/* $Id: advansys.c,v 1.1.1.1 1997/02/25 21:27:45 thomas Exp $ */ /* * advansys.c - Linux Host Driver for AdvanSys SCSI Adapters * * Copyright (c) 1995-1996 Advanced System Products, Inc. * All Rights Reserved. * * This driver may be modified and freely distributed provided that * the above copyright message and this comment are included in the * distribution. The latest version of this driver is available at * the AdvanSys FTP and BBS sites listed below. * * Please send questions, comments, bug reports to: * bobf@advansys.com (Bob Frey) */ /* The driver has been tested with Linux 1.2.1 and 1.3.57 kernels. */ #define ASC_VERSION "1.2" /* AdvanSys Driver Version */ /* Documentation for the AdvanSys Driver A. Adapters Supported by this Driver B. Linux 1.2.X - Directions for Adding the AdvanSys Driver C. Linux 1.3.X - Directions for Adding the AdvanSys Driver D. Source Comments E. Driver Compile Time Options and Debugging F. Driver LILO Option G. Release History H. Known Problems or Issues I. Credits J. AdvanSys Contact Information A. Adapters Supported by this Driver AdvanSys (Advanced System Products, Inc.) manufactures the following Bus-Mastering SCSI-2 Host Adapters for the ISA, EISA, VL, and PCI buses. This Linux driver supports all of these adapters. The CDB counts below indicate the number of SCSI CDB (Command Descriptor Block) requests that can be stored in the RISC chip cache and board LRAM. The driver detect routine will display the number of CDBs available for each adapter detected. This value can be lowered in the BIOS by changing the 'Host Queue Size' adapter setting. Connectivity Products: ABP920 - Bus-Master PCI 16 CDB ABP930 - Bus-Master PCI 16 CDB ABP5140 - Bus-Master PnP ISA 16 CDB Single Channel Products: ABP542 - Bus-Master ISA 240 CDB ABP5150 - Bus-Master ISA 240 CDB * ABP742 - Bus-Master EISA 240 CDB ABP842 - Bus-Master VL 240 CDB ABP940 - Bus-Master PCI 240 CDB Dual Channel Products: ABP950 - Dual Channel Bus-Master PCI 240 CDB Per Channel ABP852 - Dual Channel Bus-Master VL 240 CDB Per Channel ABP752 - Dual Channel Bus-Master EISA 240 CDB Per Channel * This board is shipped by HP with the 4020i CD-R drive. It has no BIOS so it cannot control a boot device, but it can control any secondary devices. B. Linux 1.2.X - Directions for Adding the AdvanSys Driver There are two source files: advansys.h and advansys.c. Copy both of these files to the directory /usr/src/linux/drivers/scsi. 1. Add the following line to /usr/src/linux/arch/i386/config.in after "comment 'SCSI low-level drivers'": bool 'AdvanSys SCSI support' CONFIG_SCSI_ADVANSYS y 2. Add the following lines to /usr/src/linux/drivers/scsi/hosts.c after "#include "hosts.h"": #ifdef CONFIG_SCSI_ADVANSYS #include "advansys.h" #endif and after "static Scsi_Host_Template builtin_scsi_hosts[] =": #ifdef CONFIG_SCSI_ADVANSYS ADVANSYS, #endif 3. Add the following lines to /usr/src/linux/drivers/scsi/Makefile: ifdef CONFIG_SCSI_ADVANSYS SCSI_SRCS := $(SCSI_SRCS) advansys.c SCSI_OBJS := $(SCSI_OBJS) advansys.o else SCSI_MODULE_OBJS := $(SCSI_MODULE_OBJS) advansys.o endif 4. (Optional) If you would like to enable the LILO command line and /etc/lilo.conf 'advansys' option, make the following changes. This option can be used to disable I/O port scanning or to limit I/O port scanning to specific addresses. Refer to the 'Driver LILO Option' section below. Add the following lines to /usr/src/linux/init/main.c in the prototype section: extern void advansys_setup(char *str, int *ints); and add the following lines to the bootsetups[] array. #ifdef CONFIG_SCSI_ADVANSYS { "advansys=", advansys_setup }, #endif 5. If you have the HP 4020i CD-R driver and Linux 1.2.X you should add a fix to the CD-ROM target driver. This fix will allow you to mount CDs with the iso9660 file system. Linux 1.3.X already has this fix. In the file /usr/src/linux/drivers/scsi/sr.c and function get_sectorsize() after the line: if(scsi_CDs[i].sector_size == 0) scsi_CDs[i].sector_size = 2048; add the following line: if(scsi_CDs[i].sector_size == 2340) scsi_CDs[i].sector_size = 2048; 6. In the directory /usr/src/linux run 'make config' to configure the AdvanSys driver, then run 'make vmlinux' or 'make zlilo' to make the kernel. If the AdvanSys driver is not configured, then a loadable module can be built by running 'make modules' and 'make modules_install'. Use 'insmod' and 'rmmod' to install and remove advansys.o. C. Linux 1.3.X - Directions for Adding the AdvanSys Driver There are two source files: advansys.h and advansys.c. Copy both of these files to the directory /usr/src/linux/drivers/scsi. 1. Add the following line to /usr/src/linux/drivers/scsi/Config.in after "comment 'SCSI low-level drivers'": dep_tristate 'AdvanSys SCSI support' CONFIG_SCSI_ADVANSYS $CONFIG_SCSI 2. Add the following lines to /usr/src/linux/drivers/scsi/hosts.c after "#include "hosts.h"": #ifdef CONFIG_SCSI_ADVANSYS #include "advansys.h" #endif and after "static Scsi_Host_Template builtin_scsi_hosts[] =": #ifdef CONFIG_SCSI_ADVANSYS ADVANSYS, #endif 3. Add the following lines to /usr/src/linux/drivers/scsi/Makefile: ifeq ($(CONFIG_SCSI_ADVANSYS),y) L_OBJS += advansys.o else ifeq ($(CONFIG_SCSI_ADVANSYS),m) M_OBJS += advansys.o endif endif 4. Add the following line to /usr/src/linux/include/linux/proc_fs.h in the enum scsi_directory_inos array: PROC_SCSI_ADVANSYS, 5. (Optional) If you would like to enable the LILO command line and /etc/lilo.conf 'advansys' option, make the following changes. This option can be used to disable I/O port scanning or to limit I/O port scanning to specific addresses. Refer to the 'Driver LILO Option' section below. Add the following lines to /usr/src/linux/init/main.c in the prototype section: extern void advansys_setup(char *str, int *ints); and add the following lines to the bootsetups[] array. #ifdef CONFIG_SCSI_ADVANSYS { "advansys=", advansys_setup }, #endif 6. In the directory /usr/src/linux run 'make config' to configure the AdvanSys driver, then run 'make vmlinux' or 'make zlilo' to make the kernel. If the AdvanSys driver is not configured, then a loadable module can be built by running 'make modules' and 'make modules_install'. Use 'insmod' and 'rmmod' to install and remove advansys.o. D. Source Comments 1. Use tab stops set to 4 for the source files. For vi use 'se tabstops=4'. 2. This driver should be maintained in multiple files. But to make it easier to include with Linux and to follow Linux conventions, the whole driver is maintained in the source files advansys.h and advansys.c. In this file logical sections of the driver begin with a comment that contains '---'. The following are the logical sections of the driver below. --- Linux Version --- Linux Include Files --- Driver Options --- Asc Library Constants and Macros --- Debugging Header --- Driver Constants --- Driver Macros --- Driver Structures --- Driver Data --- Driver Function Prototypes --- Linux 'Scsi_Host_Template' and advansys_setup() Functions --- Loadable Driver Support --- Miscellaneous Driver Functions --- Functions Required by the Asc Library --- Tracing and Debugging Functions --- Asc Library Functions 3. The string 'XXX' is used to flag code that needs to be re-written or that contains a problem that needs to be addressed. 4. I have stripped comments from and reformatted the source for the Asc Library which is included in this file. I haven't done this to obfuscate the code. Actually I have done this to deobfuscate the code. The Asc Library source can be found under the following headings. --- Asc Library Constants and Macros --- Asc Library Functions E. Driver Compile Time Options and Debugging In this source file the following constants can be defined. They are defined in the source below. Both of these options are enabled by default. 1. ADVANSYS_DEBUG - enable for debugging and assertions The amount of debugging output can be controlled with the global variable 'asc_dbglvl'. The higher the number the more output. By default the debug level is 0. If the driver is loaded at boot time and the LILO Driver Option is included in the system, the debug level can be changed by specifying a 5th (ASC_NUM_BOARD_SUPPORTED + 1) I/O Port. The first three hex digits of the pseudo I/O Port must be set to 'deb' and the fourth hex digit specifies the debug level: 0 - F. The following command line will look for an adapter at 0x330 and set the debug level to 2. linux advansys=0x330,0x0,0x0,0x0,0xdeb2 If the driver is built as a loadable module this variable can be defined when the driver is loaded. The following insmod command will set the debug level to one. insmod advansys.o asc_dbglvl=1 Debugging Message Levels: 0: Errors Only 1: High-Level Tracing 2-N: Verbose Tracing I don't know the approved way for turning on printk()s to the console. Here's a program I use to do this. Debug output is logged in /var/adm/messages. main() { syscall(103, 7, 0, 0); } I found that increasing LOG_BUF_LEN to 40960 in kernel/printk.c prevents most level 1 debug messages from being lost. 2. ADVANSYS_STATS - enable statistics and tracing For Linux 1.2.X if ADVANSYS_STATS_1_2_PRINT is defined every 10,000 I/O operations the driver will print statistics to the console. This value can be changed by modifying the constant used in advansys_queuecommand(). ADVANSYS_STATS_1_2_PRINT is off by default. For Linux 1.3.X statistics can be accessed by reading the /proc/scsi/advansys/[0-9] files. Note: these statistics are currently maintained on a global driver basis and not per board. F. Driver LILO Option If init/main.c is modified as described in the 'Directions for Adding the AdvanSys Driver to Linux' section (B.4.) above, the driver will recognize the 'advansys' LILO command line and /etc/lilo.conf option. This option can be used to either disable I/O port scanning or to limit scanning to 1 - 4 I/O ports. Regardless of the option setting EISA and PCI boards will still be searched for and detected. This option only affects searching for ISA and VL boards. Examples: 1. Eliminate I/O port scanning: boot: linux advansys= or boot: linux advansys=0x0 2. Limit I/O port scanning to one I/O port: boot: linux advansys=0x110 3. Limit I/O port scanning to four I/O ports: boot: linux advansys=0x110,0x210,0x230,0x330 For a loadable module the same effect can be achieved by setting the 'asc_iopflag' variable and 'asc_ioport' array when loading the driver, e.g. insmod advansys.o asc_iopflag=1 asc_ioport=0x110,0x330 If ADVANSYS_DEBUG is defined a 5th (ASC_NUM_BOARD_SUPPORTED + 1) I/O Port may be added to specify the driver debug level. Refer to the 'Driver Compile Time Options and Debugging' section above for more information. G. Release History 12/23/95 BETA-1.0: First Release 12/28/95 BETA-1.1: 1. Prevent advansys_detect() from being called twice. 2. Add LILO 0xdeb[0-f] option to set 'asc_dbglvl'. 1/12/96 1.2: 1. Prevent re-entrancy in the interrupt handler which resulted in the driver hanging Linux. 2. Fix problem that prevented ABP-940 cards from being recognized on some PCI motherboards. 3. Add support for the ABP-5140 PnP ISA card. 4. Fix check condition return status. 5. Add conditionally compiled code for Linux 1.3.X. H. Known Problems or Issues 1. The setting for 'cmd_per_lun' needs to be changed. It is currently less then what the AdvanSys boards can queue. Because the target and mid-level Linux drivers base memory allocation on 'cmd_per_lun' (as well as 'sg_tablesize') memory use gets out of hand with a large 'cmd_per_lun'. 'cmd_per_lun' should be per device instead of per adapter. When the driver is compiled as a loadable module both 'cmd_per_lun' and 'sg_tablesize' are tuned down to try to prevent memory allocation errors. 2. For the first scsi command sent to a device the driver increases the timeout value. This gives the driver more time to perform its own initialization for the board and each device. The timeout value is only changed on the first scsi command for each device and never thereafter. I. Credits Nathan Hartwell (mage@cdc3.cdc.net) provided the directions and and basis for the Linux 1.3.X changes which were included in the 1.2 release. J. AdvanSys Contact Information Mail: Advanced System Products, Inc. 1150 Ringwood Court San Jose, CA 95131 USA Operator: 1-408-383-9400 FAX: 1-408-383-9612 Tech Support: 1-800-525-7440 BBS: 1-408-383-9540 (9600,N,8,1) Interactive FAX: 1-408-383-9753 Customer Direct Sales: 1-800-883-1099 Tech Support E-Mail: support@advansys.com Linux Support E-Mail: bobf@advansys.com FTP Site: ftp.advansys.com (login: anonymous) Web Site: http://www.advansys.com */ /* * --- Linux Version */ /* * The driver can be used in Linux 1.2.X or 1.3.X. */ #if !defined(LINUX_1_2) && !defined(LINUX_1_3) #ifndef LINUX_VERSION_CODE #include #endif /* LINUX_VERSION_CODE */ #if LINUX_VERSION_CODE > 65536 + 3 * 256 #define LINUX_1_3 #else /* LINUX_VERSION_CODE */ #define LINUX_1_2 #endif /* LINUX_VERSION_CODE */ #endif /* !defined(LINUX_1_2) && !defined(LINUX_1_3) */ /* * --- Linux Include Files */ #ifdef MODULE #ifdef LINUX_1_3 #include #endif /* LINUX_1_3 */ #include #endif /* MODULE */ #include #include #include #include #include #include #include #include #include #ifdef LINUX_1_3 #include #endif /* LINUX_1_3 */ #include #include #include #ifdef LINUX_1_2 #include "../block/blk.h" #else /* LINUX_1_3 */ #include #include #endif /* LINUX_1_3 */ #include "scsi.h" #include "hosts.h" #include "sd.h" #include "advansys.h" /* * --- Driver Options */ #define ADVANSYS_DEBUG /* Enable for debugging and assertions. */ #define ADVANSYS_STATS /* Enable for statistics and tracing. */ #ifdef LINUX_1_2 #undef ADVANSYS_STATS_1_2_PRINT /* Enable to print statistics to console. */ #endif /* LINUX_1_2 */ /* * --- Asc Library Constants and Macros */ #define ASC_LIB_VERSION_MAJOR 1 #define ASC_LIB_VERSION_MINOR 16 #define ASC_LIB_SERIAL_NUMBER 53 typedef unsigned char uchar; typedef unsigned char BYTE; typedef unsigned short WORD; typedef unsigned long DWORD; typedef int BOOL; #ifndef NULL #define NULL (0) #endif #ifndef TRUE #define TRUE (1) #endif #ifndef FALSE #define FALSE (0) #endif #define REG register #define rchar REG char #define rshort REG short #define rint REG int #define rlong REG long #define ruchar REG uchar #define rushort REG ushort #define ruint REG uint #define rulong REG ulong #define NULLPTR ( void *)0 #define FNULLPTR ( void dosfar *)0UL #define EOF (-1) #define EOS '\0' #define ERR (-1) #define UB_ERR (uchar)(0xFF) #define UW_ERR (uint)(0xFFFF) #define UL_ERR (ulong)(0xFFFFFFFFUL) #define iseven_word( val ) ( ( ( ( uint )val) & ( uint )0x0001 ) == 0 ) #define isodd_word( val ) ( ( ( ( uint )val) & ( uint )0x0001 ) != 0 ) #define toeven_word( val ) ( ( ( uint )val ) & ( uint )0xFFFE ) #define biton( val, bits ) ((( uint )( val >> bits ) & (uint)0x0001 ) != 0 ) #define bitoff( val, bits ) ((( uint )( val >> bits ) & (uint)0x0001 ) == 0 ) #define lbiton( val, bits ) ((( ulong )( val >> bits ) & (ulong)0x00000001UL ) != 0 ) #define lbitoff( val, bits ) ((( ulong )( val >> bits ) & (ulong)0x00000001UL ) == 0 ) #define absh( val ) ( ( val ) < 0 ? -( val ) : ( val ) ) #define swapbyte( ch ) ( ( ( (ch) << 4 ) | ( (ch) >> 4 ) ) ) #ifndef GBYTE #define GBYTE (0x40000000UL) #endif #ifndef MBYTE #define MBYTE (0x100000UL) #endif #ifndef KBYTE #define KBYTE (0x400) #endif #define HI_BYTE(x) ( *( ( BYTE *)(&x)+1 ) ) #define LO_BYTE(x) ( *( ( BYTE *)&x ) ) #define HI_WORD(x) ( *( ( WORD *)(&x)+1 ) ) #define LO_WORD(x) ( *( ( WORD *)&x ) ) #ifndef MAKEWORD #define MAKEWORD(lo, hi) ((WORD) (((WORD) lo) | ((WORD) hi << 8))) #endif #ifndef MAKELONG #define MAKELONG(lo, hi) ((DWORD) (((DWORD) lo) | ((DWORD) hi << 16))) #endif #define SwapWords(dWord) ((DWORD) ((dWord >> 16) | (dWord << 16))) #define SwapBytes(word) ((WORD) ((word >> 8) | (word << 8))) #define BigToLittle(dWord) \ ((DWORD) (SwapWords(MAKELONG(SwapBytes(LO_WORD(dWord)), SwapBytes(HI_WORD(dWord)))))) #define LittleToBig(dWord) BigToLittle(dWord) #define Lptr #define dosfar #define far #define PortAddr unsigned short #define Ptr2Func ulong #define inp(port) inb(port) #define inpw(port) inw(port) #define outp(port, byte) outb((byte), (port)) #define outpw(port, word) outw((word), (port)) #define ASC_MAX_SG_QUEUE 5 #define ASC_MAX_SG_LIST (1 + ((ASC_SG_LIST_PER_Q) * (ASC_MAX_SG_QUEUE))) #define CC_INIT_INQ_DISPLAY FALSE #define CC_CLEAR_LRAM_SRB_PTR FALSE #define CC_VERIFY_LRAM_COPY FALSE #define CC_DEBUG_SG_LIST FALSE #define CC_FAST_STRING_IO FALSE #define CC_WRITE_IO_COUNT FALSE #define CC_CLEAR_DMA_REMAIN FALSE #define CC_DISABLE_PCI_PARITY_INT TRUE #define CC_LINK_BUSY_Q FALSE #define CC_TARGET_MODE FALSE #define CC_SCAM FALSE #define CC_LITTLE_ENDIAN_HOST TRUE #ifndef CC_TEST_LRAM_ENDIAN #if CC_LITTLE_ENDIAN_HOST #define CC_TEST_LRAM_ENDIAN FALSE #else #define CC_TEST_LRAM_ENDIAN TRUE #endif #endif #define CC_STRUCT_ALIGNED TRUE #define CC_MEMORY_MAPPED_IO FALSE #ifndef CC_TARGET_MODE #define CC_TARGET_MODE FALSE #endif #ifndef CC_STRUCT_ALIGNED #define CC_STRUCT_ALIGNED FALSE #endif #ifndef CC_LITTLE_ENDIAN_HOST #define CC_LITTLE_ENDIAN_HOST TRUE #endif #if !CC_LITTLE_ENDIAN_HOST #ifndef CC_TEST_LRAM_ENDIAN #define CC_TEST_LRAM_ENDIAN TRUE #endif #endif #ifndef CC_MEMORY_MAPPED_IO #define CC_MEMORY_MAPPED_IO FALSE #endif #ifndef CC_WRITE_IO_COUNT #define CC_WRITE_IO_COUNT FALSE #endif #ifndef CC_CLEAR_DMA_REMAIN #define CC_CLEAR_DMA_REMAIN FALSE #endif #define ASC_CS_TYPE unsigned short #ifndef asc_ptr_type #define asc_ptr_type #endif #ifndef CC_SCAM #define CC_SCAM FALSE #endif #ifndef ASC_GET_PTR2FUNC #define ASC_GET_PTR2FUNC( fun ) ( Ptr2Func )( fun ) #endif #define FLIP_BYTE_NIBBLE( x ) ( ((x<<4)& 0xFF) | (x>>4) ) #define ASC_IS_ISA (0x0001) #define ASC_IS_ISAPNP (0x0081) #define ASC_IS_EISA (0x0002) #define ASC_IS_PCI (0x0004) #define ASC_IS_PCMCIA (0x0008) #define ASC_IS_PNP (0x0010) #define ASC_IS_MCA (0x0020) #define ASC_IS_VL (0x0040) #define ASC_ISA_PNP_PORT_ADDR (0x279) #define ASC_ISA_PNP_PORT_WRITE (ASC_ISA_PNP_PORT_ADDR+0x800) #define ASC_IS_WIDESCSI_16 (0x0100) #define ASC_IS_WIDESCSI_32 (0x0200) #define ASC_IS_BIG_ENDIAN (0x8000) #define ASC_CHIP_MIN_VER_VL (0x01) #define ASC_CHIP_MAX_VER_VL (0x07) #define ASC_CHIP_MIN_VER_PCI (0x09) #define ASC_CHIP_MAX_VER_PCI (0x0F) #define ASC_CHIP_VER_PCI_BIT (0x08) #define ASC_CHIP_MIN_VER_ISA (0x11) #define ASC_CHIP_MIN_VER_ISA_PNP (0x21) #define ASC_CHIP_MAX_VER_ISA (0x27) #define ASC_CHIP_VER_ISA_BIT (0x30) #define ASC_CHIP_VER_ISAPNP_BIT (0x20) #define ASC_CHIP_VER_ASYN_BUG (0x21) #define ASC_CHIP_MIN_VER_EISA (0x41) #define ASC_CHIP_MAX_VER_EISA (0x47) #define ASC_CHIP_VER_EISA_BIT (0x40) #define ASC_MAX_VL_DMA_ADDR (0x07FFFFFFL) #define ASC_MAX_VL_DMA_COUNT (0x07FFFFFFL) #define ASC_MAX_PCI_DMA_ADDR (0xFFFFFFFFL) #define ASC_MAX_PCI_DMA_COUNT (0xFFFFFFFFL) #define ASC_MAX_ISA_DMA_ADDR (0x00FFFFFFL) #define ASC_MAX_ISA_DMA_COUNT (0x00FFFFFFL) #define ASC_MAX_EISA_DMA_ADDR (0x07FFFFFFL) #define ASC_MAX_EISA_DMA_COUNT (0x07FFFFFFL) #if !CC_STRUCT_ALIGNED #define DvcGetQinfo( iop_base, s_addr, outbuf, words) \ AscMemWordCopyFromLram( iop_base, s_addr, outbuf, words) #define DvcPutScsiQ( iop_base, s_addr, outbuf, words) \ AscMemWordCopyToLram( iop_base, s_addr, outbuf, words) #endif #define ASC_SCSI_ID_BITS 3 #define ASC_SCSI_TIX_TYPE uchar #define ASC_ALL_DEVICE_BIT_SET 0xFF #ifdef ASC_WIDESCSI_16 #undef ASC_SCSI_ID_BITS #define ASC_SCSI_ID_BITS 4 #define ASC_ALL_DEVICE_BIT_SET 0xFFFF #endif #ifdef ASC_WIDESCSI_32 #undef ASC_SCSI_ID_BITS #define ASC_SCSI_ID_BITS 5 #define ASC_ALL_DEVICE_BIT_SET 0xFFFFFFFFL #endif #if ASC_SCSI_ID_BITS == 3 #define ASC_SCSI_BIT_ID_TYPE uchar #define ASC_MAX_TID 7 #define ASC_MAX_LUN 7 #define ASC_SCSI_WIDTH_BIT_SET 0xFF #elif ASC_SCSI_ID_BITS == 4 #define ASC_SCSI_BIT_ID_TYPE ushort #define ASC_MAX_TID 15 #define ASC_MAX_LUN 7 #define ASC_SCSI_WIDTH_BIT_SET 0xFFFF #elif ASC_SCSI_ID_BITS == 5 #define ASC_SCSI_BIT_ID_TYPE ulong #define ASC_MAX_TID 31 #define ASC_MAX_LUN 7 #define ASC_SCSI_WIDTH_BIT_SET 0xFFFFFFFF #else #error ASC_SCSI_ID_BITS definition is wrong #endif #define ASC_MAX_SENSE_LEN 32 #define ASC_MIN_SENSE_LEN 14 #define ASC_MAX_CDB_LEN 12 #define SCSICMD_TestUnitReady 0x00 #define SCSICMD_Rewind 0x01 #define SCSICMD_Rezero 0x01 #define SCSICMD_RequestSense 0x03 #define SCSICMD_Format 0x04 #define SCSICMD_FormatUnit 0x04 #define SCSICMD_Read6 0x08 #define SCSICMD_Write6 0x0A #define SCSICMD_Seek6 0x0B #define SCSICMD_Inquiry 0x12 #define SCSICMD_Verify6 0x13 #define SCSICMD_ModeSelect6 0x15 #define SCSICMD_ModeSense6 0x1A #define SCSICMD_StartStopUnit 0x1B #define SCSICMD_LoadUnloadTape 0x1B #define SCSICMD_ReadCapacity 0x25 #define SCSICMD_Read10 0x28 #define SCSICMD_Write10 0x2A #define SCSICMD_Seek10 0x2B #define SCSICMD_Erase10 0x2C #define SCSICMD_WriteAndVerify10 0x2E #define SCSICMD_Verify10 0x2F #define SCSICMD_ModeSelect10 0x55 #define SCSICMD_ModeSense10 0x5A #define SCSI_TYPE_DASD 0x00 #define SCSI_TYPE_SASD 0x01 #define SCSI_TYPE_PRN 0x02 #define SCSI_TYPE_PROC 0x03 #define SCSI_TYPE_WORM 0x04 #define SCSI_TYPE_CDROM 0x05 #define SCSI_TYPE_SCANNER 0x06 #define SCSI_TYPE_OPTMEM 0x07 #define SCSI_TYPE_MED_CHG 0x08 #define SCSI_TYPE_COMM 0x09 #define SCSI_TYPE_UNKNOWN 0x1F #define SCSI_TYPE_NO_DVC 0xFF #define ASC_SCSIDIR_NOCHK 0x00 #define ASC_SCSIDIR_T2H 0x08 #define ASC_SCSIDIR_H2T 0x10 #define ASC_SCSIDIR_NODATA 0x18 #define SCSI_SENKEY_NO_SENSE 0x00 #define SCSI_SENKEY_UNDEFINED 0x01 #define SCSI_SENKEY_NOT_READY 0x02 #define SCSI_SENKEY_MEDIUM_ERR 0x03 #define SCSI_SENKEY_HW_ERR 0x04 #define SCSI_SENKEY_ILLEGAL 0x05 #define SCSI_SENKEY_ATTENSION 0x06 #define SCSI_SENKEY_PROTECTED 0x07 #define SCSI_SENKEY_BLANK 0x08 #define SCSI_SENKEY_V_UNIQUE 0x09 #define SCSI_SENKEY_CPY_ABORT 0x0A #define SCSI_SENKEY_ABORT 0x0B #define SCSI_SENKEY_EQUAL 0x0C #define SCSI_SENKEY_VOL_OVERFLOW 0x0D #define SCSI_SENKEY_MISCOMP 0x0E #define SCSI_SENKEY_RESERVED 0x0F #define ASC_SRB_HOST( x ) ( ( uchar )( ( uchar )( x ) >> 4 ) ) #define ASC_SRB_TID( x ) ( ( uchar )( ( uchar )( x ) & ( uchar )0x0F ) ) #define ASC_SRB_LUN( x ) ( ( uchar )( ( uint )( x ) >> 13 ) ) #define PUT_CDB1( x ) ( ( uchar )( ( uint )( x ) >> 8 ) ) #define SS_GOOD 0x00 #define SS_CHK_CONDITION 0x02 #define SS_CONDITION_MET 0x04 #define SS_TARGET_BUSY 0x08 #define SS_INTERMID 0x10 #define SS_INTERMID_COND_MET 0x14 #define SS_RSERV_CONFLICT 0x18 #define SS_CMD_TERMINATED 0x22 #define SS_QUEUE_FULL 0x28 #define MS_CMD_DONE 0x00 #define MS_EXTEND 0x01 #define MS_SDTR_LEN 0x03 #define MS_SDTR_CODE 0x01 #define M1_SAVE_DATA_PTR 0x02 #define M1_RESTORE_PTRS 0x03 #define M1_DISCONNECT 0x04 #define M1_INIT_DETECTED_ERR 0x05 #define M1_ABORT 0x06 #define M1_MSG_REJECT 0x07 #define M1_NO_OP 0x08 #define M1_MSG_PARITY_ERR 0x09 #define M1_LINK_CMD_DONE 0x0A #define M1_LINK_CMD_DONE_WFLAG 0x0B #define M1_BUS_DVC_RESET 0x0C #define M1_ABORT_TAG 0x0D #define M1_CLR_QUEUE 0x0E #define M1_INIT_RECOVERY 0x0F #define M1_RELEASE_RECOVERY 0x10 #define M1_KILL_IO_PROC 0x11 #define M2_QTAG_MSG_SIMPLE 0x20 #define M2_QTAG_MSG_HEAD 0x21 #define M2_QTAG_MSG_ORDERED 0x22 #define M2_IGNORE_WIDE_RESIDUE 0x23 typedef struct { uchar peri_dvc_type:5; uchar peri_qualifier:3; } ASC_SCSI_INQ0; typedef struct { uchar dvc_type_modifier:7; uchar rmb:1; } ASC_SCSI_INQ1; typedef struct { uchar ansi_apr_ver:3; uchar ecma_ver:3; uchar iso_ver:2; } ASC_SCSI_INQ2; typedef struct { uchar rsp_data_fmt:4; uchar res:2; uchar TemIOP:1; uchar aenc:1; } ASC_SCSI_INQ3; typedef struct { uchar StfRe:1; uchar CmdQue:1; uchar Reserved:1; uchar Linked:1; uchar Sync:1; uchar WBus16:1; uchar WBus32:1; uchar RelAdr:1; } ASC_SCSI_INQ7; typedef struct { ASC_SCSI_INQ0 byte0; ASC_SCSI_INQ1 byte1; ASC_SCSI_INQ2 byte2; ASC_SCSI_INQ3 byte3; uchar add_len; uchar res1; uchar res2; ASC_SCSI_INQ7 byte7; uchar vendor_id[8]; uchar product_id[16]; uchar product_rev_level[4]; } ASC_SCSI_INQUIRY; typedef struct asc_req_sense { uchar err_code:7; uchar info_valid:1; uchar segment_no; uchar sense_key:4; uchar reserved_bit:1; uchar sense_ILI:1; uchar sense_EOM:1; uchar file_mark:1; uchar info1[4]; uchar add_sense_len; uchar cmd_sp_info[4]; uchar asc; uchar ascq; uchar fruc; uchar sks_byte0:7; uchar sks_valid:1; uchar sks_bytes[2]; uchar notused[2]; uchar ex_sense_code; uchar info2[4]; } ASC_REQ_SENSE; #define ASC_SG_LIST_PER_Q 7 #define QS_FREE 0x00 #define QS_READY 0x01 #define QS_DISC1 0x02 #define QS_DISC2 0x04 #define QS_BUSY 0x08 #define QS_ABORTED 0x40 #define QS_DONE 0x80 #define QC_NO_CALLBACK 0x01 #define QC_SG_SWAP_QUEUE 0x02 #define QC_SG_HEAD 0x04 #define QC_DATA_IN 0x08 #define QC_DATA_OUT 0x10 #define QC_URGENT 0x20 #define QC_MSG_OUT 0x40 #define QC_REQ_SENSE 0x80 #define QCSG_SG_XFER_LIST 0x02 #define QCSG_SG_XFER_MORE 0x04 #define QCSG_SG_XFER_END 0x08 #define QD_IN_PROGRESS 0x00 #define QD_NO_ERROR 0x01 #define QD_ABORTED_BY_HOST 0x02 #define QD_WITH_ERROR 0x04 #define QD_INVALID_REQUEST 0x80 #define QD_INVALID_HOST_NUM 0x81 #define QD_INVALID_DEVICE 0x82 #define QD_ERR_INTERNAL 0xFF #define QHSTA_NO_ERROR 0x00 #define QHSTA_M_SEL_TIMEOUT 0x11 #define QHSTA_M_DATA_OVER_RUN 0x12 #define QHSTA_M_DATA_UNDER_RUN 0x12 #define QHSTA_M_UNEXPECTED_BUS_FREE 0x13 #define QHSTA_M_BAD_BUS_PHASE_SEQ 0x14 #define QHSTA_D_QDONE_SG_LIST_CORRUPTED 0x21 #define QHSTA_D_ASC_DVC_ERROR_CODE_SET 0x22 #define QHSTA_D_HOST_ABORT_FAILED 0x23 #define QHSTA_D_EXE_SCSI_Q_FAILED 0x24 #define QHSTA_D_EXE_SCSI_Q_BUSY_TIMEOUT 0x25 #define QHSTA_D_ASPI_NO_BUF_POOL 0x26 #define QHSTA_M_WTM_TIMEOUT 0x41 #define QHSTA_M_BAD_CMPL_STATUS_IN 0x42 #define QHSTA_M_NO_AUTO_REQ_SENSE 0x43 #define QHSTA_M_AUTO_REQ_SENSE_FAIL 0x44 #define QHSTA_M_TARGET_STATUS_BUSY 0x45 #define QHSTA_M_BAD_TAG_CODE 0x46 #define QHSTA_M_BAD_QUEUE_FULL_OR_BUSY 0x47 #define QHSTA_D_LRAM_CMP_ERROR 0x81 #define QHSTA_M_MICRO_CODE_ERROR_HALT 0xA1 #define ASC_FLAG_SCSIQ_REQ 0x01 #define ASC_FLAG_BIOS_SCSIQ_REQ 0x02 #define ASC_FLAG_BIOS_ASYNC_IO 0x04 #define ASC_FLAG_SRB_LINEAR_ADDR 0x08 #define ASC_FLAG_WIN16 0x10 #define ASC_FLAG_WIN32 0x20 #define ASC_FLAG_DOS_VM_CALLBACK 0x80 #define ASC_TAG_FLAG_ADD_ONE_BYTE 0x10 #define ASC_TAG_FLAG_ISAPNP_ADD_BYTES 0x40 #define ASC_SCSIQ_CPY_BEG 4 #define ASC_SCSIQ_SGHD_CPY_BEG 2 #define ASC_SCSIQ_B_FWD 0 #define ASC_SCSIQ_B_BWD 1 #define ASC_SCSIQ_B_STATUS 2 #define ASC_SCSIQ_B_QNO 3 #define ASC_SCSIQ_B_CNTL 4 #define ASC_SCSIQ_B_SG_QUEUE_CNT 5 #define ASC_SCSIQ_D_DATA_ADDR 8 #define ASC_SCSIQ_D_DATA_CNT 12 #define ASC_SCSIQ_B_SENSE_LEN 20 #define ASC_SCSIQ_DONE_INFO_BEG 22 #define ASC_SCSIQ_D_SRBPTR 22 #define ASC_SCSIQ_B_TARGET_IX 26 #define ASC_SCSIQ_B_CDB_LEN 28 #define ASC_SCSIQ_B_TAG_CODE 29 #define ASC_SCSIQ_W_VM_ID 30 #define ASC_SCSIQ_DONE_STATUS 32 #define ASC_SCSIQ_HOST_STATUS 33 #define ASC_SCSIQ_SCSI_STATUS 34 #define ASC_SCSIQ_CDB_BEG 36 #define ASC_SCSIQ_DW_REMAIN_XFER_ADDR 56 #define ASC_SCSIQ_DW_REMAIN_XFER_CNT 60 #define ASC_SCSIQ_B_SG_WK_QP 49 #define ASC_SCSIQ_B_SG_WK_IX 50 #define ASC_SCSIQ_W_REQ_COUNT 52 #define ASC_SCSIQ_B_LIST_CNT 6 #define ASC_SCSIQ_B_CUR_LIST_CNT 7 #define ASC_SGQ_B_SG_CNTL 4 #define ASC_SGQ_B_SG_HEAD_QP 5 #define ASC_SGQ_B_SG_LIST_CNT 6 #define ASC_SGQ_B_SG_CUR_LIST_CNT 7 #define ASC_SGQ_LIST_BEG 8 #define ASC_DEF_SCSI1_QNG 2 #define ASC_MAX_SCSI1_QNG 2 #define ASC_DEF_SCSI2_QNG 16 #define ASC_MAX_SCSI2_QNG 32 #define ASC_TAG_CODE_MASK 0x23 #define ASC_STOP_REQ_RISC_STOP 0x01 #define ASC_STOP_ACK_RISC_STOP 0x03 #define ASC_STOP_CLEAN_UP_BUSY_Q 0x10 #define ASC_STOP_CLEAN_UP_DISC_Q 0x20 #define ASC_STOP_HOST_REQ_RISC_HALT 0x40 #define ASC_STOP_SEND_INT_TO_HOST 0x80 #define ASC_TIDLUN_TO_IX( tid, lun ) ( ASC_SCSI_TIX_TYPE )( (tid) + ((lun)<> ASC_SCSI_ID_BITS ) & ASC_MAX_LUN ) #define ASC_QNO_TO_QADDR( q_no ) ( (ASC_QADR_BEG)+( ( int )(q_no) << 6 ) ) typedef struct asc_scisq_1 { uchar status; uchar q_no; uchar cntl; uchar sg_queue_cnt; uchar target_id; uchar target_lun; ulong data_addr; ulong data_cnt; ulong sense_addr; uchar sense_len; uchar user_def; } ASC_SCSIQ_1; typedef struct asc_scisq_2 { ulong srb_ptr; uchar target_ix; uchar flag; uchar cdb_len; uchar tag_code; ushort vm_id; } ASC_SCSIQ_2; typedef struct asc_scsiq_3 { uchar done_stat; uchar host_stat; uchar scsi_stat; uchar scsi_msg; } ASC_SCSIQ_3; typedef struct asc_scsiq_4 { uchar cdb[ASC_MAX_CDB_LEN]; uchar y_first_sg_list_qp; uchar y_working_sg_qp; uchar y_working_sg_ix; uchar y_cntl; ushort x_req_count; ushort x_reconnect_rtn; ulong x_saved_data_addr; ulong x_saved_data_cnt; } ASC_SCSIQ_4; typedef struct asc_q_done_info { ASC_SCSIQ_2 d2; ASC_SCSIQ_3 d3; uchar q_status; uchar q_no; uchar cntl; uchar sense_len; uchar user_def; uchar res; ulong remain_bytes; } ASC_QDONE_INFO; typedef struct asc_sg_list { ulong addr; ulong bytes; } ASC_SG_LIST; typedef struct asc_sg_head { uchar entry_cnt; uchar queue_cnt; uchar entry_to_copy; uchar res; ASC_SG_LIST sg_list[ASC_MAX_SG_LIST]; } ASC_SG_HEAD; #define ASC_MIN_SG_LIST 2 typedef struct asc_min_sg_head { uchar entry_cnt; uchar queue_cnt; uchar entry_to_copy; uchar res; ASC_SG_LIST sg_list[ASC_MIN_SG_LIST]; } ASC_MIN_SG_HEAD; #define QCX_SORT (0x0001) #define QCX_COALEASE (0x0002) #if CC_LINK_BUSY_Q typedef struct asc_ext_scsi_q { ulong lba; ushort lba_len; struct asc_scsi_q dosfar *next; struct asc_scsi_q dosfar *join; ushort cntl; ushort buffer_id; uchar q_required; uchar res; } ASC_EXT_SCSI_Q; #endif typedef struct asc_scsi_q { ASC_SCSIQ_1 q1; ASC_SCSIQ_2 q2; uchar dosfar *cdbptr; ASC_SG_HEAD dosfar *sg_head; #if CC_LINK_BUSY_Q ASC_EXT_SCSI_Q ext; #endif } ASC_SCSI_Q; typedef struct asc_scsi_req_q { ASC_SCSIQ_1 r1; ASC_SCSIQ_2 r2; uchar dosfar *cdbptr; ASC_SG_HEAD dosfar *sg_head; #if CC_LINK_BUSY_Q ASC_EXT_SCSI_Q ext; #endif uchar dosfar *sense_ptr; ASC_SCSIQ_3 r3; uchar cdb[ASC_MAX_CDB_LEN]; uchar sense[ASC_MIN_SENSE_LEN]; } ASC_SCSI_REQ_Q; typedef struct asc_risc_q { uchar fwd; uchar bwd; ASC_SCSIQ_1 i1; ASC_SCSIQ_2 i2; ASC_SCSIQ_3 i3; ASC_SCSIQ_4 i4; } ASC_RISC_Q; typedef struct asc_sg_list_q { uchar seq_no; uchar q_no; uchar cntl; uchar sg_head_qp; uchar sg_list_cnt; uchar sg_cur_list_cnt; } ASC_SG_LIST_Q; typedef struct asc_risc_sg_list_q { uchar fwd; uchar bwd; ASC_SG_LIST_Q sg; ASC_SG_LIST sg_list[7]; } ASC_RISC_SG_LIST_Q; #define ASC_EXE_SCSI_IO_MAX_IDLE_LOOP 0x1000000UL #define ASC_EXE_SCSI_IO_MAX_WAIT_LOOP 1024 #define ASCQ_ERR_NO_ERROR 0 #define ASCQ_ERR_IO_NOT_FOUND 1 #define ASCQ_ERR_LOCAL_MEM 2 #define ASCQ_ERR_CHKSUM 3 #define ASCQ_ERR_START_CHIP 4 #define ASCQ_ERR_INT_TARGET_ID 5 #define ASCQ_ERR_INT_LOCAL_MEM 6 #define ASCQ_ERR_HALT_RISC 7 #define ASCQ_ERR_GET_ASPI_ENTRY 8 #define ASCQ_ERR_CLOSE_ASPI 9 #define ASCQ_ERR_HOST_INQUIRY 0x0A #define ASCQ_ERR_SAVED_SRB_BAD 0x0B #define ASCQ_ERR_QCNTL_SG_LIST 0x0C #define ASCQ_ERR_Q_STATUS 0x0D #define ASCQ_ERR_WR_SCSIQ 0x0E #define ASCQ_ERR_PC_ADDR 0x0F #define ASCQ_ERR_SYN_OFFSET 0x10 #define ASCQ_ERR_SYN_XFER_TIME 0x11 #define ASCQ_ERR_LOCK_DMA 0x12 #define ASCQ_ERR_UNLOCK_DMA 0x13 #define ASCQ_ERR_VDS_CHK_INSTALL 0x14 #define ASCQ_ERR_MICRO_CODE_HALT 0x15 #define ASCQ_ERR_SET_LRAM_ADDR 0x16 #define ASCQ_ERR_CUR_QNG 0x17 #define ASCQ_ERR_SG_Q_LINKS 0x18 #define ASCQ_ERR_SCSIQ_PTR 0x19 #define ASCQ_ERR_ISR_RE_ENTRY 0x1A #define ASCQ_ERR_CRITICAL_RE_ENTRY 0x1B #define ASCQ_ERR_ISR_ON_CRITICAL 0x1C #define ASCQ_ERR_SG_LIST_ODD_ADDRESS 0x1D #define ASCQ_ERR_XFER_ADDRESS_TOO_BIG 0x1E #define ASCQ_ERR_SCSIQ_NULL_PTR 0x1F #define ASCQ_ERR_SCSIQ_BAD_NEXT_PTR 0x20 #define ASCQ_ERR_GET_NUM_OF_FREE_Q 0x21 #define ASCQ_ERR_SEND_SCSI_Q 0x22 #define ASCQ_ERR_HOST_REQ_RISC_HALT 0x23 #define ASCQ_ERR_RESET_SDTR 0x24 #define ASC_WARN_NO_ERROR 0x0000 #define ASC_WARN_IO_PORT_ROTATE 0x0001 #define ASC_WARN_EEPROM_CHKSUM 0x0002 #define ASC_WARN_IRQ_MODIFIED 0x0004 #define ASC_WARN_AUTO_CONFIG 0x0008 #define ASC_WARN_CMD_QNG_CONFLICT 0x0010 #define ASC_WARN_EEPROM_RECOVER 0x0020 #define ASC_WARN_CFG_MSW_RECOVER 0x0040 #define ASC_IERR_WRITE_EEPROM 0x0001 #define ASC_IERR_MCODE_CHKSUM 0x0002 #define ASC_IERR_SET_PC_ADDR 0x0004 #define ASC_IERR_START_STOP_CHIP 0x0008 #define ASC_IERR_IRQ_NO 0x0010 #define ASC_IERR_SET_IRQ_NO 0x0020 #define ASC_IERR_CHIP_VERSION 0x0040 #define ASC_IERR_SET_SCSI_ID 0x0080 #define ASC_IERR_GET_PHY_ADDR 0x0100 #define ASC_IERR_BAD_SIGNATURE 0x0200 #define ASC_IERR_NO_BUS_TYPE 0x0400 #define ASC_IERR_SCAM 0x0800 #define ASC_IERR_SET_SDTR 0x1000 #define ASC_IERR_RW_LRAM 0x8000 #define ASC_DEF_IRQ_NO 10 #define ASC_MAX_IRQ_NO 15 #define ASC_MIN_IRQ_NO 10 #define ASC_MIN_REMAIN_Q (0x02) #define ASC_DEF_MAX_TOTAL_QNG (0x40) #define ASC_MIN_TAG_Q_PER_DVC (0x04) #define ASC_DEF_TAG_Q_PER_DVC (0x04) #define ASC_MIN_FREE_Q ASC_MIN_REMAIN_Q #define ASC_MIN_TOTAL_QNG (( ASC_MAX_SG_QUEUE )+( ASC_MIN_FREE_Q )) #define ASC_MAX_TOTAL_QNG 240 #define ASC_MAX_PCI_INRAM_TOTAL_QNG 20 #define ASC_MAX_INRAM_TAG_QNG 16 typedef struct asc_dvc_cfg { ASC_SCSI_BIT_ID_TYPE can_tagged_qng; ASC_SCSI_BIT_ID_TYPE cmd_qng_enabled; ASC_SCSI_BIT_ID_TYPE disc_enable; uchar res; uchar chip_scsi_id:4; uchar isa_dma_speed:4; uchar isa_dma_channel; uchar chip_version; ushort pci_device_id; ushort lib_serial_no; ushort lib_version; ushort mcode_date; ushort mcode_version; uchar sdtr_data[ASC_MAX_TID + 1]; uchar max_tag_qng[ASC_MAX_TID + 1]; uchar dosfar *overrun_buf; } ASC_DVC_CFG; #define ASC_DEF_DVC_CNTL 0xFFFF #define ASC_DEF_CHIP_SCSI_ID 7 #define ASC_DEF_ISA_DMA_SPEED 4 #define ASC_INIT_STATE_NULL 0x0000 #define ASC_INIT_STATE_BEG_GET_CFG 0x0001 #define ASC_INIT_STATE_END_GET_CFG 0x0002 #define ASC_INIT_STATE_BEG_SET_CFG 0x0004 #define ASC_INIT_STATE_END_SET_CFG 0x0008 #define ASC_INIT_STATE_BEG_LOAD_MC 0x0010 #define ASC_INIT_STATE_END_LOAD_MC 0x0020 #define ASC_INIT_STATE_BEG_INQUIRY 0x0040 #define ASC_INIT_STATE_END_INQUIRY 0x0080 #define ASC_INIT_RESET_SCSI_DONE 0x0100 #define ASC_PCI_DEVICE_ID_REV_A 0x1100 #define ASC_PCI_DEVICE_ID_REV_B 0x1200 #define ASC_BUG_FIX_ADD_ONE_BYTE 0x0001 #define ASYN_SDTR_DATA_FIX_PCI_REV_AB 0x41 #define ASC_MIN_TAGGED_CMD 7 typedef struct asc_dvc_var { PortAddr iop_base; ushort err_code; ushort dvc_cntl; ushort bug_fix_cntl; ushort bus_type; Ptr2Func isr_callback; Ptr2Func exe_callback; ASC_SCSI_BIT_ID_TYPE init_sdtr; ASC_SCSI_BIT_ID_TYPE sdtr_done; ASC_SCSI_BIT_ID_TYPE use_tagged_qng; ASC_SCSI_BIT_ID_TYPE unit_not_ready; ASC_SCSI_BIT_ID_TYPE queue_full_or_busy; ASC_SCSI_BIT_ID_TYPE start_motor; uchar scsi_reset_wait; uchar chip_no; char is_in_int; uchar max_total_qng; uchar cur_total_qng; uchar in_critical_cnt; uchar irq_no; uchar last_q_shortage; ushort init_state; uchar cur_dvc_qng[ASC_MAX_TID + 1]; uchar max_dvc_qng[ASC_MAX_TID + 1]; ASC_SCSI_Q dosfar *scsiq_busy_head[ASC_MAX_TID + 1]; ASC_SCSI_Q dosfar *scsiq_busy_tail[ASC_MAX_TID + 1]; ulong int_count; ulong req_count; ulong busy_count; ASC_DVC_CFG dosfar *cfg; Ptr2Func saved_ptr2func; ulong reserved2; ulong reserved3; ulong max_dma_count; ASC_SCSI_BIT_ID_TYPE no_scam; ASC_SCSI_BIT_ID_TYPE pci_fix_asyn_xfer; } ASC_DVC_VAR; typedef int (dosfar * ASC_ISR_CALLBACK) (ASC_DVC_VAR asc_ptr_type *, ASC_QDONE_INFO dosfar *); typedef int (dosfar * ASC_EXE_CALLBACK) (ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *); typedef struct asc_dvc_inq_info { uchar type[ASC_MAX_TID + 1][ASC_MAX_LUN + 1]; } ASC_DVC_INQ_INFO; typedef struct asc_cap_info { ulong lba; ulong blk_size; } ASC_CAP_INFO; typedef struct asc_cap_info_array { ASC_CAP_INFO cap_info[ASC_MAX_TID + 1][ASC_MAX_LUN + 1]; } ASC_CAP_INFO_ARRAY; #define ASC_IOADR_TABLE_MAX_IX 11 #define ASC_IOADR_GAP 0x10 #define ASC_SEARCH_IOP_GAP 0x10 #define ASC_MIN_IOP_ADDR ( PortAddr )0x0100 #define ASC_MAX_IOP_ADDR ( PortAddr )0x3F0 #define ASC_IOADR_1 ( PortAddr )0x0110 #define ASC_IOADR_2 ( PortAddr )0x0130 #define ASC_IOADR_3 ( PortAddr )0x0150 #define ASC_IOADR_4 ( PortAddr )0x0190 #define ASC_IOADR_5 ( PortAddr )0x0210 #define ASC_IOADR_6 ( PortAddr )0x0230 #define ASC_IOADR_7 ( PortAddr )0x0250 #define ASC_IOADR_8 ( PortAddr )0x0330 #define ASC_IOADR_DEF ASC_IOADR_8 #define ASC_SYN_XFER_NO 8 #define ASC_MAX_SDTR_PERIOD_INDEX 7 #define ASC_SYN_MAX_OFFSET 0x0F #define ASC_DEF_SDTR_OFFSET 0x0F #define ASC_DEF_SDTR_INDEX 0x00 #define SYN_XFER_NS_0 25 #define SYN_XFER_NS_1 30 #define SYN_XFER_NS_2 35 #define SYN_XFER_NS_3 40 #define SYN_XFER_NS_4 50 #define SYN_XFER_NS_5 60 #define SYN_XFER_NS_6 70 #define SYN_XFER_NS_7 85 #define ASC_SDTR_PERIOD_IX_MIN 7 #define SYN_XMSG_WLEN 3 typedef struct sdtr_xmsg { uchar msg_type; uchar msg_len; uchar msg_req; uchar xfer_period; uchar req_ack_offset; uchar res; } SDTR_XMSG; #define ASC_MCNTL_NO_SEL_TIMEOUT ( ushort )0x0001 #define ASC_MCNTL_NULL_TARGET ( ushort )0x0002 #define ASC_CNTL_INITIATOR ( ushort )0x0001 #define ASC_CNTL_BIOS_GT_1GB ( ushort )0x0002 #define ASC_CNTL_BIOS_GT_2_DISK ( ushort )0x0004 #define ASC_CNTL_BIOS_REMOVABLE ( ushort )0x0008 #define ASC_CNTL_NO_SCAM ( ushort )0x0010 #define ASC_CNTL_NO_PCI_FIX_ASYN_XFER ( ushort )0x0020 #define ASC_CNTL_INT_MULTI_Q ( ushort )0x0080 #define ASC_CNTL_NO_LUN_SUPPORT ( ushort )0x0040 #define ASC_CNTL_NO_VERIFY_COPY ( ushort )0x0100 #define ASC_CNTL_RESET_SCSI ( ushort )0x0200 #define ASC_CNTL_INIT_INQUIRY ( ushort )0x0400 #define ASC_CNTL_INIT_VERBOSE ( ushort )0x0800 #define ASC_CNTL_SCSI_PARITY ( ushort )0x1000 #define ASC_CNTL_BURST_MODE ( ushort )0x2000 #define ASC_CNTL_USE_8_IOP_BASE ( ushort )0x4000 #define ASC_EEP_DVC_CFG_BEG_VL 2 #define ASC_EEP_MAX_DVC_ADDR_VL 15 #define ASC_EEP_DVC_CFG_BEG 32 #define ASC_EEP_MAX_DVC_ADDR 45 #define ASC_EEP_DEFINED_WORDS 10 #define ASC_EEP_MAX_ADDR 63 #define ASC_EEP_RES_WORDS 0 #define ASC_EEP_MAX_RETRY 20 #define ASC_MAX_INIT_BUSY_RETRY 8 #define ASC_EEP_ISA_PNP_WSIZE 16 typedef struct asceep_config { ushort cfg_lsw; ushort cfg_msw; uchar init_sdtr; uchar disc_enable; uchar use_cmd_qng; uchar start_motor; uchar max_total_qng; uchar max_tag_qng; uchar bios_scan; uchar power_up_wait; uchar no_scam; uchar chip_scsi_id:4; uchar isa_dma_speed:4; uchar sdtr_data[ASC_MAX_TID + 1]; uchar adapter_info[6]; ushort cntl; ushort chksum; } ASCEEP_CONFIG; #define ASC_EEP_CMD_READ 0x80 #define ASC_EEP_CMD_WRITE 0x40 #define ASC_EEP_CMD_WRITE_ABLE 0x30 #define ASC_EEP_CMD_WRITE_DISABLE 0x00 #define ASC_OVERRUN_BSIZE 0x00000048UL #define ASCV_MSGOUT_BEG 0x0000 #define ASCV_MSGOUT_SDTR_PERIOD (ASCV_MSGOUT_BEG+3) #define ASCV_MSGOUT_SDTR_OFFSET (ASCV_MSGOUT_BEG+4) #define ASCV_MSGIN_BEG (ASCV_MSGOUT_BEG+8) #define ASCV_MSGIN_SDTR_PERIOD (ASCV_MSGIN_BEG+3) #define ASCV_MSGIN_SDTR_OFFSET (ASCV_MSGIN_BEG+4) #define ASCV_SDTR_DATA_BEG (ASCV_MSGIN_BEG+8) #define ASCV_SDTR_DONE_BEG (ASCV_SDTR_DATA_BEG+8) #define ASCV_MAX_DVC_QNG_BEG ( ushort )0x0020 #define ASCV_ASCDVC_ERR_CODE_W ( ushort )0x0030 #define ASCV_MCODE_CHKSUM_W ( ushort )0x0032 #define ASCV_MCODE_SIZE_W ( ushort )0x0034 #define ASCV_STOP_CODE_B ( ushort )0x0036 #define ASCV_DVC_ERR_CODE_B ( ushort )0x0037 #define ASCV_OVERRUN_PADDR_D ( ushort )0x0038 #define ASCV_OVERRUN_BSIZE_D ( ushort )0x003C #define ASCV_HALTCODE_W ( ushort )0x0040 #define ASCV_CHKSUM_W ( ushort )0x0042 #define ASCV_MC_DATE_W ( ushort )0x0044 #define ASCV_MC_VER_W ( ushort )0x0046 #define ASCV_NEXTRDY_B ( ushort )0x0048 #define ASCV_DONENEXT_B ( ushort )0x0049 #define ASCV_USE_TAGGED_QNG_B ( ushort )0x004A #define ASCV_SCSIBUSY_B ( ushort )0x004B #define ASCV_CDBCNT_B ( ushort )0x004C #define ASCV_CURCDB_B ( ushort )0x004D #define ASCV_RCLUN_B ( ushort )0x004E #define ASCV_BUSY_QHEAD_B ( ushort )0x004F #define ASCV_DISC1_QHEAD_B ( ushort )0x0050 #define ASCV_DISC_ENABLE_B ( ushort )0x0052 #define ASCV_CAN_TAGGED_QNG_B ( ushort )0x0053 #define ASCV_HOSTSCSI_ID_B ( ushort )0x0055 #define ASCV_MCODE_CNTL_B ( ushort )0x0056 #define ASCV_NULL_TARGET_B ( ushort )0x0057 #define ASCV_FREE_Q_HEAD_W ( ushort )0x0058 #define ASCV_DONE_Q_TAIL_W ( ushort )0x005A #define ASCV_FREE_Q_HEAD_B ( ushort )(ASCV_FREE_Q_HEAD_W+1) #define ASCV_DONE_Q_TAIL_B ( ushort )(ASCV_DONE_Q_TAIL_W+1) #define ASCV_HOST_FLAG_B ( ushort )0x005D #define ASCV_TOTAL_READY_Q_B ( ushort )0x0064 #define ASCV_VER_SERIAL_B ( ushort )0x0065 #define ASCV_HALTCODE_SAVED_W ( ushort )0x0066 #define ASCV_WTM_FLAG_B ( ushort )0x0068 #define ASCV_RISC_FLAG_B ( ushort )0x006A #define ASCV_REQ_SG_LIST_QP ( ushort )0x006B #define ASC_HOST_FLAG_IN_ISR 0x01 #define ASC_HOST_FLAG_ACK_INT 0x02 #define ASC_RISC_FLAG_GEN_INT 0x01 #define ASC_RISC_FLAG_REQ_SG_LIST 0x02 #define IOP_CTRL (0x0F) #define IOP_STATUS (0x0E) #define IOP_INT_ACK IOP_STATUS #define IOP_REG_IFC (0x0D) #define IOP_SYN_OFFSET (0x0B) #define IOP_REG_PC (0x0C) #define IOP_RAM_ADDR (0x0A) #define IOP_RAM_DATA (0x08) #define IOP_EEP_DATA (0x06) #define IOP_EEP_CMD (0x07) #define IOP_VERSION (0x03) #define IOP_CONFIG_HIGH (0x04) #define IOP_CONFIG_LOW (0x02) #define IOP_ASPI_ID_LOW (0x01) #define IOP_ASPI_ID_HIGH (0x00) #define IOP_REG_DC1 (0x0E) #define IOP_REG_DC0 (0x0C) #define IOP_REG_SB (0x0B) #define IOP_REG_DA1 (0x0A) #define IOP_REG_DA0 (0x08) #define IOP_REG_SC (0x09) #define IOP_DMA_SPEED (0x07) #define IOP_REG_FLAG (0x07) #define IOP_FIFO_H (0x06) #define IOP_FIFO_L (0x04) #define IOP_REG_ID (0x05) #define IOP_REG_QP (0x03) #define IOP_REG_IH (0x02) #define IOP_REG_IX (0x01) #define IOP_REG_AX (0x00) #define IFC_REG_LOCK (0x00) #define IFC_REG_UNLOCK (0x09) #define IFC_WR_EN_FILTER (0x10) #define IFC_RD_NO_EEPROM (0x10) #define IFC_SLEW_RATE (0x20) #define IFC_ACT_NEG (0x40) #define IFC_INP_FILTER (0x80) #define IFC_INIT_DEFAULT ( IFC_ACT_NEG | IFC_REG_UNLOCK ) #define SC_SEL (0x80) #define SC_BSY (0x40) #define SC_ACK (0x20) #define SC_REQ (0x10) #define SC_ATN (0x08) #define SC_IO (0x04) #define SC_CD (0x02) #define SC_MSG (0x01) #define AscGetVarFreeQHead( port ) AscReadLramWord( port, ASCV_FREE_Q_HEAD_W ) #define AscGetVarDoneQTail( port ) AscReadLramWord( port, ASCV_DONE_Q_TAIL_W ) #define AscPutVarFreeQHead( port, val ) AscWriteLramWord( port, ASCV_FREE_Q_HEAD_W, val ) #define AscPutVarDoneQTail( port, val ) AscWriteLramWord( port, ASCV_DONE_Q_TAIL_W, val ) #define AscGetRiscVarFreeQHead( port ) AscReadLramByte( port, ASCV_NEXTRDY_B ) #define AscGetRiscVarDoneQTail( port ) AscReadLramByte( port, ASCV_DONENEXT_B ) #define AscPutRiscVarFreeQHead( port, val ) AscWriteLramByte( port, ASCV_NEXTRDY_B, val ) #define AscPutRiscVarDoneQTail( port, val ) AscWriteLramByte( port, ASCV_DONENEXT_B, val ) #define AscGetChipIFC( port ) inp( (port)+IOP_REG_IFC ) #define AscPutChipIFC( port, data ) outp( (port)+IOP_REG_IFC, data ) #define AscGetChipLramAddr( port ) ( ushort )inpw( ( PortAddr )((port)+IOP_RAM_ADDR) ) #define AscSetChipLramAddr( port, addr ) outpw( ( PortAddr )( (port)+IOP_RAM_ADDR ), addr ) #define AscPutChipLramData( port, data ) outpw( (port)+IOP_RAM_DATA, data ) #define AscGetChipLramData( port ) inpw( (port)+IOP_RAM_DATA ) #define AscWriteChipSyn( port, data ) outp( (port)+IOP_SYN_OFFSET, data ) #define AscReadChipSyn( port ) inp( (port)+IOP_SYN_OFFSET ) #define AscWriteChipIH( port, data ) outpw( (port)+IOP_REG_IH, data ) #define AscReadChipIH( port ) inpw( (port)+IOP_REG_IH ) #define AscWriteChipScsiID( port, data ) outp( (port)+IOP_REG_ID, data ) #define AscReadChipScsiID( port ) inp( (port)+IOP_REG_ID ) #define AscGetChipDmaSpeed( port ) ( uchar )inp( (port)+IOP_DMA_SPEED ) #define AscSetChipDmaSpeed( port, data ) outp( (port)+IOP_DMA_SPEED, data ) #define AscGetChipQP( port ) ( uchar )inp( (port)+IOP_REG_QP ) #define AscSetPCAddr( port, data ) outpw( (port)+IOP_REG_PC, data ) #define AscGetPCAddr( port ) inpw( (port)+IOP_REG_PC ) #define AscGetChipVerNo( port ) ( uchar )inp( (port)+IOP_VERSION ) #define AscGetChipEEPCmd( port ) ( uchar )inp( (port)+IOP_EEP_CMD ) #define AscSetChipEEPCmd( port, data ) outp( (port)+IOP_EEP_CMD, data ) #define AscGetChipEEPData( port ) inpw( (port)+IOP_EEP_DATA ) #define AscSetChipEEPData( port, data ) outpw( (port)+IOP_EEP_DATA, data ) #define AscGetChipControl( port ) ( uchar )inp( (port)+IOP_CTRL ) #define AscSetChipControl( port, cc_val ) outp( (port)+IOP_CTRL, cc_val ) #define AscGetChipStatus( port ) ( ASC_CS_TYPE )inpw( (port)+IOP_STATUS ) #define AscSetChipStatus( port, cs_val ) outpw( (port)+IOP_STATUS, cs_val ) #define AscGetChipCfgLsw( port ) ( ushort )inpw( (port)+IOP_CONFIG_LOW ) #define AscGetChipCfgMsw( port ) ( ushort )inpw( (port)+IOP_CONFIG_HIGH ) #define AscSetChipCfgLsw( port, data ) outpw( (port)+IOP_CONFIG_LOW, data ) #define AscSetChipCfgMsw( port, data ) outpw( (port)+IOP_CONFIG_HIGH, data ) #define AscIsIntPending( port ) ( AscGetChipStatus( port ) & CSW_INT_PENDING ) #define AscGetChipScsiID( port ) ( ( AscGetChipCfgLsw( port ) >> 8 ) & ASC_MAX_TID ) #define ASC_HALT_EXTMSG_IN ( ushort )0x8000 #define ASC_HALT_CHK_CONDITION ( ushort )0x8100 #define ASC_HALT_SS_QUEUE_FULL ( ushort )0x8200 #define ASC_HALT_SDTR_REJECTED ( ushort )0x4000 #define ASC_MAX_QNO 0xF8 #define ASC_DATA_SEC_BEG ( ushort )0x0080 #define ASC_DATA_SEC_END ( ushort )0x0080 #define ASC_CODE_SEC_BEG ( ushort )0x0080 #define ASC_CODE_SEC_END ( ushort )0x0080 #define ASC_QADR_BEG (0x4000) #define ASC_QADR_USED ( ushort )( ASC_MAX_QNO * 64 ) #define ASC_QADR_END ( ushort )0x7FFF #define ASC_QLAST_ADR ( ushort )0x7FC0 #define ASC_QBLK_SIZE 0x40 #define ASC_BIOS_DATA_QBEG 0xF8 #define ASC_MIN_ACTIVE_QNO 0x01 #define ASC_QLINK_END 0xFF #define ASC_EEPROM_WORDS 0x10 #define ASC_MAX_MGS_LEN 0x10 #define ASC_BIOS_ADDR_DEF 0xDC00 #define ASC_BIOS_SIZE 0x3800 #define ASC_BIOS_RAM_OFF 0x3800 #define ASC_BIOS_RAM_SIZE 0x800 #define ASC_BIOS_MIN_ADDR 0xC000 #define ASC_BIOS_MAX_ADDR 0xEC00 #define ASC_BIOS_BANK_SIZE 0x0400 #define ASC_MCODE_START_ADDR 0x0080 #define ASC_CFG0_HOST_INT_ON 0x0020 #define ASC_CFG0_BIOS_ON 0x0040 #define ASC_CFG0_VERA_BURST_ON 0x0080 #define ASC_CFG0_SCSI_PARITY_ON 0x0800 #define ASC_CFG1_SCSI_TARGET_ON 0x0080 #define ASC_CFG1_LRAM_8BITS_ON 0x0800 #define ASC_CFG_MSW_CLR_MASK 0xF0C0 #define CSW_TEST1 ( ASC_CS_TYPE )0x8000 #define CSW_AUTO_CONFIG ( ASC_CS_TYPE )0x4000 #define CSW_RESERVED1 ( ASC_CS_TYPE )0x2000 #define CSW_IRQ_WRITTEN ( ASC_CS_TYPE )0x1000 #define CSW_33MHZ_SELECTED ( ASC_CS_TYPE )0x0800 #define CSW_TEST2 ( ASC_CS_TYPE )0x0400 #define CSW_TEST3 ( ASC_CS_TYPE )0x0200 #define CSW_RESERVED2 ( ASC_CS_TYPE )0x0100 #define CSW_DMA_DONE ( ASC_CS_TYPE )0x0080 #define CSW_FIFO_RDY ( ASC_CS_TYPE )0x0040 #define CSW_EEP_READ_DONE ( ASC_CS_TYPE )0x0020 #define CSW_HALTED ( ASC_CS_TYPE )0x0010 #define CSW_SCSI_RESET_ACTIVE ( ASC_CS_TYPE )0x0008 #define CSW_PARITY_ERR ( ASC_CS_TYPE )0x0004 #define CSW_SCSI_RESET_LATCH ( ASC_CS_TYPE )0x0002 #define CSW_INT_PENDING ( ASC_CS_TYPE )0x0001 #define CIW_INT_ACK ( ASC_CS_TYPE )0x0100 #define CIW_TEST1 ( ASC_CS_TYPE )0x0200 #define CIW_TEST2 ( ASC_CS_TYPE )0x0400 #define CIW_SEL_33MHZ ( ASC_CS_TYPE )0x0800 #define CIW_IRQ_ACT ( ASC_CS_TYPE )0x1000 #define CC_CHIP_RESET ( uchar )0x80 #define CC_SCSI_RESET ( uchar )0x40 #define CC_HALT ( uchar )0x20 #define CC_SINGLE_STEP ( uchar )0x10 #define CC_DMA_ABLE ( uchar )0x08 #define CC_TEST ( uchar )0x04 #define CC_BANK_ONE ( uchar )0x02 #define CC_DIAG ( uchar )0x01 #define ASC_1000_ID0W 0x04C1 #define ASC_1000_ID0W_FIX 0x00C1 #define ASC_1000_ID1B 0x25 #define ASC_EISA_BIG_IOP_GAP (0x1C30-0x0C50) #define ASC_EISA_SMALL_IOP_GAP (0x0020) #define ASC_EISA_MIN_IOP_ADDR (0x0C30) #define ASC_EISA_MAX_IOP_ADDR (0xFC50) #define ASC_EISA_REV_IOP_MASK (0x0C83) #define ASC_EISA_PID_IOP_MASK (0x0C80) #define ASC_EISA_CFG_IOP_MASK (0x0C86) #define ASC_GET_EISA_SLOT( iop ) ( PortAddr )( (iop) & 0xF000 ) #define ASC_EISA_ID_740 0x01745004UL #define ASC_EISA_ID_750 0x01755004UL #define INS_HALTINT ( ushort )0x6281 #define INS_HALT ( ushort )0x6280 #define INS_SINT ( ushort )0x6200 #define INS_RFLAG_WTM ( ushort )0x7380 #define ASC_MC_SAVE_CODE_WSIZE 0x500 #define ASC_MC_SAVE_DATA_WSIZE 0x40 typedef struct asc_mc_saved { ushort data[ASC_MC_SAVE_DATA_WSIZE]; ushort code[ASC_MC_SAVE_CODE_WSIZE]; } ASC_MC_SAVED; int AscWriteEEPCmdReg(PortAddr iop_base, uchar cmd_reg); int AscWriteEEPDataReg(PortAddr iop_base, ushort data_reg); void AscWaitEEPRead(void); void AscWaitEEPWrite(void); ushort AscReadEEPWord(PortAddr, uchar); ushort AscWriteEEPWord(PortAddr, uchar, ushort); ushort AscGetEEPConfig(PortAddr, ASCEEP_CONFIG dosfar *, ushort); int AscSetEEPConfigOnce(PortAddr, ASCEEP_CONFIG dosfar *, ushort); int AscSetEEPConfig(PortAddr, ASCEEP_CONFIG dosfar *, ushort); ushort AscEEPSum(PortAddr, uchar, uchar); int AscStartChip(PortAddr); int AscStopChip(PortAddr); void AscSetChipIH(PortAddr, ushort); int AscSetRunChipSynRegAtID(PortAddr, uchar, uchar); int AscIsChipHalted(PortAddr); void AscSetChipCfgDword(PortAddr, ulong); ulong AscGetChipCfgDword(PortAddr); void AscAckInterrupt(PortAddr); void AscDisableInterrupt(PortAddr); void AscEnableInterrupt(PortAddr); void AscSetBank(PortAddr, uchar); uchar AscGetBank(PortAddr); int AscResetChipAndScsiBus(PortAddr); ushort AscGetIsaDmaChannel(PortAddr); ushort AscSetIsaDmaChannel(PortAddr, ushort); uchar AscSetIsaDmaSpeed(PortAddr, uchar); uchar AscGetIsaDmaSpeed(PortAddr); uchar AscReadLramByte(PortAddr, ushort); ushort AscReadLramWord(PortAddr, ushort); ulong AscReadLramDWord(PortAddr, ushort); void AscWriteLramWord(PortAddr, ushort, ushort); void AscWriteLramDWord(PortAddr, ushort, ulong); void AscWriteLramByte(PortAddr, ushort, uchar); int AscVerWriteLramDWord(PortAddr, ushort, ulong); int AscVerWriteLramWord(PortAddr, ushort, ushort); int AscVerWriteLramByte(PortAddr, ushort, uchar); ulong AscMemSumLramWord(PortAddr, ushort, int); void AscMemWordSetLram(PortAddr, ushort, ushort, int); void AscMemWordCopyToLram(PortAddr, ushort, ushort dosfar *, int); void AscMemDWordCopyToLram(PortAddr, ushort, ulong dosfar *, int); void AscMemWordCopyFromLram(PortAddr, ushort, ushort dosfar *, int); int AscMemWordCmpToLram(PortAddr, ushort, ushort dosfar *, int); ushort AscInitAscDvcVar(ASC_DVC_VAR asc_ptr_type *); ulong AscLoadMicroCode(PortAddr, ushort, ushort dosfar *, ushort); ushort AscInitFromEEP(ASC_DVC_VAR asc_ptr_type *); ushort AscInitFromAscDvcVar(ASC_DVC_VAR asc_ptr_type *); ushort AscInitMicroCodeVar(ASC_DVC_VAR asc_ptr_type * asc_dvc); void dosfar AscInitPollIsrCallBack(ASC_DVC_VAR asc_ptr_type *, ASC_QDONE_INFO dosfar *); int AscTestExternalLram(ASC_DVC_VAR asc_ptr_type *); ushort AscTestLramEndian(PortAddr); uchar AscMsgOutSDTR(PortAddr, uchar, uchar); uchar AscCalSDTRData(uchar, uchar); void AscSetChipSDTR(PortAddr, uchar, uchar); int AscInitChipAllSynReg(ASC_DVC_VAR asc_ptr_type *, uchar); uchar AscGetSynPeriodIndex(uchar); uchar AscSynIndexToPeriod(uchar); uchar AscAllocFreeQueue(PortAddr, uchar); uchar AscAllocMultipleFreeQueue(PortAddr, uchar, uchar); int AscRiscHaltedAbortSRB(ASC_DVC_VAR asc_ptr_type *, ulong); int AscRiscHaltedAbortTIX(ASC_DVC_VAR asc_ptr_type *, uchar); int AscRiscHaltedAbortALL(ASC_DVC_VAR asc_ptr_type *); int AscHostReqRiscHalt(PortAddr); int AscStopQueueExe(PortAddr); int AscStartQueueExe(PortAddr); int AscCleanUpDiscQueue(PortAddr); int AscCleanUpBusyQueue(PortAddr); int _AscAbortTidBusyQueue(ASC_DVC_VAR asc_ptr_type *, ASC_QDONE_INFO dosfar *, uchar); int _AscAbortSrbBusyQueue(ASC_DVC_VAR asc_ptr_type *, ASC_QDONE_INFO dosfar *, ulong); int AscWaitTixISRDone(ASC_DVC_VAR asc_ptr_type *, uchar); int AscWaitISRDone(ASC_DVC_VAR asc_ptr_type *); ulong AscGetOnePhyAddr(ASC_DVC_VAR asc_ptr_type *, uchar dosfar *, ulong); int AscSendScsiQueue(ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_Q dosfar * scsiq, uchar n_q_required); int AscPutReadyQueue(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *, uchar); int AscPutReadySgListQueue(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *, uchar); int AscAbortScsiIO(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *); void AscExeScsiIO(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *); int AscSetChipSynRegAtID(PortAddr, uchar, uchar); int AscSetRunChipSynRegAtID(PortAddr, uchar, uchar); ushort AscInitLram(ASC_DVC_VAR asc_ptr_type *); int AscReInitLram(ASC_DVC_VAR asc_ptr_type *); ushort AscInitQLinkVar(ASC_DVC_VAR asc_ptr_type *); int AscSetLibErrorCode(ASC_DVC_VAR asc_ptr_type *, ushort); int _AscWaitQDone(PortAddr, ASC_SCSI_Q dosfar *); int AscEnterCritical(void); void AscLeaveCritical(int); int AscIsrChipHalted(ASC_DVC_VAR asc_ptr_type *); uchar _AscCopyLramScsiDoneQ(PortAddr, ushort, ASC_QDONE_INFO dosfar *, ulong); int AscIsrQDone(ASC_DVC_VAR asc_ptr_type *); ushort AscIsrExeBusyQueue(ASC_DVC_VAR asc_ptr_type *, uchar); int AscScsiSetupCmdQ(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, uchar dosfar *, ulong); int AscScsiInquiry(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, uchar dosfar *, int); int AscScsiTestUnitReady(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *); int AscScsiStartStopUnit(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, uchar); int AscScsiReadCapacity(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, uchar dosfar *); ulong dosfar *swapfarbuf4(uchar dosfar *); int PollQueueDone(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, int); int PollScsiReadCapacity(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, ASC_CAP_INFO dosfar *); int PollScsiInquiry(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, uchar dosfar *, int); int PollScsiTestUnitReady(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *); int PollScsiStartUnit(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *); int InitTestUnitReady(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *); void AscDispInquiry(uchar, uchar, ASC_SCSI_INQUIRY dosfar *); int AscPollQDone(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, int); int AscSetBIOSBank(PortAddr, int, ushort); int AscSetVlBIOSBank(PortAddr, int); int AscSetEisaBIOSBank(PortAddr, int); int AscSetIsaBIOSBank(PortAddr, int); int AscIsBiosEnabled(PortAddr, ushort); void AscResetScsiBus(PortAddr); void AscClrResetScsiBus(PortAddr); void AscSingleStepChip(PortAddr); uchar AscSetChipScsiID(PortAddr, uchar); ushort AscGetChipBiosAddress(PortAddr, ushort); ushort AscSetChipBiosAddress(PortAddr, ushort, ushort); uchar AscGetChipVersion(PortAddr, ushort); ushort AscGetChipBusType(PortAddr); PortAddr AscSearchIOPortAddr11(PortAddr); PortAddr AscSearchIOPortAddr100(PortAddr); int AscFindSignature(PortAddr); void AscToggleIRQAct(PortAddr); int AscResetChip(PortAddr); void AscClrResetChip(PortAddr); short itos(ushort, uchar dosfar *, short, short); int insnchar(uchar dosfar *, short, short, ruchar, short); void itoh(ushort, ruchar dosfar *); void btoh(uchar, ruchar dosfar *); void ltoh(ulong, ruchar dosfar *); uchar dosfar *todstr(ushort, uchar dosfar *); uchar dosfar *tohstr(ushort, uchar dosfar *); uchar dosfar *tobhstr(uchar, uchar dosfar *); uchar dosfar *tolhstr(ulong, uchar dosfar *); void AscSetISAPNPWaitForKey(void); uchar AscGetChipIRQ(PortAddr, ushort); uchar AscSetChipIRQ(PortAddr, uchar, ushort); uchar AscGetChipScsiCtrl(PortAddr); ushort AscGetEisaChipCfg(PortAddr); ushort AscGetEisaChipGpReg(PortAddr); ushort AscSetEisaChipCfg(PortAddr, ushort); ushort AscSetEisaChipGpReg(PortAddr, ushort); ulong AscGetEisaProductID(PortAddr); PortAddr AscSearchIOPortAddrEISA(PortAddr); int AscPollQTailSync(PortAddr); int AscPollQHeadSync(PortAddr); int AscWaitQTailSync(PortAddr); int _AscRestoreMicroCode(PortAddr, ASC_MC_SAVED dosfar *); int AscSCAM(ASC_DVC_VAR asc_ptr_type *); ushort SwapByteOfWord(ushort word_val); ulong SwapWordOfDWord(ulong dword_val); ulong AdjEndianDword(ulong dword_val); int AscAdjEndianScsiQ(ASC_SCSI_Q dosfar *); int AscAdjEndianQDoneInfo(ASC_QDONE_INFO dosfar *); extern int DvcEnterCritical(void); extern void DvcLeaveCritical(int); extern void DvcInPortWords(PortAddr, ushort dosfar *, int); extern void DvcOutPortWords(PortAddr, ushort dosfar *, int); extern void DvcOutPortDWords(PortAddr, ulong dosfar *, int); extern void DvcSleepMilliSecond(ulong); extern void DvcDisplayString(uchar dosfar *); extern ulong DvcGetPhyAddr(uchar dosfar * buf_addr, ulong buf_len); extern ulong DvcGetSGList(ASC_DVC_VAR asc_ptr_type *, uchar dosfar *, ulong, ASC_SG_HEAD dosfar *); extern void DvcSCAMDelayMS(ulong); extern int DvcDisableCPUInterrupt(void); extern void DvcRestoreCPUInterrupt(int); void DvcPutScsiQ(PortAddr, ushort, ushort dosfar *, int); void DvcGetQinfo(PortAddr, ushort, ushort dosfar *, int); PortAddr AscSearchIOPortAddr(PortAddr, ushort); ushort AscInitGetConfig(ASC_DVC_VAR asc_ptr_type *); ushort AscInitSetConfig(ASC_DVC_VAR asc_ptr_type *); ushort AscInitAsc1000Driver(ASC_DVC_VAR asc_ptr_type *); int AscInitScsiTarget(ASC_DVC_VAR asc_ptr_type *, ASC_DVC_INQ_INFO dosfar *, uchar dosfar *, ASC_CAP_INFO_ARRAY dosfar *, ushort); int AscInitPollBegin(ASC_DVC_VAR asc_ptr_type *); int AscInitPollEnd(ASC_DVC_VAR asc_ptr_type *); int AscInitPollTarget(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_REQ_Q dosfar *, ASC_SCSI_INQUIRY dosfar *, ASC_CAP_INFO dosfar *); int AscExeScsiQueue(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_Q dosfar *); int AscISR(ASC_DVC_VAR asc_ptr_type *); void AscISR_AckInterrupt(ASC_DVC_VAR asc_ptr_type *); int AscISR_CheckQDone(ASC_DVC_VAR asc_ptr_type *, ASC_QDONE_INFO dosfar *, uchar dosfar *); int AscStartUnit(ASC_DVC_VAR asc_ptr_type *, ASC_SCSI_TIX_TYPE); int AscStopUnit( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_TIX_TYPE target_ix ); uint AscGetNumOfFreeQueue(ASC_DVC_VAR asc_ptr_type *, uchar, uchar); int AscSgListToQueue(int); int AscQueueToSgList(int); int AscSetDvcErrorCode(ASC_DVC_VAR asc_ptr_type *, uchar); int AscAbortSRB(ASC_DVC_VAR asc_ptr_type *, ulong); int AscResetDevice(ASC_DVC_VAR asc_ptr_type *, uchar); int AscResetSB(ASC_DVC_VAR asc_ptr_type *); void AscEnableIsaDma(uchar); void AscDisableIsaDma(uchar); ulong AscGetMaxDmaAddress(ushort); ulong AscGetMaxDmaCount(ushort); int AscSaveMicroCode(ASC_DVC_VAR asc_ptr_type *, ASC_MC_SAVED dosfar *); int AscRestoreOldMicroCode(ASC_DVC_VAR asc_ptr_type *, ASC_MC_SAVED dosfar *); int AscRestoreNewMicroCode(ASC_DVC_VAR asc_ptr_type *, ASC_MC_SAVED dosfar *); /* * --- Debugging Header */ #ifdef ADVANSYS_DEBUG #define STATIC #else /* ADVANSYS_DEBUG */ #define STATIC static #endif /* ADVANSYS_DEBUG */ /* * --- Driver Constants and Macros */ #define ASC_NUM_BOARD_SUPPORTED 4 #define ASC_NUM_BUS 4 /* Reference Scsi_Host hostdata */ #define ASC_BOARD(host) ((struct asc_board *) &(host)->hostdata) #define NO_ISA_DMA 0xff /* No ISA DMA Channel Used */ #ifndef min #define min(a, b) (((a) < (b)) ? (a) : (b)) #endif /* min */ /* Asc Library return codes */ #define ASC_TRUE 1 #define ASC_FALSE 0 #define ASC_NOERROR 1 #define ASC_BUSY 0 #define ASC_ERROR (-1) /* Scsi_Cmnd function return codes */ #define STATUS_BYTE(byte) (byte) #define MSG_BYTE(byte) ((byte) << 8) #define HOST_BYTE(byte) ((byte) << 16) #define DRIVER_BYTE(byte) ((byte) << 24) /* asc_enqueue() flags */ #define ASC_FRONT 1 #define ASC_BACK 2 /* PCI configuration declarations */ #define ASC_PCI_REV_A_INIT 0x01 #define ASC_PCI_REV_A_DONE 0x02 #define ASC_PCI_REV_B_INIT 0x04 #define ASC_PCI_REV_B_DONE 0x08 #define PCI_BASE_CLASS_PREDEFINED 0x00 #define PCI_BASE_CLASS_MASS_STORAGE 0x01 #define PCI_BASE_CLASS_NETWORK 0x02 #define PCI_BASE_CLASS_DISPLAY 0x03 #define PCI_BASE_CLASS_MULTIMEDIA 0x04 #define PCI_BASE_CLASS_MEMORY_CONTROLLER 0x05 #define PCI_BASE_CLASS_BRIDGE_DEVICE 0x06 /* MASS STORAGE */ #define PCI_SUB_CLASS_SCSI_CONTROLLER 0x00 #define PCI_SUB_CLASS_IDE_CONTROLLER 0x01 #define PCI_SUB_CLASS_FLOPPY_DISK_CONTROLLER 0x02 #define PCI_SUB_CLASS_IPI_BUS_CONTROLLER 0x03 #define PCI_SUB_CLASS_OTHER_MASS_CONTROLLER 0x80 /* NETWORK CONTROLLER */ #define PCI_SUB_CLASS_ETHERNET_CONTROLLER 0x00 #define PCI_SUB_CLASS_TOKEN_RING_CONTROLLER 0x01 #define PCI_SUB_CLASS_FDDI_CONTROLLER 0x02 #define PCI_SUB_CLASS_OTHER_NETWORK_CONTROLLER 0x80 /* DISPLAY CONTROLLER */ #define PCI_SUB_CLASS_VGA_CONTROLLER 0x00 #define PCI_SUB_CLASS_XGA_CONTROLLER 0x01 #define PCI_SUB_CLASS_OTHER_DISPLAY_CONTROLLER 0x80 /* MULTIMEDIA CONTROLLER */ #define PCI_SUB_CLASS_VIDEO_DEVICE 0x00 #define PCI_SUB_CLASS_AUDIO_DEVICE 0x01 #define PCI_SUB_CLASS_OTHER_MULTIMEDIA_DEVICE 0x80 /* MEMORY CONTROLLER */ #define PCI_SUB_CLASS_RAM_CONTROLLER 0x00 #define PCI_SUB_CLASS_FLASH_CONTROLLER 0x01 #define PCI_SUB_CLASS_OTHER_MEMORY_CONTROLLER 0x80 /* BRIDGE CONTROLLER */ #define PCI_SUB_CLASS_HOST_BRIDGE_CONTROLLER 0x00 #define PCI_SUB_CLASS_ISA_BRIDGE_CONTROLLER 0x01 #define PCI_SUB_CLASS_EISA_BRIDGE_CONTROLLER 0x02 #define PCI_SUB_CLASS_MC_BRIDGE_CONTROLLER 0x03 #define PCI_SUB_CLASS_PCI_TO_PCI_BRIDGE_CONTROLLER 0x04 #define PCI_SUB_CLASS_PCMCIA_BRIDGE_CONTROLLER 0x05 #define PCI_SUB_CLASS_OTHER_BRIDGE_CONTROLLER 0x80 #define PCI_MAX_SLOT 0x1F #define PCI_MAX_BUS 0xFF #define ASC_PCI_VENDORID 0x10CD #define PCI_IOADDRESS_MASK 0xFFFE /* PCI IO Port Addresses to generate special cycle */ #define PCI_CONFIG_ADDRESS_MECH1 0x0CF8 #define PCI_CONFIG_DATA_MECH1 0x0CFC #define PCI_CONFIG_FORWARD_REGISTER 0x0CFA /* 0=type 0; 1=type 1; */ #define PCI_CONFIG_BUS_NUMBER_MASK 0x00FF0000 #define PCI_CONFIG_DEVICE_FUNCTION_MASK 0x0000FF00 #define PCI_CONFIG_REGISTER_NUMBER_MASK 0x000000F8 #define PCI_DEVICE_FOUND 0x0000 #define PCI_DEVICE_NOT_FOUND 0xffff #define SUBCLASS_OFFSET 0x0A #define CLASSCODE_OFFSET 0x0B #define VENDORID_OFFSET 0x00 #define DEVICEID_OFFSET 0x02 /* * --- Driver Macros */ #ifndef ADVANSYS_STATS #define ASC_STATS(counter) #define ASC_STATS_ADD(counter, count) #else /* ADVANSYS_STATS */ #define ASC_STATS(counter) asc_stats.counter++ #define ASC_STATS_ADD(counter, count) asc_stats.counter += (count) #endif /* ADVANSYS_STATS */ #ifndef ADVANSYS_DEBUG #define ASC_DBG(lvl, s) #define ASC_DBG1(lvl, s, a1) #define ASC_DBG2(lvl, s, a1, a2) #define ASC_DBG3(lvl, s, a1, a2, a3) #define ASC_DBG4(lvl, s, a1, a2, a3, a4) #define ASC_DBG_PRT_SCSI_HOST(lvl, s) #define ASC_DBG_PRT_DVC_VAR(lvl, v) #define ASC_DBG_PRT_DVC_CFG(lvl, c) #define ASC_DBG_PRT_SCSI_Q(lvl, scsiqp) #define ASC_DBG_PRT_QDONE_INFO(lvl, qdone) #define ASC_DBG_PRT_HEX(lvl, name, start, length) #define ASC_DBG_PRT_CDB(lvl, cdb, len) #define ASC_DBG_PRT_SENSE(lvl, sense, len) #define ASC_DBG_PRT_INQUIRY(lvl, inq, len) #define ASC_ASSERT(a) #else /* ADVANSYS_DEBUG */ /* * Debugging Message Levels: * 0: Errors Only * 1: High-Level Tracing * 2-N: Verbose Tracing */ #define ASC_DBG(lvl, s) \ { \ if (asc_dbglvl >= (lvl)) { \ printk(s); \ } \ } #define ASC_DBG1(lvl, s, a1) \ { \ if (asc_dbglvl >= (lvl)) { \ printk((s), (a1)); \ } \ } #define ASC_DBG2(lvl, s, a1, a2) \ { \ if (asc_dbglvl >= (lvl)) { \ printk((s), (a1), (a2)); \ } \ } #define ASC_DBG3(lvl, s, a1, a2, a3) \ { \ if (asc_dbglvl >= (lvl)) { \ printk((s), (a1), (a2), (a3)); \ } \ } #define ASC_DBG4(lvl, s, a1, a2, a3, a4) \ { \ if (asc_dbglvl >= (lvl)) { \ printk((s), (a1), (a2), (a3), (a4)); \ } \ } #define ASC_DBG_PRT_SCSI_HOST(lvl, s) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_scsi_host(s); \ } \ } #define ASC_DBG_PRT_DVC_VAR(lvl, v) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_dvc_var(v); \ } \ } #define ASC_DBG_PRT_DVC_CFG(lvl, c) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_dvc_cfg(c); \ } \ } #define ASC_DBG_PRT_SCSI_Q(lvl, scsiqp) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_scsi_q(scsiqp); \ } \ } #define ASC_DBG_PRT_QDONE_INFO(lvl, qdone) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_qdone_info(qdone); \ } \ } #define ASC_DBG_PRT_HEX(lvl, name, start, length) \ { \ if (asc_dbglvl >= (lvl)) { \ asc_prt_hex((name), (start), (length)); \ } \ } #define ASC_DBG_PRT_CDB(lvl, cdb, len) \ ASC_DBG_PRT_HEX((lvl), "CDB", (uchar *) (cdb), (len)); #define ASC_DBG_PRT_SENSE(lvl, sense, len) \ ASC_DBG_PRT_HEX((lvl), "SENSE", (uchar *) (sense), (len)); #define ASC_DBG_PRT_INQUIRY(lvl, inq, len) \ ASC_DBG_PRT_HEX((lvl), "INQUIRY", (uchar *) (inq), (len)); #define ASC_ASSERT(a) \ { \ if (!(a)) { \ printk("ASC_ASSERT() Failure: file %s, line %d\n", \ __FILE__, __LINE__); \ } \ } #endif /* ADVANSYS_DEBUG */ /* * --- Driver Structures */ /* * Structure allocated for each board. * * This structure is allocated by scsi_register() at the end * of the 'Scsi_Host' structure starting at the 'hostdata' * field. It is guaranteed to be allocated from DMA-able memory. */ struct asc_board { /* Asc Library */ ASC_DVC_VAR board; /* Board configuration */ ASC_DVC_CFG cfg; /* Device configuration */ uchar overrun_buf[ASC_OVERRUN_BSIZE]; /* Queued Commands */ ASC_SCSI_BIT_ID_TYPE pending_tidmask; /* Pending command mask */ Scsi_Cmnd *pending[ASC_MAX_TID]; /* Target Initialization */ ASC_SCSI_BIT_ID_TYPE init_tidmask; /* Target initialized mask */ ASC_SCSI_REQ_Q scsireqq; ASC_CAP_INFO cap_info; ASC_SCSI_INQUIRY inquiry; }; /* * PCI configuration structures */ typedef struct _PCI_DATA_ { uchar type; uchar bus; uchar slot; uchar func; uchar offset; } PCI_DATA; typedef struct _PCI_DEVICE_ { ushort vendorID; ushort deviceID; ushort slotNumber; ushort slotFound; uchar busNumber; uchar maxBusNumber; uchar devFunc; ushort startSlot; ushort endSlot; uchar bridge; uchar type; } PCI_DEVICE; typedef struct _PCI_CONFIG_SPACE_ { ushort vendorID; ushort deviceID; ushort command; ushort status; uchar revision; uchar classCode[3]; uchar cacheSize; uchar latencyTimer; uchar headerType; uchar bist; ulong baseAddress[6]; ushort reserved[4]; ulong optionRomAddr; ushort reserved2[4]; uchar irqLine; uchar irqPin; uchar minGnt; uchar maxLatency; } PCI_CONFIG_SPACE; #ifdef ADVANSYS_STATS struct asc_stats { ulong command; /* # calls to advansys_command() */ ulong queuecommand; /* # calls to advansys_queuecommand() */ ulong abort; /* # calls to advansys_abort() */ ulong reset; /* # calls to advansys_reset() */ ulong biosparam; /* # calls to advansys_biosparam() */ ulong interrupt; /* # calls to advansys_interrupt() */ ulong callback; /* # calls asc_isr_callback() */ ulong cont_cnt; /* # non-scatter-gather I/O requests received */ ulong cont_xfer; /* contiguous transfer total (512 byte units) */ ulong sg_cnt; /* # scatter-gather I/O requests received */ ulong sg_elem; /* scatter-gather element total */ ulong sg_xfer; /* scatter-gather tranfer total (512 byte units) */ ulong error; /* # AscExeScsiQueue() ASC_ERROR returns. */ /* * Number of times interrupts disabled in advansys_queuecommand() and * asc_isr_callback(), respectively. For the former indicates how many * times commands were pending when a new command was received. */ ulong cmd_disable; ulong intr_disable; /* * Number of times asc_enqueue() called. Indicates how many ASC_BUSY * returns have occurred. */ ulong enqueue; ulong dequeue; /* # calls to asc_dequeue(). */ /* * Number of times asc_rmqueue() called and the specified command * was found and removed. */ ulong rmqueue; } asc_stats; #endif /* ADVANSYS_STATS */ /* * --- Driver Data */ #ifdef LINUX_1_3 struct proc_dir_entry proc_scsi_advansys = { PROC_SCSI_ADVANSYS, /* unsigned short low_ino */ 8, /* unsigned short namelen */ "advansys", /* const char *name */ S_IFDIR | S_IRUGO | S_IXUGO, /* mode_t mode */ 2 /* nlink_t nlink */ }; #endif /* LINUX_1_3 */ STATIC int asc_board_count; /* Number of boards detected in system. */ STATIC struct Scsi_Host *asc_host[ASC_NUM_BOARD_SUPPORTED]; STATIC Scsi_Cmnd *asc_scsi_done; /* Commands needing done function call. */ STATIC ushort asc_bus[ASC_NUM_BUS] = { ASC_IS_ISA, ASC_IS_VL, ASC_IS_EISA, ASC_IS_PCI, }; /* * Used with the LILO 'advansys' option to eliminate or * limit I/O port probing at boot time, cf. advansys_setup(). */ int asc_iopflag = ASC_FALSE; int asc_ioport[ASC_NUM_BOARD_SUPPORTED] = { 0, 0, 0, 0 }; #ifdef ADVANSYS_DEBUG char * asc_bus_name[ASC_NUM_BUS] = { "ASC_IS_ISA", "ASC_IS_VL", "ASC_IS_EISA", "ASC_IS_PCI", }; int asc_dbglvl = 0; #endif /* ADVANSYS_DEBUG */ /* * --- Driver Function Prototypes * * advansys.h contains function prototypes for functions global to Linux. */ #ifdef LINUX_1_3 STATIC int asc_proc_copy(off_t, off_t, char *, int , char *, int); #endif /* LINUX_1_3 */ STATIC void advansys_interrupt(int, struct pt_regs *); STATIC void advansys_command_done(Scsi_Cmnd *); STATIC int asc_execute_scsi_cmnd(Scsi_Cmnd *); STATIC void asc_isr_callback(ASC_DVC_VAR *, ASC_QDONE_INFO *); STATIC void asc_execute_pending(struct Scsi_Host *); STATIC int asc_init_dev(ASC_DVC_VAR *, Scsi_Cmnd *); STATIC int asc_srch_pci_dev(PCI_DEVICE *); STATIC uchar asc_scan_method(PCI_DEVICE *); STATIC int asc_pci_find_dev(PCI_DEVICE *); STATIC void asc_get_pci_cfg(PCI_DEVICE *, PCI_CONFIG_SPACE *); STATIC ushort asc_get_cfg_word(PCI_DATA *); STATIC uchar asc_get_cfg_byte(PCI_DATA *); STATIC void asc_enqueue(struct Scsi_Host *, Scsi_Cmnd *, int, int); STATIC Scsi_Cmnd *asc_dequeue(struct Scsi_Host *, int); STATIC int asc_rmqueue(struct Scsi_Host *, Scsi_Cmnd *, int); /* XXX - Asc Library Routines not supposed to be used directly */ ushort AscGetChipBiosAddress(PortAddr, ushort); int AscFindSignature(PortAddr); #ifdef ADVANSYS_STATS STATIC int asc_prt_stats(char *, int); STATIC int asc_prt_stats_line(char *, int, char *fmt, ...); #endif /* ADVANSYS_STATS */ #ifdef ADVANSYS_DEBUG STATIC void asc_prt_scsi_host(struct Scsi_Host *); STATIC void asc_prt_dvc_cfg(ASC_DVC_CFG *); STATIC void asc_prt_dvc_var(ASC_DVC_VAR *); STATIC void asc_prt_scsi_q(ASC_SCSI_Q *); STATIC void asc_prt_qdone_info(ASC_QDONE_INFO *); STATIC void asc_prt_hex(char *f, uchar *, int); STATIC int interrupts_enabled(void); #endif /* ADVANSYS_DEBUG */ /* * --- Linux 'Scsi_Host_Template' and advansys_setup() Functions */ #ifdef LINUX_1_3 /* * advansys_proc_info() - /proc/scsi/advansys/[0-ASC_NUM_BOARD_SUPPORTED] * * *buffer: I/O buffer * **start: if inout == FALSE pointer into buffer where user read should start * offset: current offset into /proc/scsi/advansys file * length: length of buffer * hostno: Scsi_Host host_no * inout: TRUE - user is writing; FALSE - user is reading * * Return the number of bytes read from or written to * /proc/scsi/advansys file. */ int advansys_proc_info(char *buffer, char **start, off_t offset, int length, int hostno, int inout) { struct Scsi_Host *shp; int i; char *cp; int cplen; int cnt; int totcnt; int leftlen; char *curbuf; off_t advoffset; Scsi_Device *scd; char prtbuf[480]; /* 6 lines */ ASC_DBG(1, "advansys_proc_info: begin\n"); /* * User write not supported. */ if (inout == TRUE) { return(-ENOSYS); } /* * User read of /proc/scsi/advansys file. */ /* Find the specified board. */ for (i = 0; i < asc_board_count; i++) { if (asc_host[i]->host_no == hostno) { break; } } if (i == asc_board_count) { return(-ENOENT); } shp = asc_host[i]; /* Always copy read data to the beginning of the buffer. */ *start = buffer; curbuf = buffer; advoffset = 0; totcnt = 0; leftlen = length; /* Get board information. */ cp = (char *) advansys_info(shp); strcat(cp, "\n"); cplen = strlen(cp); /* Copy board information. */ cnt = asc_proc_copy(advoffset, offset, curbuf, leftlen, cp, cplen); totcnt += cnt; leftlen -= cnt; if (leftlen == 0) { ASC_DBG1(1, "advansys_proc_info: totcnt %d\n", totcnt); return totcnt; } advoffset += cplen; curbuf += cnt; /* * Get and copy information for each device attached to the board. */ cp = &prtbuf[0]; sprintf(cp, "\nDevices attached to SCSI Host %d:\n", shp->host_no); cplen = strlen(cp); cnt = asc_proc_copy(advoffset, offset, curbuf, leftlen, cp, cplen); totcnt += cnt; leftlen -= cnt; if (leftlen == 0) { ASC_DBG1(1, "advansys_proc_info: totcnt %d\n", totcnt); return totcnt; } advoffset += cplen; curbuf += cnt; cp = &prtbuf[0]; for (scd = scsi_devices; scd; scd = scd->next) { if (scd->host == shp) { proc_print_scsidevice(scd, cp, &cplen, 0); cnt = asc_proc_copy(advoffset, offset, curbuf, leftlen, cp, cplen); totcnt += cnt; leftlen -= cnt; if (leftlen == 0) { ASC_DBG1(1, "advansys_proc_info: totcnt %d\n", totcnt); return totcnt; } advoffset += cplen; curbuf += cnt; } } #ifdef ADVANSYS_STATS /* * prtbuf[] has about 6 lines worth of space. If the statistics ever * get longer than 6 lines, prtbuf[] should be increased in size. If * prtbuf[] is too small it will not be overwritten. Instead the user * just won't get all of the available statistics. */ cp = &prtbuf[0]; cplen = asc_prt_stats(cp, sizeof(prtbuf)); cnt = asc_proc_copy(advoffset, offset, curbuf, leftlen, cp, cplen); totcnt += cnt; leftlen -= cnt; if (leftlen == 0) { ASC_DBG1(1, "advansys_proc_info: totcnt %d\n", totcnt); return totcnt; } advoffset += cplen; curbuf += cnt; #endif /* ADVANSYS_STATS */ ASC_DBG1(1, "advansys_proc_info: totcnt %d\n", totcnt); return totcnt; } #endif /* LINUX_1_3 */ /* * advansys_detect() * * Detect function for AdvanSys adapters. * * Argument is a pointer to the host driver's scsi_hosts entry. * * Return number of adapters found. * * Note: Because this function is called during system initialization * it must not call SCSI mid-level functions including scsi_malloc() * and scsi_free(). */ int advansys_detect(Scsi_Host_Template *tpnt) { static int detect_called = ASC_FALSE; int iop; int bus; struct Scsi_Host *shp; ASC_DVC_VAR *boardp; int ioport = 0; PCI_DEVICE pciDevice; PCI_CONFIG_SPACE pciConfig; int ret; extern PortAddr _asc_def_iop_base[ASC_IOADR_TABLE_MAX_IX]; if (detect_called == ASC_FALSE) { detect_called = ASC_TRUE; } else { printk("AdvanSys SCSI: advansys_detect() mulitple calls ignored\n"); return 0; } ASC_DBG(1, "advansys_detect: begin\n"); #ifdef LINUX_1_3 tpnt->proc_dir = &proc_scsi_advansys; #endif /* LINUX_1_3 */ #ifdef ADVANSYS_STATS memset(&asc_stats, 0, sizeof(asc_stats)); #endif /* ADVANSYS_STATS */ asc_board_count = 0; /* * If I/O port probing has been modified, then verify and * clean-up the 'asc_ioport' list. */ if (asc_iopflag == ASC_TRUE) { for (ioport = 0; ioport < ASC_NUM_BOARD_SUPPORTED; ioport++) { ASC_DBG2(1, "asdvansys_detect: asc_ioport[%d] %x\n", ioport, asc_ioport[ioport]); if (asc_ioport[ioport] != 0) { for (iop = 0; iop < ASC_IOADR_TABLE_MAX_IX; iop++) { if (_asc_def_iop_base[iop] == asc_ioport[ioport]) { break; } } if (iop == ASC_IOADR_TABLE_MAX_IX) { printk("AdvanSys SCSI: specified I/O Port 0x%X is invalid\n", asc_ioport[ioport]); asc_ioport[ioport] = 0; } } } ioport = 0; } memset(&pciDevice, 0, sizeof(PCI_DEVICE)); memset(&pciConfig, 0, sizeof(PCI_CONFIG_SPACE)); pciDevice.maxBusNumber = PCI_MAX_BUS; pciDevice.endSlot = PCI_MAX_SLOT; for (bus = 0; bus < ASC_NUM_BUS; bus++) { ASC_DBG2(1, "advansys_detect: bus search type %d (%s)\n", bus, asc_bus_name[bus]); iop = 0; while (asc_board_count < ASC_NUM_BOARD_SUPPORTED) { ASC_DBG1(2, "advansys_detect: asc_board_count %d\n", asc_board_count); switch (asc_bus[bus]) { case ASC_IS_ISA: case ASC_IS_VL: if (asc_iopflag == ASC_FALSE) { iop = AscSearchIOPortAddr(iop, asc_bus[bus]); } else { /* * ISA and VL I/O port scanning has either been * eliminated or limited to selected ports on * the LILO command line, /etc/lilo.conf, or * by setting variables when the module was loaded. */ ASC_DBG(1, "advansys_detect: I/O port scanning modified\n"); ioport_try_again: iop = 0; for (; ioport < ASC_NUM_BOARD_SUPPORTED; ioport++) { if ((iop = asc_ioport[ioport]) != 0) { break; } } if (iop) { ASC_DBG1(1, "advansys_detect: probing I/O port %x...\n", iop); if (check_region(iop, ASC_IOADR_GAP) != 0) { printk("AdvanSys SCSI: specified I/O Port 0x%X is busy\n", iop); /* Don't try this I/O port twice. */ asc_ioport[ioport] = 0; goto ioport_try_again; } else if (AscFindSignature(iop) == ASC_FALSE) { printk("AdvanSys SCSI: specified I/O Port 0x%X has no adapter\n", iop); /* Don't try this I/O port twice. */ asc_ioport[ioport] = 0; goto ioport_try_again; } else { /* * If this isn't an ISA board, then it must be * a VL board. If currently looking an ISA * board is being looked for then try for * another ISA board in 'asc_ioport'. */ if (asc_bus[bus] == ASC_IS_ISA && (AscGetChipVersion(iop, ASC_IS_ISA) & ASC_CHIP_VER_ISA_BIT) == 0) { /* * Don't clear 'asc_ioport[ioport]'. Try * this board again for VL. Increment * 'ioport' past this board. */ ioport++; goto ioport_try_again; } } /* * This board appears good, don't try the I/O port * again by clearing its value. Increment 'ioport' * for the next iteration. */ asc_ioport[ioport++] = 0; } } break; case ASC_IS_EISA: iop = AscSearchIOPortAddr(iop, asc_bus[bus]); break; case ASC_IS_PCI: if (asc_srch_pci_dev(&pciDevice) != PCI_DEVICE_FOUND) { iop = 0; } else { ASC_DBG2(2, "advansys_detect: slotFound %d, busNumber %d\n", pciDevice.slotFound, pciDevice.busNumber); asc_get_pci_cfg(&pciDevice, &pciConfig); iop = pciConfig.baseAddress[0] & PCI_IOADDRESS_MASK; ASC_DBG2(2, "advansys_detect: iop %x, irqLine %d\n", iop, pciConfig.irqLine); } break; default: ASC_DBG(0, "advansys_detect: unknown bus type\n"); break; } ASC_DBG1(1, "advansys_detect: iop %x\n", iop); /* * Adapter not found, try next bus type. */ if (iop == 0) { break; } /* * Adapter found. * * Register the adapter, get its configuration, and * initialize it. */ ASC_DBG(2, "advansys_detect: scsi_register()\n"); shp = scsi_register(tpnt, sizeof(struct asc_board)); /* Save a pointer to the Scsi_host of each found board. */ asc_host[asc_board_count++] = shp; /* Initialize private per board data */ memset(ASC_BOARD(shp), 0, sizeof(struct asc_board)); boardp = &ASC_BOARD(shp)->board; boardp->cfg = &ASC_BOARD(shp)->cfg; boardp->cfg->overrun_buf = &ASC_BOARD(shp)->overrun_buf[0]; boardp->iop_base = iop; /* * Set the board bus type and PCI IRQ for AscInitGetConfig(). */ boardp->bus_type = asc_bus[bus]; switch (boardp->bus_type) { case ASC_IS_ISA: shp->unchecked_isa_dma = TRUE; break; case ASC_IS_EISA: shp->unchecked_isa_dma = FALSE; break; case ASC_IS_VL: shp->unchecked_isa_dma = FALSE; break; case ASC_IS_PCI: shp->irq = boardp->irq_no = pciConfig.irqLine; boardp->cfg->pci_device_id = pciConfig.deviceID; shp->unchecked_isa_dma = FALSE; break; default: ASC_DBG(0, "advansys_detect: unknown adapter type"); shp->unchecked_isa_dma = TRUE; break; } /* * Get the board configuration. AscInitGetConfig() may change * the board's bus_type value. The asc_bus[bus] value should no * longer be used. */ ASC_DBG(2, "advansys_detect: AscInitGetConfig()\n"); switch(ret = AscInitGetConfig(boardp)) { case 0: /* No error */ break; case ASC_WARN_IO_PORT_ROTATE: ASC_DBG(0, "AscInitGetConfig: I/O port address modified\n"); break; case ASC_WARN_EEPROM_CHKSUM: ASC_DBG(0, "AscInitGetConfig: EEPROM checksum error\n"); break; case ASC_WARN_IRQ_MODIFIED: ASC_DBG(0, "AscInitGetConfig: IRQ modified\n"); break; case ASC_WARN_CMD_QNG_CONFLICT: ASC_DBG(0, "AscInitGetConfig: Tag queuing enabled w/o disconnects\n"); break; default: ASC_DBG1(0, "AscInitGetConfig: Unknown warning: %x\n", ret); break; } if (boardp->err_code != 0) { ASC_DBG2(0, "AscInitGetConfig: error: init_state %x, err_code %x\n", boardp->init_state, boardp->err_code); scsi_unregister(shp); asc_board_count--; continue; } /* * Modify board configuration. */ boardp->isr_callback = (Ptr2Func) asc_isr_callback; boardp->exe_callback = (Ptr2Func) NULL; ASC_DBG(2, "advansys_detect: AscInitSetConfig()\n"); switch (ret = AscInitSetConfig(boardp)) { case 0: /* No error. */ break; case ASC_WARN_IO_PORT_ROTATE: ASC_DBG(0, "AscInitSetConfig: I/O port address modified\n"); break; case ASC_WARN_EEPROM_CHKSUM: ASC_DBG(0, "AscInitSetConfig: EEPROM checksum error\n"); break; case ASC_WARN_IRQ_MODIFIED: ASC_DBG(0, "AscInitSetConfig: IRQ modified\n"); break; case ASC_WARN_CMD_QNG_CONFLICT: ASC_DBG(0, "AscInitSetConfig: Tag queuing w/o disconnects\n"); break; default: ASC_DBG1(0, "AscInitSetConfig: Unknown warning: %x\n", ret); break; } if (boardp->err_code != 0) { ASC_DBG2(0, "AscInitSetConfig: error: init_state %x, err_code %x\n", boardp->init_state, boardp->err_code); scsi_unregister(shp); asc_board_count--; continue; } /* * Finish initializing the 'Scsi_Host' structure. */ /* AscInitSetConfig() will set the IRQ for non-PCI boards. */ if (boardp->bus_type != ASC_IS_PCI) { shp->irq = boardp->irq_no; } shp->io_port = boardp->iop_base; shp->n_io_port = ASC_IOADR_GAP; shp->this_id = boardp->cfg->chip_scsi_id; /* Maximum number of queues this adapter can handle. */ shp->can_queue = boardp->max_total_qng; /* * XXX - Command queuing limits are maintained per target * by AdvanSys adapters. Set 'cmd_per_lun' to the minimum * value of the all the target settings for the adapter. * * For now set 'cmd_per_lun' to 'max_total_qng'. This * value should be adjusted every time a new device is * found in asc_init_dev(). * * XXX - memory allocation is done by the mid-level scsi * driver based on 'cmd_per_lun'. If 'sg_tablesize' is too large * allocation failures can occur in scsi_register_host(). * A 'Scsi_Cmnd' structure is pre-allocated for each command * also DMA memory is reserved. Set it artificially low for now. * * shp->cmd_per_lun = boardp->max_total_qng; */ #ifdef MODULE shp->cmd_per_lun = 1; #else /* MODULE */ shp->cmd_per_lun = 4; #endif /* MODULE */ ASC_DBG1(1, "advansys_detect: cmd_per_lun: %d\n", shp->cmd_per_lun); /* Maximum number of scatter-gather elements adapter can handle. */ /* * XXX - memory allocation is done by the mid-level scsi * driver based on sg_tablesize. If 'sg_tablesize' is too large * allocation failures can occur in scsi_register_host(). */ #ifdef MODULE shp->sg_tablesize = 8; #else /* MODULE */ shp->sg_tablesize = ASC_MAX_SG_LIST; #endif /* MODULE */ ASC_DBG1(1, "advansys_detect: sg_tablesize: %d\n", shp->sg_tablesize); /* BIOS start address. */ shp->base = (char *) ((ulong) AscGetChipBiosAddress( boardp->iop_base, boardp->bus_type)); /* * Register Board Resources - I/O Port, DMA, IRQ */ /* Register I/O port range */ ASC_DBG(2, "advansys_detect: request_region()\n"); request_region(shp->io_port, shp->n_io_port, "advansys"); /* Register DMA channel for ISA bus. */ if ((boardp->bus_type & ASC_IS_ISA) == 0) { shp->dma_channel = NO_ISA_DMA; } else { shp->dma_channel = boardp->cfg->isa_dma_channel; if ((ret = request_dma(shp->dma_channel, "advansys")) != 0) { ASC_DBG2(0, "advansys_detect: request_dma() %d failed %d\n", shp->dma_channel, ret); release_region(shp->io_port, shp->n_io_port); scsi_unregister(shp); asc_board_count--; continue; } AscEnableIsaDma(shp->dma_channel); } /* Register IRQ Number. */ ASC_DBG1(2, "advansys_detect: request_irq() %d\n", shp->irq); if ((ret = request_irq(shp->irq, advansys_interrupt, SA_INTERRUPT, "advansys")) != 0) { ASC_DBG1(0, "advansys_detect: request_irq() failed %d\n", ret); release_region(shp->io_port, shp->n_io_port); if (shp->dma_channel != NO_ISA_DMA) { free_dma(shp->dma_channel); } scsi_unregister(shp); asc_board_count--; continue; } /* * Initialize board RISC chip and enable interrupts. */ ASC_DBG(2, "advansys_detect: AscInitAsc1000Driver()\n"); if (AscInitAsc1000Driver(boardp)) { ASC_DBG2(0, "AscInitAsc1000Driver: error: init_state %x, err_code %x\n", boardp->init_state, boardp->err_code); release_region(shp->io_port, shp->n_io_port); if (shp->dma_channel != NO_ISA_DMA) { free_dma(shp->dma_channel); } free_irq(shp->irq); scsi_unregister(shp); asc_board_count--; continue; } ASC_DBG_PRT_SCSI_HOST(2, shp); } } ASC_DBG1(1, "advansys_detect: done: asc_board_count %d\n", asc_board_count); return asc_board_count; } /* * advansys_release() * * Release resources allocated for a single AdvanSys adapter. */ int advansys_release(struct Scsi_Host *shp) { ASC_DBG(1, "advansys_release: begin\n"); free_irq(shp->irq); if (shp->dma_channel != NO_ISA_DMA) { ASC_DBG(1, "advansys_release: free_dma()\n"); free_dma(shp->dma_channel); } release_region(shp->io_port, shp->n_io_port); scsi_unregister(shp); ASC_DBG(1, "advansys_release: end\n"); return 0; } /* * advansys_info() * * Return suitable for printing on the console with the argument * adapter's configuration information. */ const char * advansys_info(struct Scsi_Host *shp) { static char info[128]; ASC_DVC_VAR *boardp; char *busname; boardp = &ASC_BOARD(shp)->board; ASC_DBG(1, "advansys_info: begin\n"); if (boardp->bus_type & ASC_IS_ISA) { sprintf(info, "AdvanSys SCSI %s: ISA (%u CDB): BIOS %X, IO %X-%X, IRQ %u, DMA %u", ASC_VERSION, ASC_BOARD(shp)->board.max_total_qng, (unsigned) shp->base, shp->io_port, shp->io_port + (shp->n_io_port - 1), shp->irq, shp->dma_channel); } else { switch (boardp->bus_type) { case ASC_IS_EISA: busname = "EISA"; break; case ASC_IS_VL: busname = "VL"; break; case ASC_IS_PCI: busname = "PCI"; break; default: busname = "?"; ASC_DBG1(0, "advansys_info: unknown bus type %d\n", boardp->bus_type); break; } /* No DMA channel for non-ISA busses. */ sprintf(info, "AdvanSys SCSI %s: %s (%u CDB): BIOS %X, IO %X-%X, IRQ %u", ASC_VERSION, busname, ASC_BOARD(shp)->board.max_total_qng, (unsigned) shp->base, shp->io_port, shp->io_port + (shp->n_io_port - 1), shp->irq); } ASC_DBG(1, "advansys_info: end\n"); return info; } /* * advansys_command() * * Polled-I/O. Apparently host driver shouldn't return until * command is finished. * * XXX - Can host driver block here instead of spinning on command status? */ int advansys_command(Scsi_Cmnd *scp) { ASC_DBG1(1, "advansys_command: scp %x\n", (unsigned) scp); ASC_STATS(command); scp->SCp.Status = 0; /* Set to a known state */ advansys_queuecommand(scp, advansys_command_done); while (scp->SCp.Status == 0) { continue; } ASC_DBG1(1, "advansys_command: result %x\n", scp->result); return scp->result; } /* * advansys_queuecommand() * * This function always returns 0. Command return status is saved * in the 'scp' result field. */ int advansys_queuecommand(Scsi_Cmnd *scp, void (*done)(Scsi_Cmnd *)) { struct Scsi_Host *shp; int flags = 0; int interrupts_disabled; ASC_STATS(queuecommand); shp = scp->host; #ifdef LINUX_1_2 /* * For LINUX_1_3, if statistics are enabled they can be accessed * by reading /proc/scsi/advansys/[0-9]. */ #ifdef ADVANSYS_STATS_1_2_PRINT /* Display statistics every 10000 commands. */ if ((asc_stats.queuecommand % 10000) == 0) { printk("\n"); (void) asc_prt_stats(NULL, 0); printk("\n"); } #endif /* ADVANSYS_STATS_1_2_PRINT */ #endif /* LINUX_1_2 */ /* * If there are any pending commands for this board before trying * to execute them, disable interrupts to preserve request ordering. * * The typical case will be no pending commands and interrupts * not disabled. */ if (ASC_BOARD(shp)->pending_tidmask == 0) { interrupts_disabled = ASC_FALSE; } else { ASC_STATS(cmd_disable); /* Disable interrupts */ interrupts_disabled = ASC_TRUE; save_flags(flags); cli(); ASC_DBG1(1, "advansys_queuecommand: asc_execute_pending() %x\n", ASC_BOARD(shp)->pending_tidmask); asc_execute_pending(shp); } /* * Save the function pointer to Linux mid-level 'done' function and * execute the command. */ scp->scsi_done = done; if (asc_execute_scsi_cmnd(scp) == ASC_BUSY) { if (interrupts_disabled == ASC_FALSE) { save_flags(flags); cli(); interrupts_disabled = ASC_TRUE; } asc_enqueue(shp, scp, scp->target, ASC_BACK); } if (interrupts_disabled == ASC_TRUE) { restore_flags(flags); } return 0; } /* * advansys_abort() * * Abort the specified command and reset the device * associated with the command 'scp'. */ int advansys_abort(Scsi_Cmnd *scp) { ASC_DVC_VAR *boardp; int flags; int ret; ASC_DBG1(1, "advansys_abort: scp %x\n", (unsigned) scp); save_flags(flags); cli(); ASC_STATS(abort); if (scp->host == NULL) { scp->result = HOST_BYTE(DID_ERROR); ret = SCSI_ABORT_ERROR; } else if (asc_rmqueue(scp->host, scp, scp->target) == ASC_TRUE) { scp->result = HOST_BYTE(DID_ABORT); ret = SCSI_ABORT_SUCCESS; (void) AscResetDevice(&ASC_BOARD(scp->host)->board, scp->target); } else { /* Must enable interrupts for AscAbortSRB() */ sti(); boardp = &ASC_BOARD(scp->host)->board; scp->result = HOST_BYTE(DID_ABORT); switch (AscAbortSRB(boardp, (ulong) scp)) { case ASC_TRUE: /* asc_isr_callback() will be called */ ASC_DBG(1, "advansys_abort: AscAbortSRB() TRUE\n"); ret = SCSI_ABORT_PENDING; break; case ASC_FALSE: /* Request has apparently already completed. */ ASC_DBG(1, "advansys_abort: AscAbortSRB() FALSE\n"); ret = SCSI_ABORT_NOT_RUNNING; break; case ASC_ERROR: default: ASC_DBG(1, "advansys_abort: AscAbortSRB() ERROR\n"); ret = SCSI_ABORT_ERROR; break; } (void) AscResetDevice(boardp, scp->target); } restore_flags(flags); ASC_DBG1(1, "advansys_abort: ret %d\n", ret); return ret; } /* * advansys_reset() * * Reset all devices and the SCSI bus for the board * associated with 'scp'. */ int advansys_reset(Scsi_Cmnd *scp) { ASC_DVC_VAR *boardp; int flags; Scsi_Cmnd *tscp; int i; int ret; ASC_DBG1(1, "advansys_reset: %x\n", (unsigned) scp); save_flags(flags); cli(); ASC_STATS(reset); if (scp->host == NULL) { scp->result = HOST_BYTE(DID_ERROR); ret = SCSI_RESET_ERROR; } else { /* Remove any pending commands, set DID_RESET, and done them. */ for (i = 0; i < ASC_MAX_TID; i++) { while ((tscp = asc_dequeue(scp->host, i)) != NULL) { tscp->result = HOST_BYTE(DID_RESET); tscp->scsi_done(tscp); } } /* Must enable interrupts for AscResetSB() */ sti(); boardp = &ASC_BOARD(scp->host)->board; scp->result = HOST_BYTE(DID_RESET); switch (AscResetSB(boardp)) { case ASC_TRUE: ASC_DBG(1, "advansys_abort: AscResetSB() TRUE\n"); ret = SCSI_RESET_SUCCESS; break; case ASC_ERROR: default: ASC_DBG(1, "advansys_abort: AscResetSB() ERROR\n"); ret = SCSI_RESET_ERROR; break; } } restore_flags(flags); ASC_DBG1(1, "advansys_reset: ret %d", ret); return ret; } /* * advansys_biosparam() * * Translate disk drive geometry if the "BIOS greater than 1 GB" * support is enabled for a drive. * * ip (information pointer) is an int array with the following definition: * ip[0]: heads * ip[1]: sectors * ip[2]: cylinders */ int #ifdef LINUX_1_2 advansys_biosparam(Disk *dp, int dep, int ip[]) #else /* LINUX_1_3 */ advansys_biosparam(Disk *dp, kdev_t dep, int ip[]) #endif /* LINUX_1_3 */ { ASC_DBG(1, "advansys_biosparam: begin\n"); ASC_STATS(biosparam); if ((ASC_BOARD(dp->device->host)->board.dvc_cntl & ASC_CNTL_BIOS_GT_1GB) && dp->capacity > 0x200000) { ip[0] = 255; ip[1] = 64; } else { ip[0] = 64; ip[1] = 32; } ip[2] = dp->capacity / (ip[0] * ip[1]); ASC_DBG(1, "advansys_biosparam: end\n"); return 0; } /* * advansys_setup() * * This function is called from init/main.c at boot time. * It it passed LILO parameters that can be set from the * LILO command line or in /etc/lilo.conf. * * It is used by the AdvanSys driver to either disable I/O * port scanning or to limit scanning to 1 - 4 I/O ports. * Regardless of the option setting EISA and PCI boards * will still be searched for and detected. This option * only affects searching for ISA and VL boards. * * If ADVANSYS_DEBUG is defined the driver debug level may * be set using the 5th (ASC_NUM_BOARD_SUPPORTED + 1) I/O Port. * * Examples: * 1. Eliminate I/O port scanning: * boot: linux advansys= * or * boot: linux advansys=0x0 * 2. Limit I/O port scanning to one I/O port: * boot: linux advansys=0x110 * 3. Limit I/O port scanning to four I/O ports: * boot: linux advansys=0x110,0x210,0x230,0x330 * 4. If ADVANSYS_DEBUG, limit I/O port scanning to four I/O ports and * set the driver debug level to 2. * boot: linux advansys=0x110,0x210,0x230,0x330,0xdeb2 * * ints[0] - number of arguments * ints[1] - first argument * ints[2] - second argument * ... */ void advansys_setup(char *str, int *ints) { int i; if (asc_iopflag == ASC_TRUE) { printk("AdvanSys SCSI: 'advansys' LILO option may appear only once\n"); return; } asc_iopflag = ASC_TRUE; if (ints[0] > ASC_NUM_BOARD_SUPPORTED) { #ifdef ADVANSYS_DEBUG if ((ints[0] == ASC_NUM_BOARD_SUPPORTED + 1) && (ints[ASC_NUM_BOARD_SUPPORTED + 1] >> 4 == 0xdeb)) { asc_dbglvl = ints[ASC_NUM_BOARD_SUPPORTED + 1] & 0xf; } else { #endif /* ADVANSYS_DEBUG */ printk("AdvanSys SCSI: only %d I/O ports accepted\n", ASC_NUM_BOARD_SUPPORTED); #ifdef ADVANSYS_DEBUG } #endif /* ADVANSYS_DEBUG */ } #ifdef ADVANSYS_DEBUG ASC_DBG1(1, "advansys_setup: ints[0] %d\n", ints[0]); for (i = 1; i < ints[0]; i++) { ASC_DBG2(1, " ints[%d] %x", i, ints[i]); } ASC_DBG(1, "\n"); #endif /* ADVANSYS_DEBUG */ for (i = 1; i <= ints[0] && i <= ASC_NUM_BOARD_SUPPORTED; i++) { asc_ioport[i-1] = ints[i]; ASC_DBG2(1, "advansys_setup: asc_ioport[%d] %x\n", i - 1, asc_ioport[i-1]); } } /* * --- Loadable Driver Support */ #ifdef MODULE Scsi_Host_Template driver_template = ADVANSYS; # include "scsi_module.c" #endif /* MODULE */ /* * --- Miscellaneous Driver Functions */ #ifdef LINUX_1_3 /* * asc_proc_copy() * * Copy proc information to a read buffer considering the current read * offset in the file and the remaining space in the read buffer. */ STATIC int asc_proc_copy(off_t advoffset, off_t offset, char *curbuf, int leftlen, char *cp, int cplen) { int cnt = 0; ASC_DBG3(2, "asc_proc_copy: offset %d, advoffset %d, cplen %d\n", (unsigned) offset, (unsigned) advoffset, cplen); if (offset <= advoffset) { /* Read offset below current offset, copy everything. */ cnt = min(cplen, leftlen); ASC_DBG3(2, "asc_proc_copy: curbuf %x, cp %x, cnt %d\n", (unsigned) curbuf, (unsigned) cp, cnt); memcpy(curbuf, cp, cnt); } else if (offset < advoffset + cplen) { /* Read offset within current range, partial copy. */ cnt = (advoffset + cplen) - offset; cp = (cp + cplen) - cnt; cnt = min(cnt, leftlen); ASC_DBG3(2, "asc_proc_copy: curbuf %x, cp %x, cnt %d\n", (unsigned) curbuf, (unsigned) cp, cnt); memcpy(curbuf, cp, cnt); } return cnt; } #endif /* LINUX_1_3 */ /* * First-level interrupt handler. */ STATIC void advansys_interrupt(int irq, struct pt_regs *regs) { int i; int flags; Scsi_Cmnd *scp; Scsi_Cmnd *tscp; /* Disable interrupts, if the aren't already disabled. */ save_flags(flags); cli(); ASC_DBG(1, "advansys_interrupt: begin\n"); ASC_STATS(interrupt); /* * Check for interrupts on all boards. * AscISR() will call asc_isr_callback(). */ for (i = 0; i < asc_board_count; i++) { while (AscIsIntPending(asc_host[i]->io_port)) { ASC_DBG(1, "advansys_interrupt: before AscISR()\n"); AscISR(&ASC_BOARD(asc_host[i])->board); } } ASC_DBG(1, "advansys_interrupt: end\n"); /* * While interrupts are still disabled save the list of requests that * need their done function called. After re-enabling interrupts call * the done function which may re-enable interrupts anyway. */ if ((scp = asc_scsi_done) != NULL) { asc_scsi_done = NULL; } /* Re-enable interrupts, if they were enabled on entry. */ restore_flags(flags); while (scp) { tscp = (Scsi_Cmnd *) scp->host_scribble; scp->scsi_done(scp); scp = tscp; } return; } /* * Function used only with polled I/O requests that are initiated by * advansys_command(). */ STATIC void advansys_command_done(Scsi_Cmnd *scp) { ASC_DBG1(1, "advansys_command_done: scp %x\n", (unsigned) scp); scp->SCp.Status = 1; } /* * Execute a single 'Scsi_Cmnd'. * * The function 'done' is called when the request has been completed. * * Scsi_Cmnd: * * host - board controlling device * device - device to send command * target - target of device * lun - lun of device * cmd_len - length of SCSI CDB * cmnd - buffer for SCSI 8, 10, or 12 byte CDB * use_sg - if non-zero indicates scatter-gather request with use_sg elements * * if (use_sg == 0) * request_buffer - buffer address for request * request_bufflen - length of request buffer * else * request_buffer - pointer to scatterlist structure * * sense_buffer - sense command buffer * * result (4 bytes of an int): * Byte Meaning * 0 SCSI Status Byte Code * 1 SCSI One Byte Message Code * 2 Host Error Code * 3 Mid-Level Error Code * * host driver fields: * SCp - Scsi_Pointer used for command processing status * scsi_done - used to save caller's done function * host_scribble - used for pointer to another Scsi_Cmnd * * If this function returns ASC_NOERROR or ASC_ERROR the done * function has been called. If ASC_BUSY is returned the request * must be enqueued by the caller and re-tried later. */ STATIC int asc_execute_scsi_cmnd(Scsi_Cmnd *scp) { ASC_DVC_VAR *boardp; ASC_SCSI_Q scsiq; ASC_SG_HEAD sghead; int ret; ASC_DBG2(1, "asc_execute_scsi_cmnd: scp %x, done %x\n", (unsigned) scp, (unsigned) scp->scsi_done); boardp = &ASC_BOARD(scp->host)->board; /* * If this is the first command, then initialize the device. If * no device is found set 'DID_BAD_TARGET' and return. */ if ((ASC_BOARD(scp->host)->init_tidmask & ASC_TIX_TO_TARGET_ID(scp->target)) == 0) { if (asc_init_dev(boardp, scp) == ASC_FALSE) { scp->result = HOST_BYTE(DID_BAD_TARGET); scp->scsi_done(scp); return ASC_ERROR; } ASC_BOARD(scp->host)->init_tidmask |= ASC_TIX_TO_TARGET_ID(scp->target); } memset(&scsiq, 0, sizeof(ASC_SCSI_Q)); /* * Point the ASC_SCSI_Q to the 'Scsi_Cmnd'. */ scsiq.q2.srb_ptr = (ulong) scp; /* * Build the ASC_SCSI_Q request. */ scsiq.cdbptr = &scp->cmnd[0]; scsiq.q2.cdb_len = scp->cmd_len; scsiq.q1.target_id = ASC_TID_TO_TARGET_ID(scp->target); scsiq.q1.target_lun = scp->lun; scsiq.q2.target_ix = ASC_TIDLUN_TO_IX(scp->target, scp->lun); scsiq.q1.sense_addr = (ulong) &scp->sense_buffer[0]; scsiq.q1.sense_len = sizeof(scp->sense_buffer); scsiq.q2.tag_code = M2_QTAG_MSG_SIMPLE; /* * Build ASC_SCSI_Q for a contiguous buffer or a scatter-gather * buffer command. */ if (scp->use_sg == 0) { /* * CDB request of single contiguous buffer. */ ASC_STATS(cont_cnt); /* request_buffer is already a real address. */ scsiq.q1.data_addr = (ulong) scp->request_buffer; scsiq.q1.data_cnt = scp->request_bufflen; ASC_STATS_ADD(cont_xfer, (scp->request_bufflen + 511) >> 9); scsiq.q1.sg_queue_cnt = 0; scsiq.sg_head = NULL; } else { /* * CDB scatter-gather request list. */ int sgcnt; struct scatterlist *slp; if (scp->use_sg > ASC_MAX_SG_LIST) { ASC_DBG2(0, "asc_execute_scsi_cmnd: use_sg %d > %d\n", scp->use_sg, ASC_MAX_SG_LIST); scp->result = HOST_BYTE(DID_ERROR); scp->scsi_done(scp); return ASC_ERROR; } ASC_STATS(sg_cnt); /* * Allocate a ASC_SG_HEAD structure and set the ASC_SCSI_Q * to point to it. */ memset(&sghead, 0, sizeof(ASC_SG_HEAD)); scsiq.q1.cntl |= QC_SG_HEAD; scsiq.sg_head = &sghead; scsiq.q1.data_cnt = 0; scsiq.q1.data_addr = 0; sghead.entry_cnt = scsiq.q1.sg_queue_cnt = scp->use_sg; ASC_STATS_ADD(sg_elem, sghead.entry_cnt); /* * Convert scatter-gather list into ASC_SG_HEAD list. */ slp = (struct scatterlist *) scp->request_buffer; for (sgcnt = 0; sgcnt < scp->use_sg; sgcnt++, slp++) { sghead.sg_list[sgcnt].addr = (ulong) slp->address; sghead.sg_list[sgcnt].bytes = slp->length; ASC_STATS_ADD(sg_xfer, (slp->length + 511) >> 9); } } ASC_DBG_PRT_SCSI_Q(2, &scsiq); ASC_DBG_PRT_CDB(1, scp->cmnd, scp->cmd_len); switch (ret = AscExeScsiQueue(boardp, &scsiq)) { case ASC_NOERROR: ASC_DBG(1, "asc_execute_scsi_cmnd: AscExeScsiQueue() ASC_NOERROR\n"); break; case ASC_BUSY: /* Caller must enqueue request and retry later. */ break; case ASC_ERROR: ASC_DBG1(0, "asc_execute_scsi_cmnd: AscExeScsiQueue() ASC_ERROR err_code %x\n", boardp->err_code); ASC_STATS(error); scp->result = HOST_BYTE(DID_ERROR); scp->scsi_done(scp); break; } ASC_DBG(1, "asc_execute_scsi_cmnd: end\n"); return ret; } /* * asc_isr_callback() - Second Level Interrupt Handler called by AscISR(). */ void asc_isr_callback(ASC_DVC_VAR *boardp, ASC_QDONE_INFO *qdonep) { Scsi_Cmnd *scp; struct Scsi_Host *shp; int flags; Scsi_Cmnd **scpp; ASC_ASSERT(interrupts_enabled() == ASC_FALSE); ASC_DBG2(1, "asc_isr_callback: boardp %x, qdonep %x\n", (unsigned) boardp, (unsigned) qdonep); ASC_STATS(callback); ASC_DBG_PRT_QDONE_INFO(2, qdonep); /* * Get the Scsi_Cmnd structure and Scsi_Host structure for the * command that has been completed. */ scp = (Scsi_Cmnd *) qdonep->d2.srb_ptr; ASC_DBG1(1, "asc_isr_callback: scp %x\n", (unsigned) scp); ASC_DBG_PRT_CDB(2, scp->cmnd, scp->cmd_len); shp = scp->host; ASC_ASSERT(shp); ASC_DBG1(1, "asc_isr_callback: shp %x\n", (unsigned) shp); /* * 'qdonep' contains the command's ending status. */ switch (qdonep->d3.done_stat) { case QD_NO_ERROR: ASC_DBG(2, "asc_isr_callback: QD_NO_ERROR\n"); switch (qdonep->d3.host_stat) { case QHSTA_NO_ERROR: scp->result = 0; break; default: /* QHSTA error occurred */ scp->result = HOST_BYTE(DID_ERROR); break; } break; case QD_WITH_ERROR: ASC_DBG(2, "asc_isr_callback: QD_WITH_ERROR\n"); switch (qdonep->d3.host_stat) { case QHSTA_NO_ERROR: if (qdonep->d3.scsi_stat == SS_CHK_CONDITION) { ASC_DBG(2, "asc_isr_callback: SS_CHK_CONDITION\n"); ASC_DBG_PRT_SENSE(2, scp->sense_buffer, sizeof(scp->sense_buffer)); /* * Note: The status_byte() macro used by target drivers * defined in scsi.h shifts the status byte returned by * host drivers right by 1 bit. This is why target drivers * also use left shifted status byte definitions. For instance * target drivers use CHECK_CONDITION, defined to 0x1, instead * of the SCSI defined check condition value of 0x2. */ scp->result = DRIVER_BYTE(DRIVER_SENSE) | STATUS_BYTE(qdonep->d3.scsi_stat); } else { scp->result = STATUS_BYTE(qdonep->d3.scsi_stat); } break; default: /* QHSTA error occurred */ ASC_DBG1(2, "asc_isr_callback: host_stat %x\n", qdonep->d3.host_stat); scp->result = HOST_BYTE(DID_ERROR) | MSG_BYTE(qdonep->d3.scsi_msg) | STATUS_BYTE(qdonep->d3.scsi_stat); break; } break; case QD_ABORTED_BY_HOST: ASC_DBG(1, "asc_isr_callback: QD_ABORTED_BY_HOST\n"); scp->result = HOST_BYTE(DID_ABORT) | MSG_BYTE(qdonep->d3.scsi_msg) | STATUS_BYTE(qdonep->d3.scsi_stat); break; default: ASC_DBG1(0, "asc_isr_callback: done_stat %x\n", qdonep->d3.done_stat ); scp->result = HOST_BYTE(DID_ERROR) | MSG_BYTE(qdonep->d3.scsi_msg) | STATUS_BYTE(qdonep->d3.scsi_stat); break; } /* * Before calling 'scsi_done' for the current 'Scsi_Cmnd' and possibly * triggering more commands to be issued, try to start any pending * commands. */ if (ASC_BOARD(shp)->pending_tidmask != 0) { /* * If there are any pending commands for this board before trying * to execute them, disable interrupts to preserve request ordering. */ ASC_STATS(intr_disable); save_flags(flags); cli(); ASC_DBG1(1, "asc_isr_callback: asc_execute_pending() %x\n", ASC_BOARD(shp)->pending_tidmask); asc_execute_pending(shp); restore_flags(flags); } /* * Because interrupts may be enabled by the 'Scsi_Cmnd' done function, * add the command to the end of the global done list. The done function * for the command will be called in advansys_interrupt(). */ for (scpp = &asc_scsi_done; *scpp; scpp = (Scsi_Cmnd **) &(*scpp)->host_scribble) { ; } *scpp = scp; scp->host_scribble = NULL; return; } /* * Execute as many pending requests as possible for the * board specified by 'Scsi_Host'. */ STATIC void asc_execute_pending(struct Scsi_Host *shp) { ASC_SCSI_BIT_ID_TYPE scan_tidmask; Scsi_Cmnd *scp; int i; ASC_ASSERT(interrupts_enabled() == ASC_FALSE); /* * Execute pending commands for devices attached to * the current board in round-robin fashion. */ scan_tidmask = ASC_BOARD(shp)->pending_tidmask; do { for (i = 0; i < ASC_MAX_TID; i++) { if (scan_tidmask & ASC_TIX_TO_TARGET_ID(i)) { if ((scp = asc_dequeue(shp, i)) == NULL) { scan_tidmask &= ~ASC_TIX_TO_TARGET_ID(i); } else if (asc_execute_scsi_cmnd(scp) == ASC_BUSY) { scan_tidmask &= ~ASC_TIX_TO_TARGET_ID(i); /* Put the request back at front of the list. */ asc_enqueue(shp, scp, i, ASC_FRONT); } } } } while (scan_tidmask); return; } /* * asc_init_dev() * * Perform one-time initialization of a device. */ STATIC int asc_init_dev(ASC_DVC_VAR *boardp, Scsi_Cmnd *scp) { ASC_SCSI_REQ_Q *scsireqq; ASC_CAP_INFO *cap_info; ASC_SCSI_INQUIRY *inquiry; int found; ASC_SCSI_BIT_ID_TYPE save_use_tagged_qng; ASC_SCSI_BIT_ID_TYPE save_can_tagged_qng; int ret; #ifdef ADVANSYS_DEBUG ASC_SCSI_BIT_ID_TYPE tidmask; /* target id bit mask: 1 - 128 */ #endif /* ADVANSYS_DEBUG */ ASC_DBG1(1, "asc_init_dev: target %d\n", (unsigned) scp->target); /* Return true for the board's target id. */ if (boardp->cfg->chip_scsi_id == scp->target) { return ASC_TRUE; } /* * XXX - Host drivers should not modify the timeout field. * But on the first command only add some extra time to * allow the driver to complete its initialization for the * device. */ scp->timeout += 2000; /* Add 5 seconds to the request timeout. */ /* Set-up AscInitPollTarget() arguments. */ scsireqq = &ASC_BOARD(scp->host)->scsireqq; memset(scsireqq, 0, sizeof(ASC_SCSI_REQ_Q)); cap_info = &ASC_BOARD(scp->host)->cap_info; memset(cap_info, 0, sizeof(ASC_CAP_INFO)); inquiry = &ASC_BOARD(scp->host)->inquiry; memset(inquiry, 0, sizeof(ASC_SCSI_INQUIRY)); /* * XXX - AscInitPollBegin() re-initializes these fields to * zero. 'Or' in the new values and restore them before calling * AscInitPollEnd(). Normally all targets are initialized within * a call to AscInitPollBegin() and AscInitPollEnd(). */ save_use_tagged_qng = boardp->use_tagged_qng; save_can_tagged_qng = boardp->cfg->can_tagged_qng; ASC_DBG(2, "asc_init_dev: AscInitPollBegin()\n"); if (AscInitPollBegin(boardp)) { ASC_DBG(0, "asc_init_dev: AscInitPollBegin() failed\n"); return ASC_FALSE; } scsireqq->sense_ptr = &scsireqq->sense[0]; scsireqq->r1.sense_len = ASC_MIN_SENSE_LEN; scsireqq->r1.target_id = ASC_TID_TO_TARGET_ID(scp->target); scsireqq->r1.target_lun = 0; scsireqq->r2.target_ix = ASC_TIDLUN_TO_IX(scp->target, 0); found = ASC_FALSE; ASC_DBG(2, "asc_init_dev: AscInitPollTarget()\n"); switch (ret = AscInitPollTarget(boardp, scsireqq, inquiry, cap_info)) { case ASC_TRUE: found = ASC_TRUE; #ifdef ADVANSYS_DEBUG tidmask = ASC_TIX_TO_TARGET_ID(scp->target); ASC_DBG2(1, "asc_init_dev: lba %lu, blk_size %lu\n", cap_info->lba, cap_info->blk_size); ASC_DBG1(1, "asc_init_dev: peri_dvc_type %x\n", inquiry->byte0.peri_dvc_type); if (boardp->use_tagged_qng & tidmask) { ASC_DBG1(1, "asc_init_dev: command queuing enabled: %d\n", boardp->max_dvc_qng[scp->target]); } else { ASC_DBG(1, "asc_init_dev: command queuing disabled\n"); } if (boardp->init_sdtr & tidmask) { ASC_DBG(1, "asc_init_dev: synchronous transfers enabled\n"); } else { ASC_DBG(1, "asc_init_dev: synchronous transfers disabled\n"); } /* Set bit means fix disabled. */ if (boardp->pci_fix_asyn_xfer & tidmask) { ASC_DBG(1, "asc_init_dev: synchronous transfer fix disabled\n"); } else { ASC_DBG(1, "asc_init_dev: synchronous transfer fix enabled\n"); } #endif /* ADVANSYS_DEBUG */ break; case ASC_FALSE: ASC_DBG(1, "asc_init_dev: no device found\n"); break; case ASC_ERROR: ASC_DBG(0, "asc_init_dev: AscInitPollTarget() ASC_ERROR\n"); break; default: ASC_DBG1(0, "asc_init_dev: AscInitPollTarget() unknown ret %d\n", ret); break; } /* XXX - 'Or' in original tag bits. */ boardp->use_tagged_qng |= save_use_tagged_qng; boardp->cfg->can_tagged_qng |= save_can_tagged_qng; ASC_DBG(2, "asc_init_dev: AscInitPollEnd()\n"); AscInitPollEnd(boardp); #ifdef ASC_SET_CMD_PER_LUN /* * XXX - Refer to the comment in advansys_detect() * regarding cmd_per_lun. */ for (i = 0; i <= ASC_MAX_TID; i++) { if (boardp->max_dvc_qng[i] < scp->host->cmd_per_lun) { scp->host->cmd_per_lun = boardp->max_dvc_qng[i]; } } #endif /* ASC_SET_CMD_PER_LUN */ return found; } /* * Search for an AdvanSys PCI device in the PCI configuration space. */ STATIC int asc_srch_pci_dev(PCI_DEVICE *pciDevice) { int ret; static int scan = 1; ASC_DBG(2, "asc_srch_pci_dev: begin\n"); if (scan) { pciDevice->type = asc_scan_method(pciDevice); scan = 0; ASC_DBG1(2, "asc_srch_pci_dev: type %d\n", pciDevice->type); } ret = asc_pci_find_dev(pciDevice); ASC_DBG1(2, "asc_srch_pci_dev: asc_pci_find_dev() return %d\n", ret); if (ret == PCI_DEVICE_FOUND) { pciDevice->slotNumber = pciDevice->slotFound + 1; pciDevice->startSlot = pciDevice->slotFound + 1; } else { if (pciDevice->bridge > pciDevice->busNumber) { ASC_DBG2(2, "asc_srch_pci_dev: bridge %x, busNumber %x\n", pciDevice->bridge, pciDevice->busNumber); pciDevice->busNumber++; pciDevice->slotNumber = 0; pciDevice->startSlot = 0; pciDevice->endSlot = 0x0f; ret = asc_srch_pci_dev(pciDevice); ASC_DBG1(2, "asc_srch_pci_dev recursive call return %d\n", ret); } } ASC_DBG1(2, "asc_srch_pci_dev: return %d\n", ret); return ret; } /* * Determine the access method to be used for 'pciDevice'. */ STATIC uchar asc_scan_method(PCI_DEVICE *pciDevice) { ushort data; PCI_DATA pciData; uchar type; uchar slot; ASC_DBG(2, "asc_scan_method: begin\n"); memset(&pciData, 0, sizeof(pciData)); for (type = 1; type < 3; type++) { pciData.type = type; for (slot = 0; slot < PCI_MAX_SLOT; slot++) { pciData.slot = slot; data = asc_get_cfg_word(&pciData); if ((data != 0xFFFF) && (data != 0x0000)) { ASC_DBG2(4, "asc_scan_method: data %x, type %d\n", data, type); return (type); } } } ASC_DBG1(4, "asc_scan_method: type %d\n", type); return (type); } /* * Check for an AdvanSys PCI device in 'pciDevice'. * * Return PCI_DEVICE_FOUND if found, otherwise return PCI_DEVICE_NOT_FOUND. */ STATIC int asc_pci_find_dev(PCI_DEVICE *pciDevice) { PCI_DATA pciData; ushort vendorid, deviceid; uchar classcode, subclass; uchar lslot; ASC_DBG(3, "asc_pci_find_dev: begin\n"); pciData.type = pciDevice->type; pciData.bus = pciDevice->busNumber; pciData.func = pciDevice->devFunc; lslot = pciDevice->startSlot; for (; lslot < pciDevice->endSlot; lslot++) { pciData.slot = lslot; pciData.offset = VENDORID_OFFSET; vendorid = asc_get_cfg_word(&pciData); ASC_DBG1(3, "asc_pci_find_dev: vendorid %x\n", vendorid); if (vendorid != 0xffff) { pciData.offset = DEVICEID_OFFSET; deviceid = asc_get_cfg_word(&pciData); ASC_DBG1(3, "asc_pci_find_dev: deviceid %x\n", deviceid); if ((vendorid == ASC_PCI_VENDORID) && ((deviceid == ASC_PCI_DEVICE_ID_REV_A) || (deviceid == ASC_PCI_DEVICE_ID_REV_B))) { pciDevice->slotFound = lslot; ASC_DBG(3, "asc_pci_find_dev: PCI_DEVICE_FOUND\n"); return PCI_DEVICE_FOUND; } else { pciData.offset = SUBCLASS_OFFSET; subclass = asc_get_cfg_byte(&pciData); pciData.offset = CLASSCODE_OFFSET; classcode = asc_get_cfg_byte(&pciData); if ((classcode & PCI_BASE_CLASS_BRIDGE_DEVICE) && (subclass & PCI_SUB_CLASS_PCI_TO_PCI_BRIDGE_CONTROLLER)) { pciDevice->bridge++; } ASC_DBG2(3, "asc_pci_find_dev: subclass %x, classcode %x\n", subclass, classcode); } } } return PCI_DEVICE_NOT_FOUND; } /* * Read PCI configuration data into 'pciConfig'. */ STATIC void asc_get_pci_cfg(PCI_DEVICE *pciDevice, PCI_CONFIG_SPACE *pciConfig) { PCI_DATA pciData; uchar counter; uchar *localConfig; ASC_DBG1(4, "asc_get_pci_cfg: slot found - %d\n ", pciDevice->slotFound); pciData.type = pciDevice->type; pciData.bus = pciDevice->busNumber; pciData.slot = pciDevice->slotFound; pciData.func = pciDevice->devFunc; localConfig = (uchar *) pciConfig; for (counter = 0; counter < sizeof(PCI_CONFIG_SPACE); counter++) { pciData.offset = counter; *localConfig = asc_get_cfg_byte(&pciData); ASC_DBG1(4, "asc_get_pci_cfg: byte %x\n", *localConfig); localConfig++; } ASC_DBG1(4, "asc_get_pci_cfg: counter %d\n", counter); } /* * Read a word (16 bits) from the PCI configuration space. * * The configuration mechanism is checked for the correct access method. */ STATIC ushort asc_get_cfg_word(PCI_DATA *pciData) { ushort tmp; ulong address; ulong lbus = pciData->bus; ulong lslot = pciData->slot; ulong lfunc = pciData->func; uchar t2CFA, t2CF8; ushort t1CF8, t1CFA, t1CFC, t1CFE; ASC_DBG4(4, "asc_get_cfg_word: type %d, bus %lu, slot %lu, func %lu\n", pciData->type, lbus, lslot, lfunc); /* * check type of configuration mechanism */ if (pciData->type == 2) { /* * save these registers so we can restore them after we are done */ t2CFA = inp(0xCFA); /* save PCI bus register */ t2CF8 = inp(0xCF8); /* save config space enable register */ /* * go out and write the bus and enable registers */ /* set for type 1 cycle, if needed */ outp(0xCFA, pciData->bus); /* set the function number */ outp(0xCF8, 0x10 | (pciData->func << 1)) ; /* * read the configuration space type 2 locations */ tmp = (ushort) inpw(0xC000 | ((pciData->slot << 8) + pciData->offset)); } else { /* * type 1 configuration mechanism * * save the CONFIG_ADDRESS and CONFIG_DATA register values */ t1CFC = inpw(0xCFC); t1CFE = inpw(0xCFE); t1CF8 = inpw(0xCF8); t1CFA = inpw(0xCFA); /* * enable <31>, bus = <23:16>, slot = <15:11>, * func = <10:8>, reg = <7:2> */ address = (ulong) ((lbus << 16) | (lslot << 11) | (lfunc << 8) | (pciData->offset & 0xFC) | 0x80000000L); /* * write out the address to CONFIG_ADDRESS */ outl(address, 0xCF8); /* * read in the word from CONFIG_DATA */ tmp = (ushort) ((inl(0xCFC) >> ((pciData->offset & 2) * 8)) & 0xFFFF); } ASC_DBG1(4, "asc_get_cfg_word: config data: %x\n", tmp); return tmp; } /* * Reads a byte from the PCI configuration space. * * The configuration mechanism is checked for the correct access method. */ STATIC uchar asc_get_cfg_byte(PCI_DATA *pciData) { uchar tmp; ulong address; ulong lbus = pciData->bus, lslot = pciData->slot, lfunc = pciData->func; uchar t2CFA, t2CF8; ushort t1CF8, t1CFA, t1CFC, t1CFE; ASC_DBG1(4, "asc_get_cfg_byte: type: %d\n", pciData->type); /* * check type of configuration mechanism */ if (pciData->type == 2) { /* * save these registers so we can restore them after we are done */ t2CFA = inp(0xCFA); /* save PCI bus register */ t2CF8 = inp(0xCF8); /* save config space enable register */ /* * go out and write the bus and enable registers */ /* set for type 1 cycle, if needed */ outp(0xCFA, pciData->bus); /* set the function number */ outp(0xCF8, 0x10 | (pciData->func << 1)); /* * read the configuration space type 2 locations */ tmp = inp(0xC000 | ((pciData->slot << 8) + pciData->offset)); /* * restore the registers used for our transaction */ outp(0xCF8, t2CF8); /* restore the enable register */ outp(0xCFA, t2CFA); /* restore PCI bus register */ } else { /* * type 1 configuration mechanism * * save the CONFIG_ADDRESS and CONFIG_DATA register values */ t1CFC = inpw(0xCFC); t1CFE = inpw(0xCFE); t1CF8 = inpw(0xCF8); t1CFA = inpw(0xCFA); /* * enable <31>, bus = <23:16>, slot = <15:11>, func = <10:8>, * reg = <7:2> */ address = (ulong) ((lbus << 16) | (lslot << 11) | (lfunc << 8) | (pciData->offset & 0xFC) | 0x80000000L); /* * write out the address to CONFIG_ADDRESS */ outl(address, 0xCF8); /* * read in the word from CONFIG_DATA */ tmp = (uchar) ((inl(0xCFC) >> ((pciData->offset & 3) * 8)) & 0xFF); } ASC_DBG1(4, "asc_get_cfg_byte: config data: %x\n", tmp); return tmp; } /* * Add a 'Scsi_Cmnd' to the end of specified 'Scsi_Host' * target device pending command list. Set 'pending_tidmask' * to indicate a command is queued for the device. * * 'flag' may be either ASC_FRONT or ASC_BACK. * * The 'Scsi_Cmnd' host_scribble field is used as a next pointer. */ STATIC void asc_enqueue(struct Scsi_Host *shp, Scsi_Cmnd *scp, int tid, int flag) { Scsi_Cmnd **scpp; ASC_ASSERT(interrupts_enabled() == ASC_FALSE); ASC_ASSERT(flag == ASC_FRONT || flag == ASC_BACK); ASC_STATS(enqueue); if (flag == ASC_FRONT) { scp->host_scribble = (unsigned char *) ASC_BOARD(shp)->pending[tid]; ASC_BOARD(shp)->pending[tid] = (Scsi_Cmnd *) scp; } else { /* ASC_BACK */ for (scpp = &ASC_BOARD(shp)->pending[tid]; *scpp; scpp = (Scsi_Cmnd **) &(*scpp)->host_scribble) { ; } *scpp = scp; scp->host_scribble = NULL; } ASC_BOARD(shp)->pending_tidmask |= ASC_TIX_TO_TARGET_ID(tid); } /* * Return first pending 'Scsi_Cmnd' on the specified 'Scsi_Host' * for the specified target device. Clear the 'pending_tidmask' * bit for the device if no more commands are left queued for it. * * The 'Scsi_Cmnd' host_scribble field is used as a next pointer. */ STATIC Scsi_Cmnd * asc_dequeue(struct Scsi_Host *shp, int tid) { Scsi_Cmnd *scp; ASC_STATS(dequeue); ASC_ASSERT(interrupts_enabled() == ASC_FALSE); if ((scp = ASC_BOARD(shp)->pending[tid]) != NULL) { ASC_BOARD(shp)->pending[tid] = (Scsi_Cmnd *) scp->host_scribble; } if (ASC_BOARD(shp)->pending[tid] == NULL) { ASC_BOARD(shp)->pending_tidmask &= ~ASC_TIX_TO_TARGET_ID(tid); } return scp; } /* * Remove the specified 'Scsi_Cmnd' from the specified 'Scsi_Host' * for the specified target device. Clear the 'pending_tidmask' * bit for the device if no more commands are left queued for it. * * The 'Scsi_Cmnd' host_scribble field is used as a next pointer. * * Return ASC_TRUE if the command was found and removed, otherwise * return ASC_FALSE if the command was not found. */ STATIC int asc_rmqueue(struct Scsi_Host *shp, Scsi_Cmnd *scp, int tid) { Scsi_Cmnd **scpp; int ret; ASC_ASSERT(interrupts_enabled() == ASC_FALSE); ret = ASC_FALSE; for (scpp = &ASC_BOARD(shp)->pending[tid]; *scpp; scpp = (Scsi_Cmnd **) &(*scpp)->host_scribble) { if (*scpp == scp) { *scpp = (Scsi_Cmnd *) scp->host_scribble; scp->host_scribble = NULL; ASC_STATS(rmqueue); ret = ASC_TRUE; } } if (ASC_BOARD(shp)->pending[tid] == NULL) { ASC_BOARD(shp)->pending_tidmask &= ~ASC_TIX_TO_TARGET_ID(tid); } return ret; } /* * --- Functions Required by the Asc Library */ /* * Delay for 'n' milliseconds. Don't use the 'jiffies' * global variable which is incremented once every 5 ms * from a timer interrupt, because this function may be * called when interrupts are disabled. */ void DvcSleepMilliSecond(ulong n) { ulong i; ASC_DBG1(4, "DvcSleepMilliSecond: %lu\n", n); for (i = 0; i < n; i++) { udelay(1000); } } void DvcDisplayString(uchar *s) { printk(s); } int DvcEnterCritical(void) { int flags; save_flags(flags); cli(); return flags; } void DvcLeaveCritical(int flags) { restore_flags(flags); } /* * Convert a virtual address to a virtual address. * * Apparently Linux is loaded V=R (virtual equals real). Just return * the virtual address. */ ulong DvcGetPhyAddr(uchar *buf_addr, ulong buf_len) { ulong phys_addr; phys_addr = (ulong) buf_addr; return phys_addr; } ulong DvcGetSGList(ASC_DVC_VAR *asc_dvc_sg, uchar *buf_addr, ulong buf_len, ASC_SG_HEAD *asc_sg_head_ptr) { ulong buf_size; buf_size = buf_len; asc_sg_head_ptr->entry_cnt = 1; asc_sg_head_ptr->sg_list[0].addr = (ulong) buf_addr; asc_sg_head_ptr->sg_list[0].bytes = buf_size; return buf_size; } /* * void * DvcPutScsiQ(PortAddr iop_base, ushort s_addr, ushort *outbuf, int words) * * Calling/Exit State: * none * * Description: * Output an ASC_SCSI_Q structure to the chip */ void DvcPutScsiQ(PortAddr iop_base, ushort s_addr, ushort *outbuf, int words) { int i; ASC_DBG_PRT_HEX(2, "DvcPutScsiQ", (uchar *) outbuf, 2 * words); AscSetChipLramAddr(iop_base, s_addr); for (i = 0; i < words; i++, outbuf++) { if (i == 2 || i == 10) { continue; } AscPutChipLramData(iop_base, *outbuf); } } /* * void * DvcGetQinfo(PortAddr iop_base, ushort s_addr, ushort *inbuf, int words) * * Calling/Exit State: * none * * Description: * Input an ASC_QDONE_INFO structure from the chip */ void DvcGetQinfo(PortAddr iop_base, ushort s_addr, ushort *inbuf, int words) { int i; AscSetChipLramAddr(iop_base, s_addr); for (i = 0; i < words; i++, inbuf++) { if (i == 5) { continue; } *inbuf = AscGetChipLramData(iop_base); } ASC_DBG_PRT_HEX(2, "DvcGetQinfo", (uchar *) inbuf, 2 * words); } /* * void DvcOutPortWords(ushort iop_base, ushort &outbuf, int words) * * Calling/Exit State: * none * * Description: * output a buffer to an i/o port address */ void DvcOutPortWords(ushort iop_base, ushort *outbuf, int words) { int i; for (i = 0; i < words; i++, outbuf++) outpw(iop_base, *outbuf); } /* * void DvcInPortWords(ushort iop_base, ushort &outbuf, int words) * * Calling/Exit State: * none * * Description: * input a buffer from an i/o port address */ void DvcInPortWords(ushort iop_base, ushort *inbuf, int words) { int i; for (i = 0; i < words; i++, inbuf++) *inbuf = inpw(iop_base); } /* * void DvcOutPortDWords(PortAddr port, ulong *pdw, int dwords) * * Calling/Exit State: * none * * Description: * output a buffer of 32-bit integers to an i/o port address in * 16 bit integer units */ void DvcOutPortDWords(PortAddr port, ulong *pdw, int dwords) { int i; int words; ushort *pw; pw = (ushort *) pdw; words = dwords << 1; for(i = 0; i < words; i++, pw++) { outpw(port, *pw); } return; } /* * --- Tracing and Debugging Functions */ #ifdef ADVANSYS_STATS #define ASC_PRT_STATS_NEXT() \ if (cp) { \ totlen += len; \ leftlen -= len; \ if (leftlen == 0) { \ return totlen; \ } \ cp += len; \ } /* * asc_prt_stats() * * Note: no single line should be greater than 160 characters, cf. * asc_prt_stats_line(). * * Return the number of characters copied into 'cp'. No more than * 'cplen' characters will be copied to 'cp'. */ STATIC int asc_prt_stats(char *cp, int cplen) { struct asc_stats *s; int leftlen; int totlen; int len; s = &asc_stats; leftlen = cplen; totlen = len = 0; len = asc_prt_stats_line(cp, leftlen, "\nAdvanSys SCSI Host Driver Statistics:\n"); ASC_PRT_STATS_NEXT(); len = asc_prt_stats_line(cp, leftlen, " command %lu, queuecommand %lu, abort %lu, reset %lu, biosparam %lu,\n", s->command, s->queuecommand, s->abort, s->reset, s->biosparam); ASC_PRT_STATS_NEXT(); len = asc_prt_stats_line(cp, leftlen, " interrupt %lu, callback %lu, cmd_disable %lu, intr_disable %lu,\n", s->interrupt, s->callback, s->cmd_disable, s->intr_disable); ASC_PRT_STATS_NEXT(); len = asc_prt_stats_line(cp, leftlen, " error %lu, enqueue %lu, dequeue %lu, rmqueue %lu,\n", s->error, s->enqueue, s->dequeue, s->rmqueue); ASC_PRT_STATS_NEXT(); if (s->cont_cnt > 0) { len = asc_prt_stats_line(cp, leftlen, " cont_cnt %lu, cont_xfer %lu: avg_xfer=%lu kb\n", s->cont_cnt, s->cont_xfer, (s->cont_xfer/2)/s->cont_cnt); ASC_PRT_STATS_NEXT(); } if (s->sg_cnt > 0) { len = asc_prt_stats_line(cp, leftlen, " sg_cnt %lu, sg_elem %lu, sg_xfer %lu: avg_elem=%lu, avg_size=%lu kb\n", s->sg_cnt, s->sg_elem, s->sg_xfer, s->sg_elem/s->sg_cnt, (s->sg_xfer/2)/s->sg_cnt); ASC_PRT_STATS_NEXT(); } return totlen; } /* * asc_prt_stats_line() * * If 'cp' is NULL print to the console, otherwise print to a buffer. * * Return 0 if printing to the console, otherwise return the number of * bytes written to the buffer. * * Note: If any single line is greater than 160 bytes the stack * will be corrupted. 's[]' is defined to be 160 bytes. */ int asc_prt_stats_line(char *buf, int buflen, char *fmt, ...) { va_list args; int ret; char s[160]; /* 2 lines */ va_start(args, fmt); ret = vsprintf(s, fmt, args); if (buf == NULL) { (void) printk(s); ret = 0; } else { ret = min(buflen, ret); memcpy(buf, s, ret); } va_end(args); return ret; } #endif /* ADVANSYS_STATS */ #ifdef ADVANSYS_DEBUG /* * asc_prt_scsi_host() */ STATIC void asc_prt_scsi_host(struct Scsi_Host *s) { printk("Scsi_Host at addr %x\n", (unsigned) s); printk( " next %x, extra_bytes %u, host_busy %u, host_no %d, last_reset %d,\n", (unsigned) s->next, s->extra_bytes, s->host_busy, s->host_no, s->last_reset); printk( " host_wait %x, host_queue %x, hostt %x, block %x,\n", (unsigned) s->host_wait, (unsigned) s->host_queue, (unsigned) s->hostt, (unsigned) s->block); printk( " wish_block %d, base %x, io_port %d, n_io_port %d, irq %d, dma_channel %d,\n", s->wish_block, (unsigned) s->base, s->io_port, s->n_io_port, s->irq, s->dma_channel); printk( " this_id %d, can_queue %d,\n", s->this_id, s->can_queue); printk( " cmd_per_lun %d, sg_tablesize %d, unchecked_isa_dma %d, loaded_as_module %d\n", s->cmd_per_lun, s->sg_tablesize, s->unchecked_isa_dma, s->loaded_as_module); printk("hostdata (struct asc_board)\n"); asc_prt_dvc_var(&ASC_BOARD(s)->board); asc_prt_dvc_cfg(&ASC_BOARD(s)->cfg); printk(" overrun_buf %x\n", (unsigned) &ASC_BOARD(s)->overrun_buf[0]); } /* * asc_prt_dvc_var() */ STATIC void asc_prt_dvc_var(ASC_DVC_VAR *h) { printk("ASC_DVC_VAR at addr %x\n", (unsigned) h); printk( " iop_base %x, err_code %x, dvc_cntl %x, bug_fix_cntl %d,\n", h->iop_base, h->err_code, h->dvc_cntl, h->bug_fix_cntl); printk( " bus_type %d, isr_callback %x, exe_callback %x, init_sdtr %x,\n", h->bus_type, (unsigned) h->isr_callback, (unsigned) h->exe_callback, (unsigned) h->init_sdtr); printk( " sdtr_done %x, use_tagged_qng %x, unit_not_ready %x, chip_no %x,\n", (unsigned) h->sdtr_done, (unsigned) h->use_tagged_qng, (unsigned) h->unit_not_ready, (unsigned) h->chip_no); printk( " queue_full_or_busy %x, start_motor %x, scsi_reset_wait %x, irq_no %x,\n", (unsigned) h->queue_full_or_busy, (unsigned) h->start_motor, (unsigned) h->scsi_reset_wait, (unsigned) h->irq_no); printk( " is_in_int %x, max_total_qng %x, cur_total_qng %x, in_critical_cnt %x,\n", (unsigned) h->is_in_int, (unsigned) h->max_total_qng, (unsigned) h->cur_total_qng, (unsigned) h->in_critical_cnt); printk( " last_q_shortage %x, init_state %x, no_scam %x, pci_fix_asyn_xfer %x,\n", (unsigned) h->last_q_shortage, (unsigned) h->init_state, (unsigned) h->no_scam, (unsigned) h->pci_fix_asyn_xfer); printk( " int_count %ld, req_count %ld, busy_count %ld, cfg %x, saved_ptr2func %x\n", h->int_count, h->req_count, h->busy_count, (unsigned) h->cfg, (unsigned) h->saved_ptr2func); } /* * asc_prt_dvc_cfg() */ STATIC void asc_prt_dvc_cfg(ASC_DVC_CFG *h) { printk("ASC_DVC_CFG at addr %x\n", (unsigned) h); printk( " can_tagged_qng %x, cmd_qng_enabled %x, disc_enable %x, res %x,\n", h->can_tagged_qng, h->cmd_qng_enabled, h->disc_enable, h->res); printk( " chip_scsi_id %d, isa_dma_speed %d, isa_dma_channel %d, chip_version %d,\n", h->chip_scsi_id, h->isa_dma_speed, h->isa_dma_channel, h->chip_version); printk( " pci_device_id %d, lib_serial_no %d, lib_version %d, mcode_date %d,\n", h->pci_device_id, h->lib_serial_no, h->lib_version, h->mcode_date); printk( " mcode_version %d, overrun_buf %x\n", h->mcode_version, (unsigned) h->overrun_buf); } /* * asc_prt_scsi_q() */ STATIC void asc_prt_scsi_q(ASC_SCSI_Q *q) { ASC_SG_HEAD *sgp; int i; printk("ASC_SCSI_Q at addr %x\n", (unsigned) q); printk( " target_ix %u, target_lun %u, srb_ptr %x, tag_code %u,\n", q->q2.target_ix, q->q1.target_lun, (unsigned) q->q2.srb_ptr, q->q2.tag_code); printk( " data_addr %x, data_cnt %lu, sense_addr %x, sense_len %u,\n", (unsigned) q->q1.data_addr, q->q1.data_cnt, (unsigned) q->q1.sense_addr, q->q1.sense_len); printk( " cdbptr %x, cdb_len %u, sg_head %x, sg_queue_cnt %u\n", (unsigned) q->cdbptr, q->q2.cdb_len, (unsigned) q->sg_head, q->q1.sg_queue_cnt); if (q->sg_head) { sgp = q->sg_head; printk("ASC_SG_HEAD at addr %x\n", (unsigned) sgp); printk(" entry_cnt %u, queue_cnt %u\n", sgp->entry_cnt, sgp->queue_cnt); for (i = 0; i < sgp->entry_cnt; i++) { printk(" [%u]: addr %x, bytes %lu\n", i, (unsigned) sgp->sg_list[i].addr, sgp->sg_list[i].bytes); } } } /* * asc_prt_qdone_info() */ STATIC void asc_prt_qdone_info(ASC_QDONE_INFO *q) { printk("ASC_QDONE_INFO at addr %x\n", (unsigned) q); printk( " srb_ptr %x, target_ix %u, cdb_len %u, tag_code %u, done_stat %x\n", (unsigned) q->d2.srb_ptr, q->d2.target_ix, q->d2.cdb_len, q->d2.tag_code, q->d3.done_stat); printk( " host_stat %x, scsi_stat %x, scsi_msg %x\n", q->d3.host_stat, q->d3.scsi_stat, q->d3.scsi_msg); } /* * asc_prt_hex() * * Print hexadecimal output in 4 byte groupings 32 bytes * or 8 double-words per line. */ STATIC void asc_prt_hex(char *f, uchar *s, int l) { int i; int j; int k; int m; printk("%s: (%d bytes)\n", f, l); for (i = 0; i < l; i += 32) { /* Display a maximum of 8 double-words per line. */ if ((k = (l - i) / 4) >= 8) { k = 8; m = 0; } else { m = (l - i) % 4 ; } for (j = 0; j < k; j++) { printk(" %2.2X%2.2X%2.2X%2.2X", (unsigned) s[i+(j*4)], (unsigned) s[i+(j*4)+1], (unsigned) s[i+(j*4)+2], (unsigned) s[i+(j*4)+3]); } switch (m) { case 0: default: break; case 1: printk(" %2.2X", (unsigned) s[i+(j*4)+4]); break; case 2: printk(" %2.2X%2.2X", (unsigned) s[i+(j*4)+4], (unsigned) s[i+(j*4)+5]); break; case 3: printk(" %2.2X%2.2X%2.2X", (unsigned) s[i+(j*4)+4], (unsigned) s[i+(j*4)+5], (unsigned) s[i+(j*4)+6]); break; } printk("\n"); } } /* * interrupts_enabled() * * Return 1 if interrupts are enabled, otherwise return 0. */ STATIC int interrupts_enabled(void) { int flags; save_flags(flags); if (flags & 0x0200) { return ASC_TRUE; } else { return ASC_FALSE; } } #endif /* ADVANSYS_DEBUG */ /* * --- Asc Library Functions */ ushort AscGetEisaChipCfg( PortAddr iop_base ) { PortAddr eisa_cfg_iop; eisa_cfg_iop = (PortAddr) ASC_GET_EISA_SLOT(iop_base) | (PortAddr) (ASC_EISA_CFG_IOP_MASK); return (inpw(eisa_cfg_iop)); } uchar AscSetChipScsiID( PortAddr iop_base, uchar new_host_id ) { ushort cfg_lsw; if (AscGetChipScsiID(iop_base) == new_host_id) { return (new_host_id); } cfg_lsw = AscGetChipCfgLsw(iop_base); cfg_lsw &= 0xF8FF; cfg_lsw |= (ushort) ((new_host_id & ASC_MAX_TID) << 8); AscSetChipCfgLsw(iop_base, cfg_lsw); return (AscGetChipScsiID(iop_base)); } ushort AscGetChipBiosAddress( PortAddr iop_base, ushort bus_type ) { ushort cfg_lsw; ushort bios_addr; if ((bus_type & ASC_IS_EISA) != 0) { cfg_lsw = AscGetEisaChipCfg(iop_base); cfg_lsw &= 0x000F; bios_addr = (ushort) (ASC_BIOS_MIN_ADDR + (cfg_lsw * ASC_BIOS_BANK_SIZE)); return (bios_addr); } cfg_lsw = AscGetChipCfgLsw(iop_base); bios_addr = (ushort) (((cfg_lsw >> 12) * ASC_BIOS_BANK_SIZE) + ASC_BIOS_MIN_ADDR); return (bios_addr); } uchar AscGetChipVersion( PortAddr iop_base, ushort bus_type ) { if ((bus_type & ASC_IS_EISA) != 0) { PortAddr eisa_iop; uchar revision; eisa_iop = (PortAddr) ASC_GET_EISA_SLOT(iop_base) | (PortAddr) ASC_EISA_REV_IOP_MASK; revision = inp(eisa_iop); return ((uchar) ((ASC_CHIP_MIN_VER_EISA - 1) + revision)); } return (AscGetChipVerNo(iop_base)); } ushort AscGetChipBusType( PortAddr iop_base ) { ushort chip_ver; chip_ver = AscGetChipVerNo(iop_base); if ((chip_ver >= ASC_CHIP_MIN_VER_VL) && (chip_ver <= ASC_CHIP_MAX_VER_VL)) { if (((iop_base & 0x0C30) == 0x0C30) || ((iop_base & 0x0C50) == 0x0C50)) { return (ASC_IS_EISA); } return (ASC_IS_VL); } else if ((chip_ver >= ASC_CHIP_MIN_VER_ISA) && (chip_ver <= ASC_CHIP_MAX_VER_ISA)) { if (chip_ver >= ASC_CHIP_MIN_VER_ISA_PNP) { return (ASC_IS_ISAPNP); } return (ASC_IS_ISA); } else if ((chip_ver >= ASC_CHIP_MIN_VER_PCI) && (chip_ver <= ASC_CHIP_MAX_VER_PCI)) { return (ASC_IS_PCI); } else { return (0); } } void AscEnableIsaDma( uchar dma_channel ) { if (dma_channel < 4) { outp(0x000B, (ushort) (0xC0 | dma_channel)); outp(0x000A, dma_channel); } else if (dma_channel < 8) { outp(0x00D6, (ushort) (0xC0 | (dma_channel - 4))); outp(0x00D4, (ushort) (dma_channel - 4)); } return; } ulong AscLoadMicroCode( PortAddr iop_base, ushort s_addr, ushort dosfar * mcode_buf, ushort mcode_size ) { ulong chksum; ushort mcode_word_size; ushort mcode_chksum; mcode_word_size = (ushort) (mcode_size >> 1); AscMemWordSetLram(iop_base, s_addr, 0, mcode_word_size); AscMemWordCopyToLram(iop_base, s_addr, mcode_buf, mcode_word_size); chksum = AscMemSumLramWord(iop_base, s_addr, mcode_word_size); mcode_chksum = (ushort) AscMemSumLramWord(iop_base, (ushort) ASC_CODE_SEC_BEG, (ushort) ((mcode_size - s_addr - (ushort) ASC_CODE_SEC_BEG) / 2)); AscWriteLramWord(iop_base, ASCV_MCODE_CHKSUM_W, mcode_chksum); AscWriteLramWord(iop_base, ASCV_MCODE_SIZE_W, mcode_size); return (chksum); } uchar _hextbl_[16] = {'0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F'}; uchar _isa_pnp_inited = 0; PortAddr _asc_def_iop_base[ASC_IOADR_TABLE_MAX_IX] = { 0x100, ASC_IOADR_1, 0x120, ASC_IOADR_2, 0x140, ASC_IOADR_3, ASC_IOADR_4, ASC_IOADR_5, ASC_IOADR_6, ASC_IOADR_7, ASC_IOADR_8 }; PortAddr AscSearchIOPortAddr( PortAddr iop_beg, ushort bus_type ) { if (bus_type & ASC_IS_VL) { while ((iop_beg = AscSearchIOPortAddr11(iop_beg)) != 0) { if (AscGetChipVersion(iop_beg, bus_type) <= ASC_CHIP_MAX_VER_VL) { return (iop_beg); } } return (0); } if (bus_type & ASC_IS_ISA) { if (_isa_pnp_inited == 0) { AscSetISAPNPWaitForKey(); _isa_pnp_inited++; } while ((iop_beg = AscSearchIOPortAddr11(iop_beg)) != 0) { if ((AscGetChipVersion(iop_beg, bus_type) & ASC_CHIP_VER_ISA_BIT) != 0) { return (iop_beg); } } return (0); } if (bus_type & ASC_IS_EISA) { if ((iop_beg = AscSearchIOPortAddrEISA(iop_beg)) != 0) { return (iop_beg); } return (0); } return (0); } PortAddr AscSearchIOPortAddr11( PortAddr s_addr ) { int i; PortAddr iop_base; for (i = 0; i < ASC_IOADR_TABLE_MAX_IX; i++) { if (_asc_def_iop_base[i] > s_addr) { break; } } for (; i < ASC_IOADR_TABLE_MAX_IX; i++) { iop_base = _asc_def_iop_base[i]; if (AscFindSignature(iop_base)) { return (iop_base); } } return (0); } int AscFindSignature( PortAddr iop_base ) { ushort sig_word; if ((inp((PortAddr) (iop_base + 1)) & 0xFF) == (uchar) ASC_1000_ID1B) { sig_word = inpw(iop_base); if ((sig_word == (ushort) ASC_1000_ID0W) || (sig_word == (ushort) ASC_1000_ID0W_FIX)) { return (1); } } return (0); } void AscToggleIRQAct( PortAddr iop_base ) { AscSetChipStatus(iop_base, CIW_IRQ_ACT); AscSetChipStatus(iop_base, 0); return; } #if CC_INIT_INQ_DISPLAY #endif void AscSetISAPNPWaitForKey( void) { outp(ASC_ISA_PNP_PORT_ADDR, 0x02); outp(ASC_ISA_PNP_PORT_WRITE, 0x02); return; } uchar AscGetChipIRQ( PortAddr iop_base, ushort bus_type ) { ushort cfg_lsw; uchar chip_irq; if ((bus_type & ASC_IS_EISA) != 0) { cfg_lsw = AscGetEisaChipCfg(iop_base); chip_irq = (uchar) (((cfg_lsw >> 8) & 0x07) + 10); if ((chip_irq == 13) || (chip_irq > 15)) { return (0); } return (chip_irq); } else { cfg_lsw = AscGetChipCfgLsw(iop_base); if ((bus_type & ASC_IS_VL) != 0) { chip_irq = (uchar) (((cfg_lsw >> 2) & 0x07)); if ((chip_irq == 0) || (chip_irq == 4) || (chip_irq == 7)) { return (0); } return ((uchar) (chip_irq + (ASC_MIN_IRQ_NO - 1))); } chip_irq = (uchar) (((cfg_lsw >> 2) & 0x03)); if (chip_irq == 3) chip_irq += (uchar) 2; return ((uchar) (chip_irq + ASC_MIN_IRQ_NO)); } } uchar AscSetChipIRQ( PortAddr iop_base, uchar irq_no, ushort bus_type ) { ushort cfg_lsw; if ((bus_type & ASC_IS_VL) != 0) { if (irq_no != 0) { if ((irq_no < ASC_MIN_IRQ_NO) || (irq_no > ASC_MAX_IRQ_NO)) { irq_no = 0; } else { irq_no -= (uchar) ((ASC_MIN_IRQ_NO - 1)); } } cfg_lsw = (ushort) (AscGetChipCfgLsw(iop_base) & 0xFFE3); cfg_lsw |= (ushort) 0x0010; AscSetChipCfgLsw(iop_base, cfg_lsw); AscToggleIRQAct(iop_base); cfg_lsw = (ushort) (AscGetChipCfgLsw(iop_base) & 0xFFE0); cfg_lsw |= (ushort) ((irq_no & 0x07) << 2); AscSetChipCfgLsw(iop_base, cfg_lsw); AscToggleIRQAct(iop_base); return (AscGetChipIRQ(iop_base, bus_type)); } else if ((bus_type & (ASC_IS_ISA)) != 0) { if (irq_no == 15) irq_no -= (uchar) 2; irq_no -= (uchar) ASC_MIN_IRQ_NO; cfg_lsw = (ushort) (AscGetChipCfgLsw(iop_base) & 0xFFF3); cfg_lsw |= (ushort) ((irq_no & 0x03) << 2); AscSetChipCfgLsw(iop_base, cfg_lsw); return (AscGetChipIRQ(iop_base, bus_type)); } else { return (0); } } uchar AscGetChipScsiCtrl( PortAddr iop_base ) { uchar sc; AscSetBank(iop_base, 1); sc = inp(iop_base + IOP_REG_SC); AscSetBank(iop_base, 0); return (sc); } extern uchar _sdtr_period_tbl_[]; int AscIsrChipHalted( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { SDTR_XMSG sdtr_xmsg; SDTR_XMSG out_msg; ushort halt_q_addr; int sdtr_accept; ushort int_halt_code; ASC_SCSI_BIT_ID_TYPE scsi_busy; ASC_SCSI_BIT_ID_TYPE target_id; PortAddr iop_base; uchar tag_code; uchar q_status; uchar halt_qp; uchar sdtr_data; uchar target_ix; uchar q_cntl, tid_no; uchar cur_dvc_qng; uchar asyn_sdtr; uchar scsi_status; iop_base = asc_dvc->iop_base; int_halt_code = AscReadLramWord(iop_base, ASCV_HALTCODE_W); halt_qp = AscReadLramByte(iop_base, ASCV_CURCDB_B); halt_q_addr = ASC_QNO_TO_QADDR(halt_qp); target_ix = AscReadLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_TARGET_IX)); q_cntl = AscReadLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_CNTL)); tid_no = ASC_TIX_TO_TID(target_ix); target_id = (uchar) ASC_TID_TO_TARGET_ID(tid_no); if (asc_dvc->pci_fix_asyn_xfer & target_id) { asyn_sdtr = ASYN_SDTR_DATA_FIX_PCI_REV_AB; } else { asyn_sdtr = 0; } if (int_halt_code == ASC_HALT_EXTMSG_IN) { AscMemWordCopyFromLram(iop_base, ASCV_MSGIN_BEG, (ushort dosfar *) & sdtr_xmsg, (ushort) (sizeof (SDTR_XMSG) >> 1)); if ((sdtr_xmsg.msg_type == MS_EXTEND) && (sdtr_xmsg.msg_len == MS_SDTR_LEN)) { sdtr_accept = TRUE; if (sdtr_xmsg.msg_req == MS_SDTR_CODE) { if (sdtr_xmsg.req_ack_offset > ASC_SYN_MAX_OFFSET) { sdtr_accept = FALSE; sdtr_xmsg.req_ack_offset = ASC_SYN_MAX_OFFSET; } sdtr_data = AscCalSDTRData(sdtr_xmsg.xfer_period, sdtr_xmsg.req_ack_offset); if (sdtr_xmsg.req_ack_offset == 0) { q_cntl &= ~QC_MSG_OUT; asc_dvc->init_sdtr &= ~target_id; asc_dvc->sdtr_done &= ~target_id; AscSetChipSDTR(iop_base, asyn_sdtr, tid_no); } else if ((sdtr_data == 0xFF)) { q_cntl |= QC_MSG_OUT; asc_dvc->init_sdtr &= ~target_id; asc_dvc->sdtr_done &= ~target_id; AscSetChipSDTR(iop_base, asyn_sdtr, tid_no); } else { if (sdtr_accept && (q_cntl & QC_MSG_OUT)) { q_cntl &= ~QC_MSG_OUT; asc_dvc->sdtr_done |= target_id; asc_dvc->init_sdtr |= target_id; asc_dvc->pci_fix_asyn_xfer &= ~target_id; AscSetChipSDTR(iop_base, sdtr_data, tid_no); } else { q_cntl |= QC_MSG_OUT; AscMsgOutSDTR(iop_base, sdtr_xmsg.xfer_period, sdtr_xmsg.req_ack_offset); asc_dvc->pci_fix_asyn_xfer &= ~target_id; AscSetChipSDTR(iop_base, sdtr_data, tid_no); asc_dvc->sdtr_done |= target_id; asc_dvc->init_sdtr |= target_id; } } AscWriteLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_CNTL), q_cntl); AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0); return (0); } } } else if (int_halt_code == ASC_HALT_CHK_CONDITION) { q_cntl |= QC_REQ_SENSE; if (((asc_dvc->init_sdtr & target_id) != 0) && ((asc_dvc->sdtr_done & target_id) != 0)) { sdtr_data = AscReadLramByte(iop_base, (ushort) ((ushort) ASCV_SDTR_DATA_BEG + (ushort) tid_no)); AscMsgOutSDTR(iop_base, _sdtr_period_tbl_[(sdtr_data >> 4) & (uchar) (ASC_SYN_XFER_NO - 1)], (uchar) (sdtr_data & (uchar) ASC_SYN_MAX_OFFSET)); q_cntl |= QC_MSG_OUT; } AscWriteLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_CNTL), q_cntl); tag_code = AscReadLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_TAG_CODE)); tag_code &= 0xDC; AscWriteLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_TAG_CODE), tag_code); q_status = AscReadLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_STATUS)); q_status |= (QS_READY | QS_BUSY); AscWriteLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_STATUS), q_status); scsi_busy = AscReadLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B); scsi_busy &= ~target_id; AscWriteLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B, scsi_busy); AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0); return (0); } else if (int_halt_code == ASC_HALT_SDTR_REJECTED) { AscMemWordCopyFromLram(iop_base, ASCV_MSGOUT_BEG, (ushort dosfar *) & out_msg, (ushort) (sizeof (SDTR_XMSG) >> 1)); if ((out_msg.msg_type == MS_EXTEND) && (out_msg.msg_len == MS_SDTR_LEN) && (out_msg.msg_req == MS_SDTR_CODE)) { asc_dvc->init_sdtr &= ~target_id; asc_dvc->sdtr_done &= ~target_id; AscSetChipSDTR(iop_base, asyn_sdtr, tid_no); } else { } q_cntl &= ~QC_MSG_OUT; AscWriteLramByte(iop_base, (ushort) (halt_q_addr + (ushort) ASC_SCSIQ_B_CNTL), q_cntl); AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0); return (0); } else if (int_halt_code == ASC_HALT_SS_QUEUE_FULL) { scsi_status = AscReadLramByte(iop_base, (ushort) ((ushort) halt_q_addr + (ushort) ASC_SCSIQ_SCSI_STATUS)); cur_dvc_qng = AscReadLramByte(iop_base, (ushort) ((ushort) ASC_QADR_BEG + (ushort) target_ix)); if ((cur_dvc_qng > 0) && (asc_dvc->cur_dvc_qng[tid_no] > 0)) { scsi_busy = AscReadLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B); scsi_busy |= target_id; AscWriteLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B, scsi_busy); asc_dvc->queue_full_or_busy |= target_id; if (scsi_status == SS_QUEUE_FULL) { if (cur_dvc_qng > ASC_MIN_TAGGED_CMD) { cur_dvc_qng -= 1; asc_dvc->max_dvc_qng[tid_no] = cur_dvc_qng; AscWriteLramByte(iop_base, (ushort) ((ushort) ASCV_MAX_DVC_QNG_BEG + (ushort) tid_no), cur_dvc_qng); } } } AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0); return (0); } return (0); } uchar _AscCopyLramScsiDoneQ( PortAddr iop_base, ushort q_addr, ASC_QDONE_INFO dosfar * scsiq, ulong max_dma_count ) { ushort _val; uchar sg_queue_cnt; DvcGetQinfo(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_DONE_INFO_BEG), (ushort dosfar *) scsiq, (ushort) ((sizeof (ASC_SCSIQ_2) + sizeof (ASC_SCSIQ_3)) / 2)); #if !CC_LITTLE_ENDIAN_HOST AscAdjEndianQDoneInfo(scsiq); #endif _val = AscReadLramWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_STATUS)); scsiq->q_status = (uchar) _val; scsiq->q_no = (uchar) (_val >> 8); _val = AscReadLramWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_CNTL)); scsiq->cntl = (uchar) _val; sg_queue_cnt = (uchar) (_val >> 8); _val = AscReadLramWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_SENSE_LEN)); scsiq->sense_len = (uchar) _val; scsiq->user_def = (uchar) (_val >> 8); scsiq->remain_bytes = AscReadLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_DW_REMAIN_XFER_CNT)); scsiq->remain_bytes &= max_dma_count; return (sg_queue_cnt); } int AscIsrQDone( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { uchar next_qp; uchar i; uchar n_q_used; uchar sg_list_qp; uchar sg_queue_cnt; uchar done_q_tail; uchar tid_no; ASC_SCSI_BIT_ID_TYPE scsi_busy; ASC_SCSI_BIT_ID_TYPE target_id; PortAddr iop_base; ushort q_addr; ushort sg_q_addr; uchar cur_target_qng; ASC_QDONE_INFO scsiq_buf; ASC_QDONE_INFO dosfar *scsiq; int false_overrun; ASC_ISR_CALLBACK asc_isr_callback; uchar tag_code; #if CC_LINK_BUSY_Q ushort n_busy_q_done; #endif iop_base = asc_dvc->iop_base; asc_isr_callback = (ASC_ISR_CALLBACK) asc_dvc->isr_callback; n_q_used = 1; scsiq = (ASC_QDONE_INFO dosfar *) & scsiq_buf; done_q_tail = (uchar) AscGetVarDoneQTail(iop_base); q_addr = ASC_QNO_TO_QADDR(done_q_tail); next_qp = AscReadLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_FWD)); if (next_qp != ASC_QLINK_END) { AscPutVarDoneQTail(iop_base, next_qp); q_addr = ASC_QNO_TO_QADDR(next_qp); sg_queue_cnt = _AscCopyLramScsiDoneQ(iop_base, q_addr, scsiq, asc_dvc->max_dma_count); AscWriteLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_STATUS), (uchar) (scsiq->q_status & (uchar) ~ (QS_READY | QS_ABORTED))); tid_no = ASC_TIX_TO_TID(scsiq->d2.target_ix); target_id = ASC_TIX_TO_TARGET_ID(scsiq->d2.target_ix); if ((scsiq->cntl & QC_SG_HEAD) != 0) { sg_q_addr = q_addr; sg_list_qp = next_qp; for (i = 0; i < sg_queue_cnt; i++) { sg_list_qp = AscReadLramByte(iop_base, (ushort) (sg_q_addr + (ushort) ASC_SCSIQ_B_FWD)); sg_q_addr = ASC_QNO_TO_QADDR(sg_list_qp); if (sg_list_qp == ASC_QLINK_END) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_SG_Q_LINKS); scsiq->d3.done_stat = QD_WITH_ERROR; scsiq->d3.host_stat = QHSTA_D_QDONE_SG_LIST_CORRUPTED; goto FATAL_ERR_QDONE; } AscWriteLramByte(iop_base, (ushort) (sg_q_addr + (ushort) ASC_SCSIQ_B_STATUS), QS_FREE); } n_q_used = sg_queue_cnt + 1; AscPutVarDoneQTail(iop_base, sg_list_qp); } if (asc_dvc->queue_full_or_busy & target_id) { cur_target_qng = AscReadLramByte(iop_base, (ushort) ((ushort) ASC_QADR_BEG + (ushort) scsiq->d2.target_ix)); if (cur_target_qng < asc_dvc->max_dvc_qng[tid_no]) { scsi_busy = AscReadLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B); scsi_busy &= ~target_id; AscWriteLramByte(iop_base, (ushort) ASCV_SCSIBUSY_B, scsi_busy); asc_dvc->queue_full_or_busy &= ~target_id; } } if (asc_dvc->cur_total_qng >= n_q_used) { asc_dvc->cur_total_qng -= n_q_used; if (asc_dvc->cur_dvc_qng[tid_no] != 0) { asc_dvc->cur_dvc_qng[tid_no]--; } } else { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_CUR_QNG); scsiq->d3.done_stat = QD_WITH_ERROR; goto FATAL_ERR_QDONE; } if ((scsiq->d2.srb_ptr == 0UL) || ((scsiq->q_status & QS_ABORTED) != 0)) { return (0x11); } else if (scsiq->q_status == QS_DONE) { false_overrun = FALSE; if (asc_dvc->bug_fix_cntl) { if (asc_dvc->bug_fix_cntl & ASC_BUG_FIX_ADD_ONE_BYTE) { tag_code = AscReadLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_TAG_CODE)); if (tag_code & ASC_TAG_FLAG_ADD_ONE_BYTE) { if (scsiq->remain_bytes != 0UL) { scsiq->remain_bytes--; if (scsiq->remain_bytes == 0UL) { false_overrun = TRUE; } } } } } if ((scsiq->d3.done_stat == QD_WITH_ERROR) && (scsiq->d3.host_stat == QHSTA_M_DATA_OVER_RUN)) { if ((scsiq->cntl & (QC_DATA_IN | QC_DATA_OUT)) == 0) { scsiq->d3.done_stat = QD_NO_ERROR; scsiq->d3.host_stat = QHSTA_NO_ERROR; } else if (false_overrun) { scsiq->d3.done_stat = QD_NO_ERROR; scsiq->d3.host_stat = QHSTA_NO_ERROR; } } #if CC_CLEAR_LRAM_SRB_PTR AscWriteLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_D_SRBPTR), asc_dvc->int_count); #endif if ((scsiq->cntl & QC_NO_CALLBACK) == 0) { (*asc_isr_callback) (asc_dvc, scsiq); } else { if ((AscReadLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_CDB_BEG)) == SCSICMD_StartStopUnit)) { asc_dvc->unit_not_ready &= ~target_id; if (scsiq->d3.done_stat != QD_NO_ERROR) { asc_dvc->start_motor &= ~target_id; } } } #if CC_LINK_BUSY_Q n_busy_q_done = AscIsrExeBusyQueue(asc_dvc, tid_no); if (n_busy_q_done == 0) { i = tid_no + 1; while (TRUE) { if (i > ASC_MAX_TID) i = 0; if (i == tid_no) break; n_busy_q_done = AscIsrExeBusyQueue(asc_dvc, i); if (n_busy_q_done != 0) break; i++; } } if (n_busy_q_done == 0xFFFF) return (0x80); #endif return (1); } else { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_Q_STATUS); FATAL_ERR_QDONE: if ((scsiq->cntl & QC_NO_CALLBACK) == 0) { (*asc_isr_callback) (asc_dvc, scsiq); } return (0x80); } } return (0); } int AscISR( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { ASC_CS_TYPE chipstat; PortAddr iop_base; ushort saved_ram_addr; uchar ctrl_reg; uchar saved_ctrl_reg; int int_pending; int status; uchar host_flag; iop_base = asc_dvc->iop_base; int_pending = FALSE; asc_dvc->int_count++; if (((asc_dvc->init_state & ASC_INIT_STATE_END_LOAD_MC) == 0) || (asc_dvc->isr_callback == 0)) { return (ERR); } if (asc_dvc->in_critical_cnt != 0) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_ISR_ON_CRITICAL); return (ERR); } if (asc_dvc->is_in_int) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_ISR_RE_ENTRY); asc_dvc->busy_count++; return (ERR); } asc_dvc->is_in_int = TRUE; ctrl_reg = AscGetChipControl(iop_base); saved_ctrl_reg = ctrl_reg & (~(CC_SCSI_RESET | CC_CHIP_RESET | CC_SINGLE_STEP | CC_DIAG | CC_TEST)); if ((chipstat = AscGetChipStatus(iop_base)) & CSW_INT_PENDING) { int_pending = TRUE; AscAckInterrupt(iop_base); host_flag = AscReadLramByte(iop_base, ASCV_HOST_FLAG_B); AscWriteLramByte(iop_base, ASCV_HOST_FLAG_B, (uchar) (host_flag | (uchar) ASC_HOST_FLAG_IN_ISR)); saved_ram_addr = AscGetChipLramAddr(iop_base); if ((chipstat & CSW_HALTED) && (ctrl_reg & CC_SINGLE_STEP)) { if (AscIsrChipHalted(asc_dvc) == ERR) { goto ISR_REPORT_QDONE_FATAL_ERROR; } else { saved_ctrl_reg &= ~CC_HALT; } } else { ISR_REPORT_QDONE_FATAL_ERROR: if ((asc_dvc->dvc_cntl & ASC_CNTL_INT_MULTI_Q) != 0) { while (((status = AscIsrQDone(asc_dvc)) & 0x01) != 0) { } } else { do { if ((status = AscIsrQDone(asc_dvc)) == 1) { break; } } while (status == 0x11); } if ((status & 0x80) != 0) int_pending = ERR; } AscSetChipLramAddr(iop_base, saved_ram_addr); if (AscGetChipLramAddr(iop_base) != saved_ram_addr) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_SET_LRAM_ADDR); } AscWriteLramByte(iop_base, ASCV_HOST_FLAG_B, host_flag); } AscSetChipControl(iop_base, saved_ctrl_reg); asc_dvc->is_in_int = FALSE; return (int_pending); } int AscScsiSetupCmdQ( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, uchar dosfar * buf_addr, ulong buf_len ) { ulong phy_addr; scsiq->r1.cntl = 0; scsiq->r1.sg_queue_cnt = 0; scsiq->r1.q_no = 0; scsiq->r1.user_def = 0; scsiq->cdbptr = (uchar dosfar *) scsiq->cdb; scsiq->r3.scsi_stat = 0; scsiq->r3.scsi_msg = 0; scsiq->r3.host_stat = 0; scsiq->r3.done_stat = 0; scsiq->r2.vm_id = 0; scsiq->r1.data_cnt = buf_len; scsiq->r2.tag_code = (uchar) M2_QTAG_MSG_SIMPLE; scsiq->r2.flag = (uchar) ASC_FLAG_SCSIQ_REQ; scsiq->r2.srb_ptr = (ulong) scsiq; scsiq->r1.status = (uchar) QS_READY; scsiq->r1.data_addr = 0L; if (buf_len != 0L) { if ((phy_addr = AscGetOnePhyAddr(asc_dvc, (uchar dosfar *) buf_addr, scsiq->r1.data_cnt)) == 0L) { return (ERR); } scsiq->r1.data_addr = phy_addr; } return (0); } uchar _mcode_buf[] = { 0x01, 0x03, 0x01, 0x19, 0x0F, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0F, 0x0F, 0x0F, 0x0F, 0x0F, 0x0F, 0x0F, 0x0F, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 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0x02, 0x01, 0x09, 0xD8, 0xCD, 0x04, 0x4D, 0x00, 0x00, 0xA3, 0xDC, 0x00, 0x68, 0x97, 0x7F, 0x23, 0x04, 0x61, 0x84, 0x01, 0xB2, 0x84, 0xCF, 0xC1, 0x80, 0x73, 0xCD, 0x04, 0x4D, 0x00, 0x00, 0xA3, 0xE8, 0x01, 0x68, 0x97, 0xD4, 0x81, 0x00, 0x33, 0x02, 0x00, 0x82, 0x88, 0x80, 0x73, 0x80, 0x77, 0x00, 0x01, 0x01, 0xA1, 0x08, 0x01, 0x4F, 0x00, 0x46, 0x97, 0x07, 0xA6, 0x12, 0x01, 0x00, 0x33, 0x03, 0x00, 0x82, 0x88, 0x03, 0x03, 0x03, 0xDE, 0x00, 0x33, 0x05, 0x00, 0x82, 0x88, 0xCE, 0x00, 0x69, 0x60, 0xCE, 0x00, 0x02, 0x03, 0x4A, 0x60, 0x00, 0xA2, 0x86, 0x01, 0x80, 0x63, 0x07, 0xA6, 0x32, 0x01, 0x86, 0x81, 0x03, 0x03, 0x80, 0x63, 0xE2, 0x00, 0x07, 0xA6, 0x42, 0x01, 0x00, 0x33, 0x04, 0x00, 0x82, 0x88, 0x03, 0x07, 0x02, 0x01, 0x04, 0xCA, 0x0D, 0x23, 0x2A, 0x98, 0x4D, 0x04, 0xD0, 0x84, 0x05, 0xD8, 0x0D, 0x23, 0x2A, 0x98, 0xCD, 0x04, 0x15, 0x23, 0xB8, 0x88, 0xFB, 0x23, 0x02, 0x61, 0x82, 0x01, 0x80, 0x63, 0x02, 0x03, 0x06, 0xA3, 0x70, 0x01, 0x00, 0x33, 0x0A, 0x00, 0x82, 0x88, 0x4E, 0x00, 0x07, 0xA3, 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0x72, 0x04, 0x00, 0x01, 0xF1, 0x00, 0x70, 0x00, 0x80, 0x01, 0x70, 0x04, 0x71, 0x00, 0x80, 0x01, 0x72, 0x00, 0x81, 0x01, 0x71, 0x04, 0x70, 0x00, 0x81, 0x01, 0x70, 0x04, 0x00, 0x63, 0x00, 0x23, 0xB3, 0x01, 0x83, 0x05, 0xA3, 0x01, 0xA2, 0x01, 0xA1, 0x01, 0x01, 0x23, 0xA0, 0x01, 0x00, 0x01, 0xC8, 0x00, 0x03, 0xA1, 0x86, 0x07, 0x00, 0x33, 0x07, 0x00, 0x82, 0x88, 0x80, 0x05, 0x81, 0x05, 0x04, 0x01, 0x11, 0xC8, 0x48, 0x00, 0xB0, 0x01, 0xB1, 0x01, 0x08, 0x23, 0xB2, 0x01, 0x05, 0x01, 0x48, 0x04, 0x00, 0x43, 0x00, 0xA2, 0xA6, 0x07, 0x00, 0x05, 0x9C, 0x87, 0x00, 0x01, 0xC8, 0x00, 0xFF, 0x23, 0x80, 0x01, 0x05, 0x05, 0x00, 0x63, 0xF7, 0x04, 0x1A, 0x09, 0xF6, 0x08, 0x6E, 0x04, 0x00, 0x02, 0x80, 0x43, 0x76, 0x08, 0x80, 0x02, 0x77, 0x04, 0x00, 0x63, 0xF7, 0x04, 0x1A, 0x09, 0xF6, 0x08, 0x6E, 0x04, 0x00, 0x02, 0x00, 0xA0, 0xD6, 0x07, 0xD8, 0x87, 0x00, 0x43, 0x76, 0x08, 0x80, 0x02, 0x77, 0x04, 0x00, 0x63, 0xF3, 0x04, 0x00, 0x23, 0xF4, 0x00, 0x74, 0x00, 0x80, 0x43, 0xF4, 0x00, 0xCF, 0x40, 0x00, 0xA2, 0x06, 0x08, 0x74, 0x04, 0x02, 0x01, 0xF7, 0xC9, 0xF6, 0xD9, 0x00, 0x01, 0x01, 0xA1, 0xE6, 0x07, 0xC6, 0x97, 0xF4, 0x94, 0xE6, 0x87, 0x73, 0x04, 0x00, 0x63, 0xF3, 0x04, 0x75, 0x04, 0x1C, 0x88, 0x02, 0x01, 0x04, 0xD8, 0x08, 0x97, 0xC6, 0x97, 0xF4, 0x94, 0x0C, 0x88, 0x75, 0x00, 0x00, 0xA3, 0x26, 0x08, 0x00, 0x05, 0x10, 0x88, 0x73, 0x04, 0x00, 0x63, 0x80, 0x7B, 0x80, 0x63, 0x06, 0xA6, 0x38, 0x08, 0x00, 0x33, 0x3E, 0x00, 0x82, 0x88, 0x80, 0x67, 0x83, 0x03, 0x80, 0x63, 0x00, 0x63, 0x38, 0x2B, 0x5E, 0x88, 0x38, 0x2B, 0x54, 0x88, 0x32, 0x09, 0x31, 0x05, 0x54, 0x98, 0x05, 0x05, 0xB2, 0x09, 0x00, 0x63, 0x00, 0x32, 0x00, 0x36, 0x00, 0x3A, 0x00, 0x3E, 0x00, 0x63, 0x80, 0x32, 0x80, 0x36, 0x80, 0x3A, 0x80, 0x3E, 0x00, 0x63, 0x38, 0x2B, 0x40, 0x32, 0x40, 0x36, 0x40, 0x3A, 0x40, 0x3E, 0x00, 0x63, 0x5A, 0x20, 0xC9, 0x40, 0x00, 0xA0, 0x74, 0x08, 0x5D, 0x00, 0xFE, 0xC3, 0x00, 0x63, 0x80, 0x73, 0xE6, 0x20, 0x02, 0x23, 0xE8, 0x00, 0x82, 0x73, 0xFF, 0xFD, 0x80, 0x73, 0x13, 0x23, 0xB8, 0x88, 0x66, 0x20, 0xC0, 0x20, 0x04, 0x23, 0xA0, 0x01, 0xA1, 0x23, 0xA1, 0x01, 0x81, 0x62, 0xA2, 0x88, 0x80, 0x73, 0x80, 0x77, 0x68, 0x00, 0x00, 0xA2, 0x80, 0x00, 0x03, 0xC2, 0xF1, 0xC7, 0x41, 0x23, 0xB8, 0x88, 0x11, 0x23, 0xA1, 0x01, 0x04, 0x23, 0xA0, 0x01, 0xB2, 0x84, }; ushort _mcode_size = sizeof (_mcode_buf); ulong _mcode_chksum = 0x012258FBUL; extern uchar _sdtr_period_tbl_[]; int AscExeScsiQueue( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_Q dosfar * scsiq ) { PortAddr iop_base; int last_int_level; int sta; ulong addr; uchar sg_entry_cnt; uchar target_ix; int n_q_required; uchar sg_entry_cnt_minus_one; uchar tid_no; uchar sdtr_data; ASC_EXE_CALLBACK asc_exe_callback; #if CC_DEBUG_SG_LIST int i; #endif #if CC_LINK_BUSY_Q ASC_SCSI_Q dosfar *scsiq_tail; ASC_SCSI_Q dosfar *scsiq_next; ASC_SCSI_Q dosfar *scsiq_prev; #endif iop_base = asc_dvc->iop_base; asc_exe_callback = (ASC_EXE_CALLBACK) asc_dvc->exe_callback; if (asc_dvc->err_code != 0) return (ERR); if (scsiq == (ASC_SCSI_Q dosfar *) 0L) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_SCSIQ_NULL_PTR); return (ERR); } scsiq->q1.q_no = 0; sta = 0; target_ix = scsiq->q2.target_ix; tid_no = ASC_TIX_TO_TID(target_ix); n_q_required = 1; if (scsiq->cdbptr[0] == SCSICMD_RequestSense) { if (((asc_dvc->init_sdtr & scsiq->q1.target_id) != 0) && ((asc_dvc->sdtr_done & scsiq->q1.target_id) != 0)) { sdtr_data = AscReadLramByte(iop_base, (ushort) ((ushort) ASCV_SDTR_DATA_BEG + (ushort) tid_no)); AscMsgOutSDTR(iop_base, _sdtr_period_tbl_[(sdtr_data >> 4) & (uchar) (ASC_SYN_XFER_NO - 1)], (uchar) (sdtr_data & (uchar) ASC_SYN_MAX_OFFSET)); scsiq->q1.cntl |= (QC_MSG_OUT | QC_URGENT); } } last_int_level = DvcEnterCritical(); if (asc_dvc->in_critical_cnt != 0) { DvcLeaveCritical(last_int_level); AscSetLibErrorCode(asc_dvc, ASCQ_ERR_CRITICAL_RE_ENTRY); return (ERR); } asc_dvc->in_critical_cnt++; if ((scsiq->q1.cntl & QC_SG_HEAD) != 0) { if ((sg_entry_cnt = scsiq->sg_head->entry_cnt) == 0) { asc_dvc->in_critical_cnt--; DvcLeaveCritical(last_int_level); return (ERR); } if (sg_entry_cnt == 1) { scsiq->q1.data_addr = scsiq->sg_head->sg_list[0].addr; scsiq->q1.data_cnt = scsiq->sg_head->sg_list[0].bytes; scsiq->q1.cntl &= ~(QC_SG_HEAD | QC_SG_SWAP_QUEUE); goto NON_SG_LIST_REQ; } if (sg_entry_cnt > ASC_MAX_SG_LIST) { return (ERR); } sg_entry_cnt_minus_one = sg_entry_cnt - 1; #if CC_DEBUG_SG_LIST if (asc_dvc->bus_type & (ASC_IS_ISA | ASC_IS_VL | ASC_IS_EISA)) { for (i = 0; i < sg_entry_cnt_minus_one; i++) { addr = scsiq->sg_head->sg_list[i].addr + scsiq->sg_head->sg_list[i].bytes; if (((ushort) addr & 0x0003) != 0) { asc_dvc->in_critical_cnt--; DvcLeaveCritical(last_int_level); AscSetLibErrorCode(asc_dvc, ASCQ_ERR_SG_LIST_ODD_ADDRESS); return (ERR); } } } #endif if (asc_dvc->bug_fix_cntl) { if (asc_dvc->bug_fix_cntl & ASC_BUG_FIX_ADD_ONE_BYTE) { addr = scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].addr + scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].bytes; if (((ushort) addr & 0x0003) != 0) { if ((scsiq->cdbptr[0] == SCSICMD_Read6) || (scsiq->cdbptr[0] == SCSICMD_Read10)) { if ((scsiq->q2.tag_code & ASC_TAG_FLAG_ADD_ONE_BYTE) == 0) { scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].bytes++; scsiq->q2.tag_code |= ASC_TAG_FLAG_ADD_ONE_BYTE; } } } } } scsiq->sg_head->entry_to_copy = scsiq->sg_head->entry_cnt; n_q_required = AscSgListToQueue(sg_entry_cnt); #if CC_LINK_BUSY_Q scsiq_next = (ASC_SCSI_Q dosfar *) asc_dvc->scsiq_busy_head[tid_no]; if (scsiq_next != (ASC_SCSI_Q dosfar *) 0L) { goto link_scisq_to_busy_list; } #endif if ((AscGetNumOfFreeQueue(asc_dvc, target_ix, n_q_required) >= (uint) n_q_required) || ((scsiq->q1.cntl & QC_URGENT) != 0)) { if ((sta = AscSendScsiQueue(asc_dvc, scsiq, n_q_required)) == 1) { asc_dvc->in_critical_cnt--; if (asc_exe_callback != 0) { (*asc_exe_callback) (asc_dvc, scsiq); } DvcLeaveCritical(last_int_level); return (sta); } } } else { NON_SG_LIST_REQ: if (asc_dvc->bug_fix_cntl) { if (asc_dvc->bug_fix_cntl & ASC_BUG_FIX_ADD_ONE_BYTE) { addr = scsiq->q1.data_addr + scsiq->q1.data_cnt; if ((scsiq->cdbptr[0] == SCSICMD_Read6) || (scsiq->cdbptr[0] == SCSICMD_Read10)) { if (((ushort) addr & 0x0003) != 0) { if (((ushort) scsiq->q1.data_cnt & 0x01FF) == 0) { if ((scsiq->q2.tag_code & ASC_TAG_FLAG_ADD_ONE_BYTE) == 0) { scsiq->q2.tag_code |= ASC_TAG_FLAG_ADD_ONE_BYTE; scsiq->q1.data_cnt++; } } } } } } n_q_required = 1; #if CC_LINK_BUSY_Q scsiq_next = (ASC_SCSI_Q dosfar *) asc_dvc->scsiq_busy_head[tid_no]; if (scsiq_next != (ASC_SCSI_Q dosfar *) 0L) { goto link_scisq_to_busy_list; } #endif if ((AscGetNumOfFreeQueue(asc_dvc, target_ix, 1) >= 1) || ((scsiq->q1.cntl & QC_URGENT) != 0)) { if ((sta = AscSendScsiQueue(asc_dvc, scsiq, n_q_required)) == 1) { asc_dvc->in_critical_cnt--; if (asc_exe_callback != 0) { (*asc_exe_callback) (asc_dvc, scsiq); } DvcLeaveCritical(last_int_level); return (sta); } } } #if CC_LINK_BUSY_Q if (sta == 0) { link_scisq_to_busy_list: scsiq->ext.q_required = n_q_required; if (scsiq_next == (ASC_SCSI_Q dosfar *) 0L) { asc_dvc->scsiq_busy_head[tid_no] = (ASC_SCSI_Q dosfar *) scsiq; asc_dvc->scsiq_busy_tail[tid_no] = (ASC_SCSI_Q dosfar *) scsiq; scsiq->ext.next = (ASC_SCSI_Q dosfar *) 0L; scsiq->ext.join = (ASC_SCSI_Q dosfar *) 0L; scsiq->q1.status = QS_BUSY; sta = 1; } else { scsiq_tail = (ASC_SCSI_Q dosfar *) asc_dvc->scsiq_busy_tail[tid_no]; if (scsiq_tail->ext.next == (ASC_SCSI_Q dosfar *) 0L) { if ((scsiq->q1.cntl & QC_URGENT) != 0) { asc_dvc->scsiq_busy_head[tid_no] = (ASC_SCSI_Q dosfar *) scsiq; scsiq->ext.next = scsiq_next; scsiq->ext.join = (ASC_SCSI_Q dosfar *) 0L; } else { if (scsiq->ext.cntl & QCX_SORT) { do { scsiq_prev = scsiq_next; scsiq_next = scsiq_next->ext.next; if (scsiq->ext.lba < scsiq_prev->ext.lba) break; } while (scsiq_next != (ASC_SCSI_Q dosfar *) 0L); scsiq_prev->ext.next = scsiq; scsiq->ext.next = scsiq_next; if (scsiq_next == (ASC_SCSI_Q dosfar *) 0L) { asc_dvc->scsiq_busy_tail[tid_no] = (ASC_SCSI_Q dosfar *) scsiq; } scsiq->ext.join = (ASC_SCSI_Q dosfar *) 0L; } else { scsiq_tail->ext.next = (ASC_SCSI_Q dosfar *) scsiq; asc_dvc->scsiq_busy_tail[tid_no] = (ASC_SCSI_Q dosfar *) scsiq; scsiq->ext.next = (ASC_SCSI_Q dosfar *) 0L; scsiq->ext.join = (ASC_SCSI_Q dosfar *) 0L; } } scsiq->q1.status = QS_BUSY; sta = 1; } else { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_SCSIQ_BAD_NEXT_PTR); sta = ERR; } } } #endif asc_dvc->in_critical_cnt--; DvcLeaveCritical(last_int_level); return (sta); } int AscSendScsiQueue( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_Q dosfar * scsiq, uchar n_q_required ) { PortAddr iop_base; uchar free_q_head; uchar next_qp; uchar tid_no; uchar target_ix; int sta; iop_base = asc_dvc->iop_base; target_ix = scsiq->q2.target_ix; tid_no = ASC_TIX_TO_TID(target_ix); sta = 0; free_q_head = (uchar) AscGetVarFreeQHead(iop_base); if (n_q_required > 1) { if ((next_qp = AscAllocMultipleFreeQueue(iop_base, free_q_head, (uchar) (n_q_required))) != (uchar) ASC_QLINK_END) { asc_dvc->last_q_shortage = 0; scsiq->sg_head->queue_cnt = n_q_required - 1; scsiq->q1.q_no = free_q_head; if ((sta = AscPutReadySgListQueue(asc_dvc, scsiq, free_q_head)) == 1) { #if CC_WRITE_IO_COUNT asc_dvc->req_count++; #endif AscPutVarFreeQHead(iop_base, next_qp); asc_dvc->cur_total_qng += (uchar) (n_q_required); asc_dvc->cur_dvc_qng[tid_no]++; } return (sta); } } else if (n_q_required == 1) { if ((next_qp = AscAllocFreeQueue(iop_base, free_q_head)) != ASC_QLINK_END) { scsiq->q1.q_no = free_q_head; if ((sta = AscPutReadyQueue(asc_dvc, scsiq, free_q_head)) == 1) { #if CC_WRITE_IO_COUNT asc_dvc->req_count++; #endif AscPutVarFreeQHead(iop_base, next_qp); asc_dvc->cur_total_qng++; asc_dvc->cur_dvc_qng[tid_no]++; } return (sta); } } return (sta); } int AscSgListToQueue( int sg_list ) { int n_sg_list_qs; n_sg_list_qs = ((sg_list - 1) / ASC_SG_LIST_PER_Q); if (((sg_list - 1) % ASC_SG_LIST_PER_Q) != 0) n_sg_list_qs++; return (n_sg_list_qs + 1); } uint AscGetNumOfFreeQueue( ASC_DVC_VAR asc_ptr_type * asc_dvc, uchar target_ix, uchar n_qs ) { uint cur_used_qs; uint cur_free_qs; ASC_SCSI_BIT_ID_TYPE target_id; uchar tid_no; target_id = ASC_TIX_TO_TARGET_ID(target_ix); tid_no = ASC_TIX_TO_TID(target_ix); if ((asc_dvc->unit_not_ready & target_id) || (asc_dvc->queue_full_or_busy & target_id)) { return (0); } if (n_qs == 1) { cur_used_qs = (uint) asc_dvc->cur_total_qng + (uint) asc_dvc->last_q_shortage + (uint) ASC_MIN_FREE_Q; } else { cur_used_qs = (uint) asc_dvc->cur_total_qng + (uint) ASC_MIN_FREE_Q; } if ((uint) (cur_used_qs + n_qs) <= (uint) asc_dvc->max_total_qng) { cur_free_qs = (uint) asc_dvc->max_total_qng - cur_used_qs; if (asc_dvc->cur_dvc_qng[tid_no] >= asc_dvc->max_dvc_qng[tid_no]) { return (0); } return (cur_free_qs); } if (n_qs > 1) { if (n_qs > asc_dvc->last_q_shortage) { asc_dvc->last_q_shortage = n_qs; } } return (0); } int AscPutReadyQueue( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_Q dosfar * scsiq, uchar q_no ) { ushort q_addr; uchar tid_no; uchar sdtr_data; uchar syn_period_ix; uchar syn_offset; PortAddr iop_base; iop_base = asc_dvc->iop_base; if (((asc_dvc->init_sdtr & scsiq->q1.target_id) != 0) && ((asc_dvc->sdtr_done & scsiq->q1.target_id) == 0)) { tid_no = ASC_TIX_TO_TID(scsiq->q2.target_ix); sdtr_data = AscReadLramByte(iop_base, (ushort) ((ushort) ASCV_SDTR_DATA_BEG + (ushort) tid_no)); syn_period_ix = (sdtr_data >> 4) & (ASC_SYN_XFER_NO - 1); syn_offset = sdtr_data & ASC_SYN_MAX_OFFSET; AscMsgOutSDTR(iop_base, _sdtr_period_tbl_[syn_period_ix], syn_offset); scsiq->q1.cntl |= QC_MSG_OUT; } q_addr = ASC_QNO_TO_QADDR(q_no); if ((scsiq->q1.target_id & asc_dvc->use_tagged_qng) == 0) { scsiq->q2.tag_code &= ~M2_QTAG_MSG_SIMPLE; } scsiq->q1.status = QS_FREE; AscMemWordCopyToLram(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_CDB_BEG), (ushort dosfar *) scsiq->cdbptr, (ushort) ((ushort) scsiq->q2.cdb_len >> 1)); #if !CC_LITTLE_ENDIAN_HOST AscAdjEndianScsiQ(scsiq); #endif DvcPutScsiQ(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_CPY_BEG), (ushort dosfar *) & scsiq->q1.cntl, (ushort) ((((sizeof (ASC_SCSIQ_1) + sizeof (ASC_SCSIQ_2)) / 2) - 1))); #if CC_WRITE_IO_COUNT AscWriteLramWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_W_REQ_COUNT), (ushort) asc_dvc->req_count); #endif #if CC_VERIFY_LRAM_COPY if ((asc_dvc->dvc_cntl & ASC_CNTL_NO_VERIFY_COPY) == 0) { if (AscMemWordCmpToLram(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_CDB_BEG), (ushort dosfar *) scsiq->cdbptr, (ushort) (scsiq->q2.cdb_len >> 1)) != 0) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_LOCAL_MEM); return (ERR); } if (AscMemWordCmpToLram(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_CPY_BEG), (ushort dosfar *) & scsiq->q1.cntl, (ushort) (((sizeof (ASC_SCSIQ_1) + sizeof (ASC_SCSIQ_2)) / 2) - 1)) != 0) { AscSetLibErrorCode(asc_dvc, ASCQ_ERR_LOCAL_MEM); return (ERR); } } #endif #if CC_CLEAR_DMA_REMAIN AscWriteLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_DW_REMAIN_XFER_ADDR), 0UL); AscWriteLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_DW_REMAIN_XFER_CNT), 0UL); #endif AscWriteLramWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_STATUS), (ushort) (((ushort) scsiq->q1.q_no << 8) | (ushort) QS_READY)); return (1); } int AscPutReadySgListQueue( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_Q dosfar * scsiq, uchar q_no ) { uchar sg_list_dwords; uchar sg_index, i; uchar sg_entry_cnt; uchar next_qp; ushort q_addr; int sta; ASC_SG_HEAD dosfar *sg_head; ASC_SG_LIST_Q scsi_sg_q; ulong saved_data_addr; ulong saved_data_cnt; PortAddr iop_base; iop_base = asc_dvc->iop_base; sg_head = scsiq->sg_head; saved_data_addr = scsiq->q1.data_addr; saved_data_cnt = scsiq->q1.data_cnt; scsiq->q1.data_addr = sg_head->sg_list[0].addr; scsiq->q1.data_cnt = sg_head->sg_list[0].bytes; sg_entry_cnt = sg_head->entry_cnt - 1; if (sg_entry_cnt != 0) { scsiq->q1.cntl |= QC_SG_HEAD; q_addr = ASC_QNO_TO_QADDR(q_no); sg_index = 1; scsiq->q1.sg_queue_cnt = sg_head->queue_cnt; scsi_sg_q.sg_head_qp = q_no; scsi_sg_q.cntl = QCSG_SG_XFER_LIST; for (i = 0; i < sg_head->queue_cnt; i++) { scsi_sg_q.seq_no = i + 1; if (sg_entry_cnt > ASC_SG_LIST_PER_Q) { sg_list_dwords = (uchar) (ASC_SG_LIST_PER_Q * 2); sg_entry_cnt -= ASC_SG_LIST_PER_Q; if (i == 0) { scsi_sg_q.sg_list_cnt = ASC_SG_LIST_PER_Q; scsi_sg_q.sg_cur_list_cnt = ASC_SG_LIST_PER_Q; } else { scsi_sg_q.sg_list_cnt = ASC_SG_LIST_PER_Q - 1; scsi_sg_q.sg_cur_list_cnt = ASC_SG_LIST_PER_Q - 1; } } else { scsi_sg_q.cntl |= QCSG_SG_XFER_END; sg_list_dwords = sg_entry_cnt << 1; if (i == 0) { scsi_sg_q.sg_list_cnt = sg_entry_cnt; scsi_sg_q.sg_cur_list_cnt = sg_entry_cnt; } else { scsi_sg_q.sg_list_cnt = sg_entry_cnt - 1; scsi_sg_q.sg_cur_list_cnt = sg_entry_cnt - 1; } sg_entry_cnt = 0; } next_qp = AscReadLramByte(iop_base, (ushort) (q_addr + ASC_SCSIQ_B_FWD)); scsi_sg_q.q_no = next_qp; q_addr = ASC_QNO_TO_QADDR(next_qp); AscMemWordCopyToLram(iop_base, (ushort) (q_addr + ASC_SCSIQ_SGHD_CPY_BEG), (ushort dosfar *) & scsi_sg_q, (ushort) (sizeof (ASC_SG_LIST_Q) >> 1)); AscMemDWordCopyToLram(iop_base, (ushort) (q_addr + ASC_SGQ_LIST_BEG), (ulong dosfar *) & sg_head->sg_list[sg_index], (ushort) sg_list_dwords); sg_index += ASC_SG_LIST_PER_Q; } } else { scsiq->q1.cntl &= ~QC_SG_HEAD; } sta = AscPutReadyQueue(asc_dvc, scsiq, q_no); scsiq->q1.data_addr = saved_data_addr; scsiq->q1.data_cnt = saved_data_cnt; return (sta); } int AscAbortSRB( ASC_DVC_VAR asc_ptr_type * asc_dvc, ulong srb_ptr ) { int sta; ASC_SCSI_BIT_ID_TYPE saved_unit_not_ready; PortAddr iop_base; iop_base = asc_dvc->iop_base; sta = ERR; saved_unit_not_ready = asc_dvc->unit_not_ready; asc_dvc->unit_not_ready = 0xFF; AscWaitISRDone(asc_dvc); if (AscStopQueueExe(iop_base) == 1) { if (AscRiscHaltedAbortSRB(asc_dvc, srb_ptr) == 1) { sta = 1; AscCleanUpBusyQueue(iop_base); AscStartQueueExe(iop_base); } else { sta = 0; AscStartQueueExe(iop_base); } } asc_dvc->unit_not_ready = saved_unit_not_ready; return (sta); } int AscResetDevice( ASC_DVC_VAR asc_ptr_type * asc_dvc, uchar target_ix ) { PortAddr iop_base; int sta; uchar tid_no; ASC_SCSI_BIT_ID_TYPE target_id; int i; ASC_SCSI_REQ_Q scsiq_buf; ASC_SCSI_REQ_Q dosfar *scsiq; uchar dosfar *buf; ASC_SCSI_BIT_ID_TYPE saved_unit_not_ready; iop_base = asc_dvc->iop_base; tid_no = ASC_TIX_TO_TID(target_ix); target_id = ASC_TID_TO_TARGET_ID(tid_no); saved_unit_not_ready = asc_dvc->unit_not_ready; asc_dvc->unit_not_ready = target_id; sta = ERR; AscWaitTixISRDone(asc_dvc, target_ix); if (AscStopQueueExe(iop_base) == 1) { if (AscRiscHaltedAbortTIX(asc_dvc, target_ix) == 1) { AscCleanUpBusyQueue(iop_base); AscStartQueueExe(iop_base); AscWaitTixISRDone(asc_dvc, target_ix); sta = TRUE; scsiq = (ASC_SCSI_REQ_Q dosfar *) & scsiq_buf; buf = (uchar dosfar *) & scsiq_buf; for (i = 0; i < sizeof (ASC_SCSI_REQ_Q); i++) { *buf++ = 0x00; } scsiq->r1.status = (uchar) QS_READY; scsiq->r2.cdb_len = 6; scsiq->r2.tag_code = M2_QTAG_MSG_SIMPLE; scsiq->r1.target_id = target_id; scsiq->r2.target_ix = ASC_TIDLUN_TO_IX(tid_no, 0); scsiq->cdbptr = (uchar dosfar *) scsiq->cdb; scsiq->r1.cntl = QC_NO_CALLBACK | QC_MSG_OUT | QC_URGENT; AscWriteLramByte(asc_dvc->iop_base, ASCV_MSGOUT_BEG, M1_BUS_DVC_RESET); asc_dvc->unit_not_ready &= ~target_id; asc_dvc->sdtr_done |= target_id; if (AscExeScsiQueue(asc_dvc, (ASC_SCSI_Q dosfar *) scsiq) == 1) { asc_dvc->unit_not_ready = target_id; DvcSleepMilliSecond(1000); _AscWaitQDone(iop_base, (ASC_SCSI_Q dosfar *) scsiq); if (AscStopQueueExe(iop_base) == 1) { AscCleanUpDiscQueue(iop_base); AscStartQueueExe(iop_base); if (asc_dvc->pci_fix_asyn_xfer & target_id) { AscSetRunChipSynRegAtID(iop_base, tid_no, ASYN_SDTR_DATA_FIX_PCI_REV_AB); } AscWaitTixISRDone(asc_dvc, target_ix); } } else { sta = 0; } asc_dvc->sdtr_done &= ~target_id; } else { sta = ERR; AscStartQueueExe(iop_base); } } asc_dvc->unit_not_ready = saved_unit_not_ready; return (sta); } int AscResetSB( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { int sta; int i; PortAddr iop_base; iop_base = asc_dvc->iop_base; asc_dvc->unit_not_ready = 0xFF; sta = TRUE; AscWaitISRDone(asc_dvc); AscStopQueueExe(iop_base); asc_dvc->sdtr_done = 0; AscResetChipAndScsiBus(iop_base); DvcSleepMilliSecond((ulong) ((ushort) asc_dvc->scsi_reset_wait * 1000)); #if CC_SCAM if (!(asc_dvc->dvc_cntl & ASC_CNTL_NO_SCAM)) { AscSCAM(asc_dvc); } #endif AscReInitLram(asc_dvc); for (i = 0; i <= ASC_MAX_TID; i++) { asc_dvc->cur_dvc_qng[i] = 0; if (asc_dvc->pci_fix_asyn_xfer & (0x01 << i)) { AscSetChipSynRegAtID(iop_base, i, ASYN_SDTR_DATA_FIX_PCI_REV_AB); } } asc_dvc->err_code = 0; AscSetPCAddr(iop_base, ASC_MCODE_START_ADDR); if (AscGetPCAddr(iop_base) != ASC_MCODE_START_ADDR) { sta = ERR; } if (AscStartChip(iop_base) == 0) { sta = ERR; } AscStartQueueExe(iop_base); asc_dvc->unit_not_ready = 0; asc_dvc->queue_full_or_busy = 0; return (sta); } int AscSetRunChipSynRegAtID( PortAddr iop_base, uchar tid_no, uchar sdtr_data ) { int sta = FALSE; if (AscHostReqRiscHalt(iop_base)) { sta = AscSetChipSynRegAtID(iop_base, tid_no, sdtr_data); AscStartChip(iop_base); return (sta); } return (sta); } int AscSetChipSynRegAtID( PortAddr iop_base, uchar id, uchar sdtr_data ) { AscSetBank(iop_base, 1); AscWriteChipScsiID(iop_base, id); if (AscReadChipScsiID(iop_base) != (0x01 << id)) { return (FALSE); } AscSetBank(iop_base, 0); AscWriteChipSyn(iop_base, sdtr_data); if (AscReadChipSyn(iop_base) != sdtr_data) { return (FALSE); } return (TRUE); } int AscReInitLram( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { AscInitLram(asc_dvc); AscInitQLinkVar(asc_dvc); return (0); } ushort AscInitLram( ASC_DVC_VAR asc_ptr_type * asc_dvc) { uchar i; ushort s_addr; PortAddr iop_base; ushort warn_code; iop_base = asc_dvc->iop_base; warn_code = 0; AscMemWordSetLram(iop_base, ASC_QADR_BEG, 0, (ushort) (((int) (asc_dvc->max_total_qng + 2 + 1) * 64) >> 1) ); i = ASC_MIN_ACTIVE_QNO; s_addr = ASC_QADR_BEG + ASC_QBLK_SIZE; AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_FWD), (uchar) (i + 1)); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_BWD), (uchar) (asc_dvc->max_total_qng)); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_QNO), (uchar) i); i++; s_addr += ASC_QBLK_SIZE; for (; i < asc_dvc->max_total_qng; i++, s_addr += ASC_QBLK_SIZE) { AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_FWD), (uchar) (i + 1)); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_BWD), (uchar) (i - 1)); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_QNO), (uchar) i); } AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_FWD), (uchar) ASC_QLINK_END); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_BWD), (uchar) (asc_dvc->max_total_qng - 1)); AscWriteLramByte(iop_base, (ushort) (s_addr + ASC_SCSIQ_B_QNO), (uchar) asc_dvc->max_total_qng); i++; s_addr += ASC_QBLK_SIZE; for (; i <= (uchar) (asc_dvc->max_total_qng + 3); i++, s_addr += ASC_QBLK_SIZE) { AscWriteLramByte(iop_base, (ushort) (s_addr + (ushort) ASC_SCSIQ_B_FWD), i); AscWriteLramByte(iop_base, (ushort) (s_addr + (ushort) ASC_SCSIQ_B_BWD), i); AscWriteLramByte(iop_base, (ushort) (s_addr + (ushort) ASC_SCSIQ_B_QNO), i); } return (warn_code); } ushort AscInitQLinkVar( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { PortAddr iop_base; int i; ushort lram_addr; iop_base = asc_dvc->iop_base; AscPutRiscVarFreeQHead(iop_base, 1); AscPutRiscVarDoneQTail(iop_base, asc_dvc->max_total_qng); AscPutVarFreeQHead(iop_base, 1); AscPutVarDoneQTail(iop_base, asc_dvc->max_total_qng); AscWriteLramByte(iop_base, ASCV_BUSY_QHEAD_B, (uchar) ((int) asc_dvc->max_total_qng + 1)); AscWriteLramByte(iop_base, ASCV_DISC1_QHEAD_B, (uchar) ((int) asc_dvc->max_total_qng + 2)); AscWriteLramByte(iop_base, (ushort) ASCV_TOTAL_READY_Q_B, asc_dvc->max_total_qng); AscWriteLramWord(iop_base, ASCV_ASCDVC_ERR_CODE_W, 0); AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0); AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, 0); AscWriteLramByte(iop_base, ASCV_SCSIBUSY_B, 0); AscWriteLramByte(iop_base, ASCV_WTM_FLAG_B, 0); AscWriteLramByte(iop_base, (ushort) ASCV_CDBCNT_B, 0); lram_addr = ASC_QADR_BEG; for (i = 0; i < 32; i++, lram_addr += 2) { AscWriteLramWord(iop_base, lram_addr, 0); } return (0); } int AscSetLibErrorCode( ASC_DVC_VAR asc_ptr_type * asc_dvc, ushort err_code ) { if (asc_dvc->err_code == 0) { asc_dvc->err_code = err_code; AscWriteLramWord(asc_dvc->iop_base, ASCV_ASCDVC_ERR_CODE_W, err_code); } return (err_code); } int _AscWaitQDone( PortAddr iop_base, ASC_SCSI_Q dosfar * scsiq ) { ushort q_addr; uchar q_status; int count = 0; while (scsiq->q1.q_no == 0) ; q_addr = ASC_QNO_TO_QADDR(scsiq->q1.q_no); do { q_status = AscReadLramByte(iop_base, q_addr + ASC_SCSIQ_B_STATUS); DvcSleepMilliSecond(100L); if (count++ > 30) { return (0); } } while ((q_status & QS_READY) != 0); return (1); } uchar _sdtr_period_tbl_[ASC_SYN_XFER_NO] = { SYN_XFER_NS_0, SYN_XFER_NS_1, SYN_XFER_NS_2, SYN_XFER_NS_3, SYN_XFER_NS_4, SYN_XFER_NS_5, SYN_XFER_NS_6, SYN_XFER_NS_7}; uchar AscMsgOutSDTR( PortAddr iop_base, uchar sdtr_period, uchar sdtr_offset ) { SDTR_XMSG sdtr_buf; uchar sdtr_period_index; sdtr_buf.msg_type = MS_EXTEND; sdtr_buf.msg_len = MS_SDTR_LEN; sdtr_buf.msg_req = MS_SDTR_CODE; sdtr_buf.xfer_period = sdtr_period; sdtr_offset &= ASC_SYN_MAX_OFFSET; sdtr_buf.req_ack_offset = sdtr_offset; AscMemWordCopyToLram(iop_base, ASCV_MSGOUT_BEG, (ushort dosfar *) & sdtr_buf, SYN_XMSG_WLEN); if ((sdtr_period_index = AscGetSynPeriodIndex(sdtr_period)) <= ASC_MAX_SDTR_PERIOD_INDEX) { return ((sdtr_period_index << 4) | sdtr_offset); } else { return (0); } } uchar AscCalSDTRData( uchar sdtr_period, uchar syn_offset ) { uchar byte; uchar sdtr_period_ix; sdtr_period_ix = AscGetSynPeriodIndex(sdtr_period); if ((sdtr_period_ix > ASC_MAX_SDTR_PERIOD_INDEX) || (sdtr_period_ix > ASC_SDTR_PERIOD_IX_MIN)) { return (0xFF); } byte = (sdtr_period_ix << 4) | (syn_offset & ASC_SYN_MAX_OFFSET); return (byte); } void AscSetChipSDTR( PortAddr iop_base, uchar sdtr_data, uchar tid_no ) { AscWriteChipSyn(iop_base, sdtr_data); AscWriteLramByte(iop_base, (ushort) ((ushort) ASCV_SDTR_DONE_BEG + (ushort) tid_no), sdtr_data); return; } uchar AscGetSynPeriodIndex( uchar syn_time ) { if ((syn_time >= SYN_XFER_NS_0) && (syn_time <= SYN_XFER_NS_7)) { if (syn_time <= SYN_XFER_NS_6) { if (syn_time <= SYN_XFER_NS_5) { if (syn_time <= SYN_XFER_NS_4) { if (syn_time <= SYN_XFER_NS_3) { if (syn_time <= SYN_XFER_NS_2) { if (syn_time <= SYN_XFER_NS_1) { if (syn_time <= SYN_XFER_NS_0) { return (0); } else return (1); } else { return (2); } } else { return (3); } } else { return (4); } } else { return (5); } } else { return (6); } } else { return (7); } } else { return (8); } } uchar AscAllocFreeQueue( PortAddr iop_base, uchar free_q_head ) { ushort q_addr; uchar next_qp; uchar q_status; q_addr = ASC_QNO_TO_QADDR(free_q_head); q_status = (uchar) AscReadLramByte(iop_base, (ushort) (q_addr + ASC_SCSIQ_B_STATUS)); next_qp = AscReadLramByte(iop_base, (ushort) (q_addr + ASC_SCSIQ_B_FWD)); if (((q_status & QS_READY) == 0) && (next_qp != ASC_QLINK_END)) { return (next_qp); } return (ASC_QLINK_END); } uchar AscAllocMultipleFreeQueue( PortAddr iop_base, uchar free_q_head, uchar n_free_q ) { uchar i; for (i = 0; i < n_free_q; i++) { if ((free_q_head = AscAllocFreeQueue(iop_base, free_q_head)) == ASC_QLINK_END) { return (ASC_QLINK_END); } } return (free_q_head); } int AscRiscHaltedAbortSRB( ASC_DVC_VAR asc_ptr_type * asc_dvc, ulong srb_ptr ) { PortAddr iop_base; ushort q_addr; uchar q_no; ASC_QDONE_INFO scsiq_buf; ASC_QDONE_INFO dosfar *scsiq; ASC_ISR_CALLBACK asc_isr_callback; int last_int_level; iop_base = asc_dvc->iop_base; asc_isr_callback = (ASC_ISR_CALLBACK) asc_dvc->isr_callback; last_int_level = DvcEnterCritical(); scsiq = (ASC_QDONE_INFO dosfar *) & scsiq_buf; #if CC_LINK_BUSY_Q _AscAbortSrbBusyQueue(asc_dvc, scsiq, srb_ptr); #endif for (q_no = ASC_MIN_ACTIVE_QNO; q_no <= asc_dvc->max_total_qng; q_no++) { q_addr = ASC_QNO_TO_QADDR(q_no); scsiq->d2.srb_ptr = AscReadLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_D_SRBPTR)); if (scsiq->d2.srb_ptr == srb_ptr) { _AscCopyLramScsiDoneQ(iop_base, q_addr, scsiq, asc_dvc->max_dma_count); if (((scsiq->q_status & QS_READY) != 0) && ((scsiq->q_status & QS_ABORTED) == 0) && ((scsiq->cntl & QCSG_SG_XFER_LIST) == 0)) { scsiq->q_status |= QS_ABORTED; scsiq->d3.done_stat = QD_ABORTED_BY_HOST; AscWriteLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_D_SRBPTR), 0L); AscWriteLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_STATUS), scsiq->q_status); (*asc_isr_callback) (asc_dvc, scsiq); return (1); } } } DvcLeaveCritical(last_int_level); return (0); } int AscRiscHaltedAbortTIX( ASC_DVC_VAR asc_ptr_type * asc_dvc, uchar target_ix ) { PortAddr iop_base; ushort q_addr; uchar q_no; ASC_QDONE_INFO scsiq_buf; ASC_QDONE_INFO dosfar *scsiq; ASC_ISR_CALLBACK asc_isr_callback; int last_int_level; #if CC_LINK_BUSY_Q uchar tid_no; #endif iop_base = asc_dvc->iop_base; asc_isr_callback = (ASC_ISR_CALLBACK) asc_dvc->isr_callback; last_int_level = DvcEnterCritical(); scsiq = (ASC_QDONE_INFO dosfar *) & scsiq_buf; #if CC_LINK_BUSY_Q tid_no = ASC_TIX_TO_TID(target_ix); _AscAbortTidBusyQueue(asc_dvc, scsiq, tid_no); #endif for (q_no = ASC_MIN_ACTIVE_QNO; q_no <= asc_dvc->max_total_qng; q_no++) { q_addr = ASC_QNO_TO_QADDR(q_no); _AscCopyLramScsiDoneQ(iop_base, q_addr, scsiq, asc_dvc->max_dma_count); if (((scsiq->q_status & QS_READY) != 0) && ((scsiq->q_status & QS_ABORTED) == 0) && ((scsiq->cntl & QCSG_SG_XFER_LIST) == 0)) { if (scsiq->d2.target_ix == target_ix) { scsiq->q_status |= QS_ABORTED; scsiq->d3.done_stat = QD_ABORTED_BY_HOST; AscWriteLramDWord(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_D_SRBPTR), 0L); AscWriteLramByte(iop_base, (ushort) (q_addr + (ushort) ASC_SCSIQ_B_STATUS), scsiq->q_status); (*asc_isr_callback) (asc_dvc, scsiq); } } } DvcLeaveCritical(last_int_level); return (1); } #if CC_LINK_BUSY_Q #endif int AscHostReqRiscHalt( PortAddr iop_base ) { int count = 0; int sta = 0; uchar saved_stop_code; if (AscIsChipHalted(iop_base)) return (1); saved_stop_code = AscReadLramByte(iop_base, ASCV_STOP_CODE_B); AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, ASC_STOP_HOST_REQ_RISC_HALT | ASC_STOP_REQ_RISC_STOP ); do { if (AscIsChipHalted(iop_base)) { sta = 1; break; } DvcSleepMilliSecond(100); } while (count++ < 20); AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, saved_stop_code); return (sta); } int AscStopQueueExe( PortAddr iop_base ) { int count; count = 0; if (AscReadLramByte(iop_base, ASCV_STOP_CODE_B) == 0) { AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, ASC_STOP_REQ_RISC_STOP); do { if (AscReadLramByte(iop_base, ASCV_STOP_CODE_B) & ASC_STOP_ACK_RISC_STOP) { return (1); } DvcSleepMilliSecond(100); } while (count++ < 20); } return (0); } int AscStartQueueExe( PortAddr iop_base ) { if (AscReadLramByte(iop_base, ASCV_STOP_CODE_B) != 0) { AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, 0); } return (1); } int AscCleanUpBusyQueue( PortAddr iop_base ) { int count; uchar stop_code; count = 0; if (AscReadLramByte(iop_base, ASCV_STOP_CODE_B) != 0) { AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, ASC_STOP_CLEAN_UP_BUSY_Q); do { stop_code = AscReadLramByte(iop_base, ASCV_STOP_CODE_B); if ((stop_code & ASC_STOP_CLEAN_UP_BUSY_Q) == 0) break; DvcSleepMilliSecond(100); } while (count++ < 20); } return (1); } int AscCleanUpDiscQueue( PortAddr iop_base ) { int count; uchar stop_code; count = 0; if (AscReadLramByte(iop_base, ASCV_STOP_CODE_B) != 0) { AscWriteLramByte(iop_base, ASCV_STOP_CODE_B, ASC_STOP_CLEAN_UP_DISC_Q); do { stop_code = AscReadLramByte(iop_base, ASCV_STOP_CODE_B); if ((stop_code & ASC_STOP_CLEAN_UP_DISC_Q) == 0) break; DvcSleepMilliSecond(100); } while (count++ < 20); } return (1); } int AscWaitTixISRDone( ASC_DVC_VAR asc_ptr_type * asc_dvc, uchar target_ix ) { uchar cur_req; uchar tid_no; tid_no = ASC_TIX_TO_TID(target_ix); while (TRUE) { if ((cur_req = asc_dvc->cur_dvc_qng[tid_no]) == 0) { break; } DvcSleepMilliSecond(1000L); if (asc_dvc->cur_dvc_qng[tid_no] == cur_req) { break; } } return (1); } int AscWaitISRDone( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { int tid; for (tid = 0; tid <= ASC_MAX_TID; tid++) { AscWaitTixISRDone(asc_dvc, ASC_TID_TO_TIX(tid)); } return (1); } ulong AscGetOnePhyAddr( ASC_DVC_VAR asc_ptr_type * asc_dvc, uchar dosfar * buf_addr, ulong buf_size ) { ASC_MIN_SG_HEAD sg_head; sg_head.entry_cnt = ASC_MIN_SG_LIST; if (DvcGetSGList(asc_dvc, (uchar dosfar *) buf_addr, buf_size, (ASC_SG_HEAD dosfar *) & sg_head) != buf_size) { return (0L); } if (sg_head.entry_cnt > 1) { return (0L); } return (sg_head.sg_list[0].addr); } ulong AscGetEisaProductID( PortAddr iop_base ) { PortAddr eisa_iop; ushort product_id_high, product_id_low; ulong product_id; eisa_iop = ASC_GET_EISA_SLOT(iop_base) | ASC_EISA_PID_IOP_MASK; product_id_low = inpw(eisa_iop); product_id_high = inpw(eisa_iop + 2); product_id = ((ulong) product_id_high << 16) | (ulong) product_id_low; return (product_id); } PortAddr AscSearchIOPortAddrEISA( PortAddr iop_base ) { ulong eisa_product_id; if (iop_base == 0) { iop_base = ASC_EISA_MIN_IOP_ADDR; } else { if (iop_base == ASC_EISA_MAX_IOP_ADDR) return (0); if ((iop_base & 0x0050) == 0x0050) { iop_base += ASC_EISA_BIG_IOP_GAP; } else { iop_base += ASC_EISA_SMALL_IOP_GAP; } } while (iop_base <= ASC_EISA_MAX_IOP_ADDR) { eisa_product_id = AscGetEisaProductID(iop_base); if ((eisa_product_id == ASC_EISA_ID_740) || (eisa_product_id == ASC_EISA_ID_750)) { if (AscFindSignature(iop_base)) { inpw(iop_base + 4); return (iop_base); } } if (iop_base == ASC_EISA_MAX_IOP_ADDR) return (0); if ((iop_base & 0x0050) == 0x0050) { iop_base += ASC_EISA_BIG_IOP_GAP; } else { iop_base += ASC_EISA_SMALL_IOP_GAP; } } return (0); } int AscStartChip( PortAddr iop_base ) { AscSetChipControl(iop_base, 0); if ((AscGetChipStatus(iop_base) & CSW_HALTED) != 0) { return (0); } return (1); } int AscStopChip( PortAddr iop_base ) { uchar cc_val; cc_val = AscGetChipControl(iop_base) & (~(CC_SINGLE_STEP | CC_TEST | CC_DIAG)); AscSetChipControl(iop_base, (uchar) (cc_val | CC_HALT)); AscSetChipIH(iop_base, INS_HALT); AscSetChipIH(iop_base, INS_RFLAG_WTM); if ((AscGetChipStatus(iop_base) & CSW_HALTED) == 0) { return (0); } return (1); } int AscIsChipHalted( PortAddr iop_base ) { if ((AscGetChipStatus(iop_base) & CSW_HALTED) != 0) { if ((AscGetChipControl(iop_base) & CC_HALT) != 0) { return (1); } } return (0); } void AscSetChipIH( PortAddr iop_base, ushort ins_code ) { AscSetBank(iop_base, 1); AscWriteChipIH(iop_base, ins_code); AscSetBank(iop_base, 0); return; } void AscAckInterrupt( PortAddr iop_base ) { uchar host_flag; uchar risc_flag; ushort loop; loop = 0; do { risc_flag = AscReadLramByte(iop_base, ASCV_RISC_FLAG_B); if (loop++ > 0x7FFF) { break; } } while ((risc_flag & ASC_RISC_FLAG_GEN_INT) != 0); host_flag = AscReadLramByte(iop_base, ASCV_HOST_FLAG_B); AscWriteLramByte(iop_base, ASCV_HOST_FLAG_B, (uchar) (host_flag | ASC_HOST_FLAG_ACK_INT)); AscSetChipStatus(iop_base, CIW_INT_ACK); loop = 0; while (AscGetChipStatus(iop_base) & CSW_INT_PENDING) { AscSetChipStatus(iop_base, CIW_INT_ACK); if (loop++ > 3) { break; } } AscWriteLramByte(iop_base, ASCV_HOST_FLAG_B, host_flag); return; } void AscDisableInterrupt( PortAddr iop_base ) { ushort cfg; cfg = AscGetChipCfgLsw(iop_base); AscSetChipCfgLsw(iop_base, cfg & (~ASC_CFG0_HOST_INT_ON)); return; } void AscEnableInterrupt( PortAddr iop_base ) { ushort cfg; cfg = AscGetChipCfgLsw(iop_base); AscSetChipCfgLsw(iop_base, cfg | ASC_CFG0_HOST_INT_ON); return; } void AscSetBank( PortAddr iop_base, uchar bank ) { uchar val; val = AscGetChipControl(iop_base) & (~(CC_SINGLE_STEP | CC_TEST | CC_DIAG | CC_SCSI_RESET | CC_CHIP_RESET)); if (bank == 1) { val |= CC_BANK_ONE; } else if (bank == 2) { val |= CC_DIAG | CC_BANK_ONE; } else { val &= ~CC_BANK_ONE; } AscSetChipControl(iop_base, val); return; } int AscResetChipAndScsiBus( PortAddr iop_base ) { AscStopChip(iop_base); AscSetChipControl(iop_base, CC_CHIP_RESET | CC_SCSI_RESET | CC_HALT); DvcSleepMilliSecond(200); AscSetChipIH(iop_base, INS_RFLAG_WTM); AscSetChipIH(iop_base, INS_HALT); AscSetChipControl(iop_base, CC_CHIP_RESET | CC_HALT); AscSetChipControl(iop_base, CC_HALT); DvcSleepMilliSecond(200); return (AscIsChipHalted(iop_base)); } ushort AscGetIsaDmaChannel( PortAddr iop_base ) { ushort channel; channel = AscGetChipCfgLsw(iop_base) & 0x0003; if (channel == 0x03) return (0); else if (channel == 0x00) return (7); return (channel + 4); } ushort AscSetIsaDmaChannel( PortAddr iop_base, ushort dma_channel ) { ushort cfg_lsw; uchar value; if ((dma_channel >= 5) && (dma_channel <= 7)) { if (dma_channel == 7) value = 0x00; else value = dma_channel - 4; cfg_lsw = AscGetChipCfgLsw(iop_base) & 0xFFFC; cfg_lsw |= value; AscSetChipCfgLsw(iop_base, cfg_lsw); return (AscGetIsaDmaChannel(iop_base)); } return (0); } uchar AscSetIsaDmaSpeed( PortAddr iop_base, uchar speed_value ) { speed_value &= 0x07; AscSetBank(iop_base, 1); AscSetChipDmaSpeed(iop_base, speed_value); AscSetBank(iop_base, 0); return (AscGetIsaDmaSpeed(iop_base)); } uchar AscGetIsaDmaSpeed( PortAddr iop_base ) { uchar speed_value; AscSetBank(iop_base, 1); speed_value = AscGetChipDmaSpeed(iop_base); speed_value &= 0x07; AscSetBank(iop_base, 0); return (speed_value); } ulong AscGetMaxDmaCount( ushort bus_type ) { if (bus_type & ASC_IS_ISA) return (ASC_MAX_ISA_DMA_COUNT); else if (bus_type & (ASC_IS_EISA | ASC_IS_VL)) return (ASC_MAX_VL_DMA_COUNT); return (ASC_MAX_PCI_DMA_COUNT); } ushort AscInitGetConfig( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { ushort warn_code; warn_code = 0; asc_dvc->init_state = ASC_INIT_STATE_BEG_GET_CFG; if (asc_dvc->err_code != 0) return (UW_ERR); if (AscFindSignature(asc_dvc->iop_base)) { warn_code |= AscInitAscDvcVar(asc_dvc); warn_code |= AscInitFromEEP(asc_dvc); asc_dvc->init_state |= ASC_INIT_STATE_END_GET_CFG; if (asc_dvc->scsi_reset_wait > 10) asc_dvc->scsi_reset_wait = 10; } else { asc_dvc->err_code = ASC_IERR_BAD_SIGNATURE; } return (warn_code); } ushort AscInitSetConfig( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { ushort warn_code; warn_code = 0; asc_dvc->init_state |= ASC_INIT_STATE_BEG_SET_CFG; if (asc_dvc->err_code != 0) return (UW_ERR); if (AscFindSignature(asc_dvc->iop_base)) { warn_code |= AscInitFromAscDvcVar(asc_dvc); asc_dvc->init_state |= ASC_INIT_STATE_END_SET_CFG; } else { asc_dvc->err_code = ASC_IERR_BAD_SIGNATURE; } return (warn_code); } ushort AscInitAsc1000Driver( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { ushort warn_code; PortAddr iop_base; extern ushort _mcode_size; extern ulong _mcode_chksum; extern uchar _mcode_buf[]; ASC_DBG(3, "AscInitAsc1000Driver: begin\n"); iop_base = asc_dvc->iop_base; warn_code = 0; if ((asc_dvc->dvc_cntl & ASC_CNTL_RESET_SCSI) && !(asc_dvc->init_state & ASC_INIT_RESET_SCSI_DONE)) { ASC_DBG(3, "AscInitAsc1000Driver: AscResetChipAndScsiBus()\n"); AscResetChipAndScsiBus(iop_base); DvcSleepMilliSecond((ulong) ((ushort) asc_dvc->scsi_reset_wait * 1000)); } asc_dvc->init_state |= ASC_INIT_STATE_BEG_LOAD_MC; if (asc_dvc->err_code != 0) return (UW_ERR); ASC_DBG(3, "AscInitAsc1000Driver: AscFindSignature()\n"); if (!AscFindSignature(asc_dvc->iop_base)) { asc_dvc->err_code = ASC_IERR_BAD_SIGNATURE; return (warn_code); } ASC_DBG(3, "AscInitAsc1000Driver: AscDisableInterrupt()\n"); AscDisableInterrupt(iop_base); ASC_DBG(3, "AscInitAsc1000Driver: AscInitLram()\n"); warn_code |= AscInitLram(asc_dvc); if (asc_dvc->err_code != 0) return (UW_ERR); ASC_DBG(3, "AscInitAsc1000Driver: AscLoadMicroCode()\n"); if (AscLoadMicroCode(iop_base, 0, (ushort dosfar *) _mcode_buf, _mcode_size) != _mcode_chksum) { asc_dvc->err_code |= ASC_IERR_MCODE_CHKSUM; return (warn_code); } ASC_DBG(3, "AscInitAsc1000Driver: AscInitMicroCodeVar()\n"); warn_code |= AscInitMicroCodeVar(asc_dvc); asc_dvc->init_state |= ASC_INIT_STATE_END_LOAD_MC; ASC_DBG(3, "AscInitAsc1000Driver: AscEnableInterrupt()\n"); AscEnableInterrupt(iop_base); return (warn_code); } ushort AscInitAscDvcVar( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { int i; PortAddr iop_base; ushort warn_code; iop_base = asc_dvc->iop_base; warn_code = 0; asc_dvc->err_code = 0; if ((asc_dvc->bus_type & (ASC_IS_ISA | ASC_IS_PCI | ASC_IS_EISA | ASC_IS_VL)) == 0) { asc_dvc->err_code |= ASC_IERR_NO_BUS_TYPE; } #if CC_LINK_BUSY_Q for (i = 0; i <= ASC_MAX_TID; i++) { asc_dvc->scsiq_busy_head[i] = (ASC_SCSI_Q dosfar *) 0L; asc_dvc->scsiq_busy_tail[i] = (ASC_SCSI_Q dosfar *) 0L; } #endif asc_dvc->dvc_cntl = ASC_DEF_DVC_CNTL; asc_dvc->bug_fix_cntl = 0; asc_dvc->pci_fix_asyn_xfer = 0; asc_dvc->init_sdtr = 0; asc_dvc->sdtr_done = 0; asc_dvc->max_total_qng = ASC_DEF_MAX_TOTAL_QNG; asc_dvc->cur_total_qng = 0; asc_dvc->is_in_int = 0; asc_dvc->scsi_reset_wait = 3; asc_dvc->in_critical_cnt = 0; asc_dvc->last_q_shortage = 0; asc_dvc->use_tagged_qng = 0; asc_dvc->cfg->can_tagged_qng = 0; asc_dvc->no_scam = 0; asc_dvc->irq_no = 10; asc_dvc->start_motor = ASC_SCSI_WIDTH_BIT_SET; asc_dvc->cfg->disc_enable = ASC_SCSI_WIDTH_BIT_SET; asc_dvc->cfg->cmd_qng_enabled = ASC_SCSI_WIDTH_BIT_SET; asc_dvc->cfg->chip_scsi_id = ASC_DEF_CHIP_SCSI_ID; asc_dvc->cfg->chip_version = AscGetChipVersion(iop_base, asc_dvc->bus_type); if (AscGetChipBusType(iop_base) == ASC_IS_ISAPNP) { AscPutChipIFC(iop_base, IFC_INIT_DEFAULT); asc_dvc->bus_type = ASC_IS_ISAPNP; } asc_dvc->unit_not_ready = 0; asc_dvc->queue_full_or_busy = 0; if ((asc_dvc->bus_type & ASC_IS_ISA) != 0) { asc_dvc->cfg->isa_dma_channel = (uchar) AscGetIsaDmaChannel(iop_base); asc_dvc->cfg->isa_dma_speed = ASC_DEF_ISA_DMA_SPEED; } asc_dvc->cfg->lib_serial_no = ASC_LIB_SERIAL_NUMBER; asc_dvc->cfg->lib_version = (ASC_LIB_VERSION_MAJOR << 8) | ASC_LIB_VERSION_MINOR; asc_dvc->int_count = 0L; asc_dvc->req_count = 0L; asc_dvc->busy_count = 0L; asc_dvc->max_dma_count = AscGetMaxDmaCount(asc_dvc->bus_type); for (i = 0; i <= ASC_MAX_TID; i++) { asc_dvc->cfg->sdtr_data[i] = (uchar) (ASC_DEF_SDTR_OFFSET | (ASC_DEF_SDTR_INDEX << 4)); asc_dvc->cur_dvc_qng[i] = 0; asc_dvc->max_dvc_qng[i] = ASC_MAX_SCSI1_QNG; asc_dvc->scsiq_busy_head[i] = (ASC_SCSI_Q dosfar *) 0L; asc_dvc->scsiq_busy_tail[i] = (ASC_SCSI_Q dosfar *) 0L; } return (warn_code); } ushort AscInitFromAscDvcVar( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { PortAddr iop_base; ushort cfg_msw; ushort warn_code; iop_base = asc_dvc->iop_base; warn_code = 0; cfg_msw = AscGetChipCfgMsw(iop_base); if ((cfg_msw & ASC_CFG_MSW_CLR_MASK) != 0) { cfg_msw &= (~(ASC_CFG_MSW_CLR_MASK)); warn_code |= ASC_WARN_CFG_MSW_RECOVER; AscSetChipCfgMsw(iop_base, cfg_msw); } if (AscGetChipStatus(iop_base) & CSW_AUTO_CONFIG) { warn_code |= ASC_WARN_AUTO_CONFIG; } if ((asc_dvc->cfg->cmd_qng_enabled & asc_dvc->cfg->disc_enable) != asc_dvc->cfg->cmd_qng_enabled) { asc_dvc->cfg->disc_enable = asc_dvc->cfg->cmd_qng_enabled; warn_code |= ASC_WARN_CMD_QNG_CONFLICT; } if ((asc_dvc->bus_type & (ASC_IS_ISA | ASC_IS_VL)) != 0) { if (AscSetChipIRQ(iop_base, asc_dvc->irq_no, asc_dvc->bus_type) != asc_dvc->irq_no) { asc_dvc->err_code |= ASC_IERR_SET_IRQ_NO; } } if (AscSetChipScsiID(iop_base, asc_dvc->cfg->chip_scsi_id) != asc_dvc->cfg->chip_scsi_id) { asc_dvc->err_code |= ASC_IERR_SET_SCSI_ID; } if ((asc_dvc->bus_type & ASC_IS_ISA) != 0) { AscSetIsaDmaChannel(iop_base, asc_dvc->cfg->isa_dma_channel); AscSetIsaDmaSpeed(iop_base, asc_dvc->cfg->isa_dma_speed); } return (warn_code); } ushort AscInitFromEEP( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { ASCEEP_CONFIG eep_config_buf; ASCEEP_CONFIG dosfar *eep_config; PortAddr iop_base; ushort chksum; ushort warn_code; ushort cfg_msw, cfg_lsw; uchar i; iop_base = asc_dvc->iop_base; warn_code = 0; AscWriteLramWord(iop_base, ASCV_HALTCODE_W, 0x00FE); AscStopQueueExe(iop_base); if ((AscStopChip(iop_base) == FALSE) || (AscGetChipScsiCtrl(iop_base) != 0)) { asc_dvc->init_state |= ASC_INIT_RESET_SCSI_DONE; AscResetChipAndScsiBus(iop_base); DvcSleepMilliSecond((ulong) ((ushort) asc_dvc->scsi_reset_wait * 1000)); } if (AscIsChipHalted(iop_base) == FALSE) { asc_dvc->err_code |= ASC_IERR_START_STOP_CHIP; return (warn_code); } AscSetPCAddr(iop_base, ASC_MCODE_START_ADDR); if (AscGetPCAddr(iop_base) != ASC_MCODE_START_ADDR) { asc_dvc->err_code |= ASC_IERR_SET_PC_ADDR; return (warn_code); } eep_config = (ASCEEP_CONFIG dosfar *) & eep_config_buf; cfg_msw = AscGetChipCfgMsw(iop_base); cfg_lsw = AscGetChipCfgLsw(iop_base); if (asc_dvc->bus_type & ASC_IS_PCI) { #if CC_DISABLE_PCI_PARITY_INT cfg_msw &= 0xFFC0; AscSetChipCfgMsw(iop_base, cfg_msw); #endif if (asc_dvc->cfg->pci_device_id == ASC_PCI_DEVICE_ID_REV_A) { asc_dvc->bug_fix_cntl |= ASC_BUG_FIX_ADD_ONE_BYTE; } } if ((cfg_msw & ASC_CFG_MSW_CLR_MASK) != 0) { cfg_msw &= (~(ASC_CFG_MSW_CLR_MASK)); warn_code |= ASC_WARN_CFG_MSW_RECOVER; AscSetChipCfgMsw(iop_base, cfg_msw); } chksum = AscGetEEPConfig(iop_base, eep_config, asc_dvc->bus_type); eep_config->cfg_msw &= (~(ASC_CFG_MSW_CLR_MASK)); if (AscGetChipStatus(iop_base) & CSW_AUTO_CONFIG) { warn_code |= ASC_WARN_AUTO_CONFIG; if (asc_dvc->cfg->chip_version == 3) { if (eep_config->cfg_lsw != cfg_lsw) { warn_code |= ASC_WARN_EEPROM_RECOVER; eep_config->cfg_lsw = AscGetChipCfgLsw(iop_base); } if (eep_config->cfg_msw != cfg_msw) { warn_code |= ASC_WARN_EEPROM_RECOVER; eep_config->cfg_msw = AscGetChipCfgMsw(iop_base); } } } eep_config->cfg_lsw |= ASC_CFG0_HOST_INT_ON; if (chksum != eep_config->chksum) { warn_code |= ASC_WARN_EEPROM_CHKSUM; } asc_dvc->init_sdtr = eep_config->init_sdtr; asc_dvc->cfg->disc_enable = eep_config->disc_enable; asc_dvc->cfg->cmd_qng_enabled = eep_config->use_cmd_qng; asc_dvc->cfg->isa_dma_speed = eep_config->isa_dma_speed; asc_dvc->start_motor = eep_config->start_motor; asc_dvc->dvc_cntl = eep_config->cntl; asc_dvc->no_scam = eep_config->no_scam; if ((asc_dvc->bus_type & ASC_IS_PCI) && !(asc_dvc->dvc_cntl & ASC_CNTL_NO_PCI_FIX_ASYN_XFER)) { if ((asc_dvc->cfg->pci_device_id == ASC_PCI_DEVICE_ID_REV_A) || (asc_dvc->cfg->pci_device_id == ASC_PCI_DEVICE_ID_REV_B)) { asc_dvc->pci_fix_asyn_xfer = ASC_ALL_DEVICE_BIT_SET; } } else if (asc_dvc->bus_type & ASC_IS_ISAPNP) { if (AscGetChipVersion(iop_base, asc_dvc->bus_type) == ASC_CHIP_VER_ASYN_BUG) { asc_dvc->pci_fix_asyn_xfer = ASC_ALL_DEVICE_BIT_SET; } } if (!AscTestExternalLram(asc_dvc)) { if (asc_dvc->bus_type & ASC_IS_PCI) { eep_config->cfg_msw |= 0x0800; cfg_msw |= 0x0800; AscSetChipCfgMsw(iop_base, cfg_msw); eep_config->max_total_qng = ASC_MAX_PCI_INRAM_TOTAL_QNG; eep_config->max_tag_qng = ASC_MAX_INRAM_TAG_QNG; } } else { #if CC_TEST_RW_LRAM asc_dvc->err_code |= AscTestLramEndian(iop_base); #endif } if (eep_config->max_total_qng < ASC_MIN_TOTAL_QNG) { eep_config->max_total_qng = ASC_MIN_TOTAL_QNG; } if (eep_config->max_total_qng > ASC_MAX_TOTAL_QNG) { eep_config->max_total_qng = ASC_MAX_TOTAL_QNG; } if (eep_config->max_tag_qng > eep_config->max_total_qng) { eep_config->max_tag_qng = eep_config->max_total_qng; } if (eep_config->max_tag_qng < ASC_MIN_TAG_Q_PER_DVC) { eep_config->max_tag_qng = ASC_MIN_TAG_Q_PER_DVC; } asc_dvc->max_total_qng = eep_config->max_total_qng; if ((eep_config->use_cmd_qng & eep_config->disc_enable) != eep_config->use_cmd_qng) { eep_config->disc_enable = eep_config->use_cmd_qng; warn_code |= ASC_WARN_CMD_QNG_CONFLICT; } asc_dvc->irq_no = AscGetChipIRQ(iop_base, asc_dvc->bus_type); eep_config->chip_scsi_id &= ASC_MAX_TID; asc_dvc->cfg->chip_scsi_id = eep_config->chip_scsi_id; for (i = 0; i <= ASC_MAX_TID; i++) { asc_dvc->cfg->sdtr_data[i] = eep_config->sdtr_data[i]; asc_dvc->cfg->max_tag_qng[i] = eep_config->max_tag_qng; } eep_config->cfg_msw = AscGetChipCfgMsw(iop_base); if (AscSetEEPConfig(iop_base, eep_config, asc_dvc->bus_type) != 0) { asc_dvc->err_code |= ASC_IERR_WRITE_EEPROM; } return (warn_code); } ushort AscInitMicroCodeVar( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { int i; ushort warn_code; PortAddr iop_base; ulong phy_addr; iop_base = asc_dvc->iop_base; warn_code = 0; for (i = 0; i <= ASC_MAX_TID; i++) { AscWriteLramByte(iop_base, (ushort) (ASCV_SDTR_DATA_BEG + i), asc_dvc->cfg->sdtr_data[i]); } AscInitQLinkVar(asc_dvc); AscWriteLramByte(iop_base, ASCV_DISC_ENABLE_B, asc_dvc->cfg->disc_enable); AscWriteLramByte(iop_base, ASCV_HOSTSCSI_ID_B, ASC_TID_TO_TARGET_ID(asc_dvc->cfg->chip_scsi_id)); if ((phy_addr = AscGetOnePhyAddr(asc_dvc, (uchar dosfar *) asc_dvc->cfg->overrun_buf, ASC_OVERRUN_BSIZE)) == 0L) { asc_dvc->err_code |= ASC_IERR_GET_PHY_ADDR; } else { phy_addr = (phy_addr & 0xFFFFFFF8UL) + 8; AscWriteLramDWord(iop_base, ASCV_OVERRUN_PADDR_D, phy_addr); AscWriteLramDWord(iop_base, ASCV_OVERRUN_BSIZE_D, ASC_OVERRUN_BSIZE - 8); } asc_dvc->cfg->mcode_date = AscReadLramWord(iop_base, (ushort) ASCV_MC_DATE_W); asc_dvc->cfg->mcode_version = AscReadLramWord(iop_base, (ushort) ASCV_MC_VER_W); AscSetPCAddr(iop_base, ASC_MCODE_START_ADDR); if (AscGetPCAddr(iop_base) != ASC_MCODE_START_ADDR) { asc_dvc->err_code |= ASC_IERR_SET_PC_ADDR; return (warn_code); } if (AscStartChip(iop_base) != 1) { asc_dvc->err_code |= ASC_IERR_START_STOP_CHIP; return (warn_code); } return (warn_code); } void dosfar AscInitPollIsrCallBack( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_QDONE_INFO dosfar * scsi_done_q ) { ASC_SCSI_REQ_Q dosfar *scsiq_req; ASC_ISR_CALLBACK asc_isr_callback; uchar cp_sen_len; uchar i; if ((scsi_done_q->d2.flag & ASC_FLAG_SCSIQ_REQ) != 0) { scsiq_req = (ASC_SCSI_REQ_Q dosfar *) scsi_done_q->d2.srb_ptr; ASC_DBG2(3, "AscInitPollIsrCallBack: done_stat %x, host_stat %x\n", scsiq_req->r3.done_stat, scsiq_req->r3.host_stat); scsiq_req->r3.done_stat = scsi_done_q->d3.done_stat; scsiq_req->r3.host_stat = scsi_done_q->d3.host_stat; scsiq_req->r3.scsi_stat = scsi_done_q->d3.scsi_stat; scsiq_req->r3.scsi_msg = scsi_done_q->d3.scsi_msg; if ((scsi_done_q->d3.scsi_stat == SS_CHK_CONDITION) && (scsi_done_q->d3.host_stat == 0)) { cp_sen_len = (uchar) ASC_MIN_SENSE_LEN; if (scsiq_req->r1.sense_len < ASC_MIN_SENSE_LEN) { cp_sen_len = (uchar) scsiq_req->r1.sense_len; } for (i = 0; i < cp_sen_len; i++) { scsiq_req->sense[i] = scsiq_req->sense_ptr[i]; } } } else { ASC_DBG1(3, "AscInitPollIsrCallBack: isr_callback %x\n", (unsigned) asc_dvc->isr_callback); if (asc_dvc->isr_callback != 0) { asc_isr_callback = (ASC_ISR_CALLBACK) asc_dvc->isr_callback; (*asc_isr_callback) (asc_dvc, scsi_done_q); } } return; } int AscTestExternalLram( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { PortAddr iop_base; ushort q_addr; ushort saved_word; int sta; iop_base = asc_dvc->iop_base; sta = 0; q_addr = ASC_QNO_TO_QADDR(241); saved_word = AscReadLramWord(iop_base, q_addr); if (AscVerWriteLramWord(iop_base, q_addr, 0x55AA) == 0) { sta = 1; AscWriteLramWord(iop_base, q_addr, saved_word); } return (sta); } #if CC_TEST_LRAM_ENDIAN #endif int AscWriteEEPCmdReg( PortAddr iop_base, uchar cmd_reg ) { uchar read_back; int retry; retry = 0; while (TRUE) { AscSetChipEEPCmd(iop_base, cmd_reg); DvcSleepMilliSecond(1); read_back = AscGetChipEEPCmd(iop_base); if (read_back == cmd_reg) { return (1); } if (retry++ > ASC_EEP_MAX_RETRY) { return (0); } } } int AscWriteEEPDataReg( PortAddr iop_base, ushort data_reg ) { ushort read_back; int retry; retry = 0; while (TRUE) { AscSetChipEEPData(iop_base, data_reg); DvcSleepMilliSecond(1); read_back = AscGetChipEEPData(iop_base); if (read_back == data_reg) { return (1); } if (retry++ > ASC_EEP_MAX_RETRY) { return (0); } } } void AscWaitEEPRead( void ) { DvcSleepMilliSecond(1); return; } void AscWaitEEPWrite( void ) { DvcSleepMilliSecond(20); return; } ushort AscReadEEPWord( PortAddr iop_base, uchar addr ) { ushort read_wval; uchar cmd_reg; AscWriteEEPCmdReg(iop_base, ASC_EEP_CMD_WRITE_DISABLE); AscWaitEEPRead(); cmd_reg = addr | ASC_EEP_CMD_READ; AscWriteEEPCmdReg(iop_base, cmd_reg); AscWaitEEPRead(); read_wval = AscGetChipEEPData(iop_base); AscWaitEEPRead(); return (read_wval); } ushort AscWriteEEPWord( PortAddr iop_base, uchar addr, ushort word_val ) { ushort read_wval; read_wval = AscReadEEPWord(iop_base, addr); if (read_wval != word_val) { AscWriteEEPCmdReg(iop_base, ASC_EEP_CMD_WRITE_ABLE); AscWaitEEPRead(); AscWriteEEPDataReg(iop_base, word_val); AscWaitEEPRead(); AscWriteEEPCmdReg(iop_base, (uchar) ((uchar) ASC_EEP_CMD_WRITE | addr)); AscWaitEEPWrite(); AscWriteEEPCmdReg(iop_base, ASC_EEP_CMD_WRITE_DISABLE); AscWaitEEPRead(); return (AscReadEEPWord(iop_base, addr)); } return (read_wval); } ushort AscGetEEPConfig( PortAddr iop_base, ASCEEP_CONFIG dosfar * cfg_buf, ushort bus_type ) { ushort wval; ushort sum; ushort dosfar *wbuf; int cfg_beg; int cfg_end; int s_addr; int isa_pnp_wsize; wbuf = (ushort dosfar *) cfg_buf; sum = 0; isa_pnp_wsize = 0; for (s_addr = 0; s_addr < (2 + isa_pnp_wsize); s_addr++, wbuf++) { wval = AscReadEEPWord(iop_base, (uchar) s_addr); sum += wval; *wbuf = wval; } if (bus_type & ASC_IS_VL) { cfg_beg = ASC_EEP_DVC_CFG_BEG_VL; cfg_end = ASC_EEP_MAX_DVC_ADDR_VL; } else { cfg_beg = ASC_EEP_DVC_CFG_BEG; cfg_end = ASC_EEP_MAX_DVC_ADDR; } for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) { wval = AscReadEEPWord(iop_base, (uchar) s_addr); sum += wval; *wbuf = wval; } *wbuf = AscReadEEPWord(iop_base, (uchar) s_addr); return (sum); } int AscSetEEPConfigOnce( PortAddr iop_base, ASCEEP_CONFIG dosfar * cfg_buf, ushort bus_type ) { int n_error; ushort dosfar *wbuf; ushort sum; int s_addr; int cfg_beg; int cfg_end; wbuf = (ushort dosfar *) cfg_buf; n_error = 0; sum = 0; for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) { sum += *wbuf; if (*wbuf != AscWriteEEPWord(iop_base, (uchar) s_addr, *wbuf)) { n_error++; } } if (bus_type & ASC_IS_VL) { cfg_beg = ASC_EEP_DVC_CFG_BEG_VL; cfg_end = ASC_EEP_MAX_DVC_ADDR_VL; } else { cfg_beg = ASC_EEP_DVC_CFG_BEG; cfg_end = ASC_EEP_MAX_DVC_ADDR; } for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) { sum += *wbuf; if (*wbuf != AscWriteEEPWord(iop_base, (uchar) s_addr, *wbuf)) { n_error++; } } *wbuf = sum; if (sum != AscWriteEEPWord(iop_base, (uchar) s_addr, sum)) { n_error++; } wbuf = (ushort dosfar *) cfg_buf; for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) { if (*wbuf != AscReadEEPWord(iop_base, (uchar) s_addr)) { n_error++; } } for (s_addr = cfg_beg; s_addr <= cfg_end; s_addr++, wbuf++) { if (*wbuf != AscReadEEPWord(iop_base, (uchar) s_addr)) { n_error++; } } return (n_error); } int AscSetEEPConfig( PortAddr iop_base, ASCEEP_CONFIG dosfar * cfg_buf, ushort bus_type ) { int retry; int n_error; retry = 0; while (TRUE) { if ((n_error = AscSetEEPConfigOnce(iop_base, cfg_buf, bus_type)) == 0) { break; } if (++retry > ASC_EEP_MAX_RETRY) { break; } } return (n_error); } int AscInitPollBegin( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { PortAddr iop_base; iop_base = asc_dvc->iop_base; #if CC_INIT_INQ_DISPLAY DvcDisplayString((uchar dosfar *) "\r\n"); #endif AscDisableInterrupt(iop_base); asc_dvc->init_state |= ASC_INIT_STATE_BEG_INQUIRY; AscWriteLramByte(iop_base, ASCV_DISC_ENABLE_B, 0x00); asc_dvc->use_tagged_qng = 0; asc_dvc->cfg->can_tagged_qng = 0; asc_dvc->saved_ptr2func = (ulong) asc_dvc->isr_callback; asc_dvc->isr_callback = ASC_GET_PTR2FUNC(AscInitPollIsrCallBack); return (0); } int AscInitPollEnd( ASC_DVC_VAR asc_ptr_type * asc_dvc ) { PortAddr iop_base; int i; iop_base = asc_dvc->iop_base; asc_dvc->isr_callback = (Ptr2Func) asc_dvc->saved_ptr2func; AscWriteLramByte(iop_base, ASCV_DISC_ENABLE_B, asc_dvc->cfg->disc_enable); AscWriteLramByte(iop_base, ASCV_USE_TAGGED_QNG_B, asc_dvc->use_tagged_qng); AscWriteLramByte(iop_base, ASCV_CAN_TAGGED_QNG_B, asc_dvc->cfg->can_tagged_qng); for (i = 0; i <= ASC_MAX_TID; i++) { AscWriteLramByte(iop_base, (ushort) ((ushort) ASCV_MAX_DVC_QNG_BEG + (ushort) i), asc_dvc->max_dvc_qng[i]); } AscEnableInterrupt(iop_base); #if CC_INIT_INQ_DISPLAY DvcDisplayString((uchar dosfar *) "\r\n"); #endif asc_dvc->init_state |= ASC_INIT_STATE_END_INQUIRY; return (0); } int _asc_wait_slow_device_ = FALSE; int AscInitPollTarget( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, ASC_SCSI_INQUIRY dosfar * inq, ASC_CAP_INFO dosfar * cap_info ) { uchar tid_no, lun; uchar dvc_type; ASC_SCSI_BIT_ID_TYPE tid_bits; int dvc_found; int support_read_cap; int tmp_disable_init_sdtr; ulong phy_addr; dvc_found = 0; tmp_disable_init_sdtr = FALSE; tid_bits = scsiq->r1.target_id; lun = scsiq->r1.target_lun; tid_no = ASC_TIX_TO_TID(scsiq->r2.target_ix); if ((phy_addr = AscGetOnePhyAddr(asc_dvc, (uchar dosfar *) scsiq->sense_ptr, (ulong) scsiq->r1.sense_len)) == 0L) { return (ERR); } scsiq->r1.sense_addr = phy_addr; if (((asc_dvc->init_sdtr & tid_bits) != 0) && ((asc_dvc->sdtr_done & tid_bits) == 0)) { asc_dvc->init_sdtr &= ~tid_bits; tmp_disable_init_sdtr = TRUE; } ASC_DBG(3, "AscInitPollTarget: PollScsiInquiry()\n"); if (PollScsiInquiry(asc_dvc, scsiq, (uchar dosfar *) inq, sizeof (ASC_SCSI_INQUIRY)) == 1) { dvc_found = 1; support_read_cap = TRUE; dvc_type = inq->byte0.peri_dvc_type; if (dvc_type != SCSI_TYPE_UNKNOWN) { if ((dvc_type != SCSI_TYPE_DASD) && (dvc_type != SCSI_TYPE_WORM) && (dvc_type != SCSI_TYPE_CDROM) && (dvc_type != SCSI_TYPE_OPTMEM)) { asc_dvc->start_motor &= ~tid_bits; support_read_cap = FALSE; } if ((dvc_type != SCSI_TYPE_DASD) || inq->byte1.rmb) { if (!_asc_wait_slow_device_) { DvcSleepMilliSecond(3000 - ((int) tid_no * 250)); _asc_wait_slow_device_ = TRUE; } } #if CC_INIT_INQ_DISPLAY AscDispInquiry(tid_no, lun, inq); #endif if (lun == 0) { if ((inq->byte3.rsp_data_fmt >= 2) || (inq->byte2.ansi_apr_ver >= 2)) { if (inq->byte7.CmdQue) { asc_dvc->cfg->can_tagged_qng |= tid_bits; if (asc_dvc->cfg->cmd_qng_enabled & tid_bits) { asc_dvc->use_tagged_qng |= tid_bits; asc_dvc->max_dvc_qng[tid_no] = asc_dvc->cfg->max_tag_qng[tid_no]; } } if (!inq->byte7.Sync) { asc_dvc->init_sdtr &= ~tid_bits; asc_dvc->sdtr_done &= ~tid_bits; } else if (tmp_disable_init_sdtr) { asc_dvc->init_sdtr |= tid_bits; } } else { asc_dvc->init_sdtr &= ~tid_bits; asc_dvc->sdtr_done &= ~tid_bits; asc_dvc->use_tagged_qng &= ~tid_bits; } } if (asc_dvc->pci_fix_asyn_xfer & tid_bits) { if (!(asc_dvc->init_sdtr & tid_bits)) { AscSetRunChipSynRegAtID(asc_dvc->iop_base, tid_no, ASYN_SDTR_DATA_FIX_PCI_REV_AB); } } ASC_DBG(3, "AscInitPollTarget: InitTestUnitReady()\n"); if (InitTestUnitReady(asc_dvc, scsiq) != 1) { } else { if ((cap_info != 0L) && support_read_cap) { ASC_DBG(3, "AscInitPollTarget: PollScsiReadCapacity()\n"); if (PollScsiReadCapacity(asc_dvc, scsiq, cap_info) != 1) { cap_info->lba = 0L; cap_info->blk_size = 0x0000; } else { } } } } else { asc_dvc->start_motor &= ~tid_bits; } } else { } return (dvc_found); } int PollQueueDone( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, int timeout_sec ) { int status; int retry; retry = 0; do { ASC_DBG(3, "PollQueueDone: AscExeScsiQueue()\n"); if ((status = AscExeScsiQueue(asc_dvc, (ASC_SCSI_Q dosfar *) scsiq)) == 1) { ASC_DBG(3, "PollQueueDone: AscPollQDone()\n"); if ((status = AscPollQDone(asc_dvc, scsiq, timeout_sec)) != 1) { ASC_DBG1(3, "PollQueueDone: AscPollQDone() status %x\n", status); if (status == 0x80) { if (retry++ > ASC_MAX_INIT_BUSY_RETRY) { break; } scsiq->r3.done_stat = 0; scsiq->r3.host_stat = 0; scsiq->r3.scsi_stat = 0; scsiq->r3.scsi_msg = 0; DvcSleepMilliSecond(100); continue; } scsiq->r3.done_stat = 0; scsiq->r3.host_stat = 0; scsiq->r3.scsi_stat = 0; scsiq->r3.scsi_msg = 0; ASC_DBG1(3, "PollQueueDone: AscAbortSRB() scsiq %x\n", (unsigned) scsiq); AscAbortSRB(asc_dvc, (ulong) scsiq); } ASC_DBG1(3, "PollQueueDone: done_stat %x\n", scsiq->r3.done_stat); return (scsiq->r3.done_stat); } } while ((status == 0) || (status == 0x80)); ASC_DBG(3, "PollQueueDone: done_stat QD_WITH_ERROR\n"); return (scsiq->r3.done_stat = QD_WITH_ERROR); } int PollScsiInquiry( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, uchar dosfar * buf, int buf_len ) { if (AscScsiInquiry(asc_dvc, scsiq, buf, buf_len) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } return (PollQueueDone(asc_dvc, (ASC_SCSI_REQ_Q dosfar *) scsiq, 4)); } int PollScsiReadCapacity( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, ASC_CAP_INFO dosfar * cap_info ) { ASC_CAP_INFO scsi_cap_info; int status; if (AscScsiReadCapacity(asc_dvc, scsiq, (uchar dosfar *) & scsi_cap_info) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } status = PollQueueDone(asc_dvc, (ASC_SCSI_REQ_Q dosfar *) scsiq, 8); if (status == 1) { #if CC_LITTLE_ENDIAN_HOST cap_info->lba = (ulong) * swapfarbuf4((uchar dosfar *) & scsi_cap_info.lba); cap_info->blk_size = (ulong) * swapfarbuf4((uchar dosfar *) & scsi_cap_info.blk_size); #else cap_info->lba = scsi_cap_info.lba; cap_info->blk_size = scsi_cap_info.blk_size; #endif return (scsiq->r3.done_stat); } return (scsiq->r3.done_stat = QD_WITH_ERROR); } ulong dosfar * swapfarbuf4( uchar dosfar * buf ) { uchar tmp; tmp = buf[3]; buf[3] = buf[0]; buf[0] = tmp; tmp = buf[1]; buf[1] = buf[2]; buf[2] = tmp; return ((ulong dosfar *) buf); } int PollScsiTestUnitReady( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq ) { if (AscScsiTestUnitReady(asc_dvc, scsiq) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } return (PollQueueDone(asc_dvc, (ASC_SCSI_REQ_Q dosfar *) scsiq, 12)); } int PollScsiStartUnit( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq ) { if (AscScsiStartStopUnit(asc_dvc, scsiq, 1) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } return (PollQueueDone(asc_dvc, (ASC_SCSI_REQ_Q dosfar *) scsiq, 40)); } int InitTestUnitReady( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq ) { ASC_SCSI_BIT_ID_TYPE tid_bits; int retry; ASC_REQ_SENSE dosfar *sen; retry = 0; tid_bits = scsiq->r1.target_id; while (retry++ < 2) { ASC_DBG(3, "InitTestUnitReady: PollScsiTestUnitReady()\n"); PollScsiTestUnitReady(asc_dvc, scsiq); ASC_DBG1(3, "InitTestUnitReady: done_stat %x\n", scsiq->r3.done_stat); if (scsiq->r3.done_stat == 0x01) { return (1); } else if (scsiq->r3.done_stat == QD_WITH_ERROR) { DvcSleepMilliSecond(100); sen = (ASC_REQ_SENSE dosfar *) scsiq->sense_ptr; if ((scsiq->r3.scsi_stat == SS_CHK_CONDITION) && ((sen->err_code & 0x70) != 0)) { if (sen->sense_key == SCSI_SENKEY_NOT_READY) { if (asc_dvc->start_motor & tid_bits) { if (PollScsiStartUnit(asc_dvc, scsiq) == 1) { retry = 0; continue; } else { asc_dvc->start_motor &= ~tid_bits; break; } } else { DvcSleepMilliSecond(100); } } else if (sen->sense_key == SCSI_SENKEY_ATTENSION) { DvcSleepMilliSecond(100); } else { break; } } else { break; } } else if (scsiq->r3.done_stat == QD_ABORTED_BY_HOST) { break; } else { break; } } return (0); } #if CC_INIT_INQ_DISPLAY #endif int AscPollQDone( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, int timeout_sec ) { int loop, loop_end; int sta; PortAddr iop_base; iop_base = asc_dvc->iop_base; loop = 0; loop_end = timeout_sec * 100; sta = 1; while (TRUE) { ASC_DBG4(3, "AscPollQDone: loop %d, err_code %x, done_stat %x, scsi_stat %x\n", loop, asc_dvc->err_code, scsiq->r3.done_stat, scsiq->r3.scsi_stat); if (asc_dvc->err_code != 0) { scsiq->r3.done_stat = QD_WITH_ERROR; sta = ERR; break; } if (scsiq->r3.done_stat != QD_IN_PROGRESS) { if ((scsiq->r3.done_stat == QD_WITH_ERROR) && (scsiq->r3.scsi_stat == SS_TARGET_BUSY)) { sta = 0x80; break; } break; } DvcSleepMilliSecond(10); if (loop++ > loop_end) { sta = 0; break; } if (AscIsChipHalted(iop_base)) { AscISR(asc_dvc); loop = 0; } else { ASC_DBG(3, "AscPollQDone: AscIsIntPending()\n"); if (AscIsIntPending(iop_base)) { ASC_DBG(3, "AscPollQDone: AscISR()\n"); AscISR(asc_dvc); } } } ASC_DBG1(3, "AscPollQDone: sta %x\n", sta); return (sta); } uchar AscReadLramByte( PortAddr iop_base, ushort addr ) { uchar byte_data; ushort word_data; if (isodd_word(addr)) { AscSetChipLramAddr(iop_base, addr - 1); word_data = AscGetChipLramData(iop_base); #if CC_LITTLE_ENDIAN_HOST byte_data = (uchar) ((word_data >> 8) & 0xFF); #else byte_data = (uchar) (word_data & 0xFF); #endif } else { AscSetChipLramAddr(iop_base, addr); word_data = AscGetChipLramData(iop_base); #if CC_LITTLE_ENDIAN_HOST byte_data = (uchar) (word_data & 0xFF); #else byte_data = (uchar) ((word_data >> 8) & 0xFF); #endif } return (byte_data); } ushort AscReadLramWord( PortAddr iop_base, ushort addr ) { ushort word_data; AscSetChipLramAddr(iop_base, addr); word_data = AscGetChipLramData(iop_base); return (word_data); } ulong AscReadLramDWord( PortAddr iop_base, ushort addr ) { ushort val_low, val_high; ulong dword_data; AscSetChipLramAddr(iop_base, addr); #if CC_LITTLE_ENDIAN_HOST val_low = AscGetChipLramData(iop_base); val_high = AscGetChipLramData(iop_base); #else val_high = AscGetChipLramData(iop_base); val_low = AscGetChipLramData(iop_base); #endif dword_data = ((ulong) val_high << 16) | (ulong) val_low; return (dword_data); } void AscWriteLramWord( PortAddr iop_base, ushort addr, ushort word_val ) { AscSetChipLramAddr(iop_base, addr); AscPutChipLramData(iop_base, word_val); return; } void AscWriteLramDWord( PortAddr iop_base, ushort addr, ulong dword_val ) { ushort word_val; AscSetChipLramAddr(iop_base, addr); #if CC_LITTLE_ENDIAN_HOST word_val = (ushort) dword_val; AscPutChipLramData(iop_base, word_val); word_val = (ushort) (dword_val >> 16); AscPutChipLramData(iop_base, word_val); #else word_val = (ushort) (dword_val >> 16); AscPutChipLramData(iop_base, word_val); word_val = (ushort) dword_val; AscPutChipLramData(iop_base, word_val); #endif return; } void AscWriteLramByte( PortAddr iop_base, ushort addr, uchar byte_val ) { ushort word_data; if (isodd_word(addr)) { addr--; word_data = AscReadLramWord(iop_base, addr); word_data &= 0x00FF; word_data |= (((ushort) byte_val << 8) & 0xFF00); } else { word_data = AscReadLramWord(iop_base, addr); word_data &= 0xFF00; word_data |= ((ushort) byte_val & 0x00FF); } AscWriteLramWord(iop_base, addr, word_data); return; } int AscVerWriteLramWord( PortAddr iop_base, ushort addr, ushort word_val ) { int sta; sta = 0; AscSetChipLramAddr(iop_base, addr); AscPutChipLramData(iop_base, word_val); AscSetChipLramAddr(iop_base, addr); if (word_val != AscGetChipLramData(iop_base)) { sta = ERR; } return (sta); } void AscMemWordCopyToLram( PortAddr iop_base, ushort s_addr, ushort dosfar * s_buffer, int words ) { AscSetChipLramAddr(iop_base, s_addr); DvcOutPortWords(iop_base + IOP_RAM_DATA, s_buffer, words); return; } void AscMemDWordCopyToLram( PortAddr iop_base, ushort s_addr, ulong dosfar * s_buffer, int dwords ) { AscSetChipLramAddr(iop_base, s_addr); DvcOutPortDWords(iop_base + IOP_RAM_DATA, s_buffer, dwords); return; } void AscMemWordCopyFromLram( PortAddr iop_base, ushort s_addr, ushort dosfar * d_buffer, int words ) { AscSetChipLramAddr(iop_base, s_addr); DvcInPortWords(iop_base + IOP_RAM_DATA, d_buffer, words); return; } ulong AscMemSumLramWord( PortAddr iop_base, ushort s_addr, rint words ) { ulong sum; int i; sum = 0L; for (i = 0; i < words; i++, s_addr += 2) { sum += AscReadLramWord(iop_base, s_addr); } return (sum); } void AscMemWordSetLram( PortAddr iop_base, ushort s_addr, ushort set_wval, rint words ) { rint i; AscSetChipLramAddr(iop_base, s_addr); for (i = 0; i < words; i++) { AscPutChipLramData(iop_base, set_wval); } return; } int AscScsiInquiry( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, uchar dosfar * buf, int buf_len ) { if (AscScsiSetupCmdQ(asc_dvc, scsiq, buf, (ulong) buf_len) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } scsiq->cdb[0] = (uchar) SCSICMD_Inquiry; scsiq->cdb[1] = scsiq->r1.target_lun << 5; scsiq->cdb[2] = 0; scsiq->cdb[3] = 0; scsiq->cdb[4] = buf_len; scsiq->cdb[5] = 0; scsiq->r2.cdb_len = 6; return (0); } int AscScsiReadCapacity( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, uchar dosfar * info ) { if (AscScsiSetupCmdQ(asc_dvc, scsiq, info, 8L) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } scsiq->cdb[0] = (uchar) SCSICMD_ReadCapacity; scsiq->cdb[1] = scsiq->r1.target_lun << 5; scsiq->cdb[2] = 0; scsiq->cdb[3] = 0; scsiq->cdb[4] = 0; scsiq->cdb[5] = 0; scsiq->cdb[6] = 0; scsiq->cdb[7] = 0; scsiq->cdb[8] = 0; scsiq->cdb[9] = 0; scsiq->r2.cdb_len = 10; return (0); } int AscScsiTestUnitReady( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq ) { if (AscScsiSetupCmdQ(asc_dvc, scsiq, FNULLPTR, (ulong) 0L) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } scsiq->r1.cntl = (uchar) ASC_SCSIDIR_NODATA; scsiq->cdb[0] = (uchar) SCSICMD_TestUnitReady; scsiq->cdb[1] = scsiq->r1.target_lun << 5; scsiq->cdb[2] = 0; scsiq->cdb[3] = 0; scsiq->cdb[4] = 0; scsiq->cdb[5] = 0; scsiq->r2.cdb_len = 6; return (0); } int AscScsiStartStopUnit( ASC_DVC_VAR asc_ptr_type * asc_dvc, ASC_SCSI_REQ_Q dosfar * scsiq, uchar op_mode ) { if (AscScsiSetupCmdQ(asc_dvc, scsiq, FNULLPTR, (ulong) 0L) == ERR) { return (scsiq->r3.done_stat = QD_WITH_ERROR); } scsiq->r1.cntl = (uchar) ASC_SCSIDIR_NODATA; scsiq->cdb[0] = (uchar) SCSICMD_StartStopUnit; scsiq->cdb[1] = scsiq->r1.target_lun << 5; scsiq->cdb[2] = 0; scsiq->cdb[3] = 0; scsiq->cdb[4] = op_mode; scsiq->cdb[5] = 0; scsiq->r2.cdb_len = 6; return (0); }