/* SPDX-License-Identifier: GPL-2.0-only */ /* * ROMSIG At ROMBASE + 0x[0,2,4,8]20000: * 0 4 8 C * +------------+---------------+----------------+------------+ * | 0x55AA55AA |EC ROM Address |GEC ROM Address |USB3 ROM | * +------------+---------------+----------------+------------+ * | PSPDIR ADDR|PSPDIR ADDR(C) | BDT ADDR 0 | BDT ADDR 1 | * +------------+---------------+----------------+------------+ * | BDT ADDR 2 | | BDT ADDR 3(C) | | * +------------+---------------+----------------+------------+ * (C): Could be a combo header * * EC ROM should be 64K aligned. * * PSP directory (Where "PSPDIR ADDR" points) * +------------+---------------+----------------+------------+ * | 'PSP$' | Fletcher | Count | Reserved | * +------------+---------------+----------------+------------+ * | 0 | size | Base address | Reserved | Pubkey * +------------+---------------+----------------+------------+ * | 1 | size | Base address | Reserved | Bootloader * +------------+---------------+----------------+------------+ * | 8 | size | Base address | Reserved | Smu Firmware * +------------+---------------+----------------+------------+ * | 3 | size | Base address | Reserved | Recovery Firmware * +------------+---------------+----------------+------------+ * | | * | | * | Other PSP Firmware | * | | * +------------+---------------+----------------+------------+ * | 40 | size | Base address | Reserved |---+ * +------------+---------------+----------------+------------+ | * :or 48(A/B A): size : Base address : Reserved : | * + - - + - - + - - + - - + | * : 4A(A/B B): size : Base address : Reserved : | * +------------+---------------+----------------+------------+ | * (A/B A) & (A/B B): Similar as 40, pointing to PSP level 2 | * for A/B recovery | * | * | * +------------+---------------+----------------+------------+ | * | '2LP$' | Fletcher | Count | Reserved |<--+ * +------------+---------------+----------------+------------+ * | | * | | * | PSP Firmware | * | (2nd-level is not required on all families) | * | | * +------------+---------------+----------------+------------+ * BIOS Directory Table (BDT) is similar * * PSP Combo directory * +------------+---------------+----------------+------------+ * | 'PSP2' | Fletcher | Count |Look up mode| * +------------+---------------+----------------+------------+ * | R e s e r v e d | * +------------+---------------+----------------+------------+ * | ID-Sel | PSP ID | PSPDIR ADDR | | 1st PSP directory * +------------+---------------+----------------+------------+ * | ID-Sel | PSP ID | PSPDIR ADDR | | 2nd PSP directory * +------------+---------------+----------------+------------+ * | | * | Other PSP | * | | * +------------+---------------+----------------+------------+ * BDT Combo is similar */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "amdfwtool.h" #define AMD_ROMSIG_OFFSET 0x20000 #define _MAX(A, B) (((A) > (B)) ? (A) : (B)) static void output_manifest(int manifest_fd, amd_fw_entry *fw_entry); /* * Beginning with Family 15h Models 70h-7F, a.k.a Stoney Ridge, the PSP * can support an optional "combo" implementation. If the PSP sees the * PSP2 cookie, it interprets the table as a roadmap to additional PSP * tables. Using this, support for multiple product generations may be * built into one image. If the PSP$ cookie is found, the table is a * normal directory table. * * Modern generations supporting the combo directories require the * pointer to be at offset 0x14 of the Embedded Firmware Structure, * regardless of the type of directory used. The --use-combo * argument enforces this placement. * * TODO: Future work may require fully implementing the PSP_COMBO feature. */ /* * Creates the OSI Fletcher checksum. See 8473-1, Appendix C, section C.3. * The checksum field of the passed PDU does not need to be reset to zero. * * The "Fletcher Checksum" was proposed in a paper by John G. Fletcher of * Lawrence Livermore Labs. The Fletcher Checksum was proposed as an * alternative to cyclical redundancy checks because it provides error- * detection properties similar to cyclical redundancy checks but at the * cost of a simple summation technique. Its characteristics were first * published in IEEE Transactions on Communications in January 1982. One * version has been adopted by ISO for use in the class-4 transport layer * of the network protocol. * * This program expects: * stdin: The input file to compute a checksum for. The input file * not be longer than 256 bytes. * stdout: Copied from the input file with the Fletcher's Checksum * inserted 8 bytes after the beginning of the file. * stderr: Used to print out error messages. */ static uint32_t fletcher32(const void *data, int length) { uint32_t c0; uint32_t c1; uint32_t checksum; int index; const uint16_t *pptr = data; length /= 2; c0 = 0xFFFF; c1 = 0xFFFF; while (length) { index = length >= 359 ? 359 : length; length -= index; do { c0 += *(pptr++); c1 += c0; } while (--index); c0 = (c0 & 0xFFFF) + (c0 >> 16); c1 = (c1 & 0xFFFF) + (c1 >> 16); } /* Sums[0,1] mod 64K + overflow */ c0 = (c0 & 0xFFFF) + (c0 >> 16); c1 = (c1 & 0xFFFF) + (c1 >> 16); checksum = (c1 << 16) | c0; return checksum; } amd_fw_entry amd_psp_fw_table[] = { { .type = AMD_FW_PSP_PUBKEY, .level = PSP_BOTH | PSP_LVL2_AB, .skip_hashing = true }, { .type = AMD_FW_PSP_BOOTLOADER, .level = PSP_BOTH | PSP_LVL2_AB, .generate_manifest = true }, { .type = AMD_FW_PSP_SECURED_OS, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_RECOVERY, .level = PSP_LVL1 }, { .type = AMD_FW_PSP_NVRAM, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_RTM_PUBKEY, .level = PSP_BOTH }, { .type = AMD_FW_PSP_SMU_FIRMWARE, .subprog = 0, .level = PSP_BOTH | PSP_LVL2_AB, .generate_manifest = true }, { .type = AMD_FW_PSP_SMU_FIRMWARE, .subprog = 1, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SMU_FIRMWARE, .subprog = 2, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SECURED_DEBUG, .level = PSP_LVL2 | PSP_LVL2_AB, .skip_hashing = true }, { .type = AMD_FW_ABL_PUBKEY, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_PSP_FUSE_CHAIN, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_TRUSTLETS, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_TRUSTLETKEY, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SMU_FIRMWARE2, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SMU_FIRMWARE2, .subprog = 1, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SMU_FIRMWARE2, .subprog = 2, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_BOOT_DRIVER, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_SOC_DRIVER, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_DEBUG_DRIVER, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_INTERFACE_DRIVER, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_DEBUG_UNLOCK, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_HW_IPCFG, .subprog = 0, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_HW_IPCFG, .subprog = 1, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_WRAPPED_IKEK, .level = PSP_BOTH | PSP_LVL2_AB, .skip_hashing = true }, { .type = AMD_TOKEN_UNLOCK, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_SEC_GASKET, .subprog = 0, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_SEC_GASKET, .subprog = 1, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_SEC_GASKET, .subprog = 2, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_MP2_FW, .subprog = 0, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_MP2_FW, .subprog = 1, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_MP2_FW, .subprog = 2, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_DRIVER_ENTRIES, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_KVM_IMAGE, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_MP5, .subprog = 0, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_FW_MP5, .subprog = 1, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_FW_MP5, .subprog = 2, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_S0I3_DRIVER, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_ABL0, .level = PSP_BOTH | PSP_LVL2_AB, .generate_manifest = true }, { .type = AMD_ABL1, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL2, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL3, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL4, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL5, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL6, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_ABL7, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_SEV_DATA, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_SEV_CODE, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_WHITELIST, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_VBIOS_BTLOADER, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_DXIO, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_FW_USB_PHY, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_TOS_SEC_POLICY, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_DRTM_TA, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_KEYDB_BL, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_KEYDB_TOS, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_VERSTAGE, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_VERSTAGE_SIG, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_RPMC_NVRAM, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_SPL, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_DMCU_ERAM, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_DMCU_ISR, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_MSMU, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_SPIROM_CFG, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_MPIO, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_SMUSCS, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_DMCUB, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_PSP_BOOTLOADER_AB, .level = PSP_LVL2 | PSP_LVL2_AB, .generate_manifest = true }, { .type = AMD_RIB, .subprog = 0, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_RIB, .subprog = 1, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_MPDMA_TF, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_TA_IKEK, .level = PSP_BOTH | PSP_LVL2_AB, .skip_hashing = true }, { .type = AMD_FW_GMI3_PHY, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_FW_MPDMA_PM, .level = PSP_BOTH | PSP_BOTH_AB }, { .type = AMD_FW_AMF_SRAM, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_AMF_DRAM, .inst = 0, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_AMF_DRAM, .inst = 1, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_FCFG_TABLE, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_AMF_WLAN, .inst = 0, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_AMF_WLAN, .inst = 1, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_AMF_MFD, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_TA_IKEK, .level = PSP_BOTH | PSP_LVL2_AB, .skip_hashing = true }, { .type = AMD_FW_MPCCX, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_LSDMA, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_C20_MP, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_MINIMSMU, .inst = 0, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_MINIMSMU, .inst = 1, .level = PSP_BOTH | PSP_LVL2_AB }, { .type = AMD_FW_SRAM_FW_EXT, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_UMSMU, .level = PSP_LVL2 | PSP_LVL2_AB }, { .type = AMD_FW_INVALID }, }; amd_fw_entry amd_fw_table[] = { { .type = AMD_FW_XHCI }, { .type = AMD_FW_IMC }, { .type = AMD_FW_GEC }, { .type = AMD_FW_INVALID }, }; amd_bios_entry amd_bios_table[] = { { .type = AMD_BIOS_RTM_PUBKEY, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_SIG, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 2, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 3, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 4, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 5, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 6, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 7, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 8, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 9, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 10, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 11, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 12, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 13, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 14, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB, .inst = 15, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 2, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 3, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 4, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 5, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 6, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 7, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 8, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 9, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 10, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 11, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 12, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 13, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 14, .level = BDT_BOTH }, { .type = AMD_BIOS_APCB_BK, .inst = 15, .level = BDT_BOTH }, { .type = AMD_BIOS_APOB, .level = BDT_BOTH }, { .type = AMD_BIOS_BIN, .reset = 1, .copy = 1, .zlib = 1, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_APOB_NV, .level = BDT_LVL2 }, { .type = AMD_BIOS_PMUI, .inst = 1, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 1, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 2, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 2, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 3, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 3, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 4, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 4, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 5, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 5, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 6, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 6, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 7, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 7, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 9, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 9, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 10, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 10, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 11, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 11, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 12, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 12, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 13, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 13, .subpr = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 1, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 1, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 2, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 2, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 3, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 3, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 4, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 4, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 5, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 5, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 6, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 6, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 7, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 7, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 9, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 9, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 10, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 10, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 11, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 11, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 12, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 12, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUI, .inst = 13, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_PMUD, .inst = 13, .subpr = 1, .level = BDT_BOTH }, { .type = AMD_BIOS_UCODE, .inst = 0, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 1, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 2, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 3, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 4, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 5, .level = BDT_LVL2 }, { .type = AMD_BIOS_UCODE, .inst = 6, .level = BDT_LVL2 }, { .type = AMD_BIOS_MP2_CFG, .level = BDT_LVL2 }, { .type = AMD_BIOS_PSP_SHARED_MEM, .inst = 0, .level = BDT_BOTH }, { .type = AMD_BIOS_INVALID }, }; #define RUN_BASE(ctx) (0xFFFFFFFF - (ctx).rom_size + 1) #define RUN_OFFSET_MODE(ctx, offset, mode) \ ((mode) == AMD_ADDR_PHYSICAL ? RUN_BASE(ctx) + (offset) : \ ((mode) == AMD_ADDR_REL_BIOS ? (offset) : \ ((mode) == AMD_ADDR_REL_TAB ? (offset) - (ctx).current_table : (offset)))) #define RUN_OFFSET(ctx, offset) RUN_OFFSET_MODE((ctx), (offset), (ctx).address_mode) #define RUN_TO_OFFSET(ctx, run) ((ctx).address_mode == AMD_ADDR_PHYSICAL ? \ (run) - RUN_BASE(ctx) : (run)) /* TODO: */ #define RUN_CURRENT(ctx) RUN_OFFSET((ctx), (ctx).current) /* The mode in entry can not be higher than the header's. For example, if table mode is 0, all the entry mode will be 0. */ #define RUN_CURRENT_MODE(ctx, mode) RUN_OFFSET_MODE((ctx), (ctx).current, \ (ctx).address_mode < (mode) ? (ctx).address_mode : (mode)) #define BUFF_OFFSET(ctx, offset) ((void *)((ctx).rom + (offset))) #define BUFF_CURRENT(ctx) BUFF_OFFSET((ctx), (ctx).current) #define BUFF_TO_RUN(ctx, ptr) RUN_OFFSET((ctx), ((char *)(ptr) - (ctx).rom)) #define BUFF_TO_RUN_MODE(ctx, ptr, mode) RUN_OFFSET_MODE((ctx), ((char *)(ptr) - (ctx).rom), \ (ctx).address_mode < (mode) ? (ctx).address_mode : (mode)) #define BUFF_ROOM(ctx) ((ctx).rom_size - (ctx).current) /* Only set the address mode in entry if the table is mode 2. */ #define SET_ADDR_MODE(table, mode) \ ((table)->header.additional_info_fields.address_mode == \ AMD_ADDR_REL_TAB ? (mode) : 0) #define SET_ADDR_MODE_BY_TABLE(table) \ SET_ADDR_MODE((table), (table)->header.additional_info_fields.address_mode) static void free_psp_firmware_filenames(amd_fw_entry *fw_table) { amd_fw_entry *index; for (index = fw_table; index->type != AMD_FW_INVALID; index++) { if (index->filename && index->type != AMD_FW_VERSTAGE_SIG && index->type != AMD_FW_PSP_VERSTAGE && index->type != AMD_FW_SPL && index->type != AMD_FW_PSP_WHITELIST) { free(index->filename); index->filename = NULL; } } } static void free_bdt_firmware_filenames(amd_bios_entry *fw_table) { amd_bios_entry *index; for (index = fw_table; index->type != AMD_BIOS_INVALID; index++) { if (index->filename && index->type != AMD_BIOS_APCB && index->type != AMD_BIOS_BIN && index->type != AMD_BIOS_APCB_BK && index->type != AMD_BIOS_UCODE) { free(index->filename); index->filename = NULL; } } } static void amdfwtool_cleanup(context *ctx) { free(ctx->rom); ctx->rom = NULL; /* Free the filename. */ free_psp_firmware_filenames(amd_psp_fw_table); free_bdt_firmware_filenames(amd_bios_table); free(ctx->amd_psp_fw_table_clean); ctx->amd_psp_fw_table_clean = NULL; free(ctx->amd_bios_table_clean); ctx->amd_bios_table_clean = NULL; } void assert_fw_entry(uint32_t count, uint32_t max, context *ctx) { if (count >= max) { fprintf(stderr, "Error: BIOS entries (%d) exceeds max allowed items " "(%d)\n", count, max); amdfwtool_cleanup(ctx); exit(1); } } static void set_current_pointer(context *ctx, uint32_t value) { if (ctx->current_pointer_saved != 0xFFFFFFFF && ctx->current_pointer_saved != ctx->current) { fprintf(stderr, "Error: The pointer is changed elsewhere\n"); amdfwtool_cleanup(ctx); exit(1); } ctx->current = value; if (ctx->current > ctx->rom_size) { fprintf(stderr, "Error: Packing data causes overflow\n"); amdfwtool_cleanup(ctx); exit(1); } ctx->current_pointer_saved = ctx->current; } static void adjust_current_pointer(context *ctx, uint32_t add, uint32_t align) { /* Get */ set_current_pointer(ctx, ALIGN_UP(ctx->current + add, align)); } static void *new_psp_dir(context *ctx, amd_cb_config *cb_config) { void *ptr; uint32_t align_end = cb_config->need_ish ? TABLE_ALIGNMENT : 1; /* * Force both onto boundary when multi. Primary table is after * updatable table, so alignment ensures primary can stay intact * if secondary is reprogrammed. */ if (cb_config->multi_level) adjust_current_pointer(ctx, 0, TABLE_ERASE_ALIGNMENT); else adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); ptr = BUFF_CURRENT(*ctx); ((psp_directory_header *)ptr)->num_entries = 0; ((psp_directory_header *)ptr)->additional_info = 0; ((psp_directory_header *)ptr)->additional_info_fields.address_mode = ctx->address_mode; adjust_current_pointer(ctx, sizeof(psp_directory_header) + MAX_PSP_ENTRIES * sizeof(psp_directory_entry), align_end); return ptr; } static void *new_ish_dir(context *ctx) { void *ptr; adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); ptr = BUFF_CURRENT(*ctx); adjust_current_pointer(ctx, TABLE_ALIGNMENT, 1); return ptr; } static void *new_combo_dir(context *ctx) { void *ptr; adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); ptr = BUFF_CURRENT(*ctx); adjust_current_pointer(ctx, sizeof(psp_combo_header) + MAX_COMBO_ENTRIES * sizeof(psp_combo_entry), 1); return ptr; } static void fill_dir_header(void *directory, uint32_t count, uint32_t cookie, context *ctx, amd_cb_config *cb_config) { psp_combo_directory *cdir = directory; psp_directory_table *dir = directory; bios_directory_table *bdir = directory; uint32_t table_size = 0; if (!count) return; if (ctx == NULL || directory == NULL) { fprintf(stderr, "Calling %s with NULL pointers\n", __func__); return; } /* The table size needs to be 0x1000 aligned. So align the end of table. */ adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); switch (cookie) { case PSP2_COOKIE: case BHD2_COOKIE: cdir->header.cookie = cookie; /* lookup mode is hardcoded for now. */ cdir->header.lookup = 1; cdir->header.num_entries = count; cdir->header.reserved[0] = 0; cdir->header.reserved[1] = 0; /* checksum everything that comes after the Checksum field */ cdir->header.checksum = fletcher32(&cdir->header.num_entries, count * sizeof(psp_combo_entry) + sizeof(cdir->header.num_entries) + sizeof(cdir->header.lookup) + 2 * sizeof(cdir->header.reserved[0])); break; case PSP_COOKIE: case PSPL2_COOKIE: if (cookie == PSP_COOKIE && cb_config->need_ish) /* The ISH header can not be in the space defined by L1 table size. * The space is allocated when the L1 header is created. */ table_size = TABLE_ALIGNMENT; else /* Generally table size not just constains the header, * but all the FWs. */ table_size = ctx->current - ctx->current_table; if ((table_size % TABLE_ALIGNMENT) != 0) { fprintf(stderr, "The PSP table size should be 4K aligned\n"); amdfwtool_cleanup(ctx); exit(1); } dir->header.cookie = cookie; dir->header.num_entries = count; dir->header.additional_info_fields.dir_size = table_size / TABLE_ALIGNMENT; dir->header.additional_info_fields.spi_block_size = 1; dir->header.additional_info_fields.base_addr = 0; /* checksum everything that comes after the Checksum field */ dir->header.checksum = fletcher32(&dir->header.num_entries, count * sizeof(psp_directory_entry) + sizeof(dir->header.num_entries) + sizeof(dir->header.additional_info)); break; case BHD_COOKIE: case BHDL2_COOKIE: table_size = ctx->current - ctx->current_table; if ((table_size % TABLE_ALIGNMENT) != 0) { fprintf(stderr, "The BIOS table size should be 4K aligned\n"); amdfwtool_cleanup(ctx); exit(1); } bdir->header.cookie = cookie; bdir->header.num_entries = count; bdir->header.additional_info_fields.dir_size = table_size / TABLE_ALIGNMENT; bdir->header.additional_info_fields.spi_block_size = 1; bdir->header.additional_info_fields.base_addr = 0; /* checksum everything that comes after the Checksum field */ bdir->header.checksum = fletcher32(&bdir->header.num_entries, count * sizeof(bios_directory_entry) + sizeof(bdir->header.num_entries) + sizeof(bdir->header.additional_info)); break; } } static void fill_psp_directory_to_efs(embedded_firmware *amd_romsig, void *pspdir, context *ctx, amd_cb_config *cb_config) { switch (cb_config->soc_id) { case PLATFORM_UNKNOWN: amd_romsig->psp_directory = BUFF_TO_RUN_MODE(*ctx, pspdir, AMD_ADDR_REL_BIOS); break; case PLATFORM_CEZANNE: case PLATFORM_MENDOCINO: case PLATFORM_PHOENIX: case PLATFORM_GLINDA: case PLATFORM_CARRIZO: case PLATFORM_STONEYRIDGE: case PLATFORM_RAVEN: case PLATFORM_PICASSO: case PLATFORM_LUCIENNE: case PLATFORM_RENOIR: case PLATFORM_GENOA: default: /* for combo, it is also combo_psp_directory */ amd_romsig->new_psp_directory = BUFF_TO_RUN_MODE(*ctx, pspdir, AMD_ADDR_REL_BIOS); break; } } static void fill_bios_directory_to_efs(embedded_firmware *amd_romsig, void *biosdir, context *ctx, amd_cb_config *cb_config) { switch (cb_config->soc_id) { case PLATFORM_RENOIR: case PLATFORM_LUCIENNE: case PLATFORM_CEZANNE: case PLATFORM_GENOA: if (!cb_config->recovery_ab) amd_romsig->bios3_entry = BUFF_TO_RUN_MODE(*ctx, biosdir, AMD_ADDR_REL_BIOS); break; case PLATFORM_MENDOCINO: case PLATFORM_PHOENIX: case PLATFORM_GLINDA: break; case PLATFORM_CARRIZO: case PLATFORM_STONEYRIDGE: case PLATFORM_RAVEN: case PLATFORM_PICASSO: default: amd_romsig->bios1_entry = BUFF_TO_RUN_MODE(*ctx, biosdir, AMD_ADDR_REL_BIOS); break; } } static uint32_t get_psp_id(enum platform soc_id) { uint32_t psp_id; switch (soc_id) { case PLATFORM_RAVEN: case PLATFORM_PICASSO: psp_id = 0xBC0A0000; break; case PLATFORM_RENOIR: case PLATFORM_LUCIENNE: psp_id = 0xBC0C0000; break; case PLATFORM_CEZANNE: psp_id = 0xBC0C0140; break; case PLATFORM_MENDOCINO: psp_id = 0xBC0D0900; break; case PLATFORM_STONEYRIDGE: psp_id = 0x10220B00; break; case PLATFORM_GLINDA: psp_id = 0xBC0E0200; break; case PLATFORM_PHOENIX: psp_id = 0xBC0D0400; break; case PLATFORM_GENOA: psp_id = 0xBC0C0111; break; case PLATFORM_CARRIZO: default: psp_id = 0; break; } return psp_id; } static void integrate_firmwares(context *ctx, embedded_firmware *romsig, amd_fw_entry *fw_table) { ssize_t bytes; uint32_t i; adjust_current_pointer(ctx, 0, BLOB_ALIGNMENT); for (i = 0; fw_table[i].type != AMD_FW_INVALID; i++) { if (fw_table[i].filename != NULL) { switch (fw_table[i].type) { case AMD_FW_IMC: adjust_current_pointer(ctx, 0, 0x10000U); romsig->imc_entry = RUN_CURRENT(*ctx); break; case AMD_FW_GEC: romsig->gec_entry = RUN_CURRENT(*ctx); break; case AMD_FW_XHCI: romsig->xhci_entry = RUN_CURRENT(*ctx); break; default: /* Error */ break; } bytes = copy_blob(BUFF_CURRENT(*ctx), fw_table[i].filename, BUFF_ROOM(*ctx)); if (bytes < 0) { amdfwtool_cleanup(ctx); exit(1); } adjust_current_pointer(ctx, bytes, BLOB_ALIGNMENT); } } } static void output_manifest(int manifest_fd, amd_fw_entry *fw_entry) { struct amd_fw_header hdr; int blob_fd; ssize_t bytes; blob_fd = open(fw_entry->filename, O_RDONLY); if (blob_fd < 0) { fprintf(stderr, "Error opening file: %s: %s\n", fw_entry->filename, strerror(errno)); return; } bytes = read(blob_fd, &hdr, sizeof(hdr)); if (bytes != sizeof(hdr)) { close(blob_fd); fprintf(stderr, "Error while reading %s\n", fw_entry->filename); return; } dprintf(manifest_fd, "type: 0x%02x ver:%02x.%02x.%02x.%02x\n", fw_entry->type, hdr.version[3], hdr.version[2], hdr.version[1], hdr.version[0]); close(blob_fd); } static void dump_blob_version(char *manifest_file, amd_fw_entry *fw_table) { amd_fw_entry *index; int manifest_fd; manifest_fd = open(manifest_file, O_WRONLY | O_CREAT | O_TRUNC, 0666); if (manifest_fd < 0) { fprintf(stderr, "Error opening file: %s: %s\n", manifest_file, strerror(errno)); return; } for (index = fw_table; index->type != AMD_FW_INVALID; index++) { if (!(index->filename)) continue; if (index->generate_manifest == true) output_manifest(manifest_fd, index); } close(manifest_fd); } /* For debugging */ static void dump_psp_firmwares(amd_fw_entry *fw_table) { amd_fw_entry *index; printf("PSP firmware components:\n"); for (index = fw_table; index->type != AMD_FW_INVALID; index++) { if (index->type == AMD_PSP_FUSE_CHAIN) printf(" %2x: level=%x, subprog=%x, inst=%x\n", index->type, index->level, index->subprog, index->inst); else if (index->filename) printf(" %2x: level=%x, subprog=%x, inst=%x, %s\n", index->type, index->level, index->subprog, index->inst, index->filename); } } static void dump_bdt_firmwares(amd_bios_entry *fw_table) { amd_bios_entry *index; printf("BIOS Directory Table (BDT) components:\n"); for (index = fw_table; index->type != AMD_BIOS_INVALID; index++) { if (index->filename) printf(" %2x: level=%x, %s\n", index->type, index->level, index->filename); } } static void integrate_psp_ab(context *ctx, psp_directory_table *pspdir, psp_directory_table *pspdir2, ish_directory_table *ish, amd_fw_type ab, enum platform soc_id) { uint32_t count; uint32_t current_table_save; current_table_save = ctx->current_table; ctx->current_table = (char *)pspdir - ctx->rom; count = pspdir->header.num_entries; assert_fw_entry(count, MAX_PSP_ENTRIES, ctx); pspdir->entries[count].type = (uint8_t)ab; pspdir->entries[count].subprog = 0; pspdir->entries[count].rsvd = 0; if (ish != NULL) { ish->pl2_location = BUFF_TO_RUN_MODE(*ctx, pspdir2, AMD_ADDR_REL_BIOS); ish->boot_priority = ab == AMD_FW_RECOVERYAB_A ? 0xFFFFFFFF : 1; ish->update_retry_count = 2; ish->glitch_retry_count = 0; ish->psp_id = get_psp_id(soc_id); ish->checksum = fletcher32(&ish->boot_priority, sizeof(ish_directory_table) - sizeof(uint32_t)); pspdir->entries[count].addr = BUFF_TO_RUN_MODE(*ctx, ish, AMD_ADDR_REL_BIOS); pspdir->entries[count].address_mode = SET_ADDR_MODE(pspdir, AMD_ADDR_REL_BIOS); pspdir->entries[count].size = TABLE_ALIGNMENT; } else { pspdir->entries[count].addr = BUFF_TO_RUN_MODE(*ctx, pspdir2, AMD_ADDR_REL_BIOS); pspdir->entries[count].address_mode = SET_ADDR_MODE(pspdir, AMD_ADDR_REL_BIOS); pspdir->entries[count].size = _MAX(TABLE_ALIGNMENT, pspdir2->header.num_entries * sizeof(psp_directory_entry) + sizeof(psp_directory_header)); } count++; pspdir->header.num_entries = count; ctx->current_table = current_table_save; } static void integrate_psp_firmwares(context *ctx, psp_directory_table *pspdir, psp_directory_table *pspdir2, psp_directory_table *pspdir2_b, amd_fw_entry *fw_table, uint32_t cookie, amd_cb_config *cb_config) { ssize_t bytes; unsigned int i, count; int level; uint32_t size; uint64_t addr; uint32_t current_table_save; bool recovery_ab = cb_config->recovery_ab; ish_directory_table *ish_a_dir = NULL, *ish_b_dir = NULL; bool use_only_a = (cb_config->soc_id == PLATFORM_PHOENIX); /* TODO: b:285390041 */ /* This function can create a primary table, a secondary table, or a * flattened table which contains all applicable types. These if-else * statements infer what the caller intended. If a 2nd-level cookie * is passed, clearly a 2nd-level table is intended. However, a * 1st-level cookie may indicate level 1 or flattened. If the caller * passes a pointer to a 2nd-level table, then assume not flat. */ if (!cb_config->multi_level) level = PSP_BOTH; else if (cookie == PSPL2_COOKIE) level = PSP_LVL2; else if (pspdir2) level = PSP_LVL1; else level = PSP_BOTH; if (recovery_ab) { if (cookie == PSPL2_COOKIE) level = PSP_LVL2_AB; else if (pspdir2) level = PSP_LVL1_AB; else level = PSP_BOTH_AB; } current_table_save = ctx->current_table; ctx->current_table = (char *)pspdir - ctx->rom; adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); for (i = 0, count = 0; fw_table[i].type != AMD_FW_INVALID; i++) { if (!(fw_table[i].level & level)) continue; assert_fw_entry(count, MAX_PSP_ENTRIES, ctx); if (fw_table[i].type == AMD_TOKEN_UNLOCK) { if (!fw_table[i].other) continue; adjust_current_pointer(ctx, 0, ERASE_ALIGNMENT); pspdir->entries[count].type = fw_table[i].type; pspdir->entries[count].size = 4096; /* TODO: doc? */ pspdir->entries[count].addr = RUN_CURRENT(*ctx); pspdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(pspdir); pspdir->entries[count].subprog = fw_table[i].subprog; pspdir->entries[count].rsvd = 0; adjust_current_pointer(ctx, 4096, 0x100U); count++; } else if (fw_table[i].type == AMD_PSP_FUSE_CHAIN) { pspdir->entries[count].type = fw_table[i].type; pspdir->entries[count].subprog = fw_table[i].subprog; pspdir->entries[count].rsvd = 0; pspdir->entries[count].size = 0xFFFFFFFF; pspdir->entries[count].addr = fw_table[i].other; pspdir->entries[count].address_mode = 0; count++; } else if (fw_table[i].type == AMD_FW_PSP_NVRAM) { if (fw_table[i].filename == NULL) { if (fw_table[i].size == 0) continue; size = fw_table[i].size; addr = fw_table[i].dest; if (addr != ALIGN_UP(addr, ERASE_ALIGNMENT)) { fprintf(stderr, "Error: PSP NVRAM section not aligned with erase block size.\n\n"); amdfwtool_cleanup(ctx); exit(1); } } else { adjust_current_pointer(ctx, 0, ERASE_ALIGNMENT); bytes = copy_blob(BUFF_CURRENT(*ctx), fw_table[i].filename, BUFF_ROOM(*ctx)); if (bytes <= 0) { amdfwtool_cleanup(ctx); exit(1); } size = ALIGN_UP(bytes, ERASE_ALIGNMENT); addr = RUN_CURRENT(*ctx); adjust_current_pointer(ctx, bytes, BLOB_ERASE_ALIGNMENT); } pspdir->entries[count].type = fw_table[i].type; pspdir->entries[count].subprog = fw_table[i].subprog; pspdir->entries[count].rsvd = 0; pspdir->entries[count].size = size; pspdir->entries[count].addr = addr; pspdir->entries[count].address_mode = SET_ADDR_MODE(pspdir, AMD_ADDR_REL_BIOS); count++; } else if (fw_table[i].filename != NULL) { if (fw_table[i].addr_signed) { pspdir->entries[count].addr = RUN_OFFSET(*ctx, fw_table[i].addr_signed); pspdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(pspdir); bytes = fw_table[i].file_size; } else { bytes = copy_blob(BUFF_CURRENT(*ctx), fw_table[i].filename, BUFF_ROOM(*ctx)); if (bytes < 0) { amdfwtool_cleanup(ctx); exit(1); } pspdir->entries[count].addr = RUN_CURRENT(*ctx); pspdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(pspdir); adjust_current_pointer(ctx, bytes, BLOB_ALIGNMENT); } pspdir->entries[count].type = fw_table[i].type; pspdir->entries[count].subprog = fw_table[i].subprog; pspdir->entries[count].rsvd = 0; pspdir->entries[count].inst = fw_table[i].inst; pspdir->entries[count].size = (uint32_t)bytes; count++; } else { /* This APU doesn't have this firmware. */ } } if (recovery_ab && (pspdir2 != NULL)) { if (cb_config->need_ish) { /* Need ISH */ ish_a_dir = new_ish_dir(ctx); if (pspdir2_b != NULL) ish_b_dir = new_ish_dir(ctx); } pspdir->header.num_entries = count; integrate_psp_ab(ctx, pspdir, pspdir2, ish_a_dir, AMD_FW_RECOVERYAB_A, cb_config->soc_id); if (pspdir2_b != NULL) integrate_psp_ab(ctx, pspdir, pspdir2_b, ish_b_dir, use_only_a ? AMD_FW_RECOVERYAB_A : AMD_FW_RECOVERYAB_B, cb_config->soc_id); else integrate_psp_ab(ctx, pspdir, pspdir2, ish_a_dir, use_only_a ? AMD_FW_RECOVERYAB_A : AMD_FW_RECOVERYAB_B, cb_config->soc_id); count = pspdir->header.num_entries; } else if (pspdir2 != NULL) { assert_fw_entry(count, MAX_PSP_ENTRIES, ctx); pspdir->entries[count].type = AMD_FW_L2_PTR; pspdir->entries[count].subprog = 0; pspdir->entries[count].rsvd = 0; pspdir->entries[count].size = sizeof(pspdir2->header) + pspdir2->header.num_entries * sizeof(psp_directory_entry); pspdir->entries[count].addr = BUFF_TO_RUN_MODE(*ctx, pspdir2, AMD_ADDR_REL_BIOS); pspdir->entries[count].address_mode = SET_ADDR_MODE(pspdir, AMD_ADDR_REL_BIOS); count++; } fill_dir_header(pspdir, count, cookie, ctx, cb_config); ctx->current_table = current_table_save; } static void add_psp_firmware_entry(context *ctx, psp_directory_table *pspdir, void *table, amd_fw_type type, uint32_t size) { uint32_t count = pspdir->header.num_entries; uint32_t index; uint32_t current_table_save; current_table_save = ctx->current_table; ctx->current_table = (char *)pspdir - ctx->rom; /* If there is an entry of "type", replace it. */ for (index = 0; index < count; index++) { if (pspdir->entries[index].type == (uint8_t)type) break; } assert_fw_entry(count, MAX_PSP_ENTRIES, ctx); pspdir->entries[index].type = (uint8_t)type; pspdir->entries[index].subprog = 0; pspdir->entries[index].rsvd = 0; pspdir->entries[index].addr = BUFF_TO_RUN(*ctx, table); pspdir->entries[index].address_mode = SET_ADDR_MODE_BY_TABLE(pspdir); pspdir->entries[index].size = size; if (index == count) count++; pspdir->header.num_entries = count; pspdir->header.checksum = fletcher32(&pspdir->header.num_entries, count * sizeof(psp_directory_entry) + sizeof(pspdir->header.num_entries) + sizeof(pspdir->header.additional_info)); ctx->current_table = current_table_save; } static void *new_bios_dir(context *ctx, bool multi) { void *ptr; /* * Force both onto boundary when multi. Primary table is after * updatable table, so alignment ensures primary can stay intact * if secondary is reprogrammed. */ if (multi) adjust_current_pointer(ctx, 0, TABLE_ERASE_ALIGNMENT); else adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); ptr = BUFF_CURRENT(*ctx); ((bios_directory_hdr *) ptr)->additional_info = 0; ((bios_directory_hdr *) ptr)->additional_info_fields.address_mode = ctx->address_mode; adjust_current_pointer(ctx, sizeof(bios_directory_hdr) + MAX_BIOS_ENTRIES * sizeof(bios_directory_entry), 1); return ptr; } static int locate_bdt2_bios(bios_directory_table *level2, uint64_t *source, uint32_t *size) { uint32_t i; *source = 0; *size = 0; if (!level2) return 0; for (i = 0 ; i < level2->header.num_entries ; i++) { if (level2->entries[i].type == AMD_BIOS_BIN) { *source = level2->entries[i].source; *size = level2->entries[i].size; return 1; } } return 0; } static int have_bios_tables(amd_bios_entry *table) { int i; for (i = 0 ; table[i].type != AMD_BIOS_INVALID; i++) { if (table[i].level & BDT_LVL1 && table[i].filename) return 1; } return 0; } int find_bios_entry(amd_bios_type type) { int i; for (i = 0; amd_bios_table[i].type != AMD_BIOS_INVALID; i++) { if (amd_bios_table[i].type == type) return i; } return -1; } static void add_bios_apcb_bk_entry(bios_directory_table *biosdir, unsigned int idx, int inst, uint32_t size, uint64_t source) { int i; for (i = 0; amd_bios_table[i].type != AMD_BIOS_INVALID; i++) { if (amd_bios_table[i].type == AMD_BIOS_APCB_BK && amd_bios_table[i].inst == inst) break; } if (amd_bios_table[i].type != AMD_BIOS_APCB_BK) return; biosdir->entries[idx].type = amd_bios_table[i].type; biosdir->entries[idx].region_type = amd_bios_table[i].region_type; biosdir->entries[idx].dest = amd_bios_table[i].dest ? amd_bios_table[i].dest : (uint64_t)-1; biosdir->entries[idx].reset = amd_bios_table[i].reset; biosdir->entries[idx].copy = amd_bios_table[i].copy; biosdir->entries[idx].ro = amd_bios_table[i].ro; biosdir->entries[idx].compressed = amd_bios_table[i].zlib; biosdir->entries[idx].inst = amd_bios_table[i].inst; biosdir->entries[idx].subprog = amd_bios_table[i].subpr; biosdir->entries[idx].size = size; biosdir->entries[idx].source = source; biosdir->entries[idx].address_mode = SET_ADDR_MODE_BY_TABLE(biosdir); } static void integrate_bios_firmwares(context *ctx, bios_directory_table *biosdir, bios_directory_table *biosdir2, amd_bios_entry *fw_table, uint32_t cookie, amd_cb_config *cb_config) { ssize_t bytes; unsigned int i, count; int level; int apob_idx; uint32_t size; uint64_t source; uint32_t current_table_save; /* This function can create a primary table, a secondary table, or a * flattened table which contains all applicable types. These if-else * statements infer what the caller intended. If a 2nd-level cookie * is passed, clearly a 2nd-level table is intended. However, a * 1st-level cookie may indicate level 1 or flattened. If the caller * passes a pointer to a 2nd-level table, then assume not flat. */ if (!cb_config->multi_level) level = BDT_BOTH; else if (cookie == BHDL2_COOKIE) level = BDT_LVL2; else if (biosdir2) level = BDT_LVL1; else level = BDT_BOTH; current_table_save = ctx->current_table; ctx->current_table = (char *)biosdir - ctx->rom; adjust_current_pointer(ctx, 0, TABLE_ALIGNMENT); for (i = 0, count = 0; fw_table[i].type != AMD_BIOS_INVALID; i++) { if (!(fw_table[i].level & level)) continue; if (fw_table[i].filename == NULL && ( fw_table[i].type != AMD_BIOS_SIG && fw_table[i].type != AMD_BIOS_APOB && fw_table[i].type != AMD_BIOS_APOB_NV && fw_table[i].type != AMD_BIOS_L2_PTR && fw_table[i].type != AMD_BIOS_BIN && fw_table[i].type != AMD_BIOS_PSP_SHARED_MEM)) continue; /* BIOS Directory items may have additional requirements */ /* SIG needs a size, else no choice but to skip */ if (fw_table[i].type == AMD_BIOS_SIG && !fw_table[i].size) continue; /* Check APOB_NV requirements */ if (fw_table[i].type == AMD_BIOS_APOB_NV) { if (!fw_table[i].size && !fw_table[i].src) continue; /* APOB_NV not used */ if (fw_table[i].src && !fw_table[i].size) { fprintf(stderr, "Error: APOB NV address provided, but no size\n"); amdfwtool_cleanup(ctx); exit(1); } /* If the APOB isn't used, APOB_NV isn't used either */ apob_idx = find_bios_entry(AMD_BIOS_APOB); if (apob_idx < 0 || !fw_table[apob_idx].dest) continue; /* APOV NV not supported */ } /* APOB_DATA needs destination */ if (fw_table[i].type == AMD_BIOS_APOB && !fw_table[i].dest) { fprintf(stderr, "Error: APOB destination not provided\n"); amdfwtool_cleanup(ctx); exit(1); } /* BIOS binary must have destination and uncompressed size. If * no filename given, then user must provide a source address. */ if (fw_table[i].type == AMD_BIOS_BIN) { if (!fw_table[i].dest || !fw_table[i].size) { fprintf(stderr, "Error: BIOS binary destination and uncompressed size are required\n"); amdfwtool_cleanup(ctx); exit(1); } if (!fw_table[i].filename && !fw_table[i].src) { fprintf(stderr, "Error: BIOS binary assumed outside amdfw.rom but no source address given\n"); amdfwtool_cleanup(ctx); exit(1); } } /* PSP_SHARED_MEM needs a destination and size */ if (fw_table[i].type == AMD_BIOS_PSP_SHARED_MEM && (!fw_table[i].dest || !fw_table[i].size)) continue; assert_fw_entry(count, MAX_BIOS_ENTRIES, ctx); biosdir->entries[count].type = fw_table[i].type; biosdir->entries[count].region_type = fw_table[i].region_type; biosdir->entries[count].dest = fw_table[i].dest ? fw_table[i].dest : (uint64_t)-1; biosdir->entries[count].reset = fw_table[i].reset; biosdir->entries[count].copy = fw_table[i].copy; biosdir->entries[count].ro = fw_table[i].ro; biosdir->entries[count].compressed = fw_table[i].zlib; biosdir->entries[count].inst = fw_table[i].inst; biosdir->entries[count].subprog = fw_table[i].subpr; switch (fw_table[i].type) { case AMD_BIOS_SIG: /* Reserve size bytes within amdfw.rom */ biosdir->entries[count].size = fw_table[i].size; biosdir->entries[count].source = RUN_CURRENT(*ctx); biosdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(biosdir); memset(BUFF_CURRENT(*ctx), 0xff, biosdir->entries[count].size); adjust_current_pointer(ctx, biosdir->entries[count].size, 0x100U); break; case AMD_BIOS_APOB: biosdir->entries[count].size = fw_table[i].size; biosdir->entries[count].source = fw_table[i].src; biosdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(biosdir); break; case AMD_BIOS_APOB_NV: if (fw_table[i].src) { /* If source is given, use that and its size */ biosdir->entries[count].source = fw_table[i].src; biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); biosdir->entries[count].size = fw_table[i].size; } else { /* Else reserve size bytes within amdfw.rom */ adjust_current_pointer(ctx, 0, ERASE_ALIGNMENT); biosdir->entries[count].source = RUN_CURRENT(*ctx); biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); biosdir->entries[count].size = ALIGN_UP( fw_table[i].size, ERASE_ALIGNMENT); memset(BUFF_CURRENT(*ctx), 0xff, biosdir->entries[count].size); adjust_current_pointer(ctx, biosdir->entries[count].size, 1); } break; case AMD_BIOS_BIN: /* Don't make a 2nd copy, point to the same one */ if (level == BDT_LVL1 && locate_bdt2_bios(biosdir2, &source, &size)) { biosdir->entries[count].source = source; biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); biosdir->entries[count].size = size; break; } /* level 2, or level 1 and no copy found in level 2 */ biosdir->entries[count].source = fw_table[i].src; biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); biosdir->entries[count].dest = fw_table[i].dest; biosdir->entries[count].size = fw_table[i].size; if (!fw_table[i].filename) break; bytes = copy_blob(BUFF_CURRENT(*ctx), fw_table[i].filename, BUFF_ROOM(*ctx)); if (bytes <= 0) { amdfwtool_cleanup(ctx); exit(1); } biosdir->entries[count].source = RUN_CURRENT_MODE(*ctx, AMD_ADDR_REL_BIOS); biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); adjust_current_pointer(ctx, bytes, 0x100U); break; case AMD_BIOS_PSP_SHARED_MEM: biosdir->entries[count].dest = fw_table[i].dest; biosdir->entries[count].size = fw_table[i].size; break; default: /* everything else is copied from input */ if (fw_table[i].type == AMD_BIOS_APCB || fw_table[i].type == AMD_BIOS_APCB_BK) adjust_current_pointer(ctx, 0, ERASE_ALIGNMENT); bytes = copy_blob(BUFF_CURRENT(*ctx), fw_table[i].filename, BUFF_ROOM(*ctx)); if (bytes <= 0) { amdfwtool_cleanup(ctx); exit(1); } biosdir->entries[count].size = (uint32_t)bytes; biosdir->entries[count].source = RUN_CURRENT(*ctx); biosdir->entries[count].address_mode = SET_ADDR_MODE_BY_TABLE(biosdir); adjust_current_pointer(ctx, bytes, 0x100U); if (fw_table[i].type == AMD_BIOS_APCB && !cb_config->have_apcb_bk) { size = biosdir->entries[count].size; source = biosdir->entries[count].source; count++; add_bios_apcb_bk_entry(biosdir, count, fw_table[i].inst, size, source); } break; } count++; } if (biosdir2) { assert_fw_entry(count, MAX_BIOS_ENTRIES, ctx); biosdir->entries[count].type = AMD_BIOS_L2_PTR; biosdir->entries[count].region_type = 0; biosdir->entries[count].size = + MAX_BIOS_ENTRIES * sizeof(bios_directory_entry); biosdir->entries[count].source = BUFF_TO_RUN(*ctx, biosdir2); biosdir->entries[count].address_mode = SET_ADDR_MODE(biosdir, AMD_ADDR_REL_BIOS); biosdir->entries[count].subprog = 0; biosdir->entries[count].inst = 0; biosdir->entries[count].copy = 0; biosdir->entries[count].compressed = 0; biosdir->entries[count].dest = -1; biosdir->entries[count].reset = 0; biosdir->entries[count].ro = 0; count++; } fill_dir_header(biosdir, count, cookie, ctx, cb_config); ctx->current_table = current_table_save; } static int set_efs_table(uint8_t soc_id, amd_cb_config *cb_config, embedded_firmware *amd_romsig) { if ((cb_config->efs_spi_readmode == 0xFF) || (cb_config->efs_spi_speed == 0xFF)) { fprintf(stderr, "Error: EFS read mode and SPI speed must be set\n"); return 1; } /* amd_romsig->efs_gen introduced after RAVEN/PICASSO. * Leave as 0xffffffff for first gen */ if (cb_config->second_gen) { amd_romsig->efs_gen.gen = EFS_SECOND_GEN; amd_romsig->efs_gen.reserved = 0; } else { amd_romsig->efs_gen.gen = EFS_BEFORE_SECOND_GEN; amd_romsig->efs_gen.reserved = ~0; } switch (soc_id) { case PLATFORM_CARRIZO: case PLATFORM_STONEYRIDGE: amd_romsig->spi_readmode_f15_mod_60_6f = cb_config->efs_spi_readmode; amd_romsig->fast_speed_new_f15_mod_60_6f = cb_config->efs_spi_speed; break; case PLATFORM_RAVEN: case PLATFORM_PICASSO: amd_romsig->spi_readmode_f17_mod_00_2f = cb_config->efs_spi_readmode; amd_romsig->spi_fastspeed_f17_mod_00_2f = cb_config->efs_spi_speed; switch (cb_config->efs_spi_micron_flag) { case 0: amd_romsig->qpr_dummy_cycle_f17_mod_00_2f = 0xff; break; case 1: amd_romsig->qpr_dummy_cycle_f17_mod_00_2f = 0xa; break; default: fprintf(stderr, "Error: EFS Micron flag must be correctly set.\n\n"); return 1; } break; case PLATFORM_RENOIR: case PLATFORM_LUCIENNE: case PLATFORM_CEZANNE: case PLATFORM_MENDOCINO: case PLATFORM_PHOENIX: case PLATFORM_GLINDA: case PLATFORM_GENOA: amd_romsig->spi_readmode_f17_mod_30_3f = cb_config->efs_spi_readmode; amd_romsig->spi_fastspeed_f17_mod_30_3f = cb_config->efs_spi_speed; switch (cb_config->efs_spi_micron_flag) { case 0: amd_romsig->micron_detect_f17_mod_30_3f = 0xff; break; case 1: amd_romsig->micron_detect_f17_mod_30_3f = 0xaa; break; case 2: amd_romsig->micron_detect_f17_mod_30_3f = 0x55; break; default: fprintf(stderr, "Error: EFS Micron flag must be correctly set.\n\n"); return 1; } break; case PLATFORM_UNKNOWN: default: fprintf(stderr, "Error: Invalid SOC name.\n\n"); return 1; } return 0; } void open_process_config(char *config, amd_cb_config *cb_config, int debug) { FILE *config_handle; if (config) { config_handle = fopen(config, "r"); if (config_handle == NULL) { fprintf(stderr, "Can not open file %s for reading: %s\n", config, strerror(errno)); exit(1); } if (process_config(config_handle, cb_config) == 0) { fprintf(stderr, "Configuration file %s parsing error\n", config); fclose(config_handle); exit(1); } fclose(config_handle); } /* For debug. */ if (debug) { dump_psp_firmwares(amd_psp_fw_table); dump_bdt_firmwares(amd_bios_table); } } static bool is_initial_alignment_required(enum platform soc_id) { switch (soc_id) { case PLATFORM_MENDOCINO: case PLATFORM_PHOENIX: case PLATFORM_GLINDA: return false; default: return true; } } int main(int argc, char **argv) { int retval = 0; embedded_firmware *amd_romsig; psp_directory_table *pspdir = NULL; psp_directory_table *pspdir2 = NULL; psp_directory_table *pspdir2_b = NULL; psp_combo_directory *psp_combo_dir = NULL, *bhd_combo_dir = NULL; int combo_index = 0; int targetfd; context ctx = { 0 }; uint32_t romsig_offset; amd_cb_config cb_config = { .efs_spi_readmode = 0xff, .efs_spi_speed = 0xff, .efs_spi_micron_flag = 0xff }; ctx.current_pointer_saved = 0xFFFFFFFF; retval = amdfwtool_getopt(argc, argv, &cb_config, &ctx); if (retval) { return retval; } if (cb_config.use_combo) { ctx.amd_psp_fw_table_clean = malloc(sizeof(amd_psp_fw_table)); ctx.amd_bios_table_clean = malloc(sizeof(amd_bios_table)); memcpy(ctx.amd_psp_fw_table_clean, amd_psp_fw_table, sizeof(amd_psp_fw_table)); memcpy(ctx.amd_bios_table_clean, amd_bios_table, sizeof(amd_bios_table)); } open_process_config(cb_config.config, &cb_config, cb_config.debug); ctx.rom = malloc(ctx.rom_size); if (!ctx.rom) { fprintf(stderr, "Error: Failed to allocate memory\n"); return 1; } memset(ctx.rom, 0xFF, ctx.rom_size); romsig_offset = cb_config.efs_location ? cb_config.efs_location : AMD_ROMSIG_OFFSET; set_current_pointer(&ctx, romsig_offset); amd_romsig = BUFF_OFFSET(ctx, romsig_offset); amd_romsig->signature = EMBEDDED_FW_SIGNATURE; amd_romsig->imc_entry = 0; amd_romsig->gec_entry = 0; amd_romsig->xhci_entry = 0; if (cb_config.soc_id != PLATFORM_UNKNOWN) { retval = set_efs_table(cb_config.soc_id, &cb_config, amd_romsig); if (retval) { fprintf(stderr, "ERROR: Failed to initialize EFS table!\n"); return retval; } } else { fprintf(stderr, "WARNING: No SOC name specified.\n"); } if (cb_config.need_ish) ctx.address_mode = AMD_ADDR_REL_TAB; else if (cb_config.second_gen) ctx.address_mode = AMD_ADDR_REL_BIOS; else ctx.address_mode = AMD_ADDR_PHYSICAL; if (cb_config.efs_location != cb_config.body_location) set_current_pointer(&ctx, cb_config.body_location); else set_current_pointer(&ctx, romsig_offset + sizeof(embedded_firmware)); integrate_firmwares(&ctx, amd_romsig, amd_fw_table); if (is_initial_alignment_required(cb_config.soc_id)) { /* TODO: Check for older platforms. */ adjust_current_pointer(&ctx, 0, 0x10000U); } ctx.current_table = 0; /* If the tool is invoked with command-line options to keep the signed PSP binaries separate, process the signed binaries first. */ if (cb_config.signed_output_file && cb_config.signed_start_addr) process_signed_psp_firmwares(cb_config.signed_output_file, amd_psp_fw_table, cb_config.signed_start_addr, cb_config.soc_id); if (cb_config.use_combo) { psp_combo_dir = new_combo_dir(&ctx); adjust_current_pointer(&ctx, 0, 0x1000U); bhd_combo_dir = new_combo_dir(&ctx); } combo_index = 0; if (cb_config.config) cb_config.combo_config[0] = cb_config.config; do { if (cb_config.use_combo && cb_config.debug) printf("Processing %dth combo entry\n", combo_index); /* for non-combo image, combo_config[0] == config, and * it already is processed. Actually "combo_index > * 0" is enough. Put both of them here to make sure * and make it clear this will not affect non-combo * case. */ if (cb_config.use_combo && combo_index > 0) { /* Restore the table as clean data. */ memcpy(amd_psp_fw_table, ctx.amd_psp_fw_table_clean, sizeof(amd_psp_fw_table)); memcpy(amd_bios_table, ctx.amd_bios_table_clean, sizeof(amd_bios_table)); assert_fw_entry(combo_index, MAX_COMBO_ENTRIES, &ctx); open_process_config(cb_config.combo_config[combo_index], &cb_config, cb_config.debug); /* In most cases, the address modes are same. */ if (cb_config.need_ish) ctx.address_mode = AMD_ADDR_REL_TAB; else if (cb_config.second_gen) ctx.address_mode = AMD_ADDR_REL_BIOS; else ctx.address_mode = AMD_ADDR_PHYSICAL; register_apcb_combo(&cb_config, combo_index, &ctx); } if (cb_config.multi_level) { /* Do 2nd PSP directory followed by 1st */ pspdir2 = new_psp_dir(&ctx, &cb_config); integrate_psp_firmwares(&ctx, pspdir2, NULL, NULL, amd_psp_fw_table, PSPL2_COOKIE, &cb_config); if (cb_config.recovery_ab && !cb_config.recovery_ab_single_copy) { /* Create a copy of PSP Directory 2 in the backup slot B. Related biosdir2_b copy will be created later. */ pspdir2_b = new_psp_dir(&ctx, &cb_config); integrate_psp_firmwares(&ctx, pspdir2_b, NULL, NULL, amd_psp_fw_table, PSPL2_COOKIE, &cb_config); } else { /* * Either the platform is using only * one slot or B is same as above * directories for A. Skip creating * pspdir2_b here to save flash space. * Related biosdir2_b will be skipped * automatically. */ pspdir2_b = NULL; /* More explicitly */ } pspdir = new_psp_dir(&ctx, &cb_config); integrate_psp_firmwares(&ctx, pspdir, pspdir2, pspdir2_b, amd_psp_fw_table, PSP_COOKIE, &cb_config); } else { /* flat: PSP 1 cookie and no pointer to 2nd table */ pspdir = new_psp_dir(&ctx, &cb_config); integrate_psp_firmwares(&ctx, pspdir, NULL, NULL, amd_psp_fw_table, PSP_COOKIE, &cb_config); } if (!cb_config.use_combo) { fill_psp_directory_to_efs(amd_romsig, pspdir, &ctx, &cb_config); } else { fill_psp_directory_to_efs(amd_romsig, psp_combo_dir, &ctx, &cb_config); /* 0 -Compare PSP ID, 1 -Compare chip family ID */ assert_fw_entry(combo_index, MAX_COMBO_ENTRIES, &ctx); psp_combo_dir->entries[combo_index].id_sel = 0; psp_combo_dir->entries[combo_index].id = get_psp_id(cb_config.soc_id); psp_combo_dir->entries[combo_index].lvl2_addr = BUFF_TO_RUN_MODE(ctx, pspdir, AMD_ADDR_REL_BIOS); fill_dir_header(psp_combo_dir, combo_index + 1, PSP2_COOKIE, &ctx, &cb_config); } if (have_bios_tables(amd_bios_table)) { bios_directory_table *biosdir = NULL; if (cb_config.multi_level) { /* Do 2nd level BIOS directory followed by 1st */ bios_directory_table *biosdir2 = NULL; bios_directory_table *biosdir2_b = NULL; biosdir2 = new_bios_dir(&ctx, cb_config.multi_level); integrate_bios_firmwares(&ctx, biosdir2, NULL, amd_bios_table, BHDL2_COOKIE, &cb_config); if (cb_config.recovery_ab) { if (pspdir2_b != NULL) { biosdir2_b = new_bios_dir(&ctx, cb_config.multi_level); integrate_bios_firmwares(&ctx, biosdir2_b, NULL, amd_bios_table, BHDL2_COOKIE, &cb_config); } add_psp_firmware_entry(&ctx, pspdir2, biosdir2, AMD_FW_BIOS_TABLE, TABLE_ALIGNMENT); if (pspdir2_b != NULL) add_psp_firmware_entry(&ctx, pspdir2_b, biosdir2_b, AMD_FW_BIOS_TABLE, TABLE_ALIGNMENT); } else { biosdir = new_bios_dir(&ctx, cb_config.multi_level); integrate_bios_firmwares(&ctx, biosdir, biosdir2, amd_bios_table, BHD_COOKIE, &cb_config); } } else { /* flat: BHD1 cookie and no pointer to 2nd table */ biosdir = new_bios_dir(&ctx, cb_config.multi_level); integrate_bios_firmwares(&ctx, biosdir, NULL, amd_bios_table, BHD_COOKIE, &cb_config); } if (!cb_config.use_combo) { fill_bios_directory_to_efs(amd_romsig, biosdir, &ctx, &cb_config); } else { fill_bios_directory_to_efs(amd_romsig, bhd_combo_dir, &ctx, &cb_config); assert_fw_entry(combo_index, MAX_COMBO_ENTRIES, &ctx); bhd_combo_dir->entries[combo_index].id_sel = 0; bhd_combo_dir->entries[combo_index].id = get_psp_id(cb_config.soc_id); bhd_combo_dir->entries[combo_index].lvl2_addr = BUFF_TO_RUN_MODE(ctx, biosdir, AMD_ADDR_REL_BIOS); fill_dir_header(bhd_combo_dir, combo_index + 1, BHD2_COOKIE, &ctx, &cb_config); } } } while (cb_config.use_combo && ++combo_index < MAX_COMBO_ENTRIES && cb_config.combo_config[combo_index] != NULL); targetfd = open(cb_config.output, O_RDWR | O_CREAT | O_TRUNC, 0666); if (targetfd >= 0) { uint32_t offset = cb_config.efs_location; uint32_t bytes = cb_config.efs_location == cb_config.body_location ? ctx.current - offset : sizeof(*amd_romsig); uint32_t ret_bytes; ret_bytes = write_from_buf_to_file(targetfd, BUFF_OFFSET(ctx, offset), bytes); if (bytes != ret_bytes) { fprintf(stderr, "Error: Writing to file %s failed\n", cb_config.output); retval = 1; } close(targetfd); } else { fprintf(stderr, "Error: could not open file: %s\n", cb_config.output); retval = 1; } if (cb_config.efs_location != cb_config.body_location) { ssize_t bytes; bytes = write_body(cb_config.output, BUFF_OFFSET(ctx, cb_config.body_location), ctx.current - cb_config.body_location); if (bytes != ctx.current - cb_config.body_location) { fprintf(stderr, "Error: Writing body\n"); retval = 1; } } if (cb_config.manifest_file) { dump_blob_version(cb_config.manifest_file, amd_psp_fw_table); } amdfwtool_cleanup(&ctx); return retval; }