#include "ggml.h" #include /* abort() */ #include #include #include #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif #include "xxhash/xxhash.h" #include "sha1/sha1.h" #include "sha256/sha256.h" #ifdef __cplusplus } #endif // uuid.uuid5(uuid.NAMESPACE_URL, 'en.wikipedia.org/wiki/Llama.cpp') #define UUID_NAMESPACE_LLAMA_CPP "ef001206-dadc-5f6d-a15f-3359e577d4e5" #define UUID_NAMESPACE_LLAMA_CPP_HEX 0xef, 0x00, 0x12, 0x06, 0xda, 0xdc, 0x5f, 0x6d, 0xa1, 0x5f, 0x33, 0x59, 0xe5, 0x77, 0xd4, 0xe5 #define HASH_TYPE_SHA256_STR "sha256" #define HASH_TYPE_SHA1_STR "sha1" #define HASH_TYPE_XXH64_STR "xxh64" #define HASH_TYPE_UUID_STR "uuid" typedef enum { HASH_EXIT_SUCCESS = 0, // All hash has been generated or validated HASH_EXIT_FAILURE = 1, // Generic Failure HASH_EXIT_MISMATCH = 2, // Hash mismatched during validation HASH_EXIT_MANIFEST_MISSING_ENTRY = 3, // Hash attempted validation but missing entry in manifest HASH_EXIT_MANIFEST_UNKNOWN_HASH = 4, // Manifest is present, but we do not know any hash format within it HASH_EXIT_MANIFEST_FILE_ERROR = 5 // Manifest is either missing or not a known format } hash_exit_code_t; typedef enum { HASH_MANIFEST_NOT_FOUND, HASH_MANIFEST_MISMATCH, HASH_MANIFEST_OK, } hash_manifest_result_t; struct hash_params { std::string input; bool xxh64 = false; bool sha1 = false; bool sha256 = false; bool uuid = false; bool no_layer = false; bool manifest_is_usable = false; std::string manifest_file; }; struct manifest_check_params { bool xxh64 = false; bool sha1 = false; bool sha256 = false; bool uuid = false; }; static char const * hash_manifest_result_to_str(hash_manifest_result_t value) { switch (value) { case HASH_MANIFEST_NOT_FOUND: return "Not Found"; case HASH_MANIFEST_MISMATCH: return "Mismatch"; case HASH_MANIFEST_OK: return "Ok"; } return "?"; } static char const * hash_exit_code_to_str(hash_exit_code_t value) { switch (value) { case HASH_EXIT_SUCCESS: return "Success"; case HASH_EXIT_FAILURE: return "Failure"; case HASH_EXIT_MISMATCH: return "Mismatch"; case HASH_EXIT_MANIFEST_MISSING_ENTRY: return "Manifest Missing Entry"; case HASH_EXIT_MANIFEST_UNKNOWN_HASH: return "Manifest Unknown Hash"; case HASH_EXIT_MANIFEST_FILE_ERROR: return "Manifest File Error"; } return "?"; } static void hash_print_usage(const char * executable) { const hash_params default_params; printf("\n"); printf("usage: %s [options] GGUF_IN\n", executable); printf("\n"); printf("Hash a GGUF file"); printf("\n"); printf("options:\n"); printf(" -h, --help show this help message and exit\n"); printf(" --xxh64 use xxh64 hash\n"); printf(" --sha1 use sha1 hash\n"); printf(" --sha256 use sha256 hash\n"); printf(" --all use all hash\n"); printf(" --no-layer exclude per layer hash\n"); printf(" --uuid generate UUIDv5 ID\n"); printf(" -c, --check verify against a manifest\n"); printf("\n"); } static void hash_params_parse_ex(int argc, const char ** argv, hash_params & params) { std::string arg; bool invalid_param = false; const std::string arg_prefix = "--"; int arg_idx = 1; for (; arg_idx < argc && strncmp(argv[arg_idx], "--", 2) == 0; arg_idx++) { arg = argv[arg_idx]; if (arg.compare(0, arg_prefix.size(), arg_prefix) == 0) { std::replace(arg.begin(), arg.end(), '_', '-'); } bool arg_found = false; if (arg == "-h" || arg == "--help") { hash_print_usage(argv[0]); exit(0); } if (arg == "--xxh64") { arg_found = true; params.xxh64 = true; } if (arg == "--sha1") { arg_found = true; params.sha1 = true; } if (arg == "--uuid") { arg_found = true; params.uuid = true; } if (arg == "--sha256") { arg_found = true; params.sha256 = true; } if (arg == "--all") { arg_found = true; params.sha256 = true; params.sha1 = true; params.xxh64 = true; } if (arg == "--no-layer") { arg_found = true; params.no_layer = true; } if (arg == "-c" || arg == "--check") { if (++arg_idx >= argc) { invalid_param = true; break; } arg_found = true; params.manifest_file = argv[arg_idx]; } if (!arg_found) { throw std::invalid_argument("error: unknown argument: " + arg); } } if (invalid_param) { throw std::invalid_argument("error: invalid parameter for argument:" + arg); } if (argc - arg_idx < 1) { throw std::invalid_argument("error: bad arguments"); } params.input = argv[arg_idx++]; } static bool hash_params_parse(int argc, const char ** argv, hash_params & params) { bool result = true; try { hash_params_parse_ex(argc, argv, params); } catch (const std::invalid_argument & ex) { fprintf(stderr, "%s\n", ex.what()); hash_print_usage(argv[0]); exit(EXIT_FAILURE); } return result; } static bool manifest_type(const std::string & manifest_file, manifest_check_params & manifest_check) { if (manifest_file.empty()) { return false; } std::ifstream file(manifest_file); if (!file.is_open()) { return false; } std::string manifest_entry_line; while (getline(file, manifest_entry_line)) { // hash_type_str hash_str tensor_name // e.g. 'xxh64 f66e9cd66a4396a0 test.gguf:tensor_0' std::istringstream line_stream(manifest_entry_line); std::string file_hash_type; if (line_stream >> file_hash_type) { if (file_hash_type == HASH_TYPE_SHA256_STR) { manifest_check.sha256 = true; } else if (file_hash_type == HASH_TYPE_SHA1_STR) { manifest_check.sha1 = true; } else if (file_hash_type == HASH_TYPE_XXH64_STR) { manifest_check.xxh64 = true; } else if (file_hash_type == HASH_TYPE_UUID_STR) { manifest_check.uuid = true; } } } return true; } static hash_manifest_result_t manifest_verify(const std::string& manifest_file, const std::string& hash_type_str, const std::string& hash_str, const std::string& tensor_name) { if (manifest_file.empty()) { return HASH_MANIFEST_NOT_FOUND; } std::ifstream file(manifest_file); if (!file.is_open()) { return HASH_MANIFEST_NOT_FOUND; } std::string manifest_entry_line; while (getline(file, manifest_entry_line)) { std::istringstream line_stream(manifest_entry_line); std::string file_hash_type; std::string file_hash; std::string file_tensor_name; if (line_stream >> file_hash_type >> file_hash >> file_tensor_name) { // Line parsed. Check hash validity if (file_hash_type != hash_type_str) { continue; } if (file_tensor_name != tensor_name) { continue; } return (file_hash == hash_str) ? HASH_MANIFEST_OK : HASH_MANIFEST_MISMATCH; } } return HASH_MANIFEST_NOT_FOUND; } static void generate_uuidv5(const unsigned char sha1_digest[20], unsigned char uuid[16]) { // Ref: https://www.rfc-editor.org/rfc/rfc9562.html#section-5.5 // Assumes that digest was processed correctly with the expected namespace for (int i = 0; i < 16; i++) { uuid[i] = sha1_digest[i]; } // Set bits corresponding to UUID ver 5 uuid[ 6] &= ~(0xF << 4); uuid[ 6] |= (5 << 4); // Set bits corresponding to UUID variant 0b10XX uuid[ 8] &= ~(0xc << 4); uuid[ 8] |= (0x8 << 4); } static hash_exit_code_t gguf_hash(const hash_params & hash_params) { const std::string & fname = hash_params.input; struct ggml_context * ctx_data = NULL; struct gguf_init_params params = { /*.no_alloc = */ false, /*.ctx = */ &ctx_data, }; // xxh64 init XXH64_state_t* xxh64_model_hash_state = NULL; if (hash_params.xxh64) { xxh64_model_hash_state = XXH64_createState(); if (xxh64_model_hash_state==NULL) { abort(); } XXH64_hash_t const seed = 0; if (XXH64_reset(xxh64_model_hash_state, seed) == XXH_ERROR) { abort(); } } // sha1 init SHA1_CTX sha1_model_hash_ctx; if (hash_params.sha1) { SHA1Init(&sha1_model_hash_ctx); } // sha256 init sha256_t sha256_model_hash_ctx; if (hash_params.sha256) { sha256_init(&sha256_model_hash_ctx); } // sha1 for uuid init SHA1_CTX sha1_for_uuid_ctx; if (hash_params.uuid) { unsigned char const uuidv5_namespace[] = {UUID_NAMESPACE_LLAMA_CPP_HEX}; SHA1Init(&sha1_for_uuid_ctx); SHA1Update( &sha1_for_uuid_ctx, (unsigned char const *)uuidv5_namespace, sizeof(uuidv5_namespace)); } struct gguf_context * ctx = gguf_init_from_file(fname.c_str(), params); const int n_tensors = gguf_get_n_tensors(ctx); bool tensor_layer_in_manifest = false; bool model_in_manifest = false; bool tensor_layer_has_mismatch = false; bool model_has_mismatch = false; for (int i = 0; i < n_tensors; ++i) { const char * name = gguf_get_tensor_name(ctx, i); struct ggml_tensor * cur = ggml_get_tensor(ctx_data, name); auto n_bytes = ggml_nbytes(cur); auto *raw_data = cur->data; const std::string tensor_layer_name = fname + ":" + name; if (hash_params.xxh64) { if (!hash_params.no_layer) { // Per Layer Hash XXH64_hash_t hash = XXH64(raw_data, n_bytes, 0); char hex_result[17]; for (int offset = 0; offset < 8; offset++) { unsigned int shift_bits_by = (8 * (8 - offset - 1)); sprintf( ( hex_result + (2*offset)), "%02x", (unsigned char) (hash >> shift_bits_by)&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_XXH64_STR, hex_result, tensor_layer_name); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: tensor_layer_in_manifest = true; tensor_layer_has_mismatch = true; break; case HASH_MANIFEST_OK: tensor_layer_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_XXH64_STR, hex_result, tensor_layer_name.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_XXH64_STR, hex_result, tensor_layer_name.c_str()); } } // Overall Model Hash if (XXH64_update(xxh64_model_hash_state, raw_data, n_bytes) == XXH_ERROR) abort(); } if (hash_params.sha1) { if (!hash_params.no_layer) { // Per Layer Hash char result[21]; // sha1 outputs 20 bytes SHA1( result, (const char *)raw_data, n_bytes); char hex_result[41] = {0}; for (int offset = 0; offset < 20; offset++) { sprintf( ( hex_result + (2*offset)), "%02x", result[offset]&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_SHA1_STR, hex_result, tensor_layer_name); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: tensor_layer_in_manifest = true; tensor_layer_has_mismatch = true; break; case HASH_MANIFEST_OK: tensor_layer_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_SHA1_STR, hex_result, tensor_layer_name.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_SHA1_STR, hex_result, tensor_layer_name.c_str()); } } // Overall Model Hash SHA1Update( &sha1_model_hash_ctx, (unsigned char const *)raw_data, n_bytes); } if (hash_params.sha256) { if (!hash_params.no_layer) { // Per Layer Hash unsigned char result[SHA256_DIGEST_SIZE]; // sha256 outputs 32 bytes sha256_hash((unsigned char*) result, (const unsigned char *)raw_data, n_bytes); char hex_result[SHA256_DIGEST_SIZE * 2 + 1] = {0}; for (int offset = 0; offset < SHA256_DIGEST_SIZE; offset++) { sprintf( ( hex_result + (2*offset)), "%02x", result[offset]&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_SHA256_STR, hex_result, tensor_layer_name); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: tensor_layer_in_manifest = true; tensor_layer_has_mismatch = true; break; case HASH_MANIFEST_OK: tensor_layer_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_SHA256_STR, hex_result, tensor_layer_name.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_SHA256_STR, hex_result, tensor_layer_name.c_str()); } } // Overall Model Hash sha256_update( &sha256_model_hash_ctx, (unsigned char const *)raw_data, n_bytes); } if (hash_params.uuid) { SHA1Update( &sha1_for_uuid_ctx, (unsigned char const *)raw_data, n_bytes); } } if (hash_params.xxh64) { XXH64_hash_t const hash = XXH64_digest(xxh64_model_hash_state); char hex_result[17]; for (int offset = 0; offset < 8; offset++) { unsigned int shift_bits_by = (8 * (8 - offset - 1)); sprintf( ( hex_result + (2*offset)), "%02x", (unsigned char) (hash >> shift_bits_by)&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_XXH64_STR, hex_result, fname); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: model_in_manifest = true; model_has_mismatch = true; break; case HASH_MANIFEST_OK: model_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_XXH64_STR, hex_result, fname.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_XXH64_STR, hex_result, fname.c_str()); } } if (hash_params.sha1) { unsigned char result[21]; SHA1Final(result, &sha1_model_hash_ctx); char hex_result[41]; for (int offset = 0; offset < 20; offset++) { sprintf( ( hex_result + (2*offset)), "%02x", result[offset]&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_SHA1_STR, hex_result, fname); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: model_in_manifest = true; model_has_mismatch = true; break; case HASH_MANIFEST_OK: model_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_SHA1_STR, hex_result, fname.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_SHA1_STR, hex_result, fname.c_str()); } } if (hash_params.sha256) { unsigned char result[SHA256_DIGEST_SIZE]; // sha256 outputs 32 bytes sha256_final( &sha256_model_hash_ctx, result); char hex_result[SHA256_DIGEST_SIZE * 2 + 1] = {0}; for (int offset = 0; offset < SHA256_DIGEST_SIZE; offset++) { sprintf( ( hex_result + (2*offset)), "%02x", result[offset]&0xff); } if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_SHA256_STR, hex_result, fname); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: model_in_manifest = true; model_has_mismatch = true; break; case HASH_MANIFEST_OK: model_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_SHA256_STR, hex_result, fname.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_SHA256_STR, hex_result, fname.c_str()); } } if (hash_params.uuid) { unsigned char result[21]; SHA1Final(result, &sha1_for_uuid_ctx); unsigned char uuid[16]; generate_uuidv5(result, uuid); char string_buffer[37] = {0}; sprintf(string_buffer, "%02x%02x%02x%02x-%02x%02x-%02x%02x-%02x%02x-%02x%02x%02x%02x%02x%02x", uuid[0], uuid[1], uuid[2], uuid[3], uuid[4], uuid[5], uuid[6], uuid[7], uuid[8], uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14], uuid[15]); if (hash_params.manifest_is_usable) { hash_manifest_result_t verify_result = manifest_verify(hash_params.manifest_file, HASH_TYPE_SHA256_STR, string_buffer, fname); switch (verify_result) { case HASH_MANIFEST_NOT_FOUND: break; case HASH_MANIFEST_MISMATCH: model_in_manifest = true; model_has_mismatch = true; break; case HASH_MANIFEST_OK: model_in_manifest = true; break; } printf("%-8s %-s %s - %s\n", HASH_TYPE_UUID_STR, string_buffer, fname.c_str(), hash_manifest_result_to_str(verify_result)); } else { printf("%-8s %-s %s\n", HASH_TYPE_UUID_STR, string_buffer, fname.c_str()); } } ggml_free(ctx_data); gguf_free(ctx); if (hash_params.manifest_is_usable) { // In hash verification mode if (!model_in_manifest) { // model missing in manifest? // Check tensor layer... if (!tensor_layer_in_manifest) { // Still missing? Maybe we are reading the wrong manifest. return HASH_EXIT_MANIFEST_MISSING_ENTRY; } if (tensor_layer_has_mismatch) { // Per tensor check found error return HASH_EXIT_FAILURE; } // All per tensor layer checks passed? Sounds good enough. return HASH_EXIT_SUCCESS; } // Overall model check passed, but let's check per layer just in case // If missing, we don't care too much as the overall model checked if (tensor_layer_in_manifest && tensor_layer_has_mismatch) { return HASH_EXIT_FAILURE; } if (model_has_mismatch) { // model has failed hash somewhere in the model return HASH_EXIT_FAILURE; } // All checks appears to be fine return HASH_EXIT_SUCCESS; } // In hash generation mode return HASH_EXIT_SUCCESS; } int main(int argc, const char ** argv) { hash_params params; manifest_check_params manifest_check; hash_params_parse(argc, argv, params); if (!params.manifest_file.empty()) { if (!manifest_type(params.manifest_file, manifest_check)) { printf("ERROR cannot open manifest %s", params.manifest_file.c_str()); return HASH_EXIT_MANIFEST_FILE_ERROR; } if (!manifest_check.sha256 && !manifest_check.sha1 && !manifest_check.xxh64 && !manifest_check.uuid) { printf("ERROR manifest does not have any known hash format in %s", params.manifest_file.c_str()); return HASH_EXIT_MANIFEST_UNKNOWN_HASH; } printf("manifest %s", params.manifest_file.c_str()); if (manifest_check.sha256) { printf(" sha256"); } if (manifest_check.sha1) { printf(" sha1"); } if (manifest_check.xxh64) { printf(" xxh64"); } if (manifest_check.uuid) { printf(" uuid"); } printf("\n"); // Autoselect the highest security hash if manifest is provided but // the user has not specifically defined the hash they care about if (!params.xxh64 && !params.sha1 && !params.uuid && !params.sha256) { // User has not selected a specific value, pick most secure hash if (manifest_check.sha256) { params.sha256 = true; } else if (manifest_check.sha1) { params.sha1 = true; } else if (manifest_check.xxh64) { params.xxh64 = true; } else if (manifest_check.uuid) { params.uuid = true; } } params.manifest_is_usable = true; } // By default if no swich argument provided, assume xxh64 if (!params.xxh64 && !params.sha1 && !params.uuid && !params.sha256) { params.xxh64 = true; } hash_exit_code_t exit_code = gguf_hash(params); if (params.manifest_is_usable) { printf("\nVerification results for %s - %s\n", params.manifest_file.c_str(), hash_exit_code_to_str(exit_code)); } return exit_code; }