/* * Copyright (c) 2017-2021, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #include #include #define CDB_ADDR_MASK 127 #define ALIGN_CDB(x) (((x) + CDB_ADDR_MASK) & ~CDB_ADDR_MASK) #define ALIGN_8(x) (((x) + 7) & ~7) #define UFS_DESC_SIZE 0x400 #define MAX_UFS_DESC_SIZE 0x8000 /* 32 descriptors */ #define MAX_PRDT_SIZE 0x40000 /* 256KB */ static ufs_params_t ufs_params; static int nutrs; /* Number of UTP Transfer Request Slots */ /* * ufs_uic_error_handler - UIC error interrupts handler * @ignore_linereset: set to ignore PA_LAYER_GEN_ERR (UIC error) * * Returns * 0 - ignore error * -EIO - fatal error, needs re-init * -EAGAIN - non-fatal error, retries are sufficient */ static int ufs_uic_error_handler(bool ignore_linereset) { uint32_t data; int result = 0; data = mmio_read_32(ufs_params.reg_base + UECPA); if (data & UFS_UIC_PA_ERROR_MASK) { if (data & PA_LAYER_GEN_ERR) { if (!ignore_linereset) { return -EIO; } } else { result = -EAGAIN; } } data = mmio_read_32(ufs_params.reg_base + UECDL); if (data & UFS_UIC_DL_ERROR_MASK) { if (data & PA_INIT_ERR) { return -EIO; } result = -EAGAIN; } /* NL/TL/DME error requires retries */ data = mmio_read_32(ufs_params.reg_base + UECN); if (data & UFS_UIC_NL_ERROR_MASK) { result = -EAGAIN; } data = mmio_read_32(ufs_params.reg_base + UECT); if (data & UFS_UIC_TL_ERROR_MASK) { result = -EAGAIN; } data = mmio_read_32(ufs_params.reg_base + UECDME); if (data & UFS_UIC_DME_ERROR_MASK) { result = -EAGAIN; } return result; } /* * ufs_error_handler - error interrupts handler * @status: interrupt status * @ignore_linereset: set to ignore PA_LAYER_GEN_ERR (UIC error) * * Returns * 0 - ignore error * -EIO - fatal error, needs re-init * -EAGAIN - non-fatal error, retries are sufficient */ static int ufs_error_handler(uint32_t status, bool ignore_linereset) { int result; if (status & UFS_INT_UE) { result = ufs_uic_error_handler(ignore_linereset); if (result != 0) { return result; } } /* Return I/O error on fatal error, it is upto the caller to re-init UFS */ if (status & UFS_INT_FATAL) { return -EIO; } /* retry for non-fatal errors */ return -EAGAIN; } /* * ufs_wait_for_int_status - wait for expected interrupt status * @expected: expected interrupt status bit * @timeout_ms: timeout in milliseconds to poll for * @ignore_linereset: set to ignore PA_LAYER_GEN_ERR (UIC error) * * Returns * 0 - received expected interrupt and cleared it * -EIO - fatal error, needs re-init * -EAGAIN - non-fatal error, caller can retry * -ETIMEDOUT - timed out waiting for interrupt status */ static int ufs_wait_for_int_status(const uint32_t expected_status, unsigned int timeout_ms, bool ignore_linereset) { uint32_t interrupt_status, interrupts_enabled; int result = 0; interrupts_enabled = mmio_read_32(ufs_params.reg_base + IE); do { interrupt_status = mmio_read_32(ufs_params.reg_base + IS) & interrupts_enabled; if (interrupt_status & UFS_INT_ERR) { mmio_write_32(ufs_params.reg_base + IS, interrupt_status & UFS_INT_ERR); result = ufs_error_handler(interrupt_status, ignore_linereset); if (result != 0) { return result; } } if (interrupt_status & expected_status) { break; } mdelay(1); } while (timeout_ms-- > 0); if (!(interrupt_status & expected_status)) { return -ETIMEDOUT; } mmio_write_32(ufs_params.reg_base + IS, expected_status); return result; } int ufshc_send_uic_cmd(uintptr_t base, uic_cmd_t *cmd) { unsigned int data; int result, retries; if (base == 0 || cmd == NULL) return -EINVAL; for (retries = 0; retries < 100; retries++) { data = mmio_read_32(base + HCS); if ((data & HCS_UCRDY) != 0) { break; } mdelay(1); } if (retries >= 100) { return -EBUSY; } mmio_write_32(base + IS, ~0); mmio_write_32(base + UCMDARG1, cmd->arg1); mmio_write_32(base + UCMDARG2, cmd->arg2); mmio_write_32(base + UCMDARG3, cmd->arg3); mmio_write_32(base + UICCMD, cmd->op); result = ufs_wait_for_int_status(UFS_INT_UCCS, UIC_CMD_TIMEOUT_MS, cmd->op == DME_SET); if (result != 0) { return result; } return mmio_read_32(base + UCMDARG2) & CONFIG_RESULT_CODE_MASK; } int ufshc_dme_get(unsigned int attr, unsigned int idx, unsigned int *val) { uintptr_t base; int result, retries; uic_cmd_t cmd; assert(ufs_params.reg_base != 0); if (val == NULL) return -EINVAL; base = ufs_params.reg_base; cmd.arg1 = (attr << 16) | GEN_SELECTOR_IDX(idx); cmd.arg2 = 0; cmd.arg3 = 0; cmd.op = DME_GET; for (retries = 0; retries < UFS_UIC_COMMAND_RETRIES; ++retries) { result = ufshc_send_uic_cmd(base, &cmd); if (result == 0) break; /* -EIO requires UFS re-init */ if (result == -EIO) { return result; } } if (retries >= UFS_UIC_COMMAND_RETRIES) return -EIO; *val = mmio_read_32(base + UCMDARG3); return 0; } int ufshc_dme_set(unsigned int attr, unsigned int idx, unsigned int val) { uintptr_t base; int result, retries; uic_cmd_t cmd; assert((ufs_params.reg_base != 0)); base = ufs_params.reg_base; cmd.arg1 = (attr << 16) | GEN_SELECTOR_IDX(idx); cmd.arg2 = 0; cmd.arg3 = val; cmd.op = DME_SET; for (retries = 0; retries < UFS_UIC_COMMAND_RETRIES; ++retries) { result = ufshc_send_uic_cmd(base, &cmd); if (result == 0) break; /* -EIO requires UFS re-init */ if (result == -EIO) { return result; } } if (retries >= UFS_UIC_COMMAND_RETRIES) return -EIO; return 0; } static int ufshc_hce_enable(uintptr_t base) { unsigned int data; int retries; /* Enable Host Controller */ mmio_write_32(base + HCE, HCE_ENABLE); /* Wait until basic initialization sequence completed */ for (retries = 0; retries < HCE_ENABLE_INNER_RETRIES; ++retries) { data = mmio_read_32(base + HCE); if (data & HCE_ENABLE) { break; } udelay(HCE_ENABLE_TIMEOUT_US); } if (retries >= HCE_ENABLE_INNER_RETRIES) { return -ETIMEDOUT; } return 0; } static int ufshc_hce_disable(uintptr_t base) { unsigned int data; int timeout; /* Disable Host Controller */ mmio_write_32(base + HCE, HCE_DISABLE); timeout = HCE_DISABLE_TIMEOUT_US; do { data = mmio_read_32(base + HCE); if ((data & HCE_ENABLE) == HCE_DISABLE) { break; } udelay(1); } while (--timeout > 0); if (timeout <= 0) { return -ETIMEDOUT; } return 0; } static int ufshc_reset(uintptr_t base) { unsigned int data; int retries, result; /* disable controller if enabled */ if (mmio_read_32(base + HCE) & HCE_ENABLE) { result = ufshc_hce_disable(base); if (result != 0) { return -EIO; } } for (retries = 0; retries < HCE_ENABLE_OUTER_RETRIES; ++retries) { result = ufshc_hce_enable(base); if (result == 0) { break; } } if (retries >= HCE_ENABLE_OUTER_RETRIES) { return -EIO; } /* Enable UIC Interrupts alone. We can ignore other interrupts until * link is up as there might be spurious error interrupts during link-up */ data = UFS_INT_UCCS | UFS_INT_UHES | UFS_INT_UHXS | UFS_INT_UPMS; mmio_write_32(base + IE, data); return 0; } static int ufshc_dme_link_startup(uintptr_t base) { uic_cmd_t cmd; memset(&cmd, 0, sizeof(cmd)); cmd.op = DME_LINKSTARTUP; return ufshc_send_uic_cmd(base, &cmd); } static int ufshc_link_startup(uintptr_t base) { int data, result; int retries; for (retries = DME_LINKSTARTUP_RETRIES; retries > 0; retries--) { result = ufshc_dme_link_startup(base); if (result != 0) { /* Reset controller before trying again */ result = ufshc_reset(base); if (result != 0) { return result; } continue; } assert(mmio_read_32(base + HCS) & HCS_DP); data = mmio_read_32(base + IS); if (data & UFS_INT_ULSS) mmio_write_32(base + IS, UFS_INT_ULSS); /* clear UE set due to line-reset */ if (data & UFS_INT_UE) { mmio_write_32(base + IS, UFS_INT_UE); } /* clearing line-reset, UECPA is cleared on read */ mmio_read_32(base + UECPA); return 0; } return -EIO; } /* Read Door Bell register to check if slot zero is available */ static int is_slot_available(void) { if (mmio_read_32(ufs_params.reg_base + UTRLDBR) & 0x1) { return -EBUSY; } return 0; } static void get_utrd(utp_utrd_t *utrd) { uintptr_t base; int result; utrd_header_t *hd; assert(utrd != NULL); result = is_slot_available(); assert(result == 0); /* clear utrd */ memset((void *)utrd, 0, sizeof(utp_utrd_t)); base = ufs_params.desc_base; /* clear the descriptor */ memset((void *)base, 0, UFS_DESC_SIZE); utrd->header = base; utrd->task_tag = 1; /* We always use the first slot */ /* CDB address should be aligned with 128 bytes */ utrd->upiu = ALIGN_CDB(utrd->header + sizeof(utrd_header_t)); utrd->resp_upiu = ALIGN_8(utrd->upiu + sizeof(cmd_upiu_t)); utrd->size_upiu = utrd->resp_upiu - utrd->upiu; utrd->size_resp_upiu = ALIGN_8(sizeof(resp_upiu_t)); utrd->prdt = utrd->resp_upiu + utrd->size_resp_upiu; hd = (utrd_header_t *)utrd->header; hd->ucdba = utrd->upiu & UINT32_MAX; hd->ucdbau = (utrd->upiu >> 32) & UINT32_MAX; /* Both RUL and RUO is based on DWORD */ hd->rul = utrd->size_resp_upiu >> 2; hd->ruo = utrd->size_upiu >> 2; (void)result; } /* * Prepare UTRD, Command UPIU, Response UPIU. */ static int ufs_prepare_cmd(utp_utrd_t *utrd, uint8_t op, uint8_t lun, int lba, uintptr_t buf, size_t length) { utrd_header_t *hd; cmd_upiu_t *upiu; prdt_t *prdt; unsigned int ulba; unsigned int lba_cnt; uintptr_t desc_limit; uintptr_t prdt_end; hd = (utrd_header_t *)utrd->header; upiu = (cmd_upiu_t *)utrd->upiu; hd->i = 1; hd->ct = CT_UFS_STORAGE; hd->ocs = OCS_MASK; upiu->trans_type = CMD_UPIU; upiu->task_tag = utrd->task_tag; upiu->cdb[0] = op; ulba = (unsigned int)lba; lba_cnt = (unsigned int)(length >> UFS_BLOCK_SHIFT); switch (op) { case CDBCMD_TEST_UNIT_READY: break; case CDBCMD_READ_CAPACITY_10: hd->dd = DD_OUT; upiu->flags = UPIU_FLAGS_R | UPIU_FLAGS_ATTR_S; upiu->lun = lun; break; case CDBCMD_READ_10: hd->dd = DD_OUT; upiu->flags = UPIU_FLAGS_R | UPIU_FLAGS_ATTR_S; upiu->lun = lun; upiu->cdb[1] = RW_WITHOUT_CACHE; /* set logical block address */ upiu->cdb[2] = (ulba >> 24) & 0xff; upiu->cdb[3] = (ulba >> 16) & 0xff; upiu->cdb[4] = (ulba >> 8) & 0xff; upiu->cdb[5] = ulba & 0xff; /* set transfer length */ upiu->cdb[7] = (lba_cnt >> 8) & 0xff; upiu->cdb[8] = lba_cnt & 0xff; break; case CDBCMD_WRITE_10: hd->dd = DD_IN; upiu->flags = UPIU_FLAGS_W | UPIU_FLAGS_ATTR_S; upiu->lun = lun; upiu->cdb[1] = RW_WITHOUT_CACHE; /* set logical block address */ upiu->cdb[2] = (ulba >> 24) & 0xff; upiu->cdb[3] = (ulba >> 16) & 0xff; upiu->cdb[4] = (ulba >> 8) & 0xff; upiu->cdb[5] = ulba & 0xff; /* set transfer length */ upiu->cdb[7] = (lba_cnt >> 8) & 0xff; upiu->cdb[8] = lba_cnt & 0xff; break; default: assert(0); break; } if (hd->dd == DD_IN) { flush_dcache_range(buf, length); } else if (hd->dd == DD_OUT) { inv_dcache_range(buf, length); } utrd->prdt_length = 0; if (length) { upiu->exp_data_trans_len = htobe32(length); assert(lba_cnt <= UINT16_MAX); prdt = (prdt_t *)utrd->prdt; desc_limit = ufs_params.desc_base + ufs_params.desc_size; while (length > 0) { if ((uintptr_t)prdt + sizeof(prdt_t) > desc_limit) { ERROR("UFS: Exceeded descriptor limit. Image is too large\n"); panic(); } prdt->dba = (unsigned int)(buf & UINT32_MAX); prdt->dbau = (unsigned int)((buf >> 32) & UINT32_MAX); /* prdt->dbc counts from 0 */ if (length > MAX_PRDT_SIZE) { prdt->dbc = MAX_PRDT_SIZE - 1; length = length - MAX_PRDT_SIZE; } else { prdt->dbc = length - 1; length = 0; } buf += MAX_PRDT_SIZE; prdt++; utrd->prdt_length++; } hd->prdtl = utrd->prdt_length; hd->prdto = (utrd->size_upiu + utrd->size_resp_upiu) >> 2; } prdt_end = utrd->prdt + utrd->prdt_length * sizeof(prdt_t); flush_dcache_range(utrd->header, prdt_end - utrd->header); return 0; } static int ufs_prepare_query(utp_utrd_t *utrd, uint8_t op, uint8_t idn, uint8_t index, uint8_t sel, uintptr_t buf, size_t length) { utrd_header_t *hd; query_upiu_t *query_upiu; hd = (utrd_header_t *)utrd->header; query_upiu = (query_upiu_t *)utrd->upiu; hd->i = 1; hd->ct = CT_UFS_STORAGE; hd->ocs = OCS_MASK; query_upiu->trans_type = QUERY_REQUEST_UPIU; query_upiu->task_tag = utrd->task_tag; query_upiu->data_segment_len = htobe16(length); query_upiu->ts.desc.opcode = op; query_upiu->ts.desc.idn = idn; query_upiu->ts.desc.index = index; query_upiu->ts.desc.selector = sel; switch (op) { case QUERY_READ_DESC: query_upiu->query_func = QUERY_FUNC_STD_READ; query_upiu->ts.desc.length = htobe16(length); break; case QUERY_WRITE_DESC: query_upiu->query_func = QUERY_FUNC_STD_WRITE; query_upiu->ts.desc.length = htobe16(length); memcpy((void *)(utrd->upiu + sizeof(query_upiu_t)), (void *)buf, length); break; case QUERY_READ_ATTR: case QUERY_READ_FLAG: query_upiu->query_func = QUERY_FUNC_STD_READ; break; case QUERY_CLEAR_FLAG: case QUERY_SET_FLAG: query_upiu->query_func = QUERY_FUNC_STD_WRITE; break; case QUERY_WRITE_ATTR: query_upiu->query_func = QUERY_FUNC_STD_WRITE; query_upiu->ts.attr.value = htobe32(*((uint32_t *)buf)); break; default: assert(0); break; } flush_dcache_range((uintptr_t)utrd->header, UFS_DESC_SIZE); return 0; } static void ufs_prepare_nop_out(utp_utrd_t *utrd) { utrd_header_t *hd; nop_out_upiu_t *nop_out; hd = (utrd_header_t *)utrd->header; nop_out = (nop_out_upiu_t *)utrd->upiu; hd->i = 1; hd->ct = CT_UFS_STORAGE; hd->ocs = OCS_MASK; nop_out->trans_type = 0; nop_out->task_tag = utrd->task_tag; flush_dcache_range((uintptr_t)utrd->header, UFS_DESC_SIZE); } static void ufs_send_request(int task_tag) { unsigned int data; int slot; slot = task_tag - 1; /* clear all interrupts */ mmio_write_32(ufs_params.reg_base + IS, ~0); mmio_write_32(ufs_params.reg_base + UTRLRSR, 1); assert(mmio_read_32(ufs_params.reg_base + UTRLRSR) == 1); data = UTRIACR_IAEN | UTRIACR_CTR | UTRIACR_IACTH(0x1F) | UTRIACR_IATOVAL(0xFF); mmio_write_32(ufs_params.reg_base + UTRIACR, data); /* send request */ mmio_setbits_32(ufs_params.reg_base + UTRLDBR, 1U << slot); } static int ufs_check_resp(utp_utrd_t *utrd, int trans_type, unsigned int timeout_ms) { utrd_header_t *hd; resp_upiu_t *resp; sense_data_t *sense; unsigned int data; int slot, result; hd = (utrd_header_t *)utrd->header; resp = (resp_upiu_t *)utrd->resp_upiu; result = ufs_wait_for_int_status(UFS_INT_UTRCS, timeout_ms, false); if (result != 0) { return result; } slot = utrd->task_tag - 1; data = mmio_read_32(ufs_params.reg_base + UTRLDBR); assert((data & (1 << slot)) == 0); /* * Invalidate the header after DMA read operation has * completed to avoid cpu referring to the prefetched * data brought in before DMA completion. */ inv_dcache_range((uintptr_t)hd, UFS_DESC_SIZE); assert(hd->ocs == OCS_SUCCESS); assert((resp->trans_type & TRANS_TYPE_CODE_MASK) == trans_type); sense = &resp->sd.sense; if (sense->resp_code == SENSE_DATA_VALID && sense->sense_key == SENSE_KEY_UNIT_ATTENTION && sense->asc == 0x29 && sense->ascq == 0) { WARN("Unit Attention Condition\n"); return -EAGAIN; } (void)resp; (void)slot; (void)data; return 0; } static void ufs_send_cmd(utp_utrd_t *utrd, uint8_t cmd_op, uint8_t lun, int lba, uintptr_t buf, size_t length) { int result, i; for (i = 0; i < UFS_CMD_RETRIES; ++i) { get_utrd(utrd); result = ufs_prepare_cmd(utrd, cmd_op, lun, lba, buf, length); assert(result == 0); ufs_send_request(utrd->task_tag); result = ufs_check_resp(utrd, RESPONSE_UPIU, CMD_TIMEOUT_MS); if (result == 0 || result == -EIO) { break; } } assert(result == 0); (void)result; } #ifdef UFS_RESP_DEBUG static void dump_upiu(utp_utrd_t *utrd) { utrd_header_t *hd; int i; hd = (utrd_header_t *)utrd->header; INFO("utrd:0x%x, ruo:0x%x, rul:0x%x, ocs:0x%x, UTRLDBR:0x%x\n", (unsigned int)(uintptr_t)utrd, hd->ruo, hd->rul, hd->ocs, mmio_read_32(ufs_params.reg_base + UTRLDBR)); for (i = 0; i < sizeof(utrd_header_t); i += 4) { INFO("[%lx]:0x%x\n", (uintptr_t)utrd->header + i, *(unsigned int *)((uintptr_t)utrd->header + i)); } for (i = 0; i < sizeof(cmd_upiu_t); i += 4) { INFO("cmd[%lx]:0x%x\n", utrd->upiu + i, *(unsigned int *)(utrd->upiu + i)); } for (i = 0; i < sizeof(resp_upiu_t); i += 4) { INFO("resp[%lx]:0x%x\n", utrd->resp_upiu + i, *(unsigned int *)(utrd->resp_upiu + i)); } for (i = 0; i < sizeof(prdt_t); i += 4) { INFO("prdt[%lx]:0x%x\n", utrd->prdt + i, *(unsigned int *)(utrd->prdt + i)); } } #endif static void ufs_verify_init(void) { utp_utrd_t utrd; int result; get_utrd(&utrd); ufs_prepare_nop_out(&utrd); ufs_send_request(utrd.task_tag); result = ufs_check_resp(&utrd, NOP_IN_UPIU, NOP_OUT_TIMEOUT_MS); assert(result == 0); (void)result; } static void ufs_verify_ready(void) { utp_utrd_t utrd; ufs_send_cmd(&utrd, CDBCMD_TEST_UNIT_READY, 0, 0, 0, 0); } static void ufs_query(uint8_t op, uint8_t idn, uint8_t index, uint8_t sel, uintptr_t buf, size_t size) { utp_utrd_t utrd; query_resp_upiu_t *resp; int result; switch (op) { case QUERY_READ_FLAG: case QUERY_READ_ATTR: case QUERY_READ_DESC: case QUERY_WRITE_DESC: case QUERY_WRITE_ATTR: assert(((buf & 3) == 0) && (size != 0)); break; default: /* Do nothing in default case */ break; } get_utrd(&utrd); ufs_prepare_query(&utrd, op, idn, index, sel, buf, size); ufs_send_request(utrd.task_tag); result = ufs_check_resp(&utrd, QUERY_RESPONSE_UPIU, QUERY_REQ_TIMEOUT_MS); assert(result == 0); resp = (query_resp_upiu_t *)utrd.resp_upiu; #ifdef UFS_RESP_DEBUG dump_upiu(&utrd); #endif assert(resp->query_resp == QUERY_RESP_SUCCESS); switch (op) { case QUERY_READ_FLAG: *(uint32_t *)buf = (uint32_t)resp->ts.flag.value; break; case QUERY_READ_DESC: memcpy((void *)buf, (void *)(utrd.resp_upiu + sizeof(query_resp_upiu_t)), size); break; case QUERY_READ_ATTR: *(uint32_t *)buf = htobe32(resp->ts.attr.value); break; default: /* Do nothing in default case */ break; } (void)result; } unsigned int ufs_read_attr(int idn) { unsigned int value; ufs_query(QUERY_READ_ATTR, idn, 0, 0, (uintptr_t)&value, sizeof(value)); return value; } void ufs_write_attr(int idn, unsigned int value) { ufs_query(QUERY_WRITE_ATTR, idn, 0, 0, (uintptr_t)&value, sizeof(value)); } unsigned int ufs_read_flag(int idn) { unsigned int value; ufs_query(QUERY_READ_FLAG, idn, 0, 0, (uintptr_t)&value, sizeof(value)); return value; } void ufs_set_flag(int idn) { ufs_query(QUERY_SET_FLAG, idn, 0, 0, 0, 0); } void ufs_clear_flag(int idn) { ufs_query(QUERY_CLEAR_FLAG, idn, 0, 0, 0, 0); } void ufs_read_desc(int idn, int index, uintptr_t buf, size_t size) { ufs_query(QUERY_READ_DESC, idn, index, 0, buf, size); } void ufs_write_desc(int idn, int index, uintptr_t buf, size_t size) { ufs_query(QUERY_WRITE_DESC, idn, index, 0, buf, size); } static int ufs_read_capacity(int lun, unsigned int *num, unsigned int *size) { utp_utrd_t utrd; resp_upiu_t *resp; sense_data_t *sense; unsigned char data[CACHE_WRITEBACK_GRANULE << 1]; uintptr_t buf; int retries = UFS_READ_CAPACITY_RETRIES; assert((ufs_params.reg_base != 0) && (ufs_params.desc_base != 0) && (ufs_params.desc_size >= UFS_DESC_SIZE) && (num != NULL) && (size != NULL)); /* align buf address */ buf = (uintptr_t)data; buf = (buf + CACHE_WRITEBACK_GRANULE - 1) & ~(CACHE_WRITEBACK_GRANULE - 1); do { ufs_send_cmd(&utrd, CDBCMD_READ_CAPACITY_10, lun, 0, buf, READ_CAPACITY_LENGTH); #ifdef UFS_RESP_DEBUG dump_upiu(&utrd); #endif resp = (resp_upiu_t *)utrd.resp_upiu; sense = &resp->sd.sense; if (!((sense->resp_code == SENSE_DATA_VALID) && (sense->sense_key == SENSE_KEY_UNIT_ATTENTION) && (sense->asc == 0x29) && (sense->ascq == 0))) { inv_dcache_range(buf, CACHE_WRITEBACK_GRANULE); /* last logical block address */ *num = be32toh(*(unsigned int *)buf); if (*num) *num += 1; /* logical block length in bytes */ *size = be32toh(*(unsigned int *)(buf + 4)); return 0; } } while (retries-- > 0); return -ETIMEDOUT; } size_t ufs_read_blocks(int lun, int lba, uintptr_t buf, size_t size) { utp_utrd_t utrd; resp_upiu_t *resp; assert((ufs_params.reg_base != 0) && (ufs_params.desc_base != 0) && (ufs_params.desc_size >= UFS_DESC_SIZE)); ufs_send_cmd(&utrd, CDBCMD_READ_10, lun, lba, buf, size); #ifdef UFS_RESP_DEBUG dump_upiu(&utrd); #endif /* * Invalidate prefetched cache contents before cpu * accesses the buf. */ inv_dcache_range(buf, size); resp = (resp_upiu_t *)utrd.resp_upiu; return size - resp->res_trans_cnt; } size_t ufs_write_blocks(int lun, int lba, const uintptr_t buf, size_t size) { utp_utrd_t utrd; resp_upiu_t *resp; assert((ufs_params.reg_base != 0) && (ufs_params.desc_base != 0) && (ufs_params.desc_size >= UFS_DESC_SIZE)); ufs_send_cmd(&utrd, CDBCMD_WRITE_10, lun, lba, buf, size); #ifdef UFS_RESP_DEBUG dump_upiu(&utrd); #endif resp = (resp_upiu_t *)utrd.resp_upiu; return size - resp->res_trans_cnt; } static int ufs_set_fdevice_init(void) { unsigned int result; int timeout; ufs_set_flag(FLAG_DEVICE_INIT); timeout = FDEVICEINIT_TIMEOUT_MS; do { result = ufs_read_flag(FLAG_DEVICE_INIT); if (!result) { break; } mdelay(5); timeout -= 5; } while (timeout > 0); if (result != 0U) { return -ETIMEDOUT; } return 0; } static void ufs_enum(void) { unsigned int blk_num, blk_size; int i, result; mmio_write_32(ufs_params.reg_base + UTRLBA, ufs_params.desc_base & UINT32_MAX); mmio_write_32(ufs_params.reg_base + UTRLBAU, (ufs_params.desc_base >> 32) & UINT32_MAX); ufs_verify_init(); ufs_verify_ready(); result = ufs_set_fdevice_init(); assert(result == 0); blk_num = 0; blk_size = 0; /* dump available LUNs */ for (i = 0; i < UFS_MAX_LUNS; i++) { result = ufs_read_capacity(i, &blk_num, &blk_size); if (result != 0) { WARN("UFS LUN%d dump failed\n", i); } if (blk_num && blk_size) { INFO("UFS LUN%d contains %d blocks with %d-byte size\n", i, blk_num, blk_size); } } (void)result; } static void ufs_get_device_info(struct ufs_dev_desc *card_data) { uint8_t desc_buf[DESC_DEVICE_MAX_SIZE]; ufs_read_desc(DESC_TYPE_DEVICE, 0, (uintptr_t)desc_buf, DESC_DEVICE_MAX_SIZE); /* * getting vendor (manufacturerID) and Bank Index in big endian * format */ card_data->wmanufacturerid = (uint16_t)((desc_buf[DEVICE_DESC_PARAM_MANF_ID] << 8) | (desc_buf[DEVICE_DESC_PARAM_MANF_ID + 1])); } int ufs_init(const ufs_ops_t *ops, ufs_params_t *params) { int result; unsigned int data; uic_cmd_t cmd; struct ufs_dev_desc card = {0}; assert((params != NULL) && (params->reg_base != 0) && (params->desc_base != 0) && (params->desc_size >= UFS_DESC_SIZE)); memcpy(&ufs_params, params, sizeof(ufs_params_t)); /* 0 means 1 slot */ nutrs = (mmio_read_32(ufs_params.reg_base + CAP) & CAP_NUTRS_MASK) + 1; if (nutrs > (ufs_params.desc_size / UFS_DESC_SIZE)) { nutrs = ufs_params.desc_size / UFS_DESC_SIZE; } if (ufs_params.flags & UFS_FLAGS_SKIPINIT) { mmio_write_32(ufs_params.reg_base + UTRLBA, ufs_params.desc_base & UINT32_MAX); mmio_write_32(ufs_params.reg_base + UTRLBAU, (ufs_params.desc_base >> 32) & UINT32_MAX); result = ufshc_dme_get(0x1571, 0, &data); assert(result == 0); result = ufshc_dme_get(0x41, 0, &data); assert(result == 0); if (data == 1) { /* prepare to exit hibernate mode */ memset(&cmd, 0, sizeof(uic_cmd_t)); cmd.op = DME_HIBERNATE_EXIT; result = ufshc_send_uic_cmd(ufs_params.reg_base, &cmd); assert(result == 0); data = mmio_read_32(ufs_params.reg_base + UCMDARG2); assert(data == 0); do { data = mmio_read_32(ufs_params.reg_base + IS); } while ((data & UFS_INT_UHXS) == 0); mmio_write_32(ufs_params.reg_base + IS, UFS_INT_UHXS); data = mmio_read_32(ufs_params.reg_base + HCS); assert((data & HCS_UPMCRS_MASK) == HCS_PWR_LOCAL); } result = ufshc_dme_get(0x1568, 0, &data); assert(result == 0); assert((data > 0) && (data <= 3)); } else { assert((ops != NULL) && (ops->phy_init != NULL) && (ops->phy_set_pwr_mode != NULL)); result = ufshc_reset(ufs_params.reg_base); assert(result == 0); ops->phy_init(&ufs_params); result = ufshc_link_startup(ufs_params.reg_base); assert(result == 0); /* enable all interrupts */ data = UFS_INT_UCCS | UFS_INT_UHES | UFS_INT_UHXS | UFS_INT_UPMS; data |= UFS_INT_UTRCS | UFS_INT_ERR; mmio_write_32(ufs_params.reg_base + IE, data); ufs_enum(); ufs_get_device_info(&card); if (card.wmanufacturerid == UFS_VENDOR_SKHYNIX) { ufs_params.flags |= UFS_FLAGS_VENDOR_SKHYNIX; } ops->phy_set_pwr_mode(&ufs_params); } (void)result; return 0; }