/* SPDX-License-Identifier: GPL-2.0-or-later */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct fsp_header fsps_hdr; /* Callbacks for SoC/Mainboard specific overrides */ void __weak platform_fsp_silicon_multi_phase_init_cb(uint32_t phase_index) { /* Leave for the SoC/Mainboard to implement if necessary. */ } /* FSP Specification < 2.2 has only 1 stage like FspSiliconInit. FSP specification >= 2.2 * has multiple stages as below. */ enum fsp_silicon_init_phases { FSP_SILICON_INIT_API, FSP_MULTI_PHASE_SI_INIT_GET_NUMBER_OF_PHASES_API, FSP_MULTI_PHASE_SI_INIT_EXECUTE_PHASE_API }; static void fsps_return_value_handler(enum fsp_silicon_init_phases phases, uint32_t status) { uint8_t postcode; /* Handle any reset request returned by FSP-S APIs */ fsp_handle_reset(status); if (status == FSP_SUCCESS) return; /* Handle all other errors returned by FSP-S APIs */ /* Assume video failure if attempted to initialize graphics */ if (CONFIG(RUN_FSP_GOP) && vbt_get()) postcode = POSTCODE_VIDEO_FAILURE; else postcode = POSTCODE_HW_INIT_FAILURE; /* else generic */ switch (phases) { case FSP_SILICON_INIT_API: die_with_post_code(postcode, "FspSiliconInit returned with error 0x%08x\n", status); break; case FSP_MULTI_PHASE_SI_INIT_GET_NUMBER_OF_PHASES_API: printk(BIOS_SPEW, "FspMultiPhaseSiInit NumberOfPhases returned 0x%08x\n", status); break; case FSP_MULTI_PHASE_SI_INIT_EXECUTE_PHASE_API: printk(BIOS_SPEW, "FspMultiPhaseSiInit ExecutePhase returned 0x%08x\n", status); break; default: break; } } bool fsp_is_multi_phase_init_enabled(void) { return CONFIG(FSPS_USE_MULTI_PHASE_INIT) && (fsps_hdr.fsp_multi_phase_si_init_entry_offset != 0); } static void fsp_fill_common_arch_params(FSPS_UPD *supd) { #if CONFIG(FSPS_HAS_ARCH_UPD) FSPS_ARCHx_UPD *s_arch_cfg = &supd->FspsArchUpd; s_arch_cfg->EnableMultiPhaseSiliconInit = fsp_is_multi_phase_init_enabled(); #endif } static void do_silicon_init(struct fsp_header *hdr) { FSPS_UPD *upd, *supd; fsp_silicon_init_fn silicon_init; uint32_t status; fsp_multi_phase_init_fn multi_phase_si_init; struct fsp_multi_phase_params multi_phase_params; struct fsp_multi_phase_get_number_of_phases_params multi_phase_get_number; supd = (FSPS_UPD *)(uintptr_t)(hdr->cfg_region_offset + hdr->image_base); fsp_verify_upd_header_signature(supd->FspUpdHeader.Signature, FSPS_UPD_SIGNATURE); /* FSPS UPD and coreboot structure sizes should match. However, enforcing the exact * match mandates simultaneous updates to coreboot and FSP repos. Allow coreboot * to proceed if its UPD structure is smaller than FSP one to enable staggered UPD * update process on both sides. The mismatch indicates a temporary build problem, * don't leave it like this as FSP default settings can be bad choices for coreboot. */ if (!hdr->cfg_region_size || hdr->cfg_region_size < sizeof(FSPS_UPD)) die_with_post_code(POSTCODE_INVALID_VENDOR_BINARY, "Invalid FSPS UPD region\n"); else if (hdr->cfg_region_size > sizeof(FSPS_UPD)) printk(BIOS_ERR, "FSP and coreboot are out of sync! FSPS UPD size > coreboot\n"); upd = xmalloc(hdr->cfg_region_size); memcpy(upd, supd, hdr->cfg_region_size); /* Fill common settings on behalf of chipset. */ if (CONFIG(FSPS_HAS_ARCH_UPD)) fsp_fill_common_arch_params(upd); /* Give SoC/mainboard a chance to populate entries */ platform_fsp_silicon_init_params_cb(upd); /* Populate logo related entries */ if (CONFIG(BMP_LOGO)) soc_load_logo(upd); /* Call SiliconInit */ silicon_init = (void *)(uintptr_t)(hdr->image_base + hdr->fsp_silicon_init_entry_offset); fsp_debug_before_silicon_init(silicon_init, supd, upd); timestamp_add_now(TS_FSP_SILICON_INIT_START); post_code(POSTCODE_FSP_SILICON_INIT); /* FSP disables the interrupt handler so remove debug exceptions temporarily */ null_breakpoint_disable(); if (ENV_X86_64 && CONFIG(PLATFORM_USES_FSP2_X86_32)) status = protected_mode_call_1arg(silicon_init, (uintptr_t)upd); else status = silicon_init(upd); null_breakpoint_init(); printk(BIOS_INFO, "FSPS returned %x\n", status); timestamp_add_now(TS_FSP_SILICON_INIT_END); post_code(POSTCODE_FSP_SILICON_EXIT); if (CONFIG(BMP_LOGO)) bmp_release_logo(); fsp_debug_after_silicon_init(status); fsps_return_value_handler(FSP_SILICON_INIT_API, status); /* Reinitialize CPUs if FSP-S has done MP Init */ if (CONFIG(USE_INTEL_FSP_MP_INIT) && !fsp_is_multi_phase_init_enabled()) do_mpinit_after_fsp(); if (!CONFIG(PLATFORM_USES_FSP2_2)) return; /* Check if SoC user would like to call Multi Phase Init */ if (!fsp_is_multi_phase_init_enabled()) return; /* Call MultiPhaseSiInit */ multi_phase_si_init = (void *)(uintptr_t)(hdr->image_base + hdr->fsp_multi_phase_si_init_entry_offset); /* Implementing multi_phase_si_init() is optional as per FSP 2.2 spec */ if (multi_phase_si_init == NULL) return; post_code(POSTCODE_FSP_MULTI_PHASE_SI_INIT_ENTRY); timestamp_add_now(TS_FSP_MULTI_PHASE_SI_INIT_START); /* Get NumberOfPhases Value */ multi_phase_params.multi_phase_action = GET_NUMBER_OF_PHASES; multi_phase_params.phase_index = 0; multi_phase_params.multi_phase_param_ptr = &multi_phase_get_number; status = multi_phase_si_init(&multi_phase_params); fsps_return_value_handler(FSP_MULTI_PHASE_SI_INIT_GET_NUMBER_OF_PHASES_API, status); /* Execute Multi Phase Execution */ for (uint32_t i = 1; i <= multi_phase_get_number.number_of_phases; i++) { printk(BIOS_SPEW, "Executing Phase %u of FspMultiPhaseSiInit\n", i); /* * Give SoC/mainboard a chance to perform any operation before * Multi Phase Execution */ platform_fsp_silicon_multi_phase_init_cb(i); multi_phase_params.multi_phase_action = EXECUTE_PHASE; multi_phase_params.phase_index = i; multi_phase_params.multi_phase_param_ptr = NULL; status = multi_phase_si_init(&multi_phase_params); if (CONFIG(FSP_MULTIPHASE_SI_INIT_RETURN_BROKEN)) status = fsp_get_pch_reset_status(); fsps_return_value_handler(FSP_MULTI_PHASE_SI_INIT_EXECUTE_PHASE_API, status); } timestamp_add_now(TS_FSP_MULTI_PHASE_SI_INIT_END); post_code(POSTCODE_FSP_MULTI_PHASE_SI_INIT_EXIT); /* Reinitialize CPUs if FSP-S has done MP Init */ if (CONFIG(USE_INTEL_FSP_MP_INIT)) do_mpinit_after_fsp(); } static void *fsps_allocator(void *arg_unused, size_t size, const union cbfs_mdata *mdata_unused) { return cbmem_add(CBMEM_ID_REFCODE, size); } void fsps_load(void) { const char *fsps_cbfs = soc_select_fsp_s_cbfs(); struct fsp_load_descriptor fspld = { .fsp_prog = PROG_INIT(PROG_REFCODE, fsps_cbfs), .alloc = fsps_allocator, }; struct prog *fsps = &fspld.fsp_prog; static int load_done; if (load_done) return; timestamp_add_now(TS_FSP_SILICON_INIT_LOAD); if (resume_from_stage_cache()) { printk(BIOS_DEBUG, "Loading FSPS from stage_cache\n"); stage_cache_load_stage(STAGE_REFCODE, fsps); if (fsp_validate_component(&fsps_hdr, prog_start(fsps), prog_size(fsps))) die("On resume fsps header is invalid\n"); load_done = 1; return; } if (fsp_load_component(&fspld, &fsps_hdr) != CB_SUCCESS) die("FSP-S failed to load\n"); stage_cache_add(STAGE_REFCODE, fsps); load_done = 1; } void preload_fsps(void) { if (!CONFIG(CBFS_PRELOAD)) return; const char *fsps_cbfs = soc_select_fsp_s_cbfs(); printk(BIOS_DEBUG, "Preloading %s\n", fsps_cbfs); cbfs_preload(fsps_cbfs); } void fsp_silicon_init(void) { fsps_load(); do_silicon_init(&fsps_hdr); if (CONFIG(CACHE_MRC_SETTINGS) && CONFIG(FSP_NVS_DATA_POST_SILICON_INIT)) save_memory_training_data(); if (CONFIG(DISPLAY_FSP_TIMESTAMPS)) fsp_display_timestamp(); } __weak void soc_load_logo(FSPS_UPD *supd) { }