cbfstool: Update FIT entries in the second bootblock
Once a second bootblock has been added using topswap (-j) option, Update the entries in second FIT using -j option with update-fit command. Additionally add a -q option which allows to insert the address of a FMAP region (which should hold a microcode) as the first entry in the second FIT. BUG=None BRANCH=None TEST= Create ROM images with -j options and update FIT using -q option. example: ./build/util/cbfstool/cbfstool coreboot.tmp create \ -M build/fmap.fmap -r COREBOOT,FW_MAIN_A,FW_MAIN_B,RW_LEGACY build/util/cbfstool/cbfstool coreboot.tmp add \ -f build/cbfs/fallback/bootblock.bin -n bootblock -t \ bootblock -b -49152 -j 0x10000 build/util/cbfstool/cbfstool coreboot.tmp add-master-header -j 0x10000 build/util/cbfstool/cbfstool coreboot.tmp add -f build/cpu_microcode_blob.bin \ -n cpu_microcode_blob.bin -t microcode -r COREBOOT -a 16 build/util/cbfstool/cbfstool coreboot.tmp. update-fit \ -n cpu_microcode_blob.bin -x 4 -j 0x10000 -q FW_MAIN_A Also try the failure scenarion by providing invalid topswap size. Change-Id: I9a417031c279038903cdf1761a791f2da0fe8644 Signed-off-by: Rizwan Qureshi <rizwan.qureshi@intel.com> Reviewed-on: https://review.coreboot.org/26836 Reviewed-by: Subrata Banik <subrata.banik@intel.com> Reviewed-by: Aaron Durbin <adurbin@chromium.org> Reviewed-by: Furquan Shaikh <furquan@google.com> Tested-by: build bot (Jenkins) <no-reply@coreboot.org>
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@ -59,6 +59,7 @@ static struct param {
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const char *source_region;
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const char *bootblock;
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const char *ignore_section;
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const char *ucode_region;
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uint64_t u64val;
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uint32_t type;
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uint32_t baseaddress;
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@ -1209,8 +1210,25 @@ static int cbfs_update_fit(void)
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param.headeroffset))
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return 1;
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uint32_t addr = 0;
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/*
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* get the address of provided region for first row.
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*/
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if (param.ucode_region) {
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struct buffer ucode;
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if (partitioned_file_read_region(&ucode,
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param.image_file, param.ucode_region))
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addr = -convert_to_from_top_aligned(&ucode, 0);
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else
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return 1;
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}
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if (fit_update_table(&bootblock, &image, param.name,
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param.fit_empty_entries, convert_to_from_top_aligned))
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param.fit_empty_entries, convert_to_from_top_aligned,
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param.topswap_size, addr))
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return 1;
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// The region to be written depends on the type of image, so we write it
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@ -1300,7 +1318,7 @@ static const struct command commands[] = {
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{"print", "H:r:vkh?", cbfs_print, true, false},
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{"read", "r:f:vh?", cbfs_read, true, false},
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{"remove", "H:r:n:vh?", cbfs_remove, true, true},
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{"update-fit", "H:r:n:x:vh?", cbfs_update_fit, true, true},
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{"update-fit", "H:r:n:x:vh?j:q:", cbfs_update_fit, true, true},
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{"write", "r:f:i:Fudvh?", cbfs_write, true, true},
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{"expand", "r:h?", cbfs_expand, true, true},
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{"truncate", "r:h?", cbfs_truncate, true, true},
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@ -1334,6 +1352,7 @@ static struct option long_options[] = {
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{"offset", required_argument, 0, 'o' },
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{"padding", required_argument, 0, 'p' },
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{"page-size", required_argument, 0, 'P' },
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{"ucode-region", required_argument, 0, 'q' },
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{"size", required_argument, 0, 's' },
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{"top-aligned", required_argument, 0, 'T' },
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{"type", required_argument, 0, 't' },
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@ -1464,8 +1483,13 @@ static void usage(char *name)
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" expand [-r fmap-region] "
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"Expand CBFS to span entire region\n"
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" update-fit [-r image,regions] -n MICROCODE_BLOB_NAME \\\n"
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" -x EMTPY_FIT_ENTRIES "
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"Updates the FIT table with microcode entries\n"
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" -x EMTPY_FIT_ENTRIES \\ \n"
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" [-j topswap-size [-q ucode-region](Intel CPUs only)] "
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"Updates the FIT table with microcode entries.\n"
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" "
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" ucode-region is a region in the FMAP, its address is \n"
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" "
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" inserted as the first entry in the topswap FIT. \n"
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"\n"
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"OFFSETs:\n"
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" Numbers accompanying -b, -H, and -o switches* may be provided\n"
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@ -1718,6 +1742,9 @@ int main(int argc, char **argv)
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if (!is_valid_topswap())
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return 1;
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break;
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case 'q':
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param.ucode_region = optarg;
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break;
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case 'v':
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verbose++;
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break;
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@ -115,6 +115,26 @@ static inline uint32_t offset_to_ptr(fit_offset_converter_t helper,
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return -helper(region, offset);
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}
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static int fit_table_verified(struct fit_table *table)
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{
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/* Check that the address field has the proper signature. */
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if (strncmp((const char *)&table->header.address, FIT_HEADER_ADDRESS,
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sizeof(table->header.address)))
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return 0;
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if (table->header.version != FIT_HEADER_VERSION)
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return 0;
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if (fit_entry_type(&table->header) != FIT_TYPE_HEADER)
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return 0;
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/* Assume that the FIT table only contains the header */
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if (fit_entry_size_bytes(&table->header) != sizeof(struct fit_entry))
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return 0;
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return 1;
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}
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static struct fit_table *locate_fit_table(fit_offset_converter_t offset_helper,
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struct buffer *buffer)
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{
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@ -131,23 +151,10 @@ static struct fit_table *locate_fit_table(fit_offset_converter_t offset_helper,
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table = rom_buffer_pointer(buffer,
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ptr_to_offset(offset_helper, buffer, *fit_pointer));
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/* Check that the address field has the proper signature. */
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if (strncmp((const char *)&table->header.address, FIT_HEADER_ADDRESS,
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sizeof(table->header.address)))
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if (!fit_table_verified(table))
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return NULL;
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if (table->header.version != FIT_HEADER_VERSION)
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return NULL;
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if (fit_entry_type(&table->header) != FIT_TYPE_HEADER)
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return NULL;
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/* Assume that the FIT table only contains the header */
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if (fit_entry_size_bytes(&table->header) != sizeof(struct fit_entry))
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return NULL;
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return table;
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else
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return table;
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}
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static void update_fit_checksum(struct fit_table *fit)
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@ -166,24 +173,46 @@ static void update_fit_checksum(struct fit_table *fit)
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fit->header.checksum = -result;
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}
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static void update_fit_ucode_entry(struct fit_table *fit,
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struct fit_entry *entry, uint64_t mcu_addr)
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{
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entry->address = mcu_addr;
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/*
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* While loading MCU, its size is not referred from FIT and
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* rather from the MCU header, hence we can assign zero here
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*/
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entry->size_reserved = 0x0000;
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/* Checksum valid should be cleared for MCU */
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entry->type_checksum_valid = 0;
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entry->version = FIT_MICROCODE_VERSION;
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entry->checksum = 0;
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fit_entry_add_size(&fit->header, sizeof(struct fit_entry));
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}
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static void add_microcodde_entries(struct fit_table *fit,
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const struct cbfs_image *image,
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int num_mcus, struct microcode_entry *mcus,
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fit_offset_converter_t offset_helper)
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fit_offset_converter_t offset_helper,
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uint32_t first_mcu_addr)
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{
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int i;
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int i = 0;
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/*
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* Check if an entry has to be forced into the FIT at index 0.
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* first_mcu_addr is an address (in ROM) that will point to a
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* microcode patch.
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*/
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if (first_mcu_addr) {
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struct fit_entry *entry = &fit->entries[0];
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update_fit_ucode_entry(fit, entry, first_mcu_addr);
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i = 1;
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}
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for (i = 0; i < num_mcus; i++) {
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struct microcode_entry *mcu = &mcus[0];
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for (; i < num_mcus; i++) {
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struct fit_entry *entry = &fit->entries[i];
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struct microcode_entry *mcu = &mcus[i];
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entry->address = offset_to_ptr(offset_helper, &image->buffer,
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mcu->offset);
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fit_entry_update_size(entry, mcu->size);
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entry->version = FIT_MICROCODE_VERSION;
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entry->type_checksum_valid = FIT_TYPE_MICROCODE;
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entry->checksum = 0;
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fit_entry_add_size(&fit->header, sizeof(struct fit_entry));
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update_fit_ucode_entry(fit, entry, offset_to_ptr(offset_helper,
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&image->buffer, mcu->offset));
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mcu++;
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}
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}
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@ -209,8 +238,9 @@ static int fit_header(void *ptr, uint32_t *current_offset, uint32_t *file_length
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}
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static int parse_microcode_blob(struct cbfs_image *image,
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struct cbfs_file *mcode_file,
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struct microcode_entry *mcus, int *total_mcus)
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struct cbfs_file *mcode_file,
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struct microcode_entry *mcus,
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int total_entries, int *mcus_found)
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{
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int num_mcus;
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uint32_t current_offset;
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@ -245,25 +275,28 @@ static int parse_microcode_blob(struct cbfs_image *image,
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num_mcus++;
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/* Reached limit of FIT entries. */
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if (num_mcus == *total_mcus)
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if (num_mcus == total_entries)
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break;
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if (file_length < sizeof(struct microcode_header))
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break;
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}
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/* Update how many microcode updates we found. */
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*total_mcus = num_mcus;
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*mcus_found = num_mcus;
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return 0;
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}
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int fit_update_table(struct buffer *bootblock, struct cbfs_image *image,
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const char *microcode_blob_name, int empty_entries,
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fit_offset_converter_t offset_fn)
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fit_offset_converter_t offset_fn, uint32_t topswap_size,
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uint32_t first_mcu_addr)
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{
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struct fit_table *fit;
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struct fit_table *fit, *fit2;
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struct cbfs_file *mcode_file;
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struct microcode_entry *mcus;
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int mcus_found;
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int ret = 0;
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// struct rom_image image = { .rom = rom, .size = romsize, };
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return 1;
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}
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if (parse_microcode_blob(image, mcode_file, mcus, &empty_entries)) {
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if (parse_microcode_blob(image, mcode_file, mcus, empty_entries,
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&mcus_found)) {
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ERROR("Couldn't parse microcode blob.\n");
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ret = 1;
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goto out;
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}
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add_microcodde_entries(fit, image, empty_entries, mcus, offset_fn);
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add_microcodde_entries(fit, image, mcus_found, mcus, offset_fn, 0);
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update_fit_checksum(fit);
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/* A second fit is exactly topswap size away from the bottom one */
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if (topswap_size) {
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fit2 = (struct fit_table *)((uintptr_t)fit - topswap_size);
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if (!fit_table_verified(fit2)) {
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ERROR("second FIT is invalid\n");
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ret = 1;
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goto out;
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}
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/* Check if we have room for first entry */
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if (first_mcu_addr) {
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if (mcus_found >= empty_entries) {
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ERROR("No room, blob mcus = %d, total entries = %d\n",
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mcus_found, empty_entries);
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ret = 1;
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goto out;
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}
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/* Add 1 for the first entry */
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mcus_found++;
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}
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/* Add entries in the second FIT */
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add_microcodde_entries(fit2, image, mcus_found, mcus,
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offset_fn, first_mcu_addr);
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update_fit_checksum(fit2);
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}
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out:
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free(mcus);
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return ret;
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@ -28,7 +28,15 @@
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typedef unsigned (*fit_offset_converter_t)(const struct buffer *region,
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unsigned offset);
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/*
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* populate FIT with the MCUs prepsent in the blob provided.
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*
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* first_mcu_addr is an address (in ROM) that will point to a
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* microcode patch. When provided, it will be forced as the first
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* MCU entry into the FIT located in the topswap bootblock.
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*/
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int fit_update_table(struct buffer *bootblock, struct cbfs_image *image,
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const char *microcode_blob_name, int empty_entries,
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fit_offset_converter_t offset_fn);
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const char *microcode_blob_name, int empty_entries,
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fit_offset_converter_t offset_fn,
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uint32_t topswap_size, uint32_t first_mcu_addr);
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#endif
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