains FFFF.FFFFH and the Inbound Free Head Pointer Register is written. >+** The Intel XScale core needs to update the Inbound Free Head Pointer Register when it adds messages to the queue. >+** A prefetch must appear atomic from the perspective of the external PCI agent. >+** When a prefetch is started, any PCI transaction that attempts to access the Inbound Free Queue is signalled a Retry until the prefetch is completed. >+** The Intel XScale core may place messages in the Inbound Free Queue by writing the data to the >+** local memory location pointed to by the Inbound Free Head Pointer Register. >+** The processor must then increment the Inbound Free Head Pointer Register. >+** ================================================================================== >+** Outbound Post Queue >+** ------------------- >+** The Outbound Post Queue holds outbound posted messages placed there by the Intel XScale >+** core for other processors to process. This queue is read from the queue tail by external PCI agents. >+** It is written to the queue head by the Intel XScale core. The tail pointer is maintained by the >+** MU hardware. The head pointer is maintained by the Intel XScale core. >+** For a PCI read transaction that accesses the Outbound Queue Port, the MU attempts to read the >+** data at the local memory address in the Outbound Post Tail Pointer Register. When the queue is not >+** empty (head and tail pointers are not equal) or full (head and tail pointers are equal but the head >+** pointer was last written by software), the data is returned. When the queue is empty (head and tail >+** pointers are equal and the head pointer was last updated by hardware), the value of -1 >+** (FFFF.FFFFH) is returned. When the queue was not empty and the MU succeeded in returning the >+** data at the tail, the MU hardware must increment the value in the Outbound Post Tail Pointer >+** Register. >+** To reduce latency for the PCI read access, the MU implements a prefetch mechanism to anticipate >+** accesses to the Outbound Post Queue. The MU hardware prefetches the data at the tail of the >+** Outbound Post Queue and load it into an internal prefetch register. When the PCI read access >+** occurs, the data is read directly from the prefetch register. >+** The prefetch mechanism loads a value of -1 (FFFF.FFFFH) into the prefetch register when the head >+** and tail pointers are equal and the queue is empty. In order to update the prefetch register when >+** messages are added to the queue and it becomes non-empty, the prefetch mechanism automatically >+** starts a prefetch when the prefetch register contains FFFF.FFFFH and the Outbound Post Head >+** Pointer Register is written. The Intel XScale core needs to update the Outbound Post Head >+** Pointer Register when it adds messages to the queue. >+** A prefetch must appear atomic from the perspective of the external PCI agent. When a prefetch is >+** started, any PCI transaction that attempts to access the Outbound Post Queue is signalled a Retry >+** until the prefetch is completed. >+** A PCI interrupt may be generated when data in the prefetch buffer is valid. When the prefetch >+** queue is clear, no interrupt is generated. The Outbound Post Queue Interrupt bit in the Outbound >+** Interrupt Status Register shall indicate the status of the prefetch buffer data and therefore the >+** interrupt status. The interrupt is cleared when any prefetched data has been read from the Outbound >+** Queue Port. The interrupt can be masked by the Outbound Interrupt Mask Register. >+** The Intel XScale core may place messages in the Outbound Post Queue by writing the data to >+** the local memory address in the Outbound Post Head Pointer Register. The processor must then >+** increment the Outbound Post Head Pointer Register. >+** ================================================== >+** Outbound Free Queue >+** ----------------------- >+** The Outbound Free Queue holds free messages placed there by other processors for the Intel >+** XScale core to use. This queue is read from the queue tail by the Intel XScale core. It is >+** written to the queue head by external PCI agents. The tail pointer is maintained by the Intel >+** XScale core. The head pointer is maintained by the MU hardware. >+** For a PCI write transaction that accesses the Outbound Queue Port, the MU writes the data to the >+** local memory address in the Outbound Free Head Pointer Register. When the data written to the >+** Outbound Queue Port is written to local memory, the MU hardware increments the Outbound Free >+** Head Pointer Register. >+** When the head pointer and the tail pointer become equal and the queue is full, the MU may signal >+** an interrupt to the Intel XScale core to register the queue full condition. This interrupt is >+** recorded in the Inbound Interrupt Status Register. The interrupt is cleared when the Outbound Free >+** Queue Full Interrupt bit is cleared and not by writing to the head or tail pointers. The interrupt can >+** be masked by the Inbound Interrupt Mask Register. Software must be aware of the state of the >+** Outbound Free Queue Interrupt Mask bit to guarantee that the full condition is recognized by the >+** core processor. >+** From the time that a PCI write transaction is received until the data is written in local memory and >+** the Outbound Free Head Pointer Register is incremented, any PCI transaction that attempts to >+** access the Outbound Free Queue Port is signalled a retry. >+** The Intel XScale core may read messages from the Outbound Free Queue by reading the data >+** from the local memory address in the Outbound Free Tail Pointer Register. The processor must >+** then increment the Outbound Free Tail Pointer Register. When the Outbound Free Queue is full, >+** the hardware must retry any PCI writes until a slot in the queue becomes available. >+** >+** ================================================================================== >+** Circular Queue Summary >+** ---------------------- >+** ________________________________________________________________________________________________________________________________________________ >+** | Queue Name | PCI Port |Generate PCI Interrupt |Generate Intel Xscale Core Interrupt|Head Pointer maintained by|Tail Pointer maintained by| >+** |_____________|_______________|_______________________|____________________________________|__________________________|__________________________| >+** |Inbound Post | Inbound Queue | | | | | >+** | Queue | Port | NO | Yes, when queue is written | MU hardware | Intel XScale | >+** |_____________|_______________|_______________________|____________________________________|__________________________|__________________________| >+** |Inbound Free | Inbound Queue | | | | | >+** | Queue | Port | NO | NO | Intel XScale | MU hardware | >+** |_____________|_______________|_______________________|____________________________________|__________________________|__________________________| >+** ================================================================================== >+** Circular Queue Status Summary >+** ---------------------- >+** ____________________________________________________________________________________________________ >+** | Queue Name | Queue Status | Head & Tail Pointer | Last Pointer Update | >+** |_____________________|________________|_____________________|_______________________________________| >+** | Inbound Post Queue | Empty | Equal | Tail pointer last updated by software | >+** |_____________________|________________|_____________________|_______________________________________| >+** | Inbound Free Queue | Empty | Equal | Head pointer last updated by hardware | >+** |_____________________|________________|_____________________|_______________________________________| >+************************************************************************** >+*/ >+ >+/* >+************************************************************************** >+** Index Registers >+** ======================== >+** . The Index Registers are a set of 1004 registers that when written by an external PCI agent can generate an interrupt to the Intel XScale core. >+** These registers are for inbound messages only. >+** The interrupt is recorded in the Inbound Interrupt Status Register. >+** The storage for the Index Registers is allocated from the 80331 local memory. >+** PCI write accesses to the Index Registers write the data to local memory. >+** PCI read accesses to the Index Registers read the data from local memory. >+** . The local memory used for the Index Registers ranges from Inbound ATU Translate Value Register + 050H >+** to Inbound ATU Translate Value Register + FFFH. >+** . The address of the first write access is stored in the Index Address Register. >+** This register is written during the earliest write access and provides a means to determine which Index Register was written. >+** Once updated by the MU, the Index Address Register is not updated until the Index Register Interrupt bit in the Inbound Interrupt Status Register is cleared. >+** . When the interrupt is cleared, the Index Address Register is re-enabled and stores the address of the next Index Register write access. >+** Writes by the Intel XScale core to the local memory used by the Index Registers does not cause an interrupt and does not update the Index Address Register. >+** . The index registers can be accessed with Multi-DWORD reads and single QWORD aligned writes. >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** Messaging Unit Internal Bus Memory Map >+** ======================================= >+** Internal Bus Address___Register Description (Name)____________________|_PCI Configuration Space Register Number_ >+** FFFF E300H reserved | >+** .. .. | >+** FFFF E30CH reserved | >+** FFFF E310H Inbound Message Register 0 | Available through >+** FFFF E314H Inbound Message Register 1 | ATU Inbound Translation Window >+** FFFF E318H Outbound Message Register 0 | >+** FFFF E31CH Outbound Message Register 1 | or >+** FFFF E320H Inbound Doorbell Register | >+** FFFF E324H Inbound Interrupt Status Register | must translate PCI address to >+** FFFF E328H Inbound Interrupt Mask Register | the Intel Xscale Core >+** FFFF E32CH Outbound Doorbell Register | Memory-Mapped Address >+** FFFF E330H Outbound Interrupt Status Register | >+** FFFF E334H Outbound Interrupt Mask Register | >+** ______________________________________________________________________|________________________________________ >+** FFFF E338H reserved | >+** FFFF E33CH reserved | >+** FFFF E340H reserved | >+** FFFF E344H reserved | >+** FFFF E348H reserved | >+** FFFF E34CH reserved | >+** FFFF E350H MU Configuration Register | >+** FFFF E354H Queue Base Address Register | >+** FFFF E358H reserved | >+** FFFF E35CH reserved | must translate PCI address to >+** FFFF E360H Inbound Free Head Pointer Register | the Intel Xscale Core >+** FFFF E364H Inbound Free Tail Pointer Register | Memory-Mapped Address >+** FFFF E368H Inbound Post Head pointer Register | >+** FFFF E36CH Inbound Post Tail Pointer Register | >+** FFFF E370H Outbound Free Head Pointer Register | >+** FFFF E374H Outbound Free Tail Pointer Register | >+** FFFF E378H Outbound Post Head pointer Register | >+** FFFF E37CH Outbound Post Tail Pointer Register | >+** FFFF E380H Index Address Register | >+** FFFF E384H reserved | >+** .. .. | >+** FFFF E3FCH reserved | >+** ______________________________________________________________________|_______________________________________ >+************************************************************************** >+*/ >+/* >+************************************************************************** >+** MU Configuration Register - MUCR FFFF.E350H >+** >+** . The MU Configuration Register (MUCR) contains the Circular Queue Enable bit and the size of one Circular Queue. >+** . The Circular Queue Enable bit enables or disables the Circular Queues. >+** The Circular Queues are disabled at reset to allow the software to initialize the head and tail pointer registers before any PCI accesses to the Queue Ports. >+** . Each Circular Queue may range from 4 K entries (16 Kbytes) to 64 K entries (256 Kbytes) and there are four Circular Queues. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:06 000000H 00 2 Reserved >+** 05:01 00001 2 Circular Queue Size - This field determines the size of each Circular Queue. >+** All four queues are the same size. >+** ¡E 00001 2 - 4K Entries (16 Kbytes) >+** ¡E 00010 2 - 8K Entries (32 Kbytes) >+** ¡E 00100 2 - 16K Entries (64 Kbytes) >+** ¡E 01000 2 - 32K Entries (128 Kbytes) >+** ¡E 10000 2 - 64K Entries (256 Kbytes) >+** 00 0 2 Circular Queue Enable - This bit enables or disables the Circular Queues. When clear the Circular >+** Queues are disabled, however the MU accepts PCI accesses to the Circular Queue Ports but ignores >+** the data for Writes and return FFFF.FFFFH for Reads. Interrupts are not generated to the core when >+** disabled. When set, the Circular Queues are fully enabled. >+************************************************************************** >+*/ >+#define ARCMSR_MU_CONFIGURATION_REG 0xFFFFE350 >+#define ARCMSR_MU_CIRCULAR_QUEUE_SIZE64K 0x0020 >+#define ARCMSR_MU_CIRCULAR_QUEUE_SIZE32K 0x0010 >+#define ARCMSR_MU_CIRCULAR_QUEUE_SIZE16K 0x0008 >+#define ARCMSR_MU_CIRCULAR_QUEUE_SIZE8K 0x0004 >+#define ARCMSR_MU_CIRCULAR_QUEUE_SIZE4K 0x0002 >+#define ARCMSR_MU_CIRCULAR_QUEUE_ENABLE 0x0001 /*0:disable 1:enable*/ >+/* >+************************************************************************** >+** Queue Base Address Register - QBAR >+** >+** . The Queue Base Address Register (QBAR) contains the local memory address of the Circular Queues. >+** The base address is required to be located on a 1 Mbyte address boundary. >+** . All Circular Queue head and tail pointers are based on the QBAR. >+** When the head and tail pointer registers are read, the Queue Base Address is returned in the upper 12 bits. >+** Writing to the upper 12 bits of the head and tail pointer registers does not affect the Queue Base Address or Queue Base Address Register. >+** Warning: >+** The QBAR must designate a range allocated to the 80331 DDR SDRAM interface >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:20 000H Queue Base Address - Local memory address of the circular queues. >+** 19:00 00000H Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_QUEUE_BASE_ADDRESS_REG 0xFFFFE354 >+/* >+************************************************************************** >+** Inbound Free Head Pointer Register - IFHPR >+** >+** . The Inbound Free Head Pointer Register (IFHPR) contains the local memory offset from the Queue Base Address of the head pointer for the Inbound Free Queue. >+** The Head Pointer must be aligned on a DWORD address boundary. >+** When read, the Queue Base Address is provided in the upper 12 bits of the register. >+** Writes to the upper 12 bits of the register are ignored. >+** This register is maintained by software. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:20 000H Queue Base Address - Local memory address of the circular queues. >+** 19:02 0000H 00 2 Inbound Free Head Pointer - Local memory offset of the head pointer for the Inbound Free Queue. >+** 01:00 00 2 Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_FREE_HEAD_PTR_REG 0xFFFFE360 >+/* >+************************************************************************** >+** Inbound Free Tail Pointer Register - IFTPR >+** >+** . The Inbound Free Tail Pointer Register (IFTPR) contains the local memory offset from the Queue >+** Base Address of the tail pointer for the Inbound Free Queue. The Tail Pointer must be aligned on a >+** DWORD address boundary. When read, the Queue Base Address is provided in the upper 12 bits >+** of the register. Writes to the upper 12 bits of the register are ignored. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:20 000H Queue Base Address - Local memory address of the circular queues. >+** 19:02 0000H 00 2 Inbound Free Tail Pointer - Local memory offset of the tail pointer for the Inbound Free Queue. >+** 01:00 00 2 Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_FREE_TAIL_PTR_REG 0xFFFFE364 >+/* >+************************************************************************** >+** Inbound Post Head Pointer Register - IPHPR >+** >+** . The Inbound Post Head Pointer Register (IPHPR) contains the local memory offset from the Queue >+** Base Address of the head pointer for the Inbound Post Queue. The Head Pointer must be aligned on >+** a DWORD address boundary. When read, the Queue Base Address is provided in the upper 12 bits >+** of the register. Writes to the upper 12 bits of the register are ignored. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:20 000H Queue Base Address - Local memory address of the circular queues. >+** 19:02 0000H 00 2 Inbound Post Head Pointer - Local memory offset of the head pointer for the Inbound Post Queue. >+** 01:00 00 2 Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_POST_HEAD_PTR_REG 0xFFFFE368 >+/* >+************************************************************************** >+** Inbound Post Tail Pointer Register - IPTPR >+** >+** . The Inbound Post Tail Pointer Register (IPTPR) contains the local memory offset from the Queue >+** Base Address of the tail pointer for the Inbound Post Queue. The Tail Pointer must be aligned on a >+** DWORD address boundary. When read, the Queue Base Address is provided in the upper 12 bits >+** of the register. Writes to the upper 12 bits of the register are ignored. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:20 000H Queue Base Address - Local memory address of the circular queues. >+** 19:02 0000H 00 2 Inbound Post Tail Pointer - Local memory offset of the tail pointer for the Inbound Post Queue. >+** 01:00 00 2 Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_INBOUND_POST_TAIL_PTR_REG 0xFFFFE36C >+/* >+************************************************************************** >+** Index Address Register - IAR >+** >+** . The Index Address Register (IAR) contains the offset of the least recently accessed Index Register. >+** It is written by the MU when the Index Registers are written by a PCI agent. >+** The register is not updated until the Index Interrupt bit in the Inbound Interrupt Status Register is cleared. >+** . The local memory address of the Index Register least recently accessed is computed by adding the Index Address Register to the Inbound ATU Translate Value Register. >+** ------------------------------------------------------------------------ >+** Bit Default Description >+** 31:12 000000H Reserved >+** 11:02 00H 00 2 Index Address - is the local memory offset of the Index Register written (050H to FFCH) >+** 01:00 00 2 Reserved >+************************************************************************** >+*/ >+#define ARCMSR_MU_LOCAL_MEMORY_INDEX_REG 0xFFFFE380 /*1004 dwords 0x0050....0x0FFC, 4016 bytes 0x0050...0x0FFF*/ >+/* >+********************************************************************************************************** >+** RS-232 Interface for Areca Raid Controller >+** The low level command interface is exclusive with VT100 terminal >+** -------------------------------------------------------------------- >+** 1. Sequence of command execution >+** -------------------------------------------------------------------- >+** (A) Header : 3 bytes sequence (0x5E, 0x01, 0x61) >+** (B) Command block : variable length of data including length, command code, data and checksum byte >+** (C) Return data : variable length of data >+** -------------------------------------------------------------------- >+** 2. Command block >+** -------------------------------------------------------------------- >+** (A) 1st byte : command block length (low byte) >+** (B) 2nd byte : command block length (high byte) >+** note ..command block length shouldn't > 2040 bytes, length excludes these two bytes >+** (C) 3rd byte : command code >+** (D) 4th and following bytes : variable length data bytes depends on command code >+** (E) last byte : checksum byte (sum of 1st byte until last data byte) >+** -------------------------------------------------------------------- >+** 3. Command code and associated data >+** -------------------------------------------------------------------- >+** The following are command code defined in raid controller Command code 0x10--0x1? are used for system level management, no password checking is needed and should be implemented in separate well controlled utility and not for end user access. >+** Command code 0x20--0x?? always check the password, password must be entered to enable these command. >+** enum >+** { >+** GUI_SET_SERIAL=0x10, >+** GUI_SET_VENDOR, >+** GUI_SET_MODEL, >+** GUI_IDENTIFY, >+** GUI_CHECK_PASSWORD, >+** GUI_LOGOUT, >+** GUI_HTTP, >+** GUI_SET_ETHERNET_ADDR, >+** GUI_SET_LOGO, >+** GUI_POLL_EVENT, >+** GUI_GET_EVENT, >+** GUI_GET_HW_MONITOR, >+** >+** // GUI_QUICK_CREATE=0x20, (function removed) >+** GUI_GET_INFO_R=0x20, >+** GUI_GET_INFO_V, >+** GUI_GET_INFO_P, >+** GUI_GET_INFO_S, >+** GUI_CLEAR_EVENT, >+** >+** GUI_MUTE_BEEPER=0x30, >+** GUI_BEEPER_SETTING, >+** GUI_SET_PASSWORD, >+** GUI_HOST_INTERFACE_MODE, >+** GUI_REBUILD_PRIORITY, >+** GUI_MAX_ATA_MODE, >+** GUI_RESET_CONTROLLER, >+** GUI_COM_PORT_SETTING, >+** GUI_NO_OPERATION, >+** GUI_DHCP_IP, >+** >+** GUI_CREATE_PASS_THROUGH=0x40, >+** GUI_MODIFY_PASS_THROUGH, >+** GUI_DELETE_PASS_THROUGH, >+** GUI_IDENTIFY_DEVICE, >+** >+** GUI_CREATE_RAIDSET=0x50, >+** GUI_DELETE_RAIDSET, >+** GUI_EXPAND_RAIDSET, >+** GUI_ACTIVATE_RAIDSET, >+** GUI_CREATE_HOT_SPARE, >+** GUI_DELETE_HOT_SPARE, >+** >+** GUI_CREATE_VOLUME=0x60, >+** GUI_MODIFY_VOLUME, >+** GUI_DELETE_VOLUME, >+** GUI_START_CHECK_VOLUME, >+** GUI_STOP_CHECK_VOLUME >+** }; >+** >+** Command description : >+** >+** GUI_SET_SERIAL : Set the controller serial# >+** byte 0,1 : length >+** byte 2 : command code 0x10 >+** byte 3 : password length (should be 0x0f) >+** byte 4-0x13 : should be "ArEcATecHnoLogY" >+** byte 0x14--0x23 : Serial number string (must be 16 bytes) >+** GUI_SET_VENDOR : Set vendor string for the controller >+** byte 0,1 : length >+** byte 2 : command code 0x11 >+** byte 3 : password length (should be 0x08) >+** byte 4-0x13 : should be "ArEcAvAr" >+** byte 0x14--0x3B : vendor string (must be 40 bytes) >+** GUI_SET_MODEL : Set the model name of the controller >+** byte 0,1 : length >+** byte 2 : command code 0x12 >+** byte 3 : password length (should be 0x08) >+** byte 4-0x13 : should be "ArEcAvAr" >+** byte 0x14--0x1B : model string (must be 8 bytes) >+** GUI_IDENTIFY : Identify device >+** byte 0,1 : length >+** byte 2 : command code 0x13 >+** return "Areca RAID Subsystem " >+** GUI_CHECK_PASSWORD : Verify password >+** byte 0,1 : length >+** byte 2 : command code 0x14 >+** byte 3 : password length >+** byte 4-0x?? : user password to be checked >+** GUI_LOGOUT : Logout GUI (force password checking on next command) >+** byte 0,1 : length >+** byte 2 : command code 0x15 >+** GUI_HTTP : HTTP interface (reserved for Http proxy service)(0x16) >+** >+** GUI_SET_ETHERNET_ADDR : Set the ethernet MAC address >+** byte 0,1 : length >+** byte 2 : command code 0x17 >+** byte 3 : password length (should be 0x08) >+** byte 4-0x13 : should be "ArEcAvAr" >+** byte 0x14--0x19 : Ethernet MAC address (must be 6 bytes) >+** GUI_SET_LOGO : Set logo in HTTP >+** byte 0,1 : length >+** byte 2 : command code 0x18 >+** byte 3 : Page# (0/1/2/3) (0xff --> clear OEM logo) >+** byte 4/5/6/7 : 0x55/0xaa/0xa5/0x5a >+** byte 8 : TITLE.JPG data (each page must be 2000 bytes) >+** note .... page0 1st 2 byte must be actual length of the JPG file >+** GUI_POLL_EVENT : Poll If Event Log Changed >+** byte 0,1 : length >+** byte 2 : command code 0x19 >+** GUI_GET_EVENT : Read Event >+** byte 0,1 : length >+** byte 2 : command code 0x1a >+** byte 3 : Event Page (0:1st page/1/2/3:last page) >+** GUI_GET_HW_MONITOR : Get HW monitor data >+** byte 0,1 : length >+** byte 2 : command code 0x1b >+** byte 3 : # of FANs(example 2) >+** byte 4 : # of Voltage sensor(example 3) >+** byte 5 : # of temperature sensor(example 2) >+** byte 6 : # of power >+** byte 7/8 : Fan#0 (RPM) >+** byte 9/10 : Fan#1 >+** byte 11/12 : Voltage#0 original value in *1000 >+** byte 13/14 : Voltage#0 value >+** byte 15/16 : Voltage#1 org >+** byte 17/18 : Voltage#1 >+** byte 19/20 : Voltage#2 org >+** byte 21/22 : Voltage#2 >+** byte 23 : Temp#0 >+** byte 24 : Temp#1 >+** byte 25 : Power indicator (bit0 : power#0, bit1 : power#1) >+** byte 26 : UPS indicator >+** GUI_QUICK_CREATE : Quick create raid/volume set >+** byte 0,1 : length >+** byte 2 : command code 0x20 >+** byte 3/4/5/6 : raw capacity >+** byte 7 : raid level >+** byte 8 : stripe size >+** byte 9 : spare >+** byte 10/11/12/13: device mask (the devices to create raid/volume) >+** This function is removed, application like to implement quick create function >+** need to use GUI_CREATE_RAIDSET and GUI_CREATE_VOLUMESET function. >+** GUI_GET_INFO_R : Get Raid Set Information >+** byte 0,1 : length >+** byte 2 : command code 0x20 >+** byte 3 : raidset# >+** >+** typedef struct sGUI_RAIDSET >+** { >+** BYTE grsRaidSetName[16]; >+** DWORD grsCapacity; >+** DWORD grsCapacityX; >+** DWORD grsFailMask; >+** BYTE grsDevArray[32]; >+** BYTE grsMemberDevices; >+** BYTE grsNewMemberDevices; >+** BYTE grsRaidState; >+** BYTE grsVolumes; >+** BYTE grsVolumeList[16]; >+** BYTE grsRes1; >+** BYTE grsRes2; >+** BYTE grsRes3; >+** BYTE grsFreeSegments; >+** DWORD grsRawStripes[8]; >+** DWORD grsRes4; >+** DWORD grsRes5; // Total to 128 bytes >+** DWORD grsRes6; // Total to 128 bytes >+** } sGUI_RAIDSET, *pGUI_RAIDSET; >+** GUI_GET_INFO_V : Get Volume Set Information >+** byte 0,1 : length >+** byte 2 : command code 0x21 >+** byte 3 : volumeset# >+** >+** typedef struct sGUI_VOLUMESET >+** { >+** BYTE gvsVolumeName[16]; // 16 >+** DWORD gvsCapacity; >+** DWORD gvsCapacityX; >+** DWORD gvsFailMask; >+** DWORD gvsStripeSize; >+** DWORD gvsNewFailMask; >+** DWORD gvsNewStripeSize; >+** DWORD gvsVolumeStatus; >+** DWORD gvsProgress; // 32 >+** sSCSI_ATTR gvsScsi; >+** BYTE gvsMemberDisks; >+** BYTE gvsRaidLevel; // 8 >+** >+** BYTE gvsNewMemberDisks; >+** BYTE gvsNewRaidLevel; >+** BYTE gvsRaidSetNumber; >+** BYTE gvsRes0; // 4 >+** BYTE gvsRes1[4]; // 64 bytes >+** } sGUI_VOLUMESET, *pGUI_VOLUMESET; >+** >+** GUI_GET_INFO_P : Get Physical Drive Information >+** byte 0,1 : length >+** byte 2 : command code 0x22 >+** byte 3 : drive # (from 0 to max-channels - 1) >+** >+** typedef struct sGUI_PHY_DRV >+** { >+** BYTE gpdModelName[40]; >+** BYTE gpdSerialNumber[20]; >+** BYTE gpdFirmRev[8]; >+** DWORD gpdCapacity; >+** DWORD gpdCapacityX; // Reserved for expansion >+** BYTE gpdDeviceState; >+** BYTE gpdPioMode; >+** BYTE gpdCurrentUdmaMode; >+** BYTE gpdUdmaMode; >+** BYTE gpdDriveSelect; >+** BYTE gpdRaidNumber; // 0xff if not belongs to a raid set >+** sSCSI_ATTR gpdScsi; >+** BYTE gpdReserved[40]; // Total to 128 bytes >+** } sGUI_PHY_DRV, *pGUI_PHY_DRV; >+** >+** GUI_GET_INFO_S : Get System Information >+** byte 0,1 : length >+** byte 2 : command code 0x23 >+** >+** typedef struct sCOM_ATTR >+** { >+** BYTE comBaudRate; >+** BYTE comDataBits; >+** BYTE comStopBits; >+** BYTE comParity; >+** BYTE comFlowControl; >+** } sCOM_ATTR, *pCOM_ATTR; >+** >+** typedef struct sSYSTEM_INFO >+** { >+** BYTE gsiVendorName[40]; >+** BYTE gsiSerialNumber[16]; >+** BYTE gsiFirmVersion[16]; >+** BYTE gsiBootVersion[16]; >+** BYTE gsiMbVersion[16]; >+** BYTE gsiModelName[8]; >+** BYTE gsiLocalIp[4]; >+** BYTE gsiCurrentIp[4]; >+** DWORD gsiTimeTick; >+** DWORD gsiCpuSpeed; >+** DWORD gsiICache; >+** DWORD gsiDCache; >+** DWORD gsiScache; >+** DWORD gsiMemorySize; >+** DWORD gsiMemorySpeed; >+** DWORD gsiEvents; >+** BYTE gsiMacAddress[6]; >+** BYTE gsiDhcp; >+** BYTE gsiBeeper; >+** BYTE gsiChannelUsage; >+** BYTE gsiMaxAtaMode; >+** BYTE gsiSdramEcc; // 1:if ECC enabled >+** BYTE gsiRebuildPriority; >+** sCOM_ATTR gsiComA; // 5 bytes >+** sCOM_ATTR gsiComB; // 5 bytes >+** BYTE gsiIdeChannels; >+** BYTE gsiScsiHostChannels; >+** BYTE gsiIdeHostChannels; >+** BYTE gsiMaxVolumeSet; >+** BYTE gsiMaxRaidSet; >+** BYTE gsiEtherPort; // 1:if ether net port supported >+** BYTE gsiRaid6Engine; // 1:Raid6 engine supported >+** BYTE gsiRes[75]; >+** } sSYSTEM_INFO, *pSYSTEM_INFO; >+** >+** GUI_CLEAR_EVENT : Clear System Event >+** byte 0,1 : length >+** byte 2 : command code 0x24 >+** >+** GUI_MUTE_BEEPER : Mute current beeper >+** byte 0,1 : length >+** byte 2 : command code 0x30 >+** >+** GUI_BEEPER_SETTING : Disable beeper >+** byte 0,1 : length >+** byte 2 : command code 0x31 >+** byte 3 : 0->disable, 1->enable >+** >+** GUI_SET_PASSWORD : Change password >+** byte 0,1 : length >+** byte 2 : command code 0x32 >+** byte 3 : pass word length ( must <= 15 ) >+** byte 4 : password (must be alpha-numerical) >+** >+** GUI_HOST_INTERFACE_MODE : Set host interface mode >+** byte 0,1 : length >+** byte 2 : command code 0x33 >+** byte 3 : 0->Independent, 1->cluster >+** >+** GUI_REBUILD_PRIORITY : Set rebuild priority >+** byte 0,1 : length >+** byte 2 : command code 0x34 >+** byte 3 : 0/1/2/3 (low->high) >+** >+** GUI_MAX_ATA_MODE : Set maximum ATA mode to be used >+** byte 0,1 : length >+** byte 2 : command code 0x35 >+** byte 3 : 0/1/2/3 (133/100/66/33) >+** >+** GUI_RESET_CONTROLLER : Reset Controller >+** byte 0,1 : length >+** byte 2 : command code 0x36 >+** *Response with VT100 screen (discard it) >+** >+** GUI_COM_PORT_SETTING : COM port setting >+** byte 0,1 : length >+** byte 2 : command code 0x37 >+** byte 3 : 0->COMA (term port), 1->COMB (debug port) >+** byte 4 : 0/1/2/3/4/5/6/7 (1200/2400/4800/9600/19200/38400/57600/115200) >+** byte 5 : data bit (0:7 bit, 1:8 bit : must be 8 bit) >+** byte 6 : stop bit (0:1, 1:2 stop bits) >+** byte 7 : parity (0:none, 1:off, 2:even) >+** byte 8 : flow control (0:none, 1:xon/xoff, 2:hardware => must use none) >+** >+** GUI_NO_OPERATION : No operation >+** byte 0,1 : length >+** byte 2 : command code 0x38 >+** >+** GUI_DHCP_IP : Set DHCP option and local IP address >+** byte 0,1 : length >+** byte 2 : command code 0x39 >+** byte 3 : 0:dhcp disabled, 1:dhcp enabled >+** byte 4/5/6/7 : IP address >+** >+** GUI_CREATE_PASS_THROUGH : Create pass through disk >+** byte 0,1 : length >+** byte 2 : command code 0x40 >+** byte 3 : device # >+** byte 4 : scsi channel (0/1) >+** byte 5 : scsi id (0-->15) >+** byte 6 : scsi lun (0-->7) >+** byte 7 : tagged queue (1 : enabled) >+** byte 8 : cache mode (1 : enabled) >+** byte 9 : max speed (0/1/2/3/4, async/20/40/80/160 for scsi) >+** (0/1/2/3/4, 33/66/100/133/150 for ide ) >+** >+** GUI_MODIFY_PASS_THROUGH : Modify pass through disk >+** byte 0,1 : length >+** byte 2 : command code 0x41 >+** byte 3 : device # >+** byte 4 : scsi channel (0/1) >+** byte 5 : scsi id (0-->15) >+** byte 6 : scsi lun (0-->7) >+** byte 7 : tagged queue (1 : enabled) >+** byte 8 : cache mode (1 : enabled) >+** byte 9 : max speed (0/1/2/3/4, async/20/40/80/160 for scsi) >+** (0/1/2/3/4, 33/66/100/133/150 for ide ) >+** >+** GUI_DELETE_PASS_THROUGH : Delete pass through disk >+** byte 0,1 : length >+** byte 2 : command code 0x42 >+** byte 3 : device# to be deleted >+** >+** GUI_IDENTIFY_DEVICE : Identify Device >+** byte 0,1 : length >+** byte 2 : command code 0x43 >+** byte 3 : Flash Method(0:flash selected, 1:flash not selected) >+** byte 4/5/6/7 : IDE device mask to be flashed >+** note .... no response data available >+** >+** GUI_CREATE_RAIDSET : Create Raid Set >+** byte 0,1 : length >+** byte 2 : command code 0x50 >+** byte 3/4/5/6 : device mask >+** byte 7-22 : raidset name (if byte 7 == 0:use default) >+** >+** GUI_DELETE_RAIDSET : Delete Raid Set >+** byte 0,1 : length >+** byte 2 : command code 0x51 >+** byte 3 : raidset# >+** >+** GUI_EXPAND_RAIDSET : Expand Raid Set >+** byte 0,1 : length >+** byte 2 : command code 0x52 >+** byte 3 : raidset# >+** byte 4/5/6/7 : device mask for expansion >+** byte 8/9/10 : (8:0 no change, 1 change, 0xff:terminate, 9:new raid level,10:new stripe size 0/1/2/3/4/5->4/8/16/32/64/128K ) >+** byte 11/12/13 : repeat for each volume in the raidset .... >+** >+** GUI_ACTIVATE_RAIDSET : Activate incomplete raid set >+** byte 0,1 : length >+** byte 2 : command code 0x53 >+** byte 3 : raidset# >+** >+** GUI_CREATE_HOT_SPARE : Create hot spare disk >+** byte 0,1 : length >+** byte 2 : command code 0x54 >+** byte 3/4/5/6 : device mask for hot spare creation >+** >+** GUI_DELETE_HOT_SPARE : Delete hot spare disk >+** byte 0,1 : length >+** byte 2 : command code 0x55 >+** byte 3/4/5/6 : device mask for hot spare deletion >+** >+** GUI_CREATE_VOLUME : Create volume set >+** byte 0,1 : length >+** byte 2 : command code 0x60 >+** byte 3 : raidset# >+** byte 4-19 : volume set name (if byte4 == 0, use default) >+** byte 20-27 : volume capacity (blocks) >+** byte 28 : raid level >+** byte 29 : stripe size (0/1/2/3/4/5->4/8/16/32/64/128K) >+** byte 30 : channel >+** byte 31 : ID >+** byte 32 : LUN >+** byte 33 : 1 enable tag >+** byte 34 : 1 enable cache >+** byte 35 : speed (0/1/2/3/4->async/20/40/80/160 for scsi) >+** (0/1/2/3/4->33/66/100/133/150 for IDE ) >+** byte 36 : 1 to select quick init >+** >+** GUI_MODIFY_VOLUME : Modify volume Set >+** byte 0,1 : length >+** byte 2 : command code 0x61 >+** byte 3 : volumeset# >+** byte 4-19 : new volume set name (if byte4 == 0, not change) >+** byte 20-27 : new volume capacity (reserved) >+** byte 28 : new raid level >+** byte 29 : new stripe size (0/1/2/3/4/5->4/8/16/32/64/128K) >+** byte 30 : new channel >+** byte 31 : new ID >+** byte 32 : new LUN >+** byte 33 : 1 enable tag >+** byte 34 : 1 enable cache >+** byte 35 : speed (0/1/2/3/4->async/20/40/80/160 for scsi) >+** (0/1/2/3/4->33/66/100/133/150 for IDE ) >+** >+** GUI_DELETE_VOLUME : Delete volume set >+** byte 0,1 : length >+** byte 2 : command code 0x62 >+** byte 3 : volumeset# >+** >+** GUI_START_CHECK_VOLUME : Start volume consistency check >+** byte 0,1 : length >+** byte 2 : command code 0x63 >+** byte 3 : volumeset# >+** >+** GUI_STOP_CHECK_VOLUME : Stop volume consistency check >+** byte 0,1 : length >+** byte 2 : command code 0x64 >+** --------------------------------------------------------------------- >+** 4. Returned data >+** --------------------------------------------------------------------- >+** (A) Header : 3 bytes sequence (0x5E, 0x01, 0x61) >+** (B) Length : 2 bytes (low byte 1st, excludes length and checksum byte) >+** (C) status or data : >+** <1> If length == 1 ==> 1 byte status code >+** #define GUI_OK 0x41 >+** #define GUI_RAIDSET_NOT_NORMAL 0x42 >+** #define GUI_VOLUMESET_NOT_NORMAL 0x43 >+** #define GUI_NO_RAIDSET 0x44 >+** #define GUI_NO_VOLUMESET 0x45 >+** #define GUI_NO_PHYSICAL_DRIVE 0x46 >+** #define GUI_PARAMETER_ERROR 0x47 >+** #define GUI_UNSUPPORTED_COMMAND 0x48 >+** #define GUI_DISK_CONFIG_CHANGED 0x49 >+** #define GUI_INVALID_PASSWORD 0x4a >+** #define GUI_NO_DISK_SPACE 0x4b >+** #define GUI_CHECKSUM_ERROR 0x4c >+** #define GUI_PASSWORD_REQUIRED 0x4d >+** <2> If length > 1 ==> data block returned from controller and the contents depends on the command code >+** (E) Checksum : checksum of length and status or data byte >+************************************************************************** >+*/ >+extern int arcmsr_release(struct Scsi_Host *); >+extern int arcmsr_queue_command(struct scsi_cmnd *cmd,void (* done)(struct scsi_cmnd *cmd)); >+extern int arcmsr_abort(struct scsi_cmnd *cmd); >+extern int arcmsr_bus_reset(struct scsi_cmnd *cmd); >+extern const char *arcmsr_info(struct Scsi_Host *); >+#if LINUX_VERSION_CODE > KERNEL_VERSION(2,6,0) >+ extern int arcmsr_ioctl(struct scsi_device *dev,int ioctl_cmd,void __user *arg); >+#else >+ extern int arcmsr_ioctl(struct scsi_device *dev,int ioctl_cmd,void *arg); >+#endif >+#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,5,0) >+ #define arcmsr_detect NULL >+ extern int arcmsr_proc_info(struct Scsi_Host *host, char *buffer, char **start, off_t offset, int length, int inout); >+ extern int arcmsr_bios_param(struct scsi_device *sdev, struct block_device *bdev, sector_t capacity, int *info); >+ >+ static ssize_t arcmsr_show_firmware_info(struct class_device *dev, char *buf) >+ { >+ struct Scsi_Host *host=class_to_shost(dev); >+ struct AdapterControlBlock *acb=(struct AdapterControlBlock *) host->hostdata; >+ unsigned long flags=0; >+ ssize_t len; >+ >+ spin_lock_irqsave(acb->host->host_lock, flags); >+ len=snprintf(buf, PAGE_SIZE, >+ "=================================\n" >+ "Firmware Version: %s\n" >+ "Adapter Model: %s\n" >+ "Reguest Lenth: %4d\n" >+ "Numbers of Queue: %4d\n" >+ "SDRAM Size: %4d\n" >+ "IDE Channels: %4d\n" >+ "=================================\n", >+ acb->firm_version, >+ acb->firm_model, >+ acb->firm_request_len, >+ acb->firm_numbers_queue, >+ acb->firm_sdram_size, >+ acb->firm_ide_channels); >+ spin_unlock_irqrestore(acb->host->host_lock, flags); >+ return len; >+ } >+ static ssize_t arcmsr_show_driver_state(struct class_device *dev, char *buf) >+ { >+ struct Scsi_Host *host=class_to_shost(dev); >+ struct AdapterControlBlock *acb=(struct AdapterControlBlock *)host->hostdata; >+ unsigned long flags=0; >+ ssize_t len; >+ >+ spin_lock_irqsave(acb->host->host_lock, flags); >+ len=snprintf(buf, PAGE_SIZE, >+ "=================================\n" >+ "ARCMSR: %s\n" >+ "Current commands posted: %4d\n" >+ "Max commands posted: %4d\n" >+ "Max sgl length: %4d\n" >+ "Max sector count: %4d\n" >+ "SCSI Host Resets: %4d\n" >+ "SCSI Aborts/Timeouts: %4d\n" >+ "=================================\n", >+ ARCMSR_DRIVER_VERSION, >+ atomic_read(&acb->ccboutstandingcount), >+ ARCMSR_MAX_OUTSTANDING_CMD, >+ ARCMSR_MAX_SG_ENTRIES, >+ ARCMSR_MAX_XFER_SECTORS, >+ acb->num_resets, >+ acb->num_aborts); >+ spin_unlock_irqrestore(acb->host->host_lock, flags); >+ return len; >+ } >+ static struct class_device_attribute arcmsr_firmware_info_attr= >+ { >+ .attr={ >+ .name="firmware_info", >+ .mode=S_IRUGO, >+ }, >+ .show =arcmsr_show_firmware_info, >+ }; >+ static struct class_device_attribute arcmsr_driver_state_attr= >+ { >+ .attr={ >+ .name="driver_state", >+ .mode=S_IRUGO, >+ }, >+ .show=arcmsr_show_driver_state >+ }; >+ static struct class_device_attribute *arcmsr_scsi_host_attr[]= >+ { >+ &arcmsr_firmware_info_attr, >+ &arcmsr_driver_state_attr, >+ NULL >+ }; >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,11) >+ static int arcmsr_adjust_disk_queue_depth(struct scsi_device *sdev,int queue_depth) >+ { >+ if(queue_depth > ARCMSR_MAX_CMD_PERLUN) >+ { >+ queue_depth=ARCMSR_MAX_CMD_PERLUN; >+ } >+ scsi_adjust_queue_depth(sdev, MSG_ORDERED_TAG, queue_depth); >+ return queue_depth; >+ } >+ #else >+ static ssize_t arcmsr_adjust_disk_queue_depth(struct device *dev, const char *buf, size_t count) >+ { >+ int queue_depth; >+ struct scsi_device *sdev = to_scsi_device(dev); >+ >+ queue_depth = simple_strtoul(buf, NULL, 0); >+ if(queue_depth > ARCMSR_MAX_CMD_PERLUN) >+ return -EINVAL; >+ scsi_adjust_queue_depth(sdev, MSG_ORDERED_TAG, queue_depth); >+ return count; >+ } >+ static struct device_attribute arcmsr_queue_depth_attr = >+ { >+ .attr = { >+ .name = "queue_depth", >+ .mode = S_IRUSR | S_IWUSR, >+ }, >+ .store = arcmsr_adjust_disk_queue_depth >+ }; >+ static struct device_attribute *arcmsr_scsi_device_attr[] = >+ { >+ &arcmsr_queue_depth_attr, >+ NULL, >+ }; >+ #endif >+ static struct scsi_host_template arcmsr_scsi_host_template = { >+ .module = THIS_MODULE, >+ .proc_name = "arcmsr", >+ .proc_info = arcmsr_proc_info, >+ .name = "ARCMSR ARECA SATA RAID HOST Adapter" ARCMSR_DRIVER_VERSION, /* *name */ >+ .release = arcmsr_release, >+ .info = arcmsr_info, >+ .ioctl = arcmsr_ioctl, >+ .queuecommand = arcmsr_queue_command, >+ .eh_abort_handler = arcmsr_abort, >+ .eh_device_reset_handler= NULL, >+ .eh_bus_reset_handler = arcmsr_bus_reset, >+ .eh_host_reset_handler = NULL, >+ .bios_param = arcmsr_bios_param, >+ .can_queue = ARCMSR_MAX_OUTSTANDING_CMD, >+ .this_id = ARCMSR_SCSI_INITIATOR_ID, >+ .sg_tablesize = ARCMSR_MAX_SG_ENTRIES, >+ .max_sectors = ARCMSR_MAX_XFER_SECTORS, >+ .cmd_per_lun = ARCMSR_MAX_CMD_PERLUN, >+ .unchecked_isa_dma = 0, >+ .use_clustering = ENABLE_CLUSTERING, >+ .shost_attrs = arcmsr_scsi_host_attr, >+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,11) >+ .change_queue_depth =arcmsr_adjust_disk_queue_depth, >+ #else >+ .sdev_attrs = arcmsr_scsi_device_attr, >+ #endif >+ }; >+#elif LINUX_VERSION_CODE >= KERNEL_VERSION(2,3,30) >+ extern int arcmsr_detect(Scsi_Host_Template *); >+ extern int arcmsr_schedule_command(struct scsi_cmnd * pcmd); >+ extern int arcmsr_proc_info(char * buffer,char ** start,off_t offset,int length,int hostno,int inout); >+ extern int arcmsr_bios_param(Disk *, kdev_t , int []); >+ >+ static Scsi_Host_Template driver_template = { >+ .proc_name = "arcmsr", >+ .proc_info = arcmsr_proc_info, >+ .name = "ARCMSR ARECA SATA RAID HOST Adapter" ARCMSR_DRIVER_VERSION, /* *name */ >+ .detect = arcmsr_detect, >+ .release = arcmsr_release, >+ .info = arcmsr_info, >+ .ioctl = arcmsr_ioctl, >+ .command = arcmsr_schedule_command, >+ .queuecommand = arcmsr_queue_command, >+ .eh_abort_handler = arcmsr_abort, >+ .eh_device_reset_handler= NULL, >+ .eh_bus_reset_handler = arcmsr_bus_reset, >+ .eh_host_reset_handler = NULL, >+ .bios_param = arcmsr_bios_param, >+ .can_queue = ARCMSR_MAX_OUTSTANDING_CMD, >+ .this_id = ARCMSR_SCSI_INITIATOR_ID, >+ .sg_tablesize = ARCMSR_MAX_SG_ENTRIES, >+ .max_sectors = ARCMSR_MAX_XFER_SECTORS, >+ .cmd_per_lun = ARCMSR_MAX_CMD_PERLUN, >+ .unchecked_isa_dma = 0, >+ .use_clustering = DISABLE_CLUSTERING, >+ }; >+ #include "/usr/src/linux/drivers/scsi/scsi_module.c" >+#else /* KERNEL_VERSION(2,2,xx) */ >+ extern int arcmsr_detect(Scsi_Host_Template *); >+ extern int arcmsr_schedule_command(struct scsi_cmnd * pcmd); >+ extern int arcmsr_proc_info(char * buffer,char ** start,off_t offset,int length,int hostno,int inout); >+ extern int arcmsr_bios_param(Disk *, kdev_t , int []); >+ >+ #define ARCMSR { \ >+ proc_dir: NULL, \ >+ proc_info: arcmsr_proc_info, \ >+ name: "ARCMSR ARECA SATA RAID HOST Adapter" ARCMSR_DRIVER_VERSION, /* *name */ \ >+ detect: arcmsr_detect, \ >+ release: arcmsr_release, \ >+ info: arcmsr_info, \ >+ ioctl: arcmsr_ioctl, \ >+ command: arcmsr_schedule_command, \ >+ queuecommand: arcmsr_queue_command, \ >+ eh_abort_handler: arcmsr_abort, \ >+ eh_device_reset_handler: NULL, \ >+ eh_bus_reset_handler: arcmsr_bus_reset, \ >+ eh_host_reset_handler: NULL, \ >+ abort: NULL, \ >+ reset: NULL, \ >+ slave_attach: NULL, \ >+ bios_param: arcmsr_bios_param, \ >+ can_queue: ARCMSR_MAX_OUTSTANDING_CMD,\ >+ this_id: ARCMSR_SCSI_INITIATOR_ID, \ >+ sg_tablesize: ARCMSR_MAX_SG_ENTRIES, \ >+ cmd_per_lun: ARCMSR_MAX_CMD_PERLUN, \ >+ use_new_eh_code: 1, \ >+ unchecked_isa_dma: 0, \ >+ use_clustering: DISABLE_CLUSTERING \ >+ } >+ #ifdef MODULE >+ /* Eventually this will go into an include file, but this will be later */ >+ Scsi_Host_Template driver_template = ARCMSR; >+ #include "scsi_module.c" >+ #endif >+#endif >diff -urN linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/Makefile linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/Makefile >--- linux-2.6.17-gentoo-r4/drivers/scsi/arcmsr/Makefile 1970-01-01 01:00:00.000000000 +0100 >+++ linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/arcmsr/Makefile 2006-08-10 16:12:49.000000000 +0200 >@@ -0,0 +1,8 @@ >+# File: drivers/arcmsr/Makefile >+# Makefile for the ARECA PCI-X PCI-EXPRESS SATA RAID controllers SCSI driver. >+ >+obj-$(CONFIG_SCSI_ARCMSR) := arcmsr.o >+ >+EXTRA_CFLAGS += -I. >+ >+ >diff -urN linux-2.6.17-gentoo-r4/drivers/scsi/Kconfig linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/Kconfig >--- linux-2.6.17-gentoo-r4/drivers/scsi/Kconfig 2006-08-10 16:42:07.000000000 +0200 >+++ linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/Kconfig 2006-08-10 16:24:48.000000000 +0200 >@@ -1829,6 +1829,31 @@ > called zfcp. If you want to compile it as a module, say M here > and read <file:Documentation/modules.txt>. > >+config SCSI_ARCMSR >+ tristate "ARECA ARC11X0[PCI-X]/ARC12X0[PCI-EXPRESS] SATA-RAID support" >+ depends on PCI && SCSI >+ help >+ This driver supports all of ARECA's SATA RAID controllers cards. >+ This is an ARECA maintained driver by Erich Chen. If you have any >+ problems, please mail to <erich@areca.com.tw>. >+ Areca suports its Linux RAID Management Tools >+ Please contact < http://www.areca.com.tw > >+ < ftp://ftp.areca.com.tw > >+ >+ To compile this driver as a module, choose M here: the >+ module will be called arcmsr. >+ >+config SCSI_ARCMSR_MSI >+ bool "Use PCI message signal interrupt" >+ depends on PCI_MSI && SCSI_ARCMSR >+ default n >+ help >+ If you say Y here. You will enable PCI Message signaled Interrupts >+ function, but some machines may have problems. If you get >+ abort command on driver initialize, you have to answer Y here. >+ If the IRQ problem even worse, >+ please report the problem to the maintainer. >+ > endmenu > > source "drivers/scsi/pcmcia/Kconfig" >diff -urN linux-2.6.17-gentoo-r4/drivers/scsi/Makefile linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/Makefile >--- linux-2.6.17-gentoo-r4/drivers/scsi/Makefile 2006-08-10 16:42:07.000000000 +0200 >+++ linux-2.6.17-gentoo-r4-arcmsr-1.20.0X.13/drivers/scsi/Makefile 2006-08-10 16:24:30.000000000 +0200 >@@ -136,6 +136,7 @@ > obj-$(CONFIG_SCSI_SATA_ULI) += libata.o sata_uli.o > obj-$(CONFIG_SCSI_SATA_MV) += libata.o sata_mv.o > obj-$(CONFIG_SCSI_PDC_ADMA) += libata.o pdc_adma.o >+obj-$(CONFIG_SCSI_ARCMSR) += arcmsr/ > > obj-$(CONFIG_ARM) += arm/ >
<b>You cannot view the attachment while viewing its details because your browser does not support IFRAMEs. <a href="attachment.cgi?id=93911">View the attachment on a separate page</a>.</b>
View Attachment As Raw
Actions:
View
Attachments on
bug 143465
: 93911
