qemu-e2k/pc-bios/s390-ccw/scsi.h
Eric Farman fe921fc8b7 pc-bios/s390-ccw: Get Block Limits VPD device data
The "Block Limits" Inquiry VPD page is optional for any SCSI device,
but if it's supported it provides a hint of the maximum I/O transfer
length for this particular device. If this page is supported by the
disk, let's issue that Inquiry and use the minimum of it and the
SCSI controller limit. That will cover this scenario:

  qemu-system-s390x ...
    -device virtio-scsi-ccw,id=scsi0,max_sectors=32768 ...
    -drive file=/dev/sda,if=none,id=drive0,format=raw ...
    -device scsi-hd,bus=scsi0.0,channel=0,scsi-id=0,
            drive=drive0,id=disk0,max_io_size=1048576

controller: 32768 sectors x 512 bytes/sector = 16777216 bytes
      disk:                                     1048576 bytes

Now that we have a limit for a virtio-scsi disk, compare that with the
limit for the virtio-scsi controller when we actually build the I/O.
The minimum of these two limits should be the one we use.

Signed-off-by: Eric Farman <farman@linux.vnet.ibm.com>
Message-Id: <20170510155359.32727-7-farman@linux.vnet.ibm.com>
Signed-off-by: Cornelia Huck <cornelia.huck@de.ibm.com>
2017-05-19 12:29:01 +02:00

215 lines
7.1 KiB
C

/*
* SCSI definitions for s390 machine loader for qemu
*
* Copyright 2015 IBM Corp.
* Author: Eugene "jno" Dvurechenski <jno@linux.vnet.ibm.com>
*
* This work is licensed under the terms of the GNU GPL, version 2 or (at
* your option) any later version. See the COPYING file in the top-level
* directory.
*/
#ifndef SCSI_H
#define SCSI_H
#include "s390-ccw.h"
#define SCSI_DEFAULT_CDB_SIZE 32
#define SCSI_DEFAULT_SENSE_SIZE 96
#define CDB_STATUS_GOOD 0
#define CDB_STATUS_CHECK_CONDITION 0x02U
#define CDB_STATUS_VALID(status) (((status) & ~0x3eU) == 0)
#define SCSI_SENSE_CODE_MASK 0x7fU
#define SCSI_SENSE_KEY_MASK 0x0fU
#define SCSI_SENSE_KEY_NO_SENSE 0
#define SCSI_SENSE_KEY_UNIT_ATTENTION 6
/* SCSI Inquiry Types */
#define SCSI_INQUIRY_STANDARD 0x00U
#define SCSI_INQUIRY_EVPD 0x01U
/* SCSI Inquiry Pages */
#define SCSI_INQUIRY_STANDARD_NONE 0x00U
#define SCSI_INQUIRY_EVPD_SUPPORTED_PAGES 0x00U
#define SCSI_INQUIRY_EVPD_BLOCK_LIMITS 0xb0U
union ScsiLun {
uint64_t v64; /* numeric shortcut */
uint8_t v8[8]; /* generic 8 bytes representation */
uint16_t v16[4]; /* 4-level big-endian LUN as specified by SAM-2 */
};
typedef union ScsiLun ScsiLun;
struct ScsiSense70 {
uint8_t b0; /* b0 & 7f = resp code (0x70 or 0x71) */
uint8_t b1, b2; /* b2 & 0f = sense key */
uint8_t u1[1 * 4 + 1 + 1 * 4]; /* b7 = N - 7 */
uint8_t additional_sense_code; /* b12 */
uint8_t additional_sense_code_qualifier; /* b13 */
uint8_t u2[1 + 3 + 0]; /* up to N (<=252) bytes */
} __attribute__((packed));
typedef struct ScsiSense70 ScsiSense70;
/* don't confuse with virtio-scsi response/status fields! */
static inline uint8_t scsi_sense_response(const void *p)
{
return ((const ScsiSense70 *)p)->b0 & SCSI_SENSE_CODE_MASK;
}
static inline uint8_t scsi_sense_key(const void *p)
{
return ((const ScsiSense70 *)p)->b2 & SCSI_SENSE_KEY_MASK;
}
#define SCSI_INQ_RDT_CDROM 0x05
struct ScsiInquiryStd {
uint8_t peripheral_qdt; /* b0, use (b0 & 0x1f) to get SCSI_INQ_RDT */
uint8_t b1; /* Removable Media Bit = b1 & 0x80 */
uint8_t spc_version; /* b2 */
uint8_t b3; /* b3 & 0x0f == resp_data_fmt == 2, must! */
uint8_t u1[1 + 1 + 1 + 1 + 8]; /* b4..b15 unused, b4 = (N - 1) */
char prod_id[16]; /* "QEMU CD-ROM" is here */
uint8_t u2[4 /* b32..b35 unused, mandatory */
+ 8 + 12 + 1 + 1 + 8 * 2 + 22 /* b36..95 unused, optional*/
+ 0]; /* b96..bN unused, vendor specific */
/* byte N */
} __attribute__((packed));
typedef struct ScsiInquiryStd ScsiInquiryStd;
struct ScsiInquiryEvpdPages {
uint8_t peripheral_qdt; /* b0, use (b0 & 0x1f) to get SCSI_INQ_RDT */
uint8_t page_code; /* b1 */
uint16_t page_length; /* b2..b3 length = N-3 */
uint8_t byte[28]; /* b4..bN Supported EVPD pages (N=31 here) */
} __attribute__((packed));
typedef struct ScsiInquiryEvpdPages ScsiInquiryEvpdPages;
struct ScsiInquiryEvpdBl {
uint8_t peripheral_qdt; /* b0, use (b0 & 0x1f) to get SCSI_INQ_RDT */
uint8_t page_code;
uint16_t page_length;
uint8_t b4;
uint8_t b5;
uint16_t b6;
uint32_t max_transfer; /* b8 */
uint32_t b12[7]; /* b12..b43 (defined fields) */
uint32_t b44[5]; /* b44..b63 (reserved fields) */
} __attribute__((packed));
typedef struct ScsiInquiryEvpdBl ScsiInquiryEvpdBl;
struct ScsiCdbInquiry {
uint8_t command; /* b0, == 0x12 */
uint8_t b1; /* b1, |= 0x01 (evpd) */
uint8_t b2; /* b2; if evpd==1 */
uint16_t alloc_len; /* b3, b4 */
uint8_t control; /* b5 */
} __attribute__((packed));
typedef struct ScsiCdbInquiry ScsiCdbInquiry;
struct ScsiCdbRead10 {
uint8_t command; /* =0x28 */
uint8_t b1;
uint32_t lba;
uint8_t b6;
uint16_t xfer_length;
uint8_t control;
} __attribute__((packed));
typedef struct ScsiCdbRead10 ScsiCdbRead10;
struct ScsiCdbTestUnitReady {
uint8_t command; /* =0x00 */
uint8_t b1_b4[4];
uint8_t control;
} __attribute__((packed));
typedef struct ScsiCdbTestUnitReady ScsiCdbTestUnitReady;
struct ScsiCdbReportLuns {
uint8_t command; /* =0xa0 */
uint8_t b1;
uint8_t select_report; /* =0x02, "all" */
uint8_t b3_b5[3];
uint32_t alloc_len;
uint8_t b10;
uint8_t control;
} __attribute__((packed));
typedef struct ScsiCdbReportLuns ScsiCdbReportLuns;
struct ScsiLunReport {
uint32_t lun_list_len;
uint32_t b4_b7;
ScsiLun lun[1]; /* space for at least 1 lun must be allocated */
} __attribute__((packed));
typedef struct ScsiLunReport ScsiLunReport;
struct ScsiCdbReadCapacity16 {
uint8_t command; /* =0x9e = "service action in 16" */
uint8_t service_action; /* 5 bits, =0x10 = "read capacity 16" */
uint64_t b2_b9;
uint32_t alloc_len;
uint8_t b14;
uint8_t control;
} __attribute__((packed));
typedef struct ScsiCdbReadCapacity16 ScsiCdbReadCapacity16;
struct ScsiReadCapacity16Data {
uint64_t ret_lba; /* get it, 0..7 */
uint32_t lb_len; /* bytes, 8..11 */
uint8_t u1[2 + 1 * 2 + 16]; /* b12..b31, unused */
} __attribute__((packed));
typedef struct ScsiReadCapacity16Data ScsiReadCapacity16Data;
static inline ScsiLun make_lun(uint16_t channel, uint16_t target, uint32_t lun)
{
ScsiLun r = { .v64 = 0 };
/* See QEMU code to choose the way to handle LUNs.
*
* So, a valid LUN must have (always channel #0):
* lun[0] == 1
* lun[1] - target, any value
* lun[2] == 0 or (LUN, MSB, 0x40 set, 0x80 clear)
* lun[3] - LUN, LSB, any value
*/
r.v8[0] = 1;
r.v8[1] = target & 0xffU;
r.v8[2] = (lun >> 8) & 0x3fU;
if (r.v8[2]) {
r.v8[2] |= 0x40;
}
r.v8[3] = lun & 0xffU;
return r;
}
static inline const char *scsi_cdb_status_msg(uint8_t status)
{
static char err_msg[] = "STATUS=XX";
uint8_t v = status & 0x3eU;
fill_hex_val(err_msg + 7, &v, 1);
return err_msg;
}
static inline const char *scsi_cdb_asc_msg(const void *s)
{
static char err_msg[] = "RSPN=XX KEY=XX CODE=XX QLFR=XX";
const ScsiSense70 *p = s;
uint8_t sr = scsi_sense_response(s);
uint8_t sk = scsi_sense_key(s);
uint8_t ac = p->additional_sense_code;
uint8_t cq = p->additional_sense_code_qualifier;
fill_hex_val(err_msg + 5, &sr, 1);
fill_hex_val(err_msg + 12, &sk, 1);
fill_hex_val(err_msg + 20, &ac, 1);
fill_hex_val(err_msg + 28, &cq, 1);
return err_msg;
}
#endif /* SCSI_H */