src/fw/coreboot.c - pub/scm/virt/kvm/mst/seabios - Git at Google

 // Coreboot interface support.
 //
 // Copyright (C) 2008,2009  Kevin O'Connor <kevin@koconnor.net>
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "block.h" // MAXDESCSIZE
 #include "byteorder.h" // be32_to_cpu
 #include "config.h" // CONFIG_*
 #include "hw/pci.h" // pci_probe_devices
 #include "lzmadecode.h" // LzmaDecode
 #include "malloc.h" // free
 #include "memmap.h" // add_e820
 #include "output.h" // dprintf
 #include "paravirt.h" // PlatformRunningOn
 #include "romfile.h" // romfile_findprefix
 #include "stacks.h" // yield
 #include "string.h" // memset
 #include "util.h" // coreboot_preinit


 /****************************************************************
  * Memory map
  ****************************************************************/

 struct cb_header {
     u32 signature;
     u32 header_bytes;
     u32 header_checksum;
     u32 table_bytes;
     u32 table_checksum;
     u32 table_entries;
 };

 #define CB_SIGNATURE 0x4f49424C // "LBIO"

 struct cb_memory_range {
     u64 start;
     u64 size;
     u32 type;
 };

 #define CB_MEM_TABLE    16

 struct cb_memory {
     u32 tag;
     u32 size;
     struct cb_memory_range map[0];
 };

 #define CB_TAG_MEMORY 0x01

 #define MEM_RANGE_COUNT(_rec) \
         (((_rec)->size - sizeof(*(_rec))) / sizeof((_rec)->map[0]))

 struct cb_mainboard {
     u32 tag;
     u32 size;
     u8  vendor_idx;
     u8  part_idx;
     char  strings[0];
 };

 #define CB_TAG_MAINBOARD 0x0003

 struct cb_forward {
     u32 tag;
     u32 size;
     u64 forward;
 };

 #define CB_TAG_FORWARD 0x11

 struct cb_cbmem_ref {
     u32 tag;
     u32 size;
     u64 cbmem_addr;
 };

 #define CB_TAG_CBMEM_CONSOLE 0x17

 struct cbmem_console {
 	u32 buffer_size;
 	u32 buffer_cursor;
 	u8  buffer_body[0];
 } PACKED;
 static struct cbmem_console *cbcon = NULL;

 static u16
 ipchksum(char *buf, int count)
 {
     u16 *p = (u16*)buf;
     u32 sum = 0;
     while (count > 1) {
         sum += *p++;
         count -= 2;
     }
     if (count)
         sum += *(u8*)p;
     sum = (sum >> 16) + (sum & 0xffff);
     sum += (sum >> 16);
     return ~sum;
 }

 // Try to locate the coreboot header in a given address range.
 static struct cb_header *
 find_cb_header(char *addr, int len)
 {
     char *end = addr + len;
     for (; addr < end; addr += 16) {
         struct cb_header *cbh = (struct cb_header *)addr;
         if (cbh->signature != CB_SIGNATURE)
             continue;
         if (! cbh->table_bytes)
             continue;
         if (ipchksum(addr, sizeof(*cbh)) != 0)
             continue;
         if (ipchksum(addr + sizeof(*cbh), cbh->table_bytes)
             != cbh->table_checksum)
             continue;
         return cbh;
     }
     return NULL;
 }

 // Try to find the coreboot memory table in the given coreboot table.
 static void *
 find_cb_subtable(struct cb_header *cbh, u32 tag)
 {
     char *tbl = (char *)cbh + sizeof(*cbh);
     int i;
     for (i=0; i<cbh->table_entries; i++) {
         struct cb_memory *cbm = (struct cb_memory *)tbl;
         tbl += cbm->size;
         if (cbm->tag == tag)
             return cbm;
     }
     return NULL;
 }

 static struct cb_memory *CBMemTable;
 const char *CBvendor = "", *CBpart = "";

 // Populate max ram and e820 map info by scanning for a coreboot table.
 void
 coreboot_preinit(void)
 {
     if (!CONFIG_COREBOOT)
         return;

     dprintf(3, "Attempting to find coreboot table\n");

     // Find coreboot table.
     struct cb_header *cbh = find_cb_header(0, 0x1000);
     if (!cbh)
         goto fail;
     struct cb_forward *cbf = find_cb_subtable(cbh, CB_TAG_FORWARD);
     if (cbf) {
         dprintf(3, "Found coreboot table forwarder.\n");
         cbh = find_cb_header((char *)((u32)cbf->forward), 0x100);
         if (!cbh)
             goto fail;
     }
     dprintf(3, "Now attempting to find coreboot memory map\n");
     struct cb_memory *cbm = CBMemTable = find_cb_subtable(cbh, CB_TAG_MEMORY);
     if (!cbm)
         goto fail;

     int i, count = MEM_RANGE_COUNT(cbm);
     for (i=0; i<count; i++) {
         struct cb_memory_range *m = &cbm->map[i];
         u32 type = m->type;
         if (type == CB_MEM_TABLE)
             type = E820_RESERVED;
         add_e820(m->start, m->size, type);
     }

     // Ughh - coreboot likes to set a map at 0x0000-0x1000, but this
     // confuses grub.  So, override it.
     add_e820(0, 16*1024, E820_RAM);

     struct cb_cbmem_ref *cbref = find_cb_subtable(cbh, CB_TAG_CBMEM_CONSOLE);
     if (cbref) {
         cbcon = (void*)(u32)cbref->cbmem_addr;
         dprintf(1, "----- [ seabios log starts here ] -----\n");
         dprintf(1, "Found coreboot cbmem console @ %llx\n", cbref->cbmem_addr);
     }

     struct cb_mainboard *cbmb = find_cb_subtable(cbh, CB_TAG_MAINBOARD);
     if (cbmb) {
         CBvendor = &cbmb->strings[cbmb->vendor_idx];
         CBpart = &cbmb->strings[cbmb->part_idx];
         dprintf(1, "Found mainboard %s %s\n", CBvendor, CBpart);
     }

     return;

 fail:
     // No table found..  Use 16Megs as a dummy value.
     dprintf(1, "Unable to find coreboot table!\n");
     add_e820(0, 16*1024*1024, E820_RAM);
     return;
 }

 void debug_cbmem(char c)
 {
     if (!CONFIG_DEBUG_COREBOOT)
         return;
     if (!cbcon)
         return;
     if (cbcon->buffer_cursor == cbcon->buffer_size)
         return;
     cbcon->buffer_body[cbcon->buffer_cursor++] = c;
 }

 /****************************************************************
  * BIOS table copying
  ****************************************************************/

 // Attempt to find (and relocate) any standard bios tables found in a
 // given address range.
 static void
 scan_tables(u32 start, u32 size)
 {
     void *p = (void*)ALIGN(start, 16);
     void *end = (void*)start + size;
     for (; p<end; p += 16)
         copy_table(p);
 }

 void
 coreboot_platform_setup(void)
 {
     if (!CONFIG_COREBOOT)
         return;
     pci_probe_devices();

     struct cb_memory *cbm = CBMemTable;
     if (!cbm)
         return;

     dprintf(3, "Relocating coreboot bios tables\n");

     // Scan CB_MEM_TABLE areas for bios tables.
     int i, count = MEM_RANGE_COUNT(cbm);
     for (i=0; i<count; i++) {
         struct cb_memory_range *m = &cbm->map[i];
         if (m->type == CB_MEM_TABLE)
             scan_tables(m->start, m->size);
     }

     find_acpi_features();
 }


 /****************************************************************
  * ulzma
  ****************************************************************/

 // Uncompress data in flash to an area of memory.
 static int
 ulzma(u8 *dst, u32 maxlen, const u8 *src, u32 srclen)
 {
     dprintf(3, "Uncompressing data %d@%p to %d@%p\n", srclen, src, maxlen, dst);
     CLzmaDecoderState state;
     int ret = LzmaDecodeProperties(&state.Properties, src, LZMA_PROPERTIES_SIZE);
     if (ret != LZMA_RESULT_OK) {
         dprintf(1, "LzmaDecodeProperties error - %d\n", ret);
         return -1;
     }
     u8 scratch[15980];
     int need = (LzmaGetNumProbs(&state.Properties) * sizeof(CProb));
     if (need > sizeof(scratch)) {
         dprintf(1, "LzmaDecode need %d have %d\n", need, (unsigned int)sizeof(scratch));
         return -1;
     }
     state.Probs = (CProb *)scratch;

     u32 dstlen = *(u32*)(src + LZMA_PROPERTIES_SIZE);
     if (dstlen > maxlen) {
         dprintf(1, "LzmaDecode too large (max %d need %d)\n", maxlen, dstlen);
         return -1;
     }
     u32 inProcessed, outProcessed;
     ret = LzmaDecode(&state, src + LZMA_PROPERTIES_SIZE + 8, srclen
                      , &inProcessed, dst, dstlen, &outProcessed);
     if (ret) {
         dprintf(1, "LzmaDecode returned %d\n", ret);
         return -1;
     }
     return dstlen;
 }


 /****************************************************************
  * Coreboot flash format
  ****************************************************************/

 #define CBFS_HEADER_MAGIC 0x4F524243
 #define CBFS_HEADPTR_ADDR 0xFFFFFFFc
 #define CBFS_VERSION1 0x31313131

 struct cbfs_header {
     u32 magic;
     u32 version;
     u32 romsize;
     u32 bootblocksize;
     u32 align;
     u32 offset;
     u32 pad[2];
 } PACKED;

 #define CBFS_FILE_MAGIC 0x455649484352414cLL // LARCHIVE

 struct cbfs_file {
     u64 magic;
     u32 len;
     u32 type;
     u32 checksum;
     u32 offset;
     char filename[0];
 } PACKED;

 struct cbfs_romfile_s {
     struct romfile_s file;
     struct cbfs_file *fhdr;
     void *data;
     u32 rawsize, flags;
 };

 // Copy a file to memory (uncompressing if necessary)
 static int
 cbfs_copyfile(struct romfile_s *file, void *dst, u32 maxlen)
 {
     if (!CONFIG_COREBOOT_FLASH)
         return -1;

     struct cbfs_romfile_s *cfile;
     cfile = container_of(file, struct cbfs_romfile_s, file);
     u32 size = cfile->rawsize;
     void *src = cfile->data;
     if (cfile->flags) {
         // Compressed - copy to temp ram and uncompress it.
         void *temp = malloc_tmphigh(size);
         if (!temp) {
             warn_noalloc();
             return -1;
         }
         iomemcpy(temp, src, size);
         int ret = ulzma(dst, maxlen, temp, size);
         yield();
         free(temp);
         return ret;
     }

     // Not compressed.
     dprintf(3, "Copying data %d@%p to %d@%p\n", size, src, maxlen, dst);
     if (size > maxlen) {
         warn_noalloc();
         return -1;
     }
     iomemcpy(dst, src, size);
     return size;
 }

 void
 coreboot_cbfs_init(void)
 {
     if (!CONFIG_COREBOOT_FLASH)
         return;

     struct cbfs_header *hdr = *(void **)CBFS_HEADPTR_ADDR;
     if (hdr->magic != cpu_to_be32(CBFS_HEADER_MAGIC)) {
         dprintf(1, "Unable to find CBFS (ptr=%p; got %x not %x)\n"
                 , hdr, hdr->magic, cpu_to_be32(CBFS_HEADER_MAGIC));
         return;
     }
     dprintf(1, "Found CBFS header at %p\n", hdr);

     struct cbfs_file *fhdr = (void *)(0 - be32_to_cpu(hdr->romsize)
                                       + be32_to_cpu(hdr->offset));
     for (;;) {
         if (fhdr < (struct cbfs_file *)(0xFFFFFFFF - be32_to_cpu(hdr->romsize)))
             break;
         u64 magic = fhdr->magic;
         if (magic != CBFS_FILE_MAGIC)
             break;
         struct cbfs_romfile_s *cfile = malloc_tmp(sizeof(*cfile));
         if (!cfile) {
             warn_noalloc();
             break;
         }
         memset(cfile, 0, sizeof(*cfile));
         strtcpy(cfile->file.name, fhdr->filename, sizeof(cfile->file.name));
         cfile->file.size = cfile->rawsize = be32_to_cpu(fhdr->len);
         cfile->fhdr = fhdr;
         cfile->file.copy = cbfs_copyfile;
         cfile->data = (void*)fhdr + be32_to_cpu(fhdr->offset);
         int len = strlen(cfile->file.name);
         if (len > 5 && strcmp(&cfile->file.name[len-5], ".lzma") == 0) {
             // Using compression.
             cfile->flags = 1;
             cfile->file.name[len-5] = '\0';
             cfile->file.size = *(u32*)(cfile->data + LZMA_PROPERTIES_SIZE);
         }
         romfile_add(&cfile->file);

         fhdr = (void*)ALIGN((u32)cfile->data + cfile->rawsize
                             , be32_to_cpu(hdr->align));
     }
 }

 struct cbfs_payload_segment {
     u32 type;
     u32 compression;
     u32 offset;
     u64 load_addr;
     u32 len;
     u32 mem_len;
 } PACKED;

 #define PAYLOAD_SEGMENT_BSS    0x20535342
 #define PAYLOAD_SEGMENT_ENTRY  0x52544E45

 #define CBFS_COMPRESS_NONE  0
 #define CBFS_COMPRESS_LZMA  1

 struct cbfs_payload {
     struct cbfs_payload_segment segments[1];
 };

 void
 cbfs_run_payload(struct cbfs_file *fhdr)
 {
     if (!CONFIG_COREBOOT_FLASH || !fhdr)
         return;
     dprintf(1, "Run %s\n", fhdr->filename);
     struct cbfs_payload *pay = (void*)fhdr + be32_to_cpu(fhdr->offset);
     struct cbfs_payload_segment *seg = pay->segments;
     for (;;) {
         void *src = (void*)pay + be32_to_cpu(seg->offset);
         void *dest = (void*)(u32)be64_to_cpu(seg->load_addr);
         u32 src_len = be32_to_cpu(seg->len);
         u32 dest_len = be32_to_cpu(seg->mem_len);
         switch (seg->type) {
         case PAYLOAD_SEGMENT_BSS:
             dprintf(3, "BSS segment %d@%p\n", dest_len, dest);
             memset(dest, 0, dest_len);
             break;
         case PAYLOAD_SEGMENT_ENTRY: {
             dprintf(1, "Calling addr %p\n", dest);
             void (*func)() = dest;
             func();
             return;
         }
         default:
             dprintf(3, "Segment %x %d@%p -> %d@%p\n"
                     , seg->type, src_len, src, dest_len, dest);
             if (seg->compression == cpu_to_be32(CBFS_COMPRESS_NONE)) {
                 if (src_len > dest_len)
                     src_len = dest_len;
                 memcpy(dest, src, src_len);
             } else if (CONFIG_LZMA
                        && seg->compression == cpu_to_be32(CBFS_COMPRESS_LZMA)) {
                 int ret = ulzma(dest, dest_len, src, src_len);
                 if (ret < 0)
                     return;
                 src_len = ret;
             } else {
                 dprintf(1, "No support for compression type %x\n"
                         , seg->compression);
                 return;
             }
             if (dest_len > src_len)
                 memset(dest + src_len, 0, dest_len - src_len);
             break;
         }
         seg++;
     }
 }

 // Register payloads in "img/" directory with boot system.
 void
 cbfs_payload_setup(void)
 {
     if (!CONFIG_COREBOOT_FLASH)
         return;
     struct romfile_s *file = NULL;
     for (;;) {
         file = romfile_findprefix("img/", file);
         if (!file)
             break;
         struct cbfs_romfile_s *cfile;
         cfile = container_of(file, struct cbfs_romfile_s, file);
         const char *filename = file->name;
         char *desc = znprintf(MAXDESCSIZE, "Payload [%s]", &filename[4]);
         boot_add_cbfs(cfile->fhdr, desc, bootprio_find_named_rom(filename, 0));
     }
 }
	// Coreboot interface support.
	//
	// Copyright (C) 2008,2009 Kevin O'Connor <kevin@koconnor.net>
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "block.h" // MAXDESCSIZE
	#include "byteorder.h" // be32_to_cpu
	#include "config.h" // CONFIG_*
	#include "hw/pci.h" // pci_probe_devices
	#include "lzmadecode.h" // LzmaDecode
	#include "malloc.h" // free
	#include "memmap.h" // add_e820
	#include "output.h" // dprintf
	#include "paravirt.h" // PlatformRunningOn
	#include "romfile.h" // romfile_findprefix
	#include "stacks.h" // yield
	#include "string.h" // memset
	#include "util.h" // coreboot_preinit


	/****************************************************************
	* Memory map
	****************************************************************/

	struct cb_header {
	u32 signature;
	u32 header_bytes;
	u32 header_checksum;
	u32 table_bytes;
	u32 table_checksum;
	u32 table_entries;
	};

	#define CB_SIGNATURE 0x4f49424C // "LBIO"

	struct cb_memory_range {
	u64 start;
	u64 size;
	u32 type;
	};

	#define CB_MEM_TABLE 16

	struct cb_memory {
	u32 tag;
	u32 size;
	struct cb_memory_range map[0];
	};

	#define CB_TAG_MEMORY 0x01

	#define MEM_RANGE_COUNT(_rec) \
	(((_rec)->size - sizeof(*(_rec))) / sizeof((_rec)->map[0]))

	struct cb_mainboard {
	u32 tag;
	u32 size;
	u8 vendor_idx;
	u8 part_idx;
	char strings[0];
	};

	#define CB_TAG_MAINBOARD 0x0003

	struct cb_forward {
	u32 tag;
	u32 size;
	u64 forward;
	};

	#define CB_TAG_FORWARD 0x11

	struct cb_cbmem_ref {
	u32 tag;
	u32 size;
	u64 cbmem_addr;
	};

	#define CB_TAG_CBMEM_CONSOLE 0x17

	struct cbmem_console {
	u32 buffer_size;
	u32 buffer_cursor;
	u8 buffer_body[0];
	} PACKED;
	static struct cbmem_console *cbcon = NULL;

	static u16
	ipchksum(char *buf, int count)
	{
	u16 p = (u16)buf;
	u32 sum = 0;
	while (count > 1) {
	sum += *p++;
	count -= 2;
	}
	if (count)
	sum += (u8)p;
	sum = (sum >> 16) + (sum & 0xffff);
	sum += (sum >> 16);
	return ~sum;
	}

	// Try to locate the coreboot header in a given address range.
	static struct cb_header *
	find_cb_header(char *addr, int len)
	{
	char *end = addr + len;
	for (; addr < end; addr += 16) {
	struct cb_header cbh = (struct cb_header )addr;
	if (cbh->signature != CB_SIGNATURE)
	continue;
	if (! cbh->table_bytes)
	continue;
	if (ipchksum(addr, sizeof(*cbh)) != 0)
	continue;
	if (ipchksum(addr + sizeof(*cbh), cbh->table_bytes)
	!= cbh->table_checksum)
	continue;
	return cbh;
	}
	return NULL;
	}

	// Try to find the coreboot memory table in the given coreboot table.
	static void *
	find_cb_subtable(struct cb_header *cbh, u32 tag)
	{
	char tbl = (char )cbh + sizeof(*cbh);
	int i;
	for (i=0; i<cbh->table_entries; i++) {
	struct cb_memory cbm = (struct cb_memory )tbl;
	tbl += cbm->size;
	if (cbm->tag == tag)
	return cbm;
	}
	return NULL;
	}

	static struct cb_memory *CBMemTable;
	const char CBvendor = "", CBpart = "";

	// Populate max ram and e820 map info by scanning for a coreboot table.
	void
	coreboot_preinit(void)
	{
	if (!CONFIG_COREBOOT)
	return;

	dprintf(3, "Attempting to find coreboot table\n");

	// Find coreboot table.
	struct cb_header *cbh = find_cb_header(0, 0x1000);
	if (!cbh)
	goto fail;
	struct cb_forward *cbf = find_cb_subtable(cbh, CB_TAG_FORWARD);
	if (cbf) {
	dprintf(3, "Found coreboot table forwarder.\n");
	cbh = find_cb_header((char *)((u32)cbf->forward), 0x100);
	if (!cbh)
	goto fail;
	}
	dprintf(3, "Now attempting to find coreboot memory map\n");
	struct cb_memory *cbm = CBMemTable = find_cb_subtable(cbh, CB_TAG_MEMORY);
	if (!cbm)
	goto fail;

	int i, count = MEM_RANGE_COUNT(cbm);
	for (i=0; i<count; i++) {
	struct cb_memory_range *m = &cbm->map[i];
	u32 type = m->type;
	if (type == CB_MEM_TABLE)
	type = E820_RESERVED;
	add_e820(m->start, m->size, type);
	}

	// Ughh - coreboot likes to set a map at 0x0000-0x1000, but this
	// confuses grub. So, override it.
	add_e820(0, 16*1024, E820_RAM);

	struct cb_cbmem_ref *cbref = find_cb_subtable(cbh, CB_TAG_CBMEM_CONSOLE);
	if (cbref) {
	cbcon = (void*)(u32)cbref->cbmem_addr;
	dprintf(1, "----- [ seabios log starts here ] -----\n");
	dprintf(1, "Found coreboot cbmem console @ %llx\n", cbref->cbmem_addr);
	}

	struct cb_mainboard *cbmb = find_cb_subtable(cbh, CB_TAG_MAINBOARD);
	if (cbmb) {
	CBvendor = &cbmb->strings[cbmb->vendor_idx];
	CBpart = &cbmb->strings[cbmb->part_idx];
	dprintf(1, "Found mainboard %s %s\n", CBvendor, CBpart);
	}

	return;

	fail:
	// No table found.. Use 16Megs as a dummy value.
	dprintf(1, "Unable to find coreboot table!\n");
	add_e820(0, 1610241024, E820_RAM);
	return;
	}

	void debug_cbmem(char c)
	{
	if (!CONFIG_DEBUG_COREBOOT)
	return;
	if (!cbcon)
	return;
	if (cbcon->buffer_cursor == cbcon->buffer_size)
	return;
	cbcon->buffer_body[cbcon->buffer_cursor++] = c;
	}

	/****************************************************************
	* BIOS table copying
	****************************************************************/

	// Attempt to find (and relocate) any standard bios tables found in a
	// given address range.
	static void
	scan_tables(u32 start, u32 size)
	{
	void p = (void)ALIGN(start, 16);
	void end = (void)start + size;
	for (; p<end; p += 16)
	copy_table(p);
	}

	void
	coreboot_platform_setup(void)
	{
	if (!CONFIG_COREBOOT)
	return;
	pci_probe_devices();

	struct cb_memory *cbm = CBMemTable;
	if (!cbm)
	return;

	dprintf(3, "Relocating coreboot bios tables\n");

	// Scan CB_MEM_TABLE areas for bios tables.
	int i, count = MEM_RANGE_COUNT(cbm);
	for (i=0; i<count; i++) {
	struct cb_memory_range *m = &cbm->map[i];
	if (m->type == CB_MEM_TABLE)
	scan_tables(m->start, m->size);
	}

	find_acpi_features();
	}


	/****************************************************************
	* ulzma
	****************************************************************/

	// Uncompress data in flash to an area of memory.
	static int
	ulzma(u8 dst, u32 maxlen, const u8 src, u32 srclen)
	{
	dprintf(3, "Uncompressing data %d@%p to %d@%p\n", srclen, src, maxlen, dst);
	CLzmaDecoderState state;
	int ret = LzmaDecodeProperties(&state.Properties, src, LZMA_PROPERTIES_SIZE);
	if (ret != LZMA_RESULT_OK) {
	dprintf(1, "LzmaDecodeProperties error - %d\n", ret);
	return -1;
	}
	u8 scratch[15980];
	int need = (LzmaGetNumProbs(&state.Properties) * sizeof(CProb));
	if (need > sizeof(scratch)) {
	dprintf(1, "LzmaDecode need %d have %d\n", need, (unsigned int)sizeof(scratch));
	return -1;
	}
	state.Probs = (CProb *)scratch;

	u32 dstlen = (u32)(src + LZMA_PROPERTIES_SIZE);
	if (dstlen > maxlen) {
	dprintf(1, "LzmaDecode too large (max %d need %d)\n", maxlen, dstlen);
	return -1;
	}
	u32 inProcessed, outProcessed;
	ret = LzmaDecode(&state, src + LZMA_PROPERTIES_SIZE + 8, srclen
	, &inProcessed, dst, dstlen, &outProcessed);
	if (ret) {
	dprintf(1, "LzmaDecode returned %d\n", ret);
	return -1;
	}
	return dstlen;
	}


	/****************************************************************
	* Coreboot flash format
	****************************************************************/

	#define CBFS_HEADER_MAGIC 0x4F524243
	#define CBFS_HEADPTR_ADDR 0xFFFFFFFc
	#define CBFS_VERSION1 0x31313131

	struct cbfs_header {
	u32 magic;
	u32 version;
	u32 romsize;
	u32 bootblocksize;
	u32 align;
	u32 offset;
	u32 pad[2];
	} PACKED;

	#define CBFS_FILE_MAGIC 0x455649484352414cLL // LARCHIVE

	struct cbfs_file {
	u64 magic;
	u32 len;
	u32 type;
	u32 checksum;
	u32 offset;
	char filename[0];
	} PACKED;

	struct cbfs_romfile_s {
	struct romfile_s file;
	struct cbfs_file *fhdr;
	void *data;
	u32 rawsize, flags;
	};

	// Copy a file to memory (uncompressing if necessary)
	static int
	cbfs_copyfile(struct romfile_s file, void dst, u32 maxlen)
	{
	if (!CONFIG_COREBOOT_FLASH)
	return -1;

	struct cbfs_romfile_s *cfile;
	cfile = container_of(file, struct cbfs_romfile_s, file);
	u32 size = cfile->rawsize;
	void *src = cfile->data;
	if (cfile->flags) {
	// Compressed - copy to temp ram and uncompress it.
	void *temp = malloc_tmphigh(size);
	if (!temp) {
	warn_noalloc();
	return -1;
	}
	iomemcpy(temp, src, size);
	int ret = ulzma(dst, maxlen, temp, size);
	yield();
	free(temp);
	return ret;
	}

	// Not compressed.
	dprintf(3, "Copying data %d@%p to %d@%p\n", size, src, maxlen, dst);
	if (size > maxlen) {
	warn_noalloc();
	return -1;
	}
	iomemcpy(dst, src, size);
	return size;
	}

	void
	coreboot_cbfs_init(void)
	{
	if (!CONFIG_COREBOOT_FLASH)
	return;

	struct cbfs_header hdr = (void **)CBFS_HEADPTR_ADDR;
	if (hdr->magic != cpu_to_be32(CBFS_HEADER_MAGIC)) {
	dprintf(1, "Unable to find CBFS (ptr=%p; got %x not %x)\n"
	, hdr, hdr->magic, cpu_to_be32(CBFS_HEADER_MAGIC));
	return;
	}
	dprintf(1, "Found CBFS header at %p\n", hdr);

	struct cbfs_file fhdr = (void )(0 - be32_to_cpu(hdr->romsize)
	+ be32_to_cpu(hdr->offset));
	for (;;) {
	if (fhdr < (struct cbfs_file *)(0xFFFFFFFF - be32_to_cpu(hdr->romsize)))
	break;
	u64 magic = fhdr->magic;
	if (magic != CBFS_FILE_MAGIC)
	break;
	struct cbfs_romfile_s cfile = malloc_tmp(sizeof(cfile));
	if (!cfile) {
	warn_noalloc();
	break;
	}
	memset(cfile, 0, sizeof(*cfile));
	strtcpy(cfile->file.name, fhdr->filename, sizeof(cfile->file.name));
	cfile->file.size = cfile->rawsize = be32_to_cpu(fhdr->len);
	cfile->fhdr = fhdr;
	cfile->file.copy = cbfs_copyfile;
	cfile->data = (void*)fhdr + be32_to_cpu(fhdr->offset);
	int len = strlen(cfile->file.name);
	if (len > 5 && strcmp(&cfile->file.name[len-5], ".lzma") == 0) {
	// Using compression.
	cfile->flags = 1;
	cfile->file.name[len-5] = '\0';
	cfile->file.size = (u32)(cfile->data + LZMA_PROPERTIES_SIZE);
	}
	romfile_add(&cfile->file);

	fhdr = (void*)ALIGN((u32)cfile->data + cfile->rawsize
	, be32_to_cpu(hdr->align));
	}
	}

	struct cbfs_payload_segment {
	u32 type;
	u32 compression;
	u32 offset;
	u64 load_addr;
	u32 len;
	u32 mem_len;
	} PACKED;

	#define PAYLOAD_SEGMENT_BSS 0x20535342
	#define PAYLOAD_SEGMENT_ENTRY 0x52544E45

	#define CBFS_COMPRESS_NONE 0
	#define CBFS_COMPRESS_LZMA 1

	struct cbfs_payload {
	struct cbfs_payload_segment segments[1];
	};

	void
	cbfs_run_payload(struct cbfs_file *fhdr)
	{
	if (!CONFIG_COREBOOT_FLASH \|\| !fhdr)
	return;
	dprintf(1, "Run %s\n", fhdr->filename);
	struct cbfs_payload pay = (void)fhdr + be32_to_cpu(fhdr->offset);
	struct cbfs_payload_segment *seg = pay->segments;
	for (;;) {
	void src = (void)pay + be32_to_cpu(seg->offset);
	void dest = (void)(u32)be64_to_cpu(seg->load_addr);
	u32 src_len = be32_to_cpu(seg->len);
	u32 dest_len = be32_to_cpu(seg->mem_len);
	switch (seg->type) {
	case PAYLOAD_SEGMENT_BSS:
	dprintf(3, "BSS segment %d@%p\n", dest_len, dest);
	memset(dest, 0, dest_len);
	break;
	case PAYLOAD_SEGMENT_ENTRY: {
	dprintf(1, "Calling addr %p\n", dest);
	void (*func)() = dest;
	func();
	return;
	}
	default:
	dprintf(3, "Segment %x %d@%p -> %d@%p\n"
	, seg->type, src_len, src, dest_len, dest);
	if (seg->compression == cpu_to_be32(CBFS_COMPRESS_NONE)) {
	if (src_len > dest_len)
	src_len = dest_len;
	memcpy(dest, src, src_len);
	} else if (CONFIG_LZMA
	&& seg->compression == cpu_to_be32(CBFS_COMPRESS_LZMA)) {
	int ret = ulzma(dest, dest_len, src, src_len);
	if (ret < 0)
	return;
	src_len = ret;
	} else {
	dprintf(1, "No support for compression type %x\n"
	, seg->compression);
	return;
	}
	if (dest_len > src_len)
	memset(dest + src_len, 0, dest_len - src_len);
	break;
	}
	seg++;
	}
	}

	// Register payloads in "img/" directory with boot system.
	void
	cbfs_payload_setup(void)
	{
	if (!CONFIG_COREBOOT_FLASH)
	return;
	struct romfile_s *file = NULL;
	for (;;) {
	file = romfile_findprefix("img/", file);
	if (!file)
	break;
	struct cbfs_romfile_s *cfile;
	cfile = container_of(file, struct cbfs_romfile_s, file);
	const char *filename = file->name;
	char *desc = znprintf(MAXDESCSIZE, "Payload [%s]", &filename[4]);
	boot_add_cbfs(cfile->fhdr, desc, bootprio_find_named_rom(filename, 0));
	}
	}