// Support for several common scsi like command data block requests // // Copyright (C) 2010 Kevin O'Connor // Copyright (C) 2002 MandrakeSoft S.A. // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "biosvar.h" // GET_GLOBAL #include "util.h" // dprintf #include "byteorder.h" // be32_to_cpu #include "disk.h" // struct disk_op_s #include "blockcmd.h" // struct cdb_request_sense #include "ata.h" // atapi_cmd_data #include "ahci.h" // atapi_cmd_data #include "usb-msc.h" // usb_cmd_data #include "usb-uas.h" // usb_cmd_data #include "virtio-scsi.h" // virtio_scsi_cmd_data #include "lsi-scsi.h" // lsi_scsi_cmd_data #include "esp-scsi.h" // esp_scsi_cmd_data #include "megasas.h" // megasas_cmd_data #include "boot.h" // boot_add_hd // Route command to low-level handler. static int cdb_cmd_data(struct disk_op_s *op, void *cdbcmd, u16 blocksize) { u8 type = GET_GLOBAL(op->drive_g->type); switch (type) { case DTYPE_ATA_ATAPI: return atapi_cmd_data(op, cdbcmd, blocksize); case DTYPE_USB: return usb_cmd_data(op, cdbcmd, blocksize); case DTYPE_UAS: return uas_cmd_data(op, cdbcmd, blocksize); case DTYPE_AHCI_ATAPI: return ahci_cmd_data(op, cdbcmd, blocksize); case DTYPE_VIRTIO_SCSI: return virtio_scsi_cmd_data(op, cdbcmd, blocksize); case DTYPE_LSI_SCSI: return lsi_scsi_cmd_data(op, cdbcmd, blocksize); case DTYPE_ESP_SCSI: return esp_scsi_cmd_data(op, cdbcmd, blocksize); case DTYPE_MEGASAS: return megasas_cmd_data(op, cdbcmd, blocksize); default: op->count = 0; return DISK_RET_EPARAM; } } // Determine if the command is a request to pull data from the device int cdb_is_read(u8 *cdbcmd, u16 blocksize) { return blocksize && cdbcmd[0] != CDB_CMD_WRITE_10; } int scsi_is_ready(struct disk_op_s *op) { dprintf(6, "scsi_is_ready (drive=%p)\n", op->drive_g); /* Retry TEST UNIT READY for 5 seconds unless MEDIUM NOT PRESENT is * reported by the device. If the device reports "IN PROGRESS", * 30 seconds is added. */ int in_progress = 0; u64 end = calc_future_tsc(5000); for (;;) { if (check_tsc(end)) { dprintf(1, "test unit ready failed\n"); return -1; } int ret = cdb_test_unit_ready(op); if (!ret) // Success break; struct cdbres_request_sense sense; ret = cdb_get_sense(op, &sense); if (ret) // Error - retry. continue; // Sense succeeded. if (sense.asc == 0x3a) { /* MEDIUM NOT PRESENT */ dprintf(1, "Device reports MEDIUM NOT PRESENT\n"); return -1; } if (sense.asc == 0x04 && sense.ascq == 0x01 && !in_progress) { /* IN PROGRESS OF BECOMING READY */ printf("Waiting for device to detect medium... "); /* Allow 30 seconds more */ end = calc_future_tsc(30000); in_progress = 1; } } return 0; } // Validate drive, find block size / sector count, and register drive. int scsi_drive_setup(struct drive_s *drive, const char *s, int prio) { struct disk_op_s dop; memset(&dop, 0, sizeof(dop)); dop.drive_g = drive; struct cdbres_inquiry data; int ret = cdb_get_inquiry(&dop, &data); if (ret) return ret; char vendor[sizeof(data.vendor)+1], product[sizeof(data.product)+1]; char rev[sizeof(data.rev)+1]; strtcpy(vendor, data.vendor, sizeof(vendor)); nullTrailingSpace(vendor); strtcpy(product, data.product, sizeof(product)); nullTrailingSpace(product); strtcpy(rev, data.rev, sizeof(rev)); nullTrailingSpace(rev); int pdt = data.pdt & 0x1f; int removable = !!(data.removable & 0x80); dprintf(1, "%s vendor='%s' product='%s' rev='%s' type=%d removable=%d\n" , s, vendor, product, rev, pdt, removable); drive->removable = removable; if (pdt == SCSI_TYPE_CDROM) { drive->blksize = CDROM_SECTOR_SIZE; drive->sectors = (u64)-1; char *desc = znprintf(MAXDESCSIZE, "DVD/CD [%s Drive %s %s %s]" , s, vendor, product, rev); boot_add_cd(drive, desc, prio); return 0; } ret = scsi_is_ready(&dop); if (ret) { dprintf(1, "scsi_is_ready returned %d\n", ret); return ret; } struct cdbres_read_capacity capdata; ret = cdb_read_capacity(&dop, &capdata); if (ret) return ret; // READ CAPACITY returns the address of the last block. // We do not bother with READ CAPACITY(16) because BIOS does not support // 64-bit LBA anyway. drive->blksize = be32_to_cpu(capdata.blksize); if (drive->blksize != DISK_SECTOR_SIZE) { dprintf(1, "%s: unsupported block size %d\n", s, drive->blksize); return -1; } drive->sectors = (u64)be32_to_cpu(capdata.sectors) + 1; dprintf(1, "%s blksize=%d sectors=%d\n" , s, drive->blksize, (unsigned)drive->sectors); // We do not recover from USB stalls, so try to be safe and avoid // sending the command if the (obsolete, but still provided by QEMU) // fixed disk geometry page may not be supported. // // We could also send the command only to small disks (e.g. <504MiB) // but some old USB keys only support a very small subset of SCSI which // does not even include the MODE SENSE command! // if (CONFIG_QEMU_HARDWARE && memcmp(vendor, "QEMU", 5) == 0) { struct cdbres_mode_sense_geom geomdata; ret = cdb_mode_sense_geom(&dop, &geomdata); if (ret == 0) { u32 cylinders; cylinders = geomdata.cyl[0] << 16; cylinders |= geomdata.cyl[1] << 8; cylinders |= geomdata.cyl[2]; if (cylinders && geomdata.heads && drive->sectors <= 0xFFFFFFFFULL && ((u32)drive->sectors % (geomdata.heads * cylinders) == 0)) { drive->pchs.cylinders = cylinders; drive->pchs.heads = geomdata.heads; drive->pchs.spt = (u32)drive->sectors / (geomdata.heads * cylinders); } } } char *desc = znprintf(MAXDESCSIZE, "%s Drive %s %s %s" , s, vendor, product, rev); boot_add_hd(drive, desc, prio); return 0; } int cdb_get_inquiry(struct disk_op_s *op, struct cdbres_inquiry *data) { struct cdb_request_sense cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_INQUIRY; cmd.length = sizeof(*data); op->count = 1; op->buf_fl = data; return cdb_cmd_data(op, &cmd, sizeof(*data)); } // Request SENSE int cdb_get_sense(struct disk_op_s *op, struct cdbres_request_sense *data) { struct cdb_request_sense cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_REQUEST_SENSE; cmd.length = sizeof(*data); op->count = 1; op->buf_fl = data; return cdb_cmd_data(op, &cmd, sizeof(*data)); } // Test unit ready int cdb_test_unit_ready(struct disk_op_s *op) { struct cdb_request_sense cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_TEST_UNIT_READY; op->count = 0; op->buf_fl = NULL; return cdb_cmd_data(op, &cmd, 0); } // Request capacity int cdb_read_capacity(struct disk_op_s *op, struct cdbres_read_capacity *data) { struct cdb_read_capacity cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_READ_CAPACITY; op->count = 1; op->buf_fl = data; return cdb_cmd_data(op, &cmd, sizeof(*data)); } // Mode sense, geometry page. int cdb_mode_sense_geom(struct disk_op_s *op, struct cdbres_mode_sense_geom *data) { struct cdb_mode_sense cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_MODE_SENSE; cmd.flags = 8; /* DBD */ cmd.page = MODE_PAGE_HD_GEOMETRY; cmd.count = cpu_to_be16(sizeof(*data)); op->count = 1; op->buf_fl = data; return cdb_cmd_data(op, &cmd, sizeof(*data)); } // Read sectors. int cdb_read(struct disk_op_s *op) { struct cdb_rwdata_10 cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_READ_10; cmd.lba = cpu_to_be32(op->lba); cmd.count = cpu_to_be16(op->count); return cdb_cmd_data(op, &cmd, GET_GLOBAL(op->drive_g->blksize)); } // Write sectors. int cdb_write(struct disk_op_s *op) { struct cdb_rwdata_10 cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = CDB_CMD_WRITE_10; cmd.lba = cpu_to_be32(op->lba); cmd.count = cpu_to_be16(op->count); return cdb_cmd_data(op, &cmd, GET_GLOBAL(op->drive_g->blksize)); }