freebsd-skq/sys/cam/ata/ata_all.c
pfg 39ac7c1b27 sys/cam: further adoption of SPDX licensing ID tags.
Mainly focus on files that use BSD 2-Clause license, however the tool I
was using misidentified many licenses so this was mostly a manual - error
prone - task.

The Software Package Data Exchange (SPDX) group provides a specification
to make it easier for automated tools to detect and summarize well known
opensource licenses. We are gradually adopting the specification, noting
that the tags are considered only advisory and do not, in any way,
superceed or replace the license texts.
2017-11-27 15:12:43 +00:00

1215 lines
33 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2009 Alexander Motin <mav@FreeBSD.org>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer,
* without modification, immediately at the beginning of the file.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#ifdef _KERNEL
#include "opt_scsi.h"
#include <sys/systm.h>
#include <sys/libkern.h>
#include <sys/kernel.h>
#include <sys/sysctl.h>
#else
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifndef min
#define min(a,b) (((a)<(b))?(a):(b))
#endif
#endif
#include <cam/cam.h>
#include <cam/cam_ccb.h>
#include <cam/cam_queue.h>
#include <cam/cam_xpt.h>
#include <sys/ata.h>
#include <cam/ata/ata_all.h>
#include <sys/sbuf.h>
#include <sys/endian.h>
int
ata_version(int ver)
{
int bit;
if (ver == 0xffff)
return 0;
for (bit = 15; bit >= 0; bit--)
if (ver & (1<<bit))
return bit;
return 0;
}
char *
ata_op_string(struct ata_cmd *cmd)
{
if (cmd->control & 0x04)
return ("SOFT_RESET");
switch (cmd->command) {
case 0x00:
switch (cmd->features) {
case 0x00: return ("NOP FLUSHQUEUE");
case 0x01: return ("NOP AUTOPOLL");
}
return ("NOP");
case 0x03: return ("CFA_REQUEST_EXTENDED_ERROR");
case 0x06:
switch (cmd->features) {
case 0x01: return ("DSM TRIM");
}
return "DSM";
case 0x08: return ("DEVICE_RESET");
case 0x0b: return ("REQUEST_SENSE_DATA_EXT");
case 0x20: return ("READ");
case 0x24: return ("READ48");
case 0x25: return ("READ_DMA48");
case 0x26: return ("READ_DMA_QUEUED48");
case 0x27: return ("READ_NATIVE_MAX_ADDRESS48");
case 0x29: return ("READ_MUL48");
case 0x2a: return ("READ_STREAM_DMA48");
case 0x2b: return ("READ_STREAM48");
case 0x2f: return ("READ_LOG_EXT");
case 0x30: return ("WRITE");
case 0x34: return ("WRITE48");
case 0x35: return ("WRITE_DMA48");
case 0x36: return ("WRITE_DMA_QUEUED48");
case 0x37: return ("SET_MAX_ADDRESS48");
case 0x39: return ("WRITE_MUL48");
case 0x3a: return ("WRITE_STREAM_DMA48");
case 0x3b: return ("WRITE_STREAM48");
case 0x3d: return ("WRITE_DMA_FUA48");
case 0x3e: return ("WRITE_DMA_QUEUED_FUA48");
case 0x3f: return ("WRITE_LOG_EXT");
case 0x40: return ("READ_VERIFY");
case 0x42: return ("READ_VERIFY48");
case 0x44: return ("ZERO_EXT");
case 0x45:
switch (cmd->features) {
case 0x55: return ("WRITE_UNCORRECTABLE48 PSEUDO");
case 0xaa: return ("WRITE_UNCORRECTABLE48 FLAGGED");
}
return "WRITE_UNCORRECTABLE48";
case 0x47: return ("READ_LOG_DMA_EXT");
case 0x4a: return ("ZAC_MANAGEMENT_IN");
case 0x51: return ("CONFIGURE_STREAM");
case 0x57: return ("WRITE_LOG_DMA_EXT");
case 0x5b: return ("TRUSTED_NON_DATA");
case 0x5c: return ("TRUSTED_RECEIVE");
case 0x5d: return ("TRUSTED_RECEIVE_DMA");
case 0x5e: return ("TRUSTED_SEND");
case 0x5f: return ("TRUSTED_SEND_DMA");
case 0x60: return ("READ_FPDMA_QUEUED");
case 0x61: return ("WRITE_FPDMA_QUEUED");
case 0x63:
switch (cmd->features & 0xf) {
case 0x00: return ("NCQ_NON_DATA ABORT NCQ QUEUE");
case 0x01: return ("NCQ_NON_DATA DEADLINE HANDLING");
case 0x05: return ("NCQ_NON_DATA SET FEATURES");
/*
* XXX KDM need common decoding between NCQ and non-NCQ
* versions of SET FEATURES.
*/
case 0x06: return ("NCQ_NON_DATA ZERO EXT");
case 0x07: return ("NCQ_NON_DATA ZAC MANAGEMENT OUT");
}
return ("NCQ_NON_DATA");
case 0x64:
switch (cmd->sector_count_exp & 0xf) {
case 0x00: return ("SEND_FPDMA_QUEUED DATA SET MANAGEMENT");
case 0x02: return ("SEND_FPDMA_QUEUED WRITE LOG DMA EXT");
case 0x03: return ("SEND_FPDMA_QUEUED ZAC MANAGEMENT OUT");
case 0x04: return ("SEND_FPDMA_QUEUED DATA SET MANAGEMENT XL");
}
return ("SEND_FPDMA_QUEUED");
case 0x65:
switch (cmd->sector_count_exp & 0xf) {
case 0x01: return ("RECEIVE_FPDMA_QUEUED READ LOG DMA EXT");
case 0x02: return ("RECEIVE_FPDMA_QUEUED ZAC MANAGEMENT IN");
}
return ("RECEIVE_FPDMA_QUEUED");
case 0x67:
if (cmd->features == 0xec)
return ("SEP_ATTN IDENTIFY");
switch (cmd->lba_low) {
case 0x00: return ("SEP_ATTN READ BUFFER");
case 0x02: return ("SEP_ATTN RECEIVE DIAGNOSTIC RESULTS");
case 0x80: return ("SEP_ATTN WRITE BUFFER");
case 0x82: return ("SEP_ATTN SEND DIAGNOSTIC");
}
return ("SEP_ATTN");
case 0x70: return ("SEEK");
case 0x77: return ("SET_DATE_TIME_EXT");
case 0x78: return ("ACCESSIBLE_MAX_ADDRESS_CONFIGURATION");
case 0x87: return ("CFA_TRANSLATE_SECTOR");
case 0x90: return ("EXECUTE_DEVICE_DIAGNOSTIC");
case 0x92: return ("DOWNLOAD_MICROCODE");
case 0x93: return ("DOWNLOAD_MICROCODE_DMA");
case 0x9a: return ("ZAC_MANAGEMENT_OUT");
case 0xa0: return ("PACKET");
case 0xa1: return ("ATAPI_IDENTIFY");
case 0xa2: return ("SERVICE");
case 0xb0:
switch(cmd->features) {
case 0xd0: return ("SMART READ ATTR VALUES");
case 0xd1: return ("SMART READ ATTR THRESHOLDS");
case 0xd3: return ("SMART SAVE ATTR VALUES");
case 0xd4: return ("SMART EXECUTE OFFLINE IMMEDIATE");
case 0xd5: return ("SMART READ LOG DATA");
case 0xd8: return ("SMART ENABLE OPERATION");
case 0xd9: return ("SMART DISABLE OPERATION");
case 0xda: return ("SMART RETURN STATUS");
}
return ("SMART");
case 0xb1: return ("DEVICE CONFIGURATION");
case 0xb4: return ("SANITIZE_DEVICE");
case 0xc0: return ("CFA_ERASE");
case 0xc4: return ("READ_MUL");
case 0xc5: return ("WRITE_MUL");
case 0xc6: return ("SET_MULTI");
case 0xc7: return ("READ_DMA_QUEUED");
case 0xc8: return ("READ_DMA");
case 0xca: return ("WRITE_DMA");
case 0xcc: return ("WRITE_DMA_QUEUED");
case 0xcd: return ("CFA_WRITE_MULTIPLE_WITHOUT_ERASE");
case 0xce: return ("WRITE_MUL_FUA48");
case 0xd1: return ("CHECK_MEDIA_CARD_TYPE");
case 0xda: return ("GET_MEDIA_STATUS");
case 0xde: return ("MEDIA_LOCK");
case 0xdf: return ("MEDIA_UNLOCK");
case 0xe0: return ("STANDBY_IMMEDIATE");
case 0xe1: return ("IDLE_IMMEDIATE");
case 0xe2: return ("STANDBY");
case 0xe3: return ("IDLE");
case 0xe4: return ("READ_BUFFER/PM");
case 0xe5: return ("CHECK_POWER_MODE");
case 0xe6: return ("SLEEP");
case 0xe7: return ("FLUSHCACHE");
case 0xe8: return ("WRITE_PM");
case 0xea: return ("FLUSHCACHE48");
case 0xec: return ("ATA_IDENTIFY");
case 0xed: return ("MEDIA_EJECT");
case 0xef:
/*
* XXX KDM need common decoding between NCQ and non-NCQ
* versions of SET FEATURES.
*/
switch (cmd->features) {
case 0x02: return ("SETFEATURES ENABLE WCACHE");
case 0x03: return ("SETFEATURES SET TRANSFER MODE");
case 0x04: return ("SETFEATURES ENABLE APM");
case 0x06: return ("SETFEATURES ENABLE PUIS");
case 0x07: return ("SETFEATURES SPIN-UP");
case 0x0b: return ("SETFEATURES ENABLE WRITE READ VERIFY");
case 0x0c: return ("SETFEATURES ENABLE DEVICE LIFE CONTROL");
case 0x10: return ("SETFEATURES ENABLE SATA FEATURE");
case 0x41: return ("SETFEATURES ENABLE FREEFALL CONTROL");
case 0x43: return ("SETFEATURES SET MAX HOST INT SECT TIMES");
case 0x45: return ("SETFEATURES SET RATE BASIS");
case 0x4a: return ("SETFEATURES EXTENDED POWER CONDITIONS");
case 0x55: return ("SETFEATURES DISABLE RCACHE");
case 0x5d: return ("SETFEATURES ENABLE RELIRQ");
case 0x5e: return ("SETFEATURES ENABLE SRVIRQ");
case 0x62: return ("SETFEATURES LONG PHYS SECT ALIGN ERC");
case 0x63: return ("SETFEATURES DSN");
case 0x66: return ("SETFEATURES DISABLE DEFAULTS");
case 0x82: return ("SETFEATURES DISABLE WCACHE");
case 0x85: return ("SETFEATURES DISABLE APM");
case 0x86: return ("SETFEATURES DISABLE PUIS");
case 0x8b: return ("SETFEATURES DISABLE WRITE READ VERIFY");
case 0x8c: return ("SETFEATURES DISABLE DEVICE LIFE CONTROL");
case 0x90: return ("SETFEATURES DISABLE SATA FEATURE");
case 0xaa: return ("SETFEATURES ENABLE RCACHE");
case 0xC1: return ("SETFEATURES DISABLE FREEFALL CONTROL");
case 0xC3: return ("SETFEATURES SENSE DATA REPORTING");
case 0xC4: return ("SETFEATURES NCQ SENSE DATA RETURN");
case 0xCC: return ("SETFEATURES ENABLE DEFAULTS");
case 0xdd: return ("SETFEATURES DISABLE RELIRQ");
case 0xde: return ("SETFEATURES DISABLE SRVIRQ");
}
return "SETFEATURES";
case 0xf1: return ("SECURITY_SET_PASSWORD");
case 0xf2: return ("SECURITY_UNLOCK");
case 0xf3: return ("SECURITY_ERASE_PREPARE");
case 0xf4: return ("SECURITY_ERASE_UNIT");
case 0xf5: return ("SECURITY_FREEZE_LOCK");
case 0xf6: return ("SECURITY_DISABLE_PASSWORD");
case 0xf8: return ("READ_NATIVE_MAX_ADDRESS");
case 0xf9: return ("SET_MAX_ADDRESS");
}
return "UNKNOWN";
}
char *
ata_cmd_string(struct ata_cmd *cmd, char *cmd_string, size_t len)
{
struct sbuf sb;
int error;
if (len == 0)
return ("");
sbuf_new(&sb, cmd_string, len, SBUF_FIXEDLEN);
ata_cmd_sbuf(cmd, &sb);
error = sbuf_finish(&sb);
if (error != 0 && error != ENOMEM)
return ("");
return(sbuf_data(&sb));
}
void
ata_cmd_sbuf(struct ata_cmd *cmd, struct sbuf *sb)
{
sbuf_printf(sb, "%02x %02x %02x %02x "
"%02x %02x %02x %02x %02x %02x %02x %02x",
cmd->command, cmd->features,
cmd->lba_low, cmd->lba_mid, cmd->lba_high, cmd->device,
cmd->lba_low_exp, cmd->lba_mid_exp, cmd->lba_high_exp,
cmd->features_exp, cmd->sector_count, cmd->sector_count_exp);
}
char *
ata_res_string(struct ata_res *res, char *res_string, size_t len)
{
struct sbuf sb;
int error;
if (len == 0)
return ("");
sbuf_new(&sb, res_string, len, SBUF_FIXEDLEN);
ata_res_sbuf(res, &sb);
error = sbuf_finish(&sb);
if (error != 0 && error != ENOMEM)
return ("");
return(sbuf_data(&sb));
}
int
ata_res_sbuf(struct ata_res *res, struct sbuf *sb)
{
sbuf_printf(sb, "%02x %02x %02x %02x "
"%02x %02x %02x %02x %02x %02x %02x",
res->status, res->error,
res->lba_low, res->lba_mid, res->lba_high, res->device,
res->lba_low_exp, res->lba_mid_exp, res->lba_high_exp,
res->sector_count, res->sector_count_exp);
return (0);
}
/*
* ata_command_sbuf() returns 0 for success and -1 for failure.
*/
int
ata_command_sbuf(struct ccb_ataio *ataio, struct sbuf *sb)
{
sbuf_printf(sb, "%s. ACB: ",
ata_op_string(&ataio->cmd));
ata_cmd_sbuf(&ataio->cmd, sb);
return(0);
}
/*
* ata_status_abuf() returns 0 for success and -1 for failure.
*/
int
ata_status_sbuf(struct ccb_ataio *ataio, struct sbuf *sb)
{
sbuf_printf(sb, "ATA status: %02x (%s%s%s%s%s%s%s%s)",
ataio->res.status,
(ataio->res.status & 0x80) ? "BSY " : "",
(ataio->res.status & 0x40) ? "DRDY " : "",
(ataio->res.status & 0x20) ? "DF " : "",
(ataio->res.status & 0x10) ? "SERV " : "",
(ataio->res.status & 0x08) ? "DRQ " : "",
(ataio->res.status & 0x04) ? "CORR " : "",
(ataio->res.status & 0x02) ? "IDX " : "",
(ataio->res.status & 0x01) ? "ERR" : "");
if (ataio->res.status & 1) {
sbuf_printf(sb, ", error: %02x (%s%s%s%s%s%s%s%s)",
ataio->res.error,
(ataio->res.error & 0x80) ? "ICRC " : "",
(ataio->res.error & 0x40) ? "UNC " : "",
(ataio->res.error & 0x20) ? "MC " : "",
(ataio->res.error & 0x10) ? "IDNF " : "",
(ataio->res.error & 0x08) ? "MCR " : "",
(ataio->res.error & 0x04) ? "ABRT " : "",
(ataio->res.error & 0x02) ? "NM " : "",
(ataio->res.error & 0x01) ? "ILI" : "");
}
return(0);
}
void
ata_print_ident(struct ata_params *ident_data)
{
const char *proto;
char ata[12], sata[12];
ata_print_ident_short(ident_data);
proto = (ident_data->config == ATA_PROTO_CFA) ? "CFA" :
(ident_data->config & ATA_PROTO_ATAPI) ? "ATAPI" : "ATA";
if (ata_version(ident_data->version_major) == 0) {
snprintf(ata, sizeof(ata), "%s", proto);
} else if (ata_version(ident_data->version_major) <= 7) {
snprintf(ata, sizeof(ata), "%s-%d", proto,
ata_version(ident_data->version_major));
} else if (ata_version(ident_data->version_major) == 8) {
snprintf(ata, sizeof(ata), "%s8-ACS", proto);
} else {
snprintf(ata, sizeof(ata), "ACS-%d %s",
ata_version(ident_data->version_major) - 7, proto);
}
if (ident_data->satacapabilities && ident_data->satacapabilities != 0xffff) {
if (ident_data->satacapabilities & ATA_SATA_GEN3)
snprintf(sata, sizeof(sata), " SATA 3.x");
else if (ident_data->satacapabilities & ATA_SATA_GEN2)
snprintf(sata, sizeof(sata), " SATA 2.x");
else if (ident_data->satacapabilities & ATA_SATA_GEN1)
snprintf(sata, sizeof(sata), " SATA 1.x");
else
snprintf(sata, sizeof(sata), " SATA");
} else
sata[0] = 0;
printf(" %s%s device\n", ata, sata);
}
void
ata_print_ident_sbuf(struct ata_params *ident_data, struct sbuf *sb)
{
const char *proto, *sata;
int version;
ata_print_ident_short_sbuf(ident_data, sb);
sbuf_printf(sb, " ");
proto = (ident_data->config == ATA_PROTO_CFA) ? "CFA" :
(ident_data->config & ATA_PROTO_ATAPI) ? "ATAPI" : "ATA";
version = ata_version(ident_data->version_major);
switch (version) {
case 0:
sbuf_printf(sb, "%s", proto);
break;
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
sbuf_printf(sb, "%s-%d", proto, version);
break;
case 8:
sbuf_printf(sb, "%s8-ACS", proto);
break;
default:
sbuf_printf(sb, "ACS-%d %s", version - 7, proto);
break;
}
if (ident_data->satacapabilities && ident_data->satacapabilities != 0xffff) {
if (ident_data->satacapabilities & ATA_SATA_GEN3)
sata = " SATA 3.x";
else if (ident_data->satacapabilities & ATA_SATA_GEN2)
sata = " SATA 2.x";
else if (ident_data->satacapabilities & ATA_SATA_GEN1)
sata = " SATA 1.x";
else
sata = " SATA";
} else
sata = "";
sbuf_printf(sb, "%s device\n", sata);
}
void
ata_print_ident_short(struct ata_params *ident_data)
{
char product[48], revision[16];
cam_strvis(product, ident_data->model, sizeof(ident_data->model),
sizeof(product));
cam_strvis(revision, ident_data->revision, sizeof(ident_data->revision),
sizeof(revision));
printf("<%s %s>", product, revision);
}
void
ata_print_ident_short_sbuf(struct ata_params *ident_data, struct sbuf *sb)
{
sbuf_printf(sb, "<");
cam_strvis_sbuf(sb, ident_data->model, sizeof(ident_data->model), 0);
sbuf_printf(sb, " ");
cam_strvis_sbuf(sb, ident_data->revision, sizeof(ident_data->revision), 0);
sbuf_printf(sb, ">");
}
void
semb_print_ident(struct sep_identify_data *ident_data)
{
char in[7], ins[5];
semb_print_ident_short(ident_data);
cam_strvis(in, ident_data->interface_id, 6, sizeof(in));
cam_strvis(ins, ident_data->interface_rev, 4, sizeof(ins));
printf(" SEMB %s %s device\n", in, ins);
}
void
semb_print_ident_sbuf(struct sep_identify_data *ident_data, struct sbuf *sb)
{
semb_print_ident_short_sbuf(ident_data, sb);
sbuf_printf(sb, " SEMB ");
cam_strvis_sbuf(sb, ident_data->interface_id, 6, 0);
sbuf_printf(sb, " ");
cam_strvis_sbuf(sb, ident_data->interface_rev, 4, 0);
sbuf_printf(sb, " device\n");
}
void
semb_print_ident_short(struct sep_identify_data *ident_data)
{
char vendor[9], product[17], revision[5], fw[5];
cam_strvis(vendor, ident_data->vendor_id, 8, sizeof(vendor));
cam_strvis(product, ident_data->product_id, 16, sizeof(product));
cam_strvis(revision, ident_data->product_rev, 4, sizeof(revision));
cam_strvis(fw, ident_data->firmware_rev, 4, sizeof(fw));
printf("<%s %s %s %s>", vendor, product, revision, fw);
}
void
semb_print_ident_short_sbuf(struct sep_identify_data *ident_data, struct sbuf *sb)
{
sbuf_printf(sb, "<");
cam_strvis_sbuf(sb, ident_data->vendor_id, 8, 0);
sbuf_printf(sb, " ");
cam_strvis_sbuf(sb, ident_data->product_id, 16, 0);
sbuf_printf(sb, " ");
cam_strvis_sbuf(sb, ident_data->product_rev, 4, 0);
sbuf_printf(sb, " ");
cam_strvis_sbuf(sb, ident_data->firmware_rev, 4, 0);
sbuf_printf(sb, ">");
}
uint32_t
ata_logical_sector_size(struct ata_params *ident_data)
{
if ((ident_data->pss & ATA_PSS_VALID_MASK) == ATA_PSS_VALID_VALUE &&
(ident_data->pss & ATA_PSS_LSSABOVE512)) {
return (((u_int32_t)ident_data->lss_1 |
((u_int32_t)ident_data->lss_2 << 16)) * 2);
}
return (512);
}
uint64_t
ata_physical_sector_size(struct ata_params *ident_data)
{
if ((ident_data->pss & ATA_PSS_VALID_MASK) == ATA_PSS_VALID_VALUE) {
if (ident_data->pss & ATA_PSS_MULTLS) {
return ((uint64_t)ata_logical_sector_size(ident_data) *
(1 << (ident_data->pss & ATA_PSS_LSPPS)));
} else {
return (uint64_t)ata_logical_sector_size(ident_data);
}
}
return (512);
}
uint64_t
ata_logical_sector_offset(struct ata_params *ident_data)
{
if ((ident_data->lsalign & 0xc000) == 0x4000) {
return ((uint64_t)ata_logical_sector_size(ident_data) *
(ident_data->lsalign & 0x3fff));
}
return (0);
}
void
ata_28bit_cmd(struct ccb_ataio *ataio, uint8_t cmd, uint8_t features,
uint32_t lba, uint8_t sector_count)
{
bzero(&ataio->cmd, sizeof(ataio->cmd));
ataio->cmd.flags = 0;
if (cmd == ATA_READ_DMA ||
cmd == ATA_READ_DMA_QUEUED ||
cmd == ATA_WRITE_DMA ||
cmd == ATA_WRITE_DMA_QUEUED)
ataio->cmd.flags |= CAM_ATAIO_DMA;
ataio->cmd.command = cmd;
ataio->cmd.features = features;
ataio->cmd.lba_low = lba;
ataio->cmd.lba_mid = lba >> 8;
ataio->cmd.lba_high = lba >> 16;
ataio->cmd.device = ATA_DEV_LBA | ((lba >> 24) & 0x0f);
ataio->cmd.sector_count = sector_count;
}
void
ata_48bit_cmd(struct ccb_ataio *ataio, uint8_t cmd, uint16_t features,
uint64_t lba, uint16_t sector_count)
{
ataio->cmd.flags = CAM_ATAIO_48BIT;
if (cmd == ATA_READ_DMA48 ||
cmd == ATA_READ_DMA_QUEUED48 ||
cmd == ATA_READ_STREAM_DMA48 ||
cmd == ATA_WRITE_DMA48 ||
cmd == ATA_WRITE_DMA_FUA48 ||
cmd == ATA_WRITE_DMA_QUEUED48 ||
cmd == ATA_WRITE_DMA_QUEUED_FUA48 ||
cmd == ATA_WRITE_STREAM_DMA48 ||
cmd == ATA_DATA_SET_MANAGEMENT ||
cmd == ATA_READ_LOG_DMA_EXT)
ataio->cmd.flags |= CAM_ATAIO_DMA;
ataio->cmd.command = cmd;
ataio->cmd.features = features;
ataio->cmd.lba_low = lba;
ataio->cmd.lba_mid = lba >> 8;
ataio->cmd.lba_high = lba >> 16;
ataio->cmd.device = ATA_DEV_LBA;
ataio->cmd.lba_low_exp = lba >> 24;
ataio->cmd.lba_mid_exp = lba >> 32;
ataio->cmd.lba_high_exp = lba >> 40;
ataio->cmd.features_exp = features >> 8;
ataio->cmd.sector_count = sector_count;
ataio->cmd.sector_count_exp = sector_count >> 8;
ataio->cmd.control = 0;
}
void
ata_ncq_cmd(struct ccb_ataio *ataio, uint8_t cmd,
uint64_t lba, uint16_t sector_count)
{
ataio->cmd.flags = CAM_ATAIO_48BIT | CAM_ATAIO_FPDMA;
ataio->cmd.command = cmd;
ataio->cmd.features = sector_count;
ataio->cmd.lba_low = lba;
ataio->cmd.lba_mid = lba >> 8;
ataio->cmd.lba_high = lba >> 16;
ataio->cmd.device = ATA_DEV_LBA;
ataio->cmd.lba_low_exp = lba >> 24;
ataio->cmd.lba_mid_exp = lba >> 32;
ataio->cmd.lba_high_exp = lba >> 40;
ataio->cmd.features_exp = sector_count >> 8;
ataio->cmd.sector_count = 0;
ataio->cmd.sector_count_exp = 0;
ataio->cmd.control = 0;
}
void
ata_reset_cmd(struct ccb_ataio *ataio)
{
bzero(&ataio->cmd, sizeof(ataio->cmd));
ataio->cmd.flags = CAM_ATAIO_CONTROL | CAM_ATAIO_NEEDRESULT;
ataio->cmd.control = 0x04;
}
void
ata_pm_read_cmd(struct ccb_ataio *ataio, int reg, int port)
{
bzero(&ataio->cmd, sizeof(ataio->cmd));
ataio->cmd.flags = CAM_ATAIO_NEEDRESULT;
ataio->cmd.command = ATA_READ_PM;
ataio->cmd.features = reg;
ataio->cmd.device = port & 0x0f;
}
void
ata_pm_write_cmd(struct ccb_ataio *ataio, int reg, int port, uint32_t val)
{
bzero(&ataio->cmd, sizeof(ataio->cmd));
ataio->cmd.flags = 0;
ataio->cmd.command = ATA_WRITE_PM;
ataio->cmd.features = reg;
ataio->cmd.sector_count = val;
ataio->cmd.lba_low = val >> 8;
ataio->cmd.lba_mid = val >> 16;
ataio->cmd.lba_high = val >> 24;
ataio->cmd.device = port & 0x0f;
}
void
ata_read_log(struct ccb_ataio *ataio, uint32_t retries,
void (*cbfcnp)(struct cam_periph *, union ccb *),
uint32_t log_address, uint32_t page_number, uint16_t block_count,
uint32_t protocol, uint8_t *data_ptr, uint32_t dxfer_len,
uint32_t timeout)
{
uint64_t lba;
cam_fill_ataio(ataio,
/*retries*/ 1,
/*cbfcnp*/ cbfcnp,
/*flags*/ CAM_DIR_IN,
/*tag_action*/ 0,
/*data_ptr*/ data_ptr,
/*dxfer_len*/ dxfer_len,
/*timeout*/ timeout);
lba = (((uint64_t)page_number & 0xff00) << 32) |
((page_number & 0x00ff) << 8) |
(log_address & 0xff);
ata_48bit_cmd(ataio,
/*cmd*/ (protocol & CAM_ATAIO_DMA) ? ATA_READ_LOG_DMA_EXT :
ATA_READ_LOG_EXT,
/*features*/ 0,
/*lba*/ lba,
/*sector_count*/ block_count);
}
void
ata_bswap(int8_t *buf, int len)
{
u_int16_t *ptr = (u_int16_t*)(buf + len);
while (--ptr >= (u_int16_t*)buf)
*ptr = be16toh(*ptr);
}
void
ata_btrim(int8_t *buf, int len)
{
int8_t *ptr;
for (ptr = buf; ptr < buf+len; ++ptr)
if (!*ptr || *ptr == '_')
*ptr = ' ';
for (ptr = buf + len - 1; ptr >= buf && *ptr == ' '; --ptr)
*ptr = 0;
}
void
ata_bpack(int8_t *src, int8_t *dst, int len)
{
int i, j, blank;
for (i = j = blank = 0 ; i < len; i++) {
if (blank && src[i] == ' ') continue;
if (blank && src[i] != ' ') {
dst[j++] = src[i];
blank = 0;
continue;
}
if (src[i] == ' ') {
blank = 1;
if (i == 0)
continue;
}
dst[j++] = src[i];
}
while (j < len)
dst[j++] = 0x00;
}
int
ata_max_pmode(struct ata_params *ap)
{
if (ap->atavalid & ATA_FLAG_64_70) {
if (ap->apiomodes & 0x02)
return ATA_PIO4;
if (ap->apiomodes & 0x01)
return ATA_PIO3;
}
if (ap->mwdmamodes & 0x04)
return ATA_PIO4;
if (ap->mwdmamodes & 0x02)
return ATA_PIO3;
if (ap->mwdmamodes & 0x01)
return ATA_PIO2;
if ((ap->retired_piomode & ATA_RETIRED_PIO_MASK) == 0x200)
return ATA_PIO2;
if ((ap->retired_piomode & ATA_RETIRED_PIO_MASK) == 0x100)
return ATA_PIO1;
if ((ap->retired_piomode & ATA_RETIRED_PIO_MASK) == 0x000)
return ATA_PIO0;
return ATA_PIO0;
}
int
ata_max_wmode(struct ata_params *ap)
{
if (ap->mwdmamodes & 0x04)
return ATA_WDMA2;
if (ap->mwdmamodes & 0x02)
return ATA_WDMA1;
if (ap->mwdmamodes & 0x01)
return ATA_WDMA0;
return -1;
}
int
ata_max_umode(struct ata_params *ap)
{
if (ap->atavalid & ATA_FLAG_88) {
if (ap->udmamodes & 0x40)
return ATA_UDMA6;
if (ap->udmamodes & 0x20)
return ATA_UDMA5;
if (ap->udmamodes & 0x10)
return ATA_UDMA4;
if (ap->udmamodes & 0x08)
return ATA_UDMA3;
if (ap->udmamodes & 0x04)
return ATA_UDMA2;
if (ap->udmamodes & 0x02)
return ATA_UDMA1;
if (ap->udmamodes & 0x01)
return ATA_UDMA0;
}
return -1;
}
int
ata_max_mode(struct ata_params *ap, int maxmode)
{
if (maxmode == 0)
maxmode = ATA_DMA_MAX;
if (maxmode >= ATA_UDMA0 && ata_max_umode(ap) > 0)
return (min(maxmode, ata_max_umode(ap)));
if (maxmode >= ATA_WDMA0 && ata_max_wmode(ap) > 0)
return (min(maxmode, ata_max_wmode(ap)));
return (min(maxmode, ata_max_pmode(ap)));
}
char *
ata_mode2string(int mode)
{
switch (mode) {
case -1: return "UNSUPPORTED";
case 0: return "NONE";
case ATA_PIO0: return "PIO0";
case ATA_PIO1: return "PIO1";
case ATA_PIO2: return "PIO2";
case ATA_PIO3: return "PIO3";
case ATA_PIO4: return "PIO4";
case ATA_WDMA0: return "WDMA0";
case ATA_WDMA1: return "WDMA1";
case ATA_WDMA2: return "WDMA2";
case ATA_UDMA0: return "UDMA0";
case ATA_UDMA1: return "UDMA1";
case ATA_UDMA2: return "UDMA2";
case ATA_UDMA3: return "UDMA3";
case ATA_UDMA4: return "UDMA4";
case ATA_UDMA5: return "UDMA5";
case ATA_UDMA6: return "UDMA6";
default:
if (mode & ATA_DMA_MASK)
return "BIOSDMA";
else
return "BIOSPIO";
}
}
int
ata_string2mode(char *str)
{
if (!strcasecmp(str, "PIO0")) return (ATA_PIO0);
if (!strcasecmp(str, "PIO1")) return (ATA_PIO1);
if (!strcasecmp(str, "PIO2")) return (ATA_PIO2);
if (!strcasecmp(str, "PIO3")) return (ATA_PIO3);
if (!strcasecmp(str, "PIO4")) return (ATA_PIO4);
if (!strcasecmp(str, "WDMA0")) return (ATA_WDMA0);
if (!strcasecmp(str, "WDMA1")) return (ATA_WDMA1);
if (!strcasecmp(str, "WDMA2")) return (ATA_WDMA2);
if (!strcasecmp(str, "UDMA0")) return (ATA_UDMA0);
if (!strcasecmp(str, "UDMA16")) return (ATA_UDMA0);
if (!strcasecmp(str, "UDMA1")) return (ATA_UDMA1);
if (!strcasecmp(str, "UDMA25")) return (ATA_UDMA1);
if (!strcasecmp(str, "UDMA2")) return (ATA_UDMA2);
if (!strcasecmp(str, "UDMA33")) return (ATA_UDMA2);
if (!strcasecmp(str, "UDMA3")) return (ATA_UDMA3);
if (!strcasecmp(str, "UDMA44")) return (ATA_UDMA3);
if (!strcasecmp(str, "UDMA4")) return (ATA_UDMA4);
if (!strcasecmp(str, "UDMA66")) return (ATA_UDMA4);
if (!strcasecmp(str, "UDMA5")) return (ATA_UDMA5);
if (!strcasecmp(str, "UDMA100")) return (ATA_UDMA5);
if (!strcasecmp(str, "UDMA6")) return (ATA_UDMA6);
if (!strcasecmp(str, "UDMA133")) return (ATA_UDMA6);
return (-1);
}
u_int
ata_mode2speed(int mode)
{
switch (mode) {
case ATA_PIO0:
default:
return (3300);
case ATA_PIO1:
return (5200);
case ATA_PIO2:
return (8300);
case ATA_PIO3:
return (11100);
case ATA_PIO4:
return (16700);
case ATA_WDMA0:
return (4200);
case ATA_WDMA1:
return (13300);
case ATA_WDMA2:
return (16700);
case ATA_UDMA0:
return (16700);
case ATA_UDMA1:
return (25000);
case ATA_UDMA2:
return (33300);
case ATA_UDMA3:
return (44400);
case ATA_UDMA4:
return (66700);
case ATA_UDMA5:
return (100000);
case ATA_UDMA6:
return (133000);
}
}
u_int
ata_revision2speed(int revision)
{
switch (revision) {
case 1:
default:
return (150000);
case 2:
return (300000);
case 3:
return (600000);
}
}
int
ata_speed2revision(u_int speed)
{
switch (speed) {
case 0:
return (0);
case 150000:
return (1);
case 300000:
return (2);
case 600000:
return (3);
default:
return (-1);
}
}
int
ata_identify_match(caddr_t identbuffer, caddr_t table_entry)
{
struct scsi_inquiry_pattern *entry;
struct ata_params *ident;
entry = (struct scsi_inquiry_pattern *)table_entry;
ident = (struct ata_params *)identbuffer;
if ((cam_strmatch(ident->model, entry->product,
sizeof(ident->model)) == 0)
&& (cam_strmatch(ident->revision, entry->revision,
sizeof(ident->revision)) == 0)) {
return (0);
}
return (-1);
}
int
ata_static_identify_match(caddr_t identbuffer, caddr_t table_entry)
{
struct scsi_static_inquiry_pattern *entry;
struct ata_params *ident;
entry = (struct scsi_static_inquiry_pattern *)table_entry;
ident = (struct ata_params *)identbuffer;
if ((cam_strmatch(ident->model, entry->product,
sizeof(ident->model)) == 0)
&& (cam_strmatch(ident->revision, entry->revision,
sizeof(ident->revision)) == 0)) {
return (0);
}
return (-1);
}
void
semb_receive_diagnostic_results(struct ccb_ataio *ataio,
u_int32_t retries, void (*cbfcnp)(struct cam_periph *, union ccb*),
uint8_t tag_action, int pcv, uint8_t page_code,
uint8_t *data_ptr, uint16_t length, uint32_t timeout)
{
length = min(length, 1020);
length = (length + 3) & ~3;
cam_fill_ataio(ataio,
retries,
cbfcnp,
/*flags*/CAM_DIR_IN,
tag_action,
data_ptr,
length,
timeout);
ata_28bit_cmd(ataio, ATA_SEP_ATTN,
pcv ? page_code : 0, 0x02, length / 4);
}
void
semb_send_diagnostic(struct ccb_ataio *ataio,
u_int32_t retries, void (*cbfcnp)(struct cam_periph *, union ccb *),
uint8_t tag_action, uint8_t *data_ptr, uint16_t length, uint32_t timeout)
{
length = min(length, 1020);
length = (length + 3) & ~3;
cam_fill_ataio(ataio,
retries,
cbfcnp,
/*flags*/length ? CAM_DIR_OUT : CAM_DIR_NONE,
tag_action,
data_ptr,
length,
timeout);
ata_28bit_cmd(ataio, ATA_SEP_ATTN,
length > 0 ? data_ptr[0] : 0, 0x82, length / 4);
}
void
semb_read_buffer(struct ccb_ataio *ataio,
u_int32_t retries, void (*cbfcnp)(struct cam_periph *, union ccb*),
uint8_t tag_action, uint8_t page_code,
uint8_t *data_ptr, uint16_t length, uint32_t timeout)
{
length = min(length, 1020);
length = (length + 3) & ~3;
cam_fill_ataio(ataio,
retries,
cbfcnp,
/*flags*/CAM_DIR_IN,
tag_action,
data_ptr,
length,
timeout);
ata_28bit_cmd(ataio, ATA_SEP_ATTN,
page_code, 0x00, length / 4);
}
void
semb_write_buffer(struct ccb_ataio *ataio,
u_int32_t retries, void (*cbfcnp)(struct cam_periph *, union ccb *),
uint8_t tag_action, uint8_t *data_ptr, uint16_t length, uint32_t timeout)
{
length = min(length, 1020);
length = (length + 3) & ~3;
cam_fill_ataio(ataio,
retries,
cbfcnp,
/*flags*/length ? CAM_DIR_OUT : CAM_DIR_NONE,
tag_action,
data_ptr,
length,
timeout);
ata_28bit_cmd(ataio, ATA_SEP_ATTN,
length > 0 ? data_ptr[0] : 0, 0x80, length / 4);
}
void
ata_zac_mgmt_out(struct ccb_ataio *ataio, uint32_t retries,
void (*cbfcnp)(struct cam_periph *, union ccb *),
int use_ncq, uint8_t zm_action, uint64_t zone_id,
uint8_t zone_flags, uint16_t sector_count, uint8_t *data_ptr,
uint32_t dxfer_len, uint32_t timeout)
{
uint8_t command_out, ata_flags;
uint16_t features_out, sectors_out;
uint32_t auxiliary;
if (use_ncq == 0) {
command_out = ATA_ZAC_MANAGEMENT_OUT;
features_out = (zm_action & 0xf) | (zone_flags << 8);
if (dxfer_len == 0) {
ata_flags = 0;
sectors_out = 0;
} else {
ata_flags = CAM_ATAIO_DMA;
/* XXX KDM use sector count? */
sectors_out = ((dxfer_len >> 9) & 0xffff);
}
auxiliary = 0;
} else {
if (dxfer_len == 0) {
command_out = ATA_NCQ_NON_DATA;
features_out = ATA_NCQ_ZAC_MGMT_OUT;
sectors_out = 0;
} else {
command_out = ATA_SEND_FPDMA_QUEUED;
/* Note that we're defaulting to normal priority */
sectors_out = ATA_SFPDMA_ZAC_MGMT_OUT << 8;
/*
* For SEND FPDMA QUEUED, the transfer length is
* encoded in the FEATURE register, and 0 means
* that 65536 512 byte blocks are to be tranferred.
* In practice, it seems unlikely that we'll see
* a transfer that large.
*/
if (dxfer_len == (65536 * 512)) {
features_out = 0;
} else {
/*
* Yes, the caller can theoretically send a
* transfer larger than we can handle.
* Anyone using this function needs enough
* knowledge to avoid doing that.
*/
features_out = ((dxfer_len >> 9) & 0xffff);
}
}
auxiliary = (zm_action & 0xf) | (zone_flags << 8);
ata_flags = CAM_ATAIO_FPDMA;
}
cam_fill_ataio(ataio,
/*retries*/ retries,
/*cbfcnp*/ cbfcnp,
/*flags*/ (dxfer_len > 0) ? CAM_DIR_OUT : CAM_DIR_NONE,
/*tag_action*/ 0,
/*data_ptr*/ data_ptr,
/*dxfer_len*/ dxfer_len,
/*timeout*/ timeout);
ata_48bit_cmd(ataio,
/*cmd*/ command_out,
/*features*/ features_out,
/*lba*/ zone_id,
/*sector_count*/ sectors_out);
ataio->cmd.flags |= ata_flags;
if (auxiliary != 0) {
ataio->ata_flags |= ATA_FLAG_AUX;
ataio->aux = auxiliary;
}
}
void
ata_zac_mgmt_in(struct ccb_ataio *ataio, uint32_t retries,
void (*cbfcnp)(struct cam_periph *, union ccb *),
int use_ncq, uint8_t zm_action, uint64_t zone_id,
uint8_t zone_flags, uint8_t *data_ptr, uint32_t dxfer_len,
uint32_t timeout)
{
uint8_t command_out, ata_flags;
uint16_t features_out, sectors_out;
uint32_t auxiliary;
if (use_ncq == 0) {
command_out = ATA_ZAC_MANAGEMENT_IN;
/* XXX KDM put a macro here */
features_out = (zm_action & 0xf) | (zone_flags << 8);
ata_flags = CAM_ATAIO_DMA;
sectors_out = ((dxfer_len >> 9) & 0xffff);
auxiliary = 0;
} else {
command_out = ATA_RECV_FPDMA_QUEUED;
sectors_out = ATA_RFPDMA_ZAC_MGMT_IN << 8;
auxiliary = (zm_action & 0xf) | (zone_flags << 8);
ata_flags = CAM_ATAIO_FPDMA;
/*
* For RECEIVE FPDMA QUEUED, the transfer length is
* encoded in the FEATURE register, and 0 means
* that 65536 512 byte blocks are to be tranferred.
* In practice, it is unlikely we will see a transfer that
* large.
*/
if (dxfer_len == (65536 * 512)) {
features_out = 0;
} else {
/*
* Yes, the caller can theoretically request a
* transfer larger than we can handle.
* Anyone using this function needs enough
* knowledge to avoid doing that.
*/
features_out = ((dxfer_len >> 9) & 0xffff);
}
}
cam_fill_ataio(ataio,
/*retries*/ retries,
/*cbfcnp*/ cbfcnp,
/*flags*/ CAM_DIR_IN,
/*tag_action*/ 0,
/*data_ptr*/ data_ptr,
/*dxfer_len*/ dxfer_len,
/*timeout*/ timeout);
ata_48bit_cmd(ataio,
/*cmd*/ command_out,
/*features*/ features_out,
/*lba*/ zone_id,
/*sector_count*/ sectors_out);
ataio->cmd.flags |= ata_flags;
if (auxiliary != 0) {
ataio->ata_flags |= ATA_FLAG_AUX;
ataio->aux = auxiliary;
}
}