/* * Copyright (c) 2023 Nuvoton Technology Corporation. * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nuvoton_npcx_espi_taf #include #include #include #include #include #include LOG_MODULE_REGISTER(espi_taf, CONFIG_ESPI_LOG_LEVEL); static const struct device *const spi_dev = DEVICE_DT_GET(DT_ALIAS(taf_flash)); struct espi_taf_npcx_config { uintptr_t base; uintptr_t mapped_addr; uintptr_t rx_plsz; enum NPCX_ESPI_TAF_ERASE_BLOCK_SIZE erase_sz; enum NPCX_ESPI_TAF_MAX_READ_REQ max_rd_sz; }; struct espi_taf_npcx_data { sys_slist_t callbacks; }; #define HAL_INSTANCE(dev) \ ((struct espi_reg *)((const struct espi_taf_npcx_config *) \ (dev)->config)->base) #define FLBASE_ADDR ( \ GET_FIELD(inst->FLASHBASE, NPCX_FLASHBASE_FLBASE_ADDR) \ << GET_FIELD_POS(NPCX_FLASHBASE_FLBASE_ADDR)) #define PRTR_BADDR(i) ( \ GET_FIELD(inst->FLASH_PRTR_BADDR[i], NPCX_FLASH_PRTR_BADDR) \ << GET_FIELD_POS(NPCX_FLASH_PRTR_BADDR)) #define PRTR_HADDR(i) ( \ GET_FIELD(inst->FLASH_PRTR_HADDR[i], NPCX_FLASH_PRTR_HADDR) \ << GET_FIELD_POS(NPCX_FLASH_PRTR_HADDR)) | 0xFFF; /* Check access region of read request is protected or not */ static bool espi_taf_check_read_protect(const struct device *dev, uint32_t addr, uint32_t len, uint8_t tag) { struct espi_reg *const inst = HAL_INSTANCE(dev); uint32_t flash_addr = addr; uint8_t i; uint16_t override_rd; uint32_t base, high; bool rdpr; flash_addr += FLBASE_ADDR; for (i = 0; i < CONFIG_ESPI_TAF_PR_NUM; i++) { base = PRTR_BADDR(i); high = PRTR_HADDR(i); rdpr = IS_BIT_SET(inst->FLASH_PRTR_BADDR[i], NPCX_FRGN_RPR); override_rd = GET_FIELD(inst->FLASH_RGN_TAG_OVR[i], NPCX_FLASH_TAG_OVR_RPR); if (rdpr && !IS_BIT_SET(override_rd, tag) && (base <= flash_addr + len - 1 && flash_addr <= high)) { return true; } } return false; } /* Check access region of write request is protected or not */ static bool espi_taf_check_write_protect(const struct device *dev, uint32_t addr, uint32_t len, uint8_t tag) { struct espi_reg *const inst = HAL_INSTANCE(dev); uint32_t flash_addr = addr; uint8_t i; uint16_t override_wr; uint32_t base, high; bool wrpr; flash_addr += FLBASE_ADDR; for (i = 0; i < CONFIG_ESPI_TAF_PR_NUM; i++) { base = PRTR_BADDR(i); high = PRTR_HADDR(i); wrpr = IS_BIT_SET(inst->FLASH_PRTR_BADDR[i], NPCX_FRGN_WPR); override_wr = GET_FIELD(inst->FLASH_RGN_TAG_OVR[i], NPCX_FLASH_TAG_OVR_WPR); if (wrpr && !IS_BIT_SET(override_wr, tag) && (base <= flash_addr + len - 1 && flash_addr <= high)) { return true; } } return false; } static int espi_taf_npcx_configure(const struct device *dev, const struct espi_saf_cfg *cfg) { struct espi_reg *const inst = HAL_INSTANCE(dev); #if defined(CONFIG_ESPI_TAF_AUTO_MODE) inst->FLASHCTL |= BIT(NPCX_FLASHCTL_SAF_AUTO_READ); #else inst->FLASHCTL &= ~BIT(NPCX_FLASHCTL_SAF_AUTO_READ); #endif return 0; } static int espi_taf_npcx_set_pr(const struct device *dev, const struct espi_saf_protection *pr) { struct espi_reg *const inst = HAL_INSTANCE(dev); const struct espi_saf_pr *preg = pr->pregions; size_t n = pr->nregions; uint8_t regnum; uint16_t bitmask, offset; uint32_t rw_pr, override_rw; if ((dev == NULL) || (pr == NULL)) { return -EINVAL; } if (pr->nregions >= CONFIG_ESPI_TAF_PR_NUM) { return -EINVAL; } while (n--) { regnum = preg->pr_num; if (regnum >= CONFIG_ESPI_TAF_PR_NUM) { return -EINVAL; } rw_pr = preg->master_bm_we << NPCX_FRGN_WPR; rw_pr = rw_pr | (preg->master_bm_rd << NPCX_FRGN_RPR); if (preg->flags) { bitmask = BIT_MASK(GET_FIELD_SZ(NPCX_FLASH_PRTR_BADDR)); offset = GET_FIELD_POS(NPCX_FLASH_PRTR_BADDR); inst->FLASH_PRTR_BADDR[regnum] = ((preg->start & bitmask) << offset) | rw_pr; bitmask = BIT_MASK(GET_FIELD_SZ(NPCX_FLASH_PRTR_HADDR)); offset = GET_FIELD_POS(NPCX_FLASH_PRTR_HADDR); inst->FLASH_PRTR_HADDR[regnum] = (preg->end & bitmask) << offset; } override_rw = (preg->override_r << 16) | preg->override_w; inst->FLASH_RGN_TAG_OVR[regnum] = override_rw; preg++; } return 0; } static int espi_taf_npcx_activate(const struct device *dev) { struct espi_reg *const inst = HAL_INSTANCE(dev); inst->FLASHCTL &= ~BIT(NPCX_FLASHCTL_AUTO_RD_DIS_CTL); inst->FLASHCTL &= ~BIT(NPCX_FLASHCTL_BLK_FLASH_NP_FREE); return 0; } static bool espi_taf_npcx_channel_ready(const struct device *dev) { struct espi_reg *const inst = HAL_INSTANCE(dev); if (!IS_BIT_SET(inst->ESPICFG, NPCX_ESPICFG_FLCHANMODE)) { return false; } return true; } /* This routine set FLASH_C_AVAIL for standard request */ static void taf_set_flash_c_avail(const struct device *dev) { struct espi_reg *const inst = HAL_INSTANCE(dev); uint32_t tmp = inst->FLASHCTL; /* * Clear FLASHCTL_FLASH_NP_FREE to avoid host puts a flash * standard request command at here. */ tmp &= NPCX_FLASHCTL_ACCESS_MASK; /* Set FLASHCTL_FLASH_TX_AVAIL */ tmp |= BIT(NPCX_FLASHCTL_FLASH_TX_AVAIL); inst->FLASHCTL = tmp; } /* This routine release FLASH_NP_FREE for standard request */ static void taf_release_flash_np_free(const struct device *dev) { struct espi_reg *const inst = HAL_INSTANCE(dev); uint32_t tmp = inst->FLASHCTL; /* * Clear FLASHCTL_FLASH_TX_AVAIL to avoid host puts a * GET_FLASH_C command at here. */ tmp &= NPCX_FLASHCTL_ACCESS_MASK; /* Release FLASH_NP_FREE */ tmp |= BIT(NPCX_FLASHCTL_FLASH_NP_FREE); inst->FLASHCTL = tmp; } static int taf_npcx_completion_handler(const struct device *dev, uint32_t *buffer) { uint16_t size = DIV_ROUND_UP((uint8_t)(buffer[0]) + 1, sizeof(uint32_t)); struct espi_reg *const inst = HAL_INSTANCE(dev); struct npcx_taf_head *head = (struct npcx_taf_head *)buffer; uint8_t i; /* Check the Flash Access TX Queue is empty by polling * FLASH_TX_AVAIL. */ if (WAIT_FOR(IS_BIT_SET(inst->FLASHCTL, NPCX_FLASHCTL_FLASH_TX_AVAIL), NPCX_FLASH_CHK_TIMEOUT, NULL)) { LOG_ERR("Check TX Queue Is Empty Timeout"); return -EBUSY; } /* Check ESPISTS.FLNACS is clear (no slave completion is detected) */ if (WAIT_FOR(IS_BIT_SET(inst->ESPISTS, NPCX_ESPISTS_FLNACS), NPCX_FLASH_CHK_TIMEOUT, NULL)) { LOG_ERR("Check Slave Completion Timeout"); return -EBUSY; } /* Write packet to FLASHTXBUF */ for (i = 0; i < size; i++) { inst->FLASHTXBUF[i] = buffer[i]; } /* Set the FLASHCTL.FLASH_TX_AVAIL bit to 1 to enqueue the packet */ taf_set_flash_c_avail(dev); /* Release FLASH_NP_FREE here to ready get next TAF request */ if ((head->type != CYC_SCS_CMP_WITH_DATA_FIRST) && (head->type != CYC_SCS_CMP_WITH_DATA_MIDDLE)) { taf_release_flash_np_free(dev); } return 0; } static int espi_taf_npcx_flash_read(const struct device *dev, struct espi_saf_packet *pckt) { struct espi_reg *const inst = HAL_INSTANCE(dev); struct espi_taf_npcx_config *config = ((struct espi_taf_npcx_config *)(dev)->config); struct espi_taf_npcx_pckt *taf_data_ptr = (struct espi_taf_npcx_pckt *)pckt->buf; uint8_t *data_ptr = (uint8_t *)taf_data_ptr->data; uint8_t cycle_type = CYC_SCS_CMP_WITH_DATA_ONLY; uint32_t total_len = pckt->len; uint32_t len = total_len; uint32_t addr = pckt->flash_addr; uint8_t flash_req_size = GET_FIELD(inst->FLASHCFG, NPCX_FLASHCFG_FLASHREQSIZE); uint8_t target_max_size = GET_FIELD(inst->FLASHCFG, NPCX_FLASHCFG_FLREQSUP); uint16_t max_read_req = 32 << flash_req_size; struct npcx_taf_head taf_head; int rc; if (flash_req_size > target_max_size) { LOG_DBG("Exceeded the maximum supported length"); if (target_max_size == 0) { target_max_size = 1; } max_read_req = 32 << target_max_size; } if (total_len > max_read_req) { LOG_ERR("Exceeded the limitation of read length"); return -EINVAL; } if (espi_taf_check_read_protect(dev, addr, len, taf_data_ptr->tag)) { LOG_ERR("Access protect region"); return -EINVAL; } if (total_len <= config->rx_plsz) { cycle_type = CYC_SCS_CMP_WITH_DATA_ONLY; len = total_len; } else { cycle_type = CYC_SCS_CMP_WITH_DATA_FIRST; len = config->rx_plsz; } do { data_ptr = (uint8_t *)taf_data_ptr->data; taf_head.pkt_len = len + NPCX_TAF_CMP_HEADER_LEN; taf_head.type = cycle_type; taf_head.tag_hlen = (taf_data_ptr->tag << 4) | ((len & 0xF00) >> 8); taf_head.llen = len & 0xFF; memcpy(data_ptr, &taf_head, sizeof(taf_head)); rc = flash_read(spi_dev, addr, data_ptr + 4, len); if (rc) { LOG_ERR("flash read fail 0x%x", rc); return -EIO; } rc = taf_npcx_completion_handler(dev, (uint32_t *)taf_data_ptr->data); if (rc) { LOG_ERR("espi taf completion handler fail"); return rc; } total_len -= len; addr += len; if (total_len <= config->rx_plsz) { cycle_type = CYC_SCS_CMP_WITH_DATA_LAST; len = total_len; } else { cycle_type = CYC_SCS_CMP_WITH_DATA_MIDDLE; } } while (total_len); return 0; } static int espi_taf_npcx_flash_write(const struct device *dev, struct espi_saf_packet *pckt) { struct espi_taf_npcx_pckt *taf_data_ptr = (struct espi_taf_npcx_pckt *)pckt->buf; uint8_t *data_ptr = (uint8_t *)(taf_data_ptr->data); struct npcx_taf_head taf_head; int rc; if (espi_taf_check_write_protect(dev, pckt->flash_addr, pckt->len, taf_data_ptr->tag)) { LOG_ERR("Access protection region"); return -EINVAL; } rc = flash_write(spi_dev, pckt->flash_addr, data_ptr, pckt->len); if (rc) { LOG_ERR("flash write fail 0x%x", rc); return -EIO; } taf_head.pkt_len = NPCX_TAF_CMP_HEADER_LEN; taf_head.type = CYC_SCS_CMP_WITHOUT_DATA; taf_head.tag_hlen = (taf_data_ptr->tag << 4); taf_head.llen = 0x0; memcpy(data_ptr, &taf_head, sizeof(taf_head)); rc = taf_npcx_completion_handler(dev, (uint32_t *)taf_data_ptr->data); if (rc) { LOG_ERR("espi taf completion handler fail"); return rc; } return 0; } static int espi_taf_npcx_flash_erase(const struct device *dev, struct espi_saf_packet *pckt) { struct espi_taf_npcx_pckt *taf_data_ptr = (struct espi_taf_npcx_pckt *)pckt->buf; uint8_t *data_ptr = (uint8_t *)taf_data_ptr->data; uint32_t addr = pckt->flash_addr; uint32_t len = pckt->len; struct npcx_taf_head taf_head; int rc; if (espi_taf_check_write_protect(dev, addr, len, taf_data_ptr->tag)) { LOG_ERR("Access protection region"); return -EINVAL; } rc = flash_erase(spi_dev, addr, len); if (rc) { LOG_ERR("flash erase fail"); return -EIO; } taf_head.pkt_len = NPCX_TAF_CMP_HEADER_LEN; taf_head.type = CYC_SCS_CMP_WITHOUT_DATA; taf_head.tag_hlen = (taf_data_ptr->tag << 4); taf_head.llen = 0x0; memcpy(data_ptr, &taf_head, sizeof(taf_head)); rc = taf_npcx_completion_handler(dev, (uint32_t *)taf_data_ptr->data); if (rc) { LOG_ERR("espi taf completion handler fail"); return rc; } return 0; } static int espi_taf_npcx_flash_unsuccess(const struct device *dev, struct espi_saf_packet *pckt) { struct espi_taf_npcx_pckt *taf_data_ptr = (struct espi_taf_npcx_pckt *)pckt->buf; uint8_t *data_ptr = (uint8_t *)taf_data_ptr->data; struct npcx_taf_head taf_head; int rc; taf_head.pkt_len = NPCX_TAF_CMP_HEADER_LEN; taf_head.type = CYC_UNSCS_CMP_WITHOUT_DATA_ONLY; taf_head.tag_hlen = (taf_data_ptr->tag << 4); taf_head.llen = 0x0; memcpy(data_ptr, &taf_head, sizeof(taf_head)); rc = taf_npcx_completion_handler(dev, (uint32_t *)taf_data_ptr->data); if (rc) { LOG_ERR("espi taf completion handler fail"); return rc; } return 0; } static int espi_taf_npcx_init(const struct device *dev) { struct espi_reg *const inst = HAL_INSTANCE(dev); struct espi_taf_npcx_config *config = ((struct espi_taf_npcx_config *)(dev)->config); SET_FIELD(inst->FLASHCFG, NPCX_FLASHCFG_FLCAPA, NPCX_FLASH_SHARING_CAP_SUPP_TAF_AND_CAF); SET_FIELD(inst->FLASHCFG, NPCX_FLASHCFG_TRGFLEBLKSIZE, BIT(config->erase_sz)); SET_FIELD(inst->FLASHCFG, NPCX_FLASHCFG_FLREQSUP, config->max_rd_sz); inst->FLASHBASE = config->mapped_addr; return 0; } static const struct espi_saf_driver_api espi_taf_npcx_driver_api = { .config = espi_taf_npcx_configure, .set_protection_regions = espi_taf_npcx_set_pr, .activate = espi_taf_npcx_activate, .get_channel_status = espi_taf_npcx_channel_ready, .flash_read = espi_taf_npcx_flash_read, .flash_write = espi_taf_npcx_flash_write, .flash_erase = espi_taf_npcx_flash_erase, .flash_unsuccess = espi_taf_npcx_flash_unsuccess, }; static struct espi_taf_npcx_data npcx_espi_taf_data; static const struct espi_taf_npcx_config espi_taf_npcx_config = { .base = DT_INST_REG_ADDR(0), .mapped_addr = DT_INST_PROP(0, mapped_addr), .rx_plsz = DT_PROP(DT_INST_PARENT(0), rx_plsize), .erase_sz = DT_INST_STRING_TOKEN(0, erase_sz), .max_rd_sz = DT_INST_STRING_TOKEN(0, max_read_sz), }; DEVICE_DT_INST_DEFINE(0, &espi_taf_npcx_init, NULL, &npcx_espi_taf_data, &espi_taf_npcx_config, PRE_KERNEL_2, CONFIG_ESPI_INIT_PRIORITY, &espi_taf_npcx_driver_api);