src/drivers/intel/fsp2_0/memory_init.c - coreboot - Gitiles

 /* SPDX-License-Identifier: GPL-2.0-or-later */

 #include <arch/null_breakpoint.h>
 #include <arch/symbols.h>
 #include <assert.h>
 #include <cbfs.h>
 #include <cbmem.h>
 #include <cf9_reset.h>
 #include <console/console.h>
 #include <elog.h>
 #include <fsp/api.h>
 #include <fsp/util.h>
 #include <memrange.h>
 #include <mode_switch.h>
 #include <mrc_cache.h>
 #include <program_loading.h>
 #include <romstage_handoff.h>
 #include <security/tpm/tspi.h>
 #include <security/vboot/antirollback.h>
 #include <security/vboot/vboot_common.h>
 #include <string.h>
 #include <symbols.h>
 #include <timestamp.h>
 #include <types.h>
 #include <vb2_api.h>

 #if CONFIG(SOC_INTEL_COMMON_BASECODE_RAMTOP)
 #include <intelbasecode/ramtop.h>
 #endif

 static uint8_t temp_ram[CONFIG_FSP_TEMP_RAM_SIZE] __aligned(sizeof(uint64_t));

 /*
  * Helper function to store the MRC cache version into CBMEM
  *
  * ramstage uses either the MRC version or FSP-M version (depending on the config)
  * when updating the MRC cache
  */
 static void do_cbmem_version_entry(uint32_t cbmem_id, uint32_t version)
 {
 	uint32_t *cbmem_version_entry = cbmem_add(cbmem_id, sizeof(version));
 	if (!cbmem_version_entry) {
 		printk(BIOS_ERR, "Failed to add %s version to cbmem.\n",
 				CONFIG(MRC_CACHE_USING_MRC_VERSION) ? "MRC" : "FSP-M");
 		return;
 	}
 	*cbmem_version_entry = version;
 }

 static void do_fsp_post_memory_init(bool s3wake, uint32_t version)
 {
 	struct range_entry fsp_mem;
 	uint32_t cbmem_id = CONFIG(MRC_CACHE_USING_MRC_VERSION) ? CBMEM_ID_MRC_VERSION :
 					 CBMEM_ID_FSPM_VERSION;

 	fsp_find_reserved_memory(&fsp_mem);

 	/* initialize cbmem by adding FSP reserved memory first thing */
 	if (!s3wake) {
 		cbmem_initialize_empty_id_size(CBMEM_ID_FSP_RESERVED_MEMORY,
 			range_entry_size(&fsp_mem));
 	} else if (cbmem_initialize_id_size(CBMEM_ID_FSP_RESERVED_MEMORY,
 				range_entry_size(&fsp_mem))) {
 		if (CONFIG(HAVE_ACPI_RESUME)) {
 			printk(BIOS_ERR, "Failed to recover CBMEM in S3 resume.\n");
 			/* Failed S3 resume, reset to come up cleanly */
 			/* FIXME: A "system" reset is likely enough: */
 			full_reset();
 		}
 	}

 	/* make sure FSP memory is reserved in cbmem */
 	if (range_entry_base(&fsp_mem) !=
 		(uintptr_t)cbmem_find(CBMEM_ID_FSP_RESERVED_MEMORY))
 		die("Failed to accommodate FSP reserved memory request!\n");

 	if (CONFIG(CACHE_MRC_SETTINGS) && !s3wake)
 		do_cbmem_version_entry(cbmem_id, version);

 	/* Create romstage handof information */
 	romstage_handoff_init(s3wake);
 }

 static void fsp_fill_mrc_cache(FSPM_ARCH_UPD *arch_upd, uint32_t version)
 {
 	void *data;
 	size_t mrc_size;

 	arch_upd->NvsBufferPtr = 0;

 	if (!CONFIG(CACHE_MRC_SETTINGS))
 		return;

 	/* Assume boot device is memory mapped. */
 	assert(CONFIG(BOOT_DEVICE_MEMORY_MAPPED));

 	data = mrc_cache_current_mmap_leak(MRC_TRAINING_DATA, version,
 					   &mrc_size);
 	if (data == NULL)
 		return;

 	/* MRC cache found */
 	arch_upd->NvsBufferPtr = (uintptr_t)data;

 	printk(BIOS_SPEW, "MRC cache found, size %zu bytes\n", mrc_size);
 }

 static enum cb_err check_region_overlap(const struct memranges *ranges,
 					const char *description,
 					uintptr_t begin, uintptr_t end)
 {
 	const struct range_entry *r;

 	memranges_each_entry(r, ranges) {
 		if (end <= range_entry_base(r))
 			continue;
 		if (begin >= range_entry_end(r))
 			continue;
 		printk(BIOS_CRIT, "'%s' overlaps currently running program: "
 			"[%p, %p)\n", description, (void *)begin, (void *)end);
 		return CB_ERR;
 	}

 	return CB_SUCCESS;
 }

 static enum cb_err setup_fsp_stack_frame(FSPM_ARCH_UPD *arch_upd,
 		const struct memranges *memmap)
 {
 	uintptr_t stack_begin;
 	uintptr_t stack_end;

 	/*
 	 * FSPM_UPD passed here is populated with default values
 	 * provided by the blob itself. We let FSPM use top of CAR
 	 * region of the size it requests.
 	 */
 	stack_end = (uintptr_t)_car_region_end;
 	stack_begin = stack_end - arch_upd->StackSize;
 	if (check_region_overlap(memmap, "FSPM stack", stack_begin,
 				stack_end) != CB_SUCCESS)
 		return CB_ERR;

 	arch_upd->StackBase = stack_begin;
 	return CB_SUCCESS;
 }

 static enum cb_err fsp_fill_common_arch_params(FSPM_ARCH_UPD *arch_upd,
 					bool s3wake, uint32_t version,
 					const struct memranges *memmap)
 {
 	/*
 	 * FSP 2.1 version would use same stack as coreboot instead of
 	 * setting up separate stack frame. FSP 2.1 would not relocate stack
 	 * top and does not reinitialize stack pointer. The parameters passed
 	 * as StackBase and StackSize are actually for temporary RAM and HOBs
 	 * and are not related to FSP stack at all.
 	 * Non-CAR FSP 2.0 platforms pass a DRAM location for the FSP stack.
 	 */
 	if (CONFIG(FSP_USES_CB_STACK) || !ENV_CACHE_AS_RAM) {
 		arch_upd->StackBase = (uintptr_t)temp_ram;
 		arch_upd->StackSize = sizeof(temp_ram);
 	} else if (setup_fsp_stack_frame(arch_upd, memmap)) {
 		return CB_ERR;
 	}

 	fsp_fill_mrc_cache(arch_upd, version);

 	/* Configure bootmode */
 	if (s3wake) {
 		arch_upd->BootMode = FSP_BOOT_ON_S3_RESUME;
 	} else {
 		if (arch_upd->NvsBufferPtr)
 			arch_upd->BootMode =
 				FSP_BOOT_ASSUMING_NO_CONFIGURATION_CHANGES;
 		else
 			arch_upd->BootMode = FSP_BOOT_WITH_FULL_CONFIGURATION;
 	}

 	printk(BIOS_SPEW, "bootmode is set to: %d\n", arch_upd->BootMode);

 	return CB_SUCCESS;
 }

 __weak
 uint8_t fsp_memory_mainboard_version(void)
 {
 	return 0;
 }

 __weak
 uint8_t fsp_memory_soc_version(void)
 {
 	return 0;
 }

 /*
  * Allow SoC and/or mainboard to bump the revision of the FSP setting
  * number. The FSP spec uses the low 8 bits as the build number. Take over
  * bits 3:0 for the SoC setting and bits 7:4 for the mainboard. That way
  * a tweak in the settings will bump the version used to track the cached
  * setting which triggers retraining when the FSP version hasn't changed, but
  * the SoC or mainboard settings have.
  */
 static uint32_t fsp_memory_settings_version(const struct fsp_header *hdr)
 {
 	/* Use the full FSP version by default. */
 	uint32_t ver = hdr->image_revision;

 	if (!CONFIG(FSP_PLATFORM_MEMORY_SETTINGS_VERSIONS))
 		return ver;

 	ver &= ~0xff;
 	ver |= (0xf & fsp_memory_mainboard_version()) << 4;
 	ver |= (0xf & fsp_memory_soc_version()) << 0;

 	return ver;
 }

 struct fspm_context {
 	struct fsp_header header;
 	struct memranges memmap;
 };

 /*
  * Helper function to read MRC version
  *
  * There are multiple ways to read the MRC version using
  * Intel FSP. Currently the only supported method to get the
  * MRC version is by reading the FSP_PRODUCDER_DATA_TABLES
  * from the FSP-M binary (by parsing the FSP header).
  */
 static uint32_t fsp_mrc_version(void)
 {
 	uint32_t ver = 0;
 #if CONFIG(MRC_CACHE_USING_MRC_VERSION)
 	size_t fspm_blob_size;
 	void *fspm_blob_file = cbfs_map(CONFIG_FSP_M_CBFS, &fspm_blob_size);
 	if (!fspm_blob_file)
 		return 0;

 	FSP_PRODUCER_DATA_TABLES *ft = fspm_blob_file + FSP_HDR_OFFSET;
 	FSP_PRODUCER_DATA_TYPE2 *table2 = &ft->FspProduceDataType2;
 	size_t mrc_version_size = sizeof(table2->MrcVersion);
 	for (size_t i = 0; i < mrc_version_size; i++) {
 		ver |= (table2->MrcVersion[i] << ((mrc_version_size - 1) - i) * 8);
 	}
 	cbfs_unmap(fspm_blob_file);
 #endif
 	return ver;
 }

 static void do_fsp_memory_init(const struct fspm_context *context, bool s3wake)
 {
 	uint32_t status;
 	fsp_memory_init_fn fsp_raminit;
 	FSPM_UPD fspm_upd, *upd;
 	FSPM_ARCH_UPD *arch_upd;
 	uint32_t version;
 	const struct fsp_header *hdr = &context->header;
 	const struct memranges *memmap = &context->memmap;

 	post_code(POSTCODE_MEM_PREINIT_PREP_START);

 	if (CONFIG(MRC_CACHE_USING_MRC_VERSION))
 		version = fsp_mrc_version();
 	else
 		version = fsp_memory_settings_version(hdr);

 	upd = (FSPM_UPD *)(uintptr_t)(hdr->cfg_region_offset + hdr->image_base);

 	/*
 	 * Verify UPD region size. We don't have malloc before ramstage, so we
 	 * use a static buffer for the FSP-M UPDs which is sizeof(FSPM_UPD)
 	 * bytes long, since that is the value known at compile time. If
 	 * hdr->cfg_region_size is bigger than that, not all UPD defaults will
 	 * be copied, so it'll contain random data at the end, so we just call
 	 * die() in that case. If hdr->cfg_region_size is smaller than that,
 	 * there's a mismatch between the FSP and the header, but since it will
 	 * copy the full UPD defaults to the buffer, we try to continue and
 	 * hope that there was no incompatible change in the UPDs.
 	 */
 	if (hdr->cfg_region_size > sizeof(FSPM_UPD))
 		die("FSP-M UPD size is larger than FSPM_UPD struct size.\n");
 	if (hdr->cfg_region_size < sizeof(FSPM_UPD))
 		printk(BIOS_ERR, "FSP-M UPD size is smaller than FSPM_UPD struct size. "
 				"Check if the FSP binary matches the FSP headers.\n");

 	fsp_verify_upd_header_signature(upd->FspUpdHeader.Signature, FSPM_UPD_SIGNATURE);

 	/* Copy the default values from the UPD area */
 	memcpy(&fspm_upd, upd, sizeof(fspm_upd));

 	arch_upd = &fspm_upd.FspmArchUpd;

 	/* Reserve enough memory under TOLUD to save CBMEM header */
 	arch_upd->BootLoaderTolumSize = cbmem_overhead_size();

 	/* Fill common settings on behalf of chipset. */
 	if (fsp_fill_common_arch_params(arch_upd, s3wake, version,
 					memmap) != CB_SUCCESS)
 		die_with_post_code(POSTCODE_INVALID_VENDOR_BINARY,
 			"FSPM_ARCH_UPD not found!\n");

 	/* Early caching of RAMTOP region if valid mrc cache data is found */
 #if (CONFIG(SOC_INTEL_COMMON_BASECODE_RAMTOP))
 	if (arch_upd->NvsBufferPtr)
 		early_ramtop_enable_cache_range();
 #endif

 	/* Give SoC and mainboard a chance to update the UPD */
 	platform_fsp_memory_init_params_cb(&fspm_upd, version);

 	/*
 	 * For S3 resume case, if valid mrc cache data is not found or
 	 * RECOVERY_MRC_CACHE hash verification fails, the S3 data
 	 * pointer would be null and S3 resume fails with fsp-m
 	 * returning error. Invoking a reset here saves time.
 	 */
 	if (s3wake && !arch_upd->NvsBufferPtr)
 		/* FIXME: A "system" reset is likely enough: */
 		full_reset();

 	if (CONFIG(MMA))
 		setup_mma(&fspm_upd.FspmConfig);

 	post_code(POSTCODE_MEM_PREINIT_PREP_END);

 	/* Call FspMemoryInit */
 	fsp_raminit = (void *)(uintptr_t)(hdr->image_base + hdr->fsp_memory_init_entry_offset);
 	fsp_debug_before_memory_init(fsp_raminit, upd, &fspm_upd);

 	/* FSP disables the interrupt handler so remove debug exceptions temporarily  */
 	null_breakpoint_disable();
 	post_code(POSTCODE_FSP_MEMORY_INIT);
 	timestamp_add_now(TS_FSP_MEMORY_INIT_START);
 	if (ENV_X86_64 && CONFIG(PLATFORM_USES_FSP2_X86_32))
 		status = protected_mode_call_2arg(fsp_raminit,
 						  (uintptr_t)&fspm_upd,
 						  (uintptr_t)fsp_get_hob_list_ptr());
 	else
 		status = fsp_raminit(&fspm_upd, fsp_get_hob_list_ptr());
 	null_breakpoint_init();

 	post_code(POSTCODE_FSP_MEMORY_EXIT);
 	timestamp_add_now(TS_FSP_MEMORY_INIT_END);

 	/* Handle any errors returned by FspMemoryInit */
 	fsp_handle_reset(status);
 	if (status != FSP_SUCCESS) {
 		die_with_post_code(POSTCODE_RAM_FAILURE,
 			"FspMemoryInit returned with error 0x%08x!\n", status);
 	}

 	do_fsp_post_memory_init(s3wake, version);

 	/*
 	 * fsp_debug_after_memory_init() checks whether the end of the tolum
 	 * region is the same as the top of cbmem, so must be called here
 	 * after cbmem has been initialised in do_fsp_post_memory_init().
 	 */
 	fsp_debug_after_memory_init(status);
 }

 static void *fspm_allocator(void *arg, size_t size, const union cbfs_mdata *unused)
 {
 	const struct fsp_load_descriptor *fspld = arg;
 	struct fspm_context *context = fspld->arg;
 	struct memranges *memmap = &context->memmap;

 	/* Non XIP FSP-M uses FSP-M address */
 	uintptr_t fspm_begin = (uintptr_t)CONFIG_FSP_M_ADDR;
 	uintptr_t fspm_end = fspm_begin + size;

 	if (check_region_overlap(memmap, "FSPM", fspm_begin, fspm_end) != CB_SUCCESS)
 		return NULL;

 	return (void *)fspm_begin;
 }

 void preload_fspm(void)
 {
 	if (!CONFIG(CBFS_PRELOAD))
 		return;

 	printk(BIOS_DEBUG, "Preloading %s\n", CONFIG_FSP_M_CBFS);
 	cbfs_preload(CONFIG_FSP_M_CBFS);
 }

 void fsp_memory_init(bool s3wake)
 {
 	struct range_entry prog_ranges[2];
 	struct fspm_context context;
 	struct fsp_load_descriptor fspld = {
 		.fsp_prog = PROG_INIT(PROG_REFCODE, CONFIG_FSP_M_CBFS),
 		.arg = &context,
 	};
 	struct fsp_header *hdr = &context.header;
 	struct memranges *memmap = &context.memmap;

 	/* For FSP-M XIP we leave alloc NULL to get a direct mapping to flash. */
 	if (!CONFIG(FSP_M_XIP))
 		fspld.alloc = fspm_allocator;

 	elog_boot_notify(s3wake);

 	/* Build up memory map of romstage address space including CAR. */
 	memranges_init_empty(memmap, &prog_ranges[0], ARRAY_SIZE(prog_ranges));
 	if (ENV_CACHE_AS_RAM)
 		memranges_insert(memmap, (uintptr_t)_car_region_start,
 			_car_unallocated_start - _car_region_start, 0);
 	memranges_insert(memmap, (uintptr_t)_program, REGION_SIZE(program), 0);

 	timestamp_add_now(TS_FSP_MEMORY_INIT_LOAD);
 	if (fsp_load_component(&fspld, hdr) != CB_SUCCESS)
 		die("FSPM not available or failed to load!\n");

 	if (CONFIG(FSP_M_XIP) && (uintptr_t)prog_start(&fspld.fsp_prog) != hdr->image_base)
 		die("FSPM XIP base does not match: %p vs %p\n",
 		    (void *)(uintptr_t)hdr->image_base, prog_start(&fspld.fsp_prog));

 	timestamp_add_now(TS_INITRAM_START);

 	do_fsp_memory_init(&context, s3wake);

 	timestamp_add_now(TS_INITRAM_END);
 }
	/* SPDX-License-Identifier: GPL-2.0-or-later */

	#include <arch/null_breakpoint.h>
	#include <arch/symbols.h>
	#include <assert.h>
	#include <cbfs.h>
	#include <cbmem.h>
	#include <cf9_reset.h>
	#include <console/console.h>
	#include <elog.h>
	#include <fsp/api.h>
	#include <fsp/util.h>
	#include <memrange.h>
	#include <mode_switch.h>
	#include <mrc_cache.h>
	#include <program_loading.h>
	#include <romstage_handoff.h>
	#include <security/tpm/tspi.h>
	#include <security/vboot/antirollback.h>
	#include <security/vboot/vboot_common.h>
	#include <string.h>
	#include <symbols.h>
	#include <timestamp.h>
	#include <types.h>
	#include <vb2_api.h>

	#if CONFIG(SOC_INTEL_COMMON_BASECODE_RAMTOP)
	#include <intelbasecode/ramtop.h>
	#endif

	static uint8_t temp_ram[CONFIG_FSP_TEMP_RAM_SIZE] __aligned(sizeof(uint64_t));

	/*
	* Helper function to store the MRC cache version into CBMEM
	*
	* ramstage uses either the MRC version or FSP-M version (depending on the config)
	* when updating the MRC cache
	*/
	static void do_cbmem_version_entry(uint32_t cbmem_id, uint32_t version)
	{
	uint32_t *cbmem_version_entry = cbmem_add(cbmem_id, sizeof(version));
	if (!cbmem_version_entry) {
	printk(BIOS_ERR, "Failed to add %s version to cbmem.\n",
	CONFIG(MRC_CACHE_USING_MRC_VERSION) ? "MRC" : "FSP-M");
	return;
	}
	*cbmem_version_entry = version;
	}

	static void do_fsp_post_memory_init(bool s3wake, uint32_t version)
	{
	struct range_entry fsp_mem;
	uint32_t cbmem_id = CONFIG(MRC_CACHE_USING_MRC_VERSION) ? CBMEM_ID_MRC_VERSION :
	CBMEM_ID_FSPM_VERSION;

	fsp_find_reserved_memory(&fsp_mem);

	/* initialize cbmem by adding FSP reserved memory first thing */
	if (!s3wake) {
	cbmem_initialize_empty_id_size(CBMEM_ID_FSP_RESERVED_MEMORY,
	range_entry_size(&fsp_mem));
	} else if (cbmem_initialize_id_size(CBMEM_ID_FSP_RESERVED_MEMORY,
	range_entry_size(&fsp_mem))) {
	if (CONFIG(HAVE_ACPI_RESUME)) {
	printk(BIOS_ERR, "Failed to recover CBMEM in S3 resume.\n");
	/* Failed S3 resume, reset to come up cleanly */
	/* FIXME: A "system" reset is likely enough: */
	full_reset();
	}
	}

	/* make sure FSP memory is reserved in cbmem */
	if (range_entry_base(&fsp_mem) !=
	(uintptr_t)cbmem_find(CBMEM_ID_FSP_RESERVED_MEMORY))
	die("Failed to accommodate FSP reserved memory request!\n");

	if (CONFIG(CACHE_MRC_SETTINGS) && !s3wake)
	do_cbmem_version_entry(cbmem_id, version);

	/* Create romstage handof information */
	romstage_handoff_init(s3wake);
	}

	static void fsp_fill_mrc_cache(FSPM_ARCH_UPD *arch_upd, uint32_t version)
	{
	void *data;
	size_t mrc_size;

	arch_upd->NvsBufferPtr = 0;

	if (!CONFIG(CACHE_MRC_SETTINGS))
	return;

	/* Assume boot device is memory mapped. */
	assert(CONFIG(BOOT_DEVICE_MEMORY_MAPPED));

	data = mrc_cache_current_mmap_leak(MRC_TRAINING_DATA, version,
	&mrc_size);
	if (data == NULL)
	return;

	/* MRC cache found */
	arch_upd->NvsBufferPtr = (uintptr_t)data;

	printk(BIOS_SPEW, "MRC cache found, size %zu bytes\n", mrc_size);
	}

	static enum cb_err check_region_overlap(const struct memranges *ranges,
	const char *description,
	uintptr_t begin, uintptr_t end)
	{
	const struct range_entry *r;

	memranges_each_entry(r, ranges) {
	if (end <= range_entry_base(r))
	continue;
	if (begin >= range_entry_end(r))
	continue;
	printk(BIOS_CRIT, "'%s' overlaps currently running program: "
	"[%p, %p)\n", description, (void )begin, (void )end);
	return CB_ERR;
	}

	return CB_SUCCESS;
	}

	static enum cb_err setup_fsp_stack_frame(FSPM_ARCH_UPD *arch_upd,
	const struct memranges *memmap)
	{
	uintptr_t stack_begin;
	uintptr_t stack_end;

	/*
	* FSPM_UPD passed here is populated with default values
	* provided by the blob itself. We let FSPM use top of CAR
	* region of the size it requests.
	*/
	stack_end = (uintptr_t)_car_region_end;
	stack_begin = stack_end - arch_upd->StackSize;
	if (check_region_overlap(memmap, "FSPM stack", stack_begin,
	stack_end) != CB_SUCCESS)
	return CB_ERR;

	arch_upd->StackBase = stack_begin;
	return CB_SUCCESS;
	}

	static enum cb_err fsp_fill_common_arch_params(FSPM_ARCH_UPD *arch_upd,
	bool s3wake, uint32_t version,
	const struct memranges *memmap)
	{
	/*
	* FSP 2.1 version would use same stack as coreboot instead of
	* setting up separate stack frame. FSP 2.1 would not relocate stack
	* top and does not reinitialize stack pointer. The parameters passed
	* as StackBase and StackSize are actually for temporary RAM and HOBs
	* and are not related to FSP stack at all.
	* Non-CAR FSP 2.0 platforms pass a DRAM location for the FSP stack.
	*/
	if (CONFIG(FSP_USES_CB_STACK) \|\| !ENV_CACHE_AS_RAM) {
	arch_upd->StackBase = (uintptr_t)temp_ram;
	arch_upd->StackSize = sizeof(temp_ram);
	} else if (setup_fsp_stack_frame(arch_upd, memmap)) {
	return CB_ERR;
	}

	fsp_fill_mrc_cache(arch_upd, version);

	/* Configure bootmode */
	if (s3wake) {
	arch_upd->BootMode = FSP_BOOT_ON_S3_RESUME;
	} else {
	if (arch_upd->NvsBufferPtr)
	arch_upd->BootMode =
	FSP_BOOT_ASSUMING_NO_CONFIGURATION_CHANGES;
	else
	arch_upd->BootMode = FSP_BOOT_WITH_FULL_CONFIGURATION;
	}

	printk(BIOS_SPEW, "bootmode is set to: %d\n", arch_upd->BootMode);

	return CB_SUCCESS;
	}

	__weak
	uint8_t fsp_memory_mainboard_version(void)
	{
	return 0;
	}

	__weak
	uint8_t fsp_memory_soc_version(void)
	{
	return 0;
	}

	/*
	* Allow SoC and/or mainboard to bump the revision of the FSP setting
	* number. The FSP spec uses the low 8 bits as the build number. Take over
	* bits 3:0 for the SoC setting and bits 7:4 for the mainboard. That way
	* a tweak in the settings will bump the version used to track the cached
	* setting which triggers retraining when the FSP version hasn't changed, but
	* the SoC or mainboard settings have.
	*/
	static uint32_t fsp_memory_settings_version(const struct fsp_header *hdr)
	{
	/* Use the full FSP version by default. */
	uint32_t ver = hdr->image_revision;

	if (!CONFIG(FSP_PLATFORM_MEMORY_SETTINGS_VERSIONS))
	return ver;

	ver &= ~0xff;
	ver \|= (0xf & fsp_memory_mainboard_version()) << 4;
	ver \|= (0xf & fsp_memory_soc_version()) << 0;

	return ver;
	}

	struct fspm_context {
	struct fsp_header header;
	struct memranges memmap;
	};

	/*
	* Helper function to read MRC version
	*
	* There are multiple ways to read the MRC version using
	* Intel FSP. Currently the only supported method to get the
	* MRC version is by reading the FSP_PRODUCDER_DATA_TABLES
	* from the FSP-M binary (by parsing the FSP header).
	*/
	static uint32_t fsp_mrc_version(void)
	{
	uint32_t ver = 0;
	#if CONFIG(MRC_CACHE_USING_MRC_VERSION)
	size_t fspm_blob_size;
	void *fspm_blob_file = cbfs_map(CONFIG_FSP_M_CBFS, &fspm_blob_size);
	if (!fspm_blob_file)
	return 0;

	FSP_PRODUCER_DATA_TABLES *ft = fspm_blob_file + FSP_HDR_OFFSET;
	FSP_PRODUCER_DATA_TYPE2 *table2 = &ft->FspProduceDataType2;
	size_t mrc_version_size = sizeof(table2->MrcVersion);
	for (size_t i = 0; i < mrc_version_size; i++) {
	ver \|= (table2->MrcVersion[i] << ((mrc_version_size - 1) - i) * 8);
	}
	cbfs_unmap(fspm_blob_file);
	#endif
	return ver;
	}

	static void do_fsp_memory_init(const struct fspm_context *context, bool s3wake)
	{
	uint32_t status;
	fsp_memory_init_fn fsp_raminit;
	FSPM_UPD fspm_upd, *upd;
	FSPM_ARCH_UPD *arch_upd;
	uint32_t version;
	const struct fsp_header *hdr = &context->header;
	const struct memranges *memmap = &context->memmap;

	post_code(POSTCODE_MEM_PREINIT_PREP_START);

	if (CONFIG(MRC_CACHE_USING_MRC_VERSION))
	version = fsp_mrc_version();
	else
	version = fsp_memory_settings_version(hdr);

	upd = (FSPM_UPD *)(uintptr_t)(hdr->cfg_region_offset + hdr->image_base);

	/*
	* Verify UPD region size. We don't have malloc before ramstage, so we
	* use a static buffer for the FSP-M UPDs which is sizeof(FSPM_UPD)
	* bytes long, since that is the value known at compile time. If
	* hdr->cfg_region_size is bigger than that, not all UPD defaults will
	* be copied, so it'll contain random data at the end, so we just call
	* die() in that case. If hdr->cfg_region_size is smaller than that,
	* there's a mismatch between the FSP and the header, but since it will
	* copy the full UPD defaults to the buffer, we try to continue and
	* hope that there was no incompatible change in the UPDs.
	*/
	if (hdr->cfg_region_size > sizeof(FSPM_UPD))
	die("FSP-M UPD size is larger than FSPM_UPD struct size.\n");
	if (hdr->cfg_region_size < sizeof(FSPM_UPD))
	printk(BIOS_ERR, "FSP-M UPD size is smaller than FSPM_UPD struct size. "
	"Check if the FSP binary matches the FSP headers.\n");

	fsp_verify_upd_header_signature(upd->FspUpdHeader.Signature, FSPM_UPD_SIGNATURE);

	/* Copy the default values from the UPD area */
	memcpy(&fspm_upd, upd, sizeof(fspm_upd));

	arch_upd = &fspm_upd.FspmArchUpd;

	/* Reserve enough memory under TOLUD to save CBMEM header */
	arch_upd->BootLoaderTolumSize = cbmem_overhead_size();

	/* Fill common settings on behalf of chipset. */
	if (fsp_fill_common_arch_params(arch_upd, s3wake, version,
	memmap) != CB_SUCCESS)
	die_with_post_code(POSTCODE_INVALID_VENDOR_BINARY,
	"FSPM_ARCH_UPD not found!\n");

	/* Early caching of RAMTOP region if valid mrc cache data is found */
	#if (CONFIG(SOC_INTEL_COMMON_BASECODE_RAMTOP))
	if (arch_upd->NvsBufferPtr)
	early_ramtop_enable_cache_range();
	#endif

	/* Give SoC and mainboard a chance to update the UPD */
	platform_fsp_memory_init_params_cb(&fspm_upd, version);

	/*
	* For S3 resume case, if valid mrc cache data is not found or
	* RECOVERY_MRC_CACHE hash verification fails, the S3 data
	* pointer would be null and S3 resume fails with fsp-m
	* returning error. Invoking a reset here saves time.
	*/
	if (s3wake && !arch_upd->NvsBufferPtr)
	/* FIXME: A "system" reset is likely enough: */
	full_reset();

	if (CONFIG(MMA))
	setup_mma(&fspm_upd.FspmConfig);

	post_code(POSTCODE_MEM_PREINIT_PREP_END);

	/* Call FspMemoryInit */
	fsp_raminit = (void *)(uintptr_t)(hdr->image_base + hdr->fsp_memory_init_entry_offset);
	fsp_debug_before_memory_init(fsp_raminit, upd, &fspm_upd);

	/* FSP disables the interrupt handler so remove debug exceptions temporarily */
	null_breakpoint_disable();
	post_code(POSTCODE_FSP_MEMORY_INIT);
	timestamp_add_now(TS_FSP_MEMORY_INIT_START);
	if (ENV_X86_64 && CONFIG(PLATFORM_USES_FSP2_X86_32))
	status = protected_mode_call_2arg(fsp_raminit,
	(uintptr_t)&fspm_upd,
	(uintptr_t)fsp_get_hob_list_ptr());
	else
	status = fsp_raminit(&fspm_upd, fsp_get_hob_list_ptr());
	null_breakpoint_init();

	post_code(POSTCODE_FSP_MEMORY_EXIT);
	timestamp_add_now(TS_FSP_MEMORY_INIT_END);

	/* Handle any errors returned by FspMemoryInit */
	fsp_handle_reset(status);
	if (status != FSP_SUCCESS) {
	die_with_post_code(POSTCODE_RAM_FAILURE,
	"FspMemoryInit returned with error 0x%08x!\n", status);
	}

	do_fsp_post_memory_init(s3wake, version);

	/*
	* fsp_debug_after_memory_init() checks whether the end of the tolum
	* region is the same as the top of cbmem, so must be called here
	* after cbmem has been initialised in do_fsp_post_memory_init().
	*/
	fsp_debug_after_memory_init(status);
	}

	static void fspm_allocator(void arg, size_t size, const union cbfs_mdata *unused)
	{
	const struct fsp_load_descriptor *fspld = arg;
	struct fspm_context *context = fspld->arg;
	struct memranges *memmap = &context->memmap;

	/* Non XIP FSP-M uses FSP-M address */
	uintptr_t fspm_begin = (uintptr_t)CONFIG_FSP_M_ADDR;
	uintptr_t fspm_end = fspm_begin + size;

	if (check_region_overlap(memmap, "FSPM", fspm_begin, fspm_end) != CB_SUCCESS)
	return NULL;

	return (void *)fspm_begin;
	}

	void preload_fspm(void)
	{
	if (!CONFIG(CBFS_PRELOAD))
	return;

	printk(BIOS_DEBUG, "Preloading %s\n", CONFIG_FSP_M_CBFS);
	cbfs_preload(CONFIG_FSP_M_CBFS);
	}

	void fsp_memory_init(bool s3wake)
	{
	struct range_entry prog_ranges[2];
	struct fspm_context context;
	struct fsp_load_descriptor fspld = {
	.fsp_prog = PROG_INIT(PROG_REFCODE, CONFIG_FSP_M_CBFS),
	.arg = &context,
	};
	struct fsp_header *hdr = &context.header;
	struct memranges *memmap = &context.memmap;

	/* For FSP-M XIP we leave alloc NULL to get a direct mapping to flash. */
	if (!CONFIG(FSP_M_XIP))
	fspld.alloc = fspm_allocator;

	elog_boot_notify(s3wake);

	/* Build up memory map of romstage address space including CAR. */
	memranges_init_empty(memmap, &prog_ranges[0], ARRAY_SIZE(prog_ranges));
	if (ENV_CACHE_AS_RAM)
	memranges_insert(memmap, (uintptr_t)_car_region_start,
	_car_unallocated_start - _car_region_start, 0);
	memranges_insert(memmap, (uintptr_t)_program, REGION_SIZE(program), 0);

	timestamp_add_now(TS_FSP_MEMORY_INIT_LOAD);
	if (fsp_load_component(&fspld, hdr) != CB_SUCCESS)
	die("FSPM not available or failed to load!\n");

	if (CONFIG(FSP_M_XIP) && (uintptr_t)prog_start(&fspld.fsp_prog) != hdr->image_base)
	die("FSPM XIP base does not match: %p vs %p\n",
	(void *)(uintptr_t)hdr->image_base, prog_start(&fspld.fsp_prog));

	timestamp_add_now(TS_INITRAM_START);

	do_fsp_memory_init(&context, s3wake);

	timestamp_add_now(TS_INITRAM_END);
	}