// This file defines tests for various GGML ops and backends. // For the forward pass it asserts that the results of multiple backends computing the same GGML ops are consistent. // For the backward pass it asserts that the gradients from backpropagation are consistent // with the gradients obtained via the method of finite differences ("grad" mode, this is optional). // It is also possible to check the performance ("perf" mode). // // this file has three sections: Section 1 does general setup, section 2 defines the GGML ops to be tested, // and section 3 defines which tests to run. // Quick start for adding a new GGML op: Go to section 2 and create a struct that inherits from test_case, // then go to section 3 and add an instantiation of your struct. // ############################## // ## Section 1: General Setup ## // ############################## #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __EMSCRIPTEN__ # define N_THREADS 1 #else # define N_THREADS std::thread::hardware_concurrency() #endif static void init_tensor_uniform(ggml_tensor * tensor, float min = -1.0f, float max = 1.0f) { size_t nels = ggml_nelements(tensor); std::vector data(nels); { // parallel initialization static const size_t n_threads = N_THREADS; // static RNG initialization (revisit if n_threads stops being constant) static std::vector generators = []() { std::random_device rd; std::vector vec; vec.reserve(n_threads); //for (size_t i = 0; i < n_threads; i++) { vec.emplace_back(1234 + i); } // fixed seed for (size_t i = 0; i < n_threads; i++) { vec.emplace_back(rd()); } return vec; }(); auto init_thread = [&](size_t ith, size_t start, size_t end) { std::uniform_real_distribution distribution(min, max); auto & gen = generators[ith]; for (size_t i = start; i < end; i++) { data[i] = distribution(gen); } }; if (n_threads == 1) { init_thread(0, 0, nels); } else { std::vector> tasks; tasks.reserve(n_threads); for (size_t i = 0; i < n_threads; i++) { size_t start = i*nels/n_threads; size_t end = (i+1)*nels/n_threads; tasks.push_back(std::async(std::launch::async, init_thread, i, start, end)); } for (auto & t : tasks) { t.get(); } } } if (tensor->type == GGML_TYPE_F32 || tensor->type == GGML_TYPE_I32) { ggml_backend_tensor_set(tensor, data.data(), 0, nels * sizeof(float)); } else if (ggml_is_quantized(tensor->type) || tensor->type == GGML_TYPE_F16 || tensor->type == GGML_TYPE_BF16) { GGML_ASSERT(nels % ggml_blck_size(tensor->type) == 0); // dummy importance matrix std::vector imatrix(tensor->ne[0], 1.0f); const float * im = imatrix.data(); if (!ggml_quantize_requires_imatrix(tensor->type)) { // when the imatrix is optional, we want to test both quantization with and without imatrix // use one of the random numbers to decide if (data[0] > 0.5f*(min + max)) { im = nullptr; } } std::vector dataq(ggml_row_size(tensor->type, nels)); { // parallel quantization by block size_t blck_size = ggml_blck_size(tensor->type); size_t n_blocks = nels / blck_size; auto quantize_thread = [&](size_t start, size_t end) { ggml_quantize_chunk(tensor->type, data.data(), dataq.data(), start * blck_size, end - start, blck_size, im); }; const size_t min_blocks_per_thread = 1; const size_t n_quant_threads = std::min(std::max(N_THREADS/2, 1), std::max(1, n_blocks / min_blocks_per_thread)); if (n_quant_threads == 1) { // single-threaded quantization: do all blocks in the current thread quantize_thread(0, n_blocks); } else { std::vector> tasks; tasks.reserve(n_quant_threads); for (size_t i = 0; i < n_quant_threads; i++) { size_t start = i*n_blocks/n_quant_threads; size_t end = (i+1)*n_blocks/n_quant_threads; tasks.push_back(std::async(std::launch::async, quantize_thread, start, end)); } for (auto & t : tasks) { t.get(); } } } ggml_backend_tensor_set(tensor, dataq.data(), 0, dataq.size()); } else if (tensor->type == GGML_TYPE_I8 || tensor->type == GGML_TYPE_I16 || tensor->type == GGML_TYPE_I32) { // This is going to create some weird integers though. ggml_backend_tensor_set(tensor, data.data(), 0, ggml_nbytes(tensor)); } else if (tensor->type == GGML_TYPE_I64) { // Integers with a size of 8 bytes can be set by mirroring the float data, the specific values are again not really meaningful. const size_t nbytes_half = ggml_nbytes(tensor)/2; ggml_backend_tensor_set(tensor, data.data(), 0*nbytes_half, nbytes_half); ggml_backend_tensor_set(tensor, data.data(), 1*nbytes_half, nbytes_half); } else { GGML_ABORT("fatal error"); } } // generate an F16 mask where certain blocks are randomly masked with -INF value static void init_tensor_kq_mask(ggml_tensor * tensor, float min = -1.0f, float max = 1.0f) { GGML_ASSERT(tensor->type == GGML_TYPE_F16); GGML_TENSOR_LOCALS( int32_t, ne, tensor, ne); std::vector data_f32(ne0*ne1*ne2*ne3); std::vector data_f16(ne0*ne1*ne2*ne3); std::random_device rd; std::mt19937 gen(rd()); std::uniform_real_distribution dis(min, max); for (size_t i = 0; i < data_f32.size(); i++) { data_f32[i] = dis(gen); } // block size const int blck0 = 128; const int blck1 = 64; // number of INF/zero blocks const int n_inf_zero_blocks = 0.2*(ne0*ne1*ne2*ne3)/(blck0*blck1); for (int b = 0; b < n_inf_zero_blocks; b++) { const int p3 = (rd() % ne3); const int p2 = (rd() % ne2); const int p1 = (rd() % ne1); const int p0 = (rd() % ne0); bool inf = rd() & 1; for (int i1 = 0; i1 < blck1 && p1 + i1 < ne1; i1++) { const int idx = p3*ne2*ne1*ne0 + p2*ne1*ne0 + (p1 + i1)*ne0 + p0; for (int i0 = 0; i0 < blck0 && p0 + i0 < ne0; i0++) { data_f32[idx + i0] = inf ? -INFINITY : 0.0f; } } } ggml_fp32_to_fp16_row(data_f32.data(), data_f16.data(), ne0*ne1*ne2*ne3); ggml_backend_tensor_set(tensor, data_f16.data(), 0, data_f16.size()*sizeof(ggml_fp16_t)); } // generate a lower triangular matrix static void init_tensor_tril(ggml_tensor * tensor, float min = -1.0f, float max = 1.0f) { GGML_ASSERT(tensor->type == GGML_TYPE_F32); GGML_ASSERT(tensor->ne[0] == tensor->ne[1]); GGML_TENSOR_LOCALS(int32_t, ne, tensor, ne); GGML_TENSOR_LOCALS(size_t, nb, tensor, nb); std::vector data_f32(ne0*ne1*ne2*ne3); std::random_device rd; std::mt19937 gen(rd()); std::uniform_real_distribution dis(min, max); for (int64_t i3 = 0; i3 < ne3; i3++) { for (int64_t i2 = 0; i2 < ne2; i2++) { for (int64_t i1 = 0; i1 < ne1; i1++) { for (int64_t i0 = 0; i0 < ne0; i0++) { int64_t idx = (i0 * nb0 + i1 * nb1 + i2 * nb2 + i3 * nb3) / sizeof(float); if (i0 <= i1) { data_f32[idx] = dis(gen); } else { data_f32[idx] = 0.0f; } } } } } ggml_backend_tensor_set(tensor, data_f32.data(), 0, ggml_nbytes(tensor)); } static std::vector tensor_to_float(const ggml_tensor * t) { std::vector tv; tv.reserve(ggml_nelements(t)); std::vector buf(ggml_nbytes(t)); ggml_backend_tensor_get(t, buf.data(), 0, ggml_nbytes(t)); const auto * tt = ggml_get_type_traits(t->type); size_t bs = ggml_blck_size(t->type); std::vector vq(ggml_blck_size(t->type)); bool quantized = ggml_is_quantized(t->type); // access elements by index to avoid gaps in views for (int64_t i3 = 0; i3 < t->ne[3]; i3++) { for (int64_t i2 = 0; i2 < t->ne[2]; i2++) { for (int64_t i1 = 0; i1 < t->ne[1]; i1++) { for (int64_t i0 = 0; i0 < t->ne[0]; i0 += bs) { size_t i = i3*t->nb[3] + i2*t->nb[2] + i1*t->nb[1] + i0/bs*t->nb[0]; if (t->type == GGML_TYPE_F16) { tv.push_back(ggml_fp16_to_fp32(*(ggml_fp16_t*)&buf[i])); } else if (t->type == GGML_TYPE_BF16) { tv.push_back(ggml_bf16_to_fp32(*(ggml_bf16_t*)&buf[i])); } else if (t->type == GGML_TYPE_F32) { tv.push_back(*(float *) &buf[i]); } else if (t->type == GGML_TYPE_I64) { tv.push_back((float)*(int64_t *) &buf[i]); } else if (t->type == GGML_TYPE_I32) { tv.push_back((float)*(int32_t *) &buf[i]); } else if (t->type == GGML_TYPE_I16) { tv.push_back((float)*(int16_t *) &buf[i]); } else if (t->type == GGML_TYPE_I8) { tv.push_back((float)*(int8_t *) &buf[i]); } else if (quantized) { tt->to_float(&buf[i], vq.data(), bs); tv.insert(tv.end(), vq.begin(), vq.end()); } else { GGML_ABORT("fatal error"); } } } } } return tv; } // normalized mean squared error = mse(a, b) / mse(a, 0) static double nmse(const float * a, const float * b, size_t n) { double mse_a_b = 0.0; double mse_a_0 = 0.0; for (size_t i = 0; i < n; i++) { float a_i = a[i]; float b_i = b[i]; mse_a_b += (a_i - b_i) * (a_i - b_i); mse_a_0 += a_i * a_i; } return mse_a_b / mse_a_0; } // difference between 2 sets (Jaccard distance, 0 - no difference, 1 - no overlap) template static double jdst(const T * a, const T * b, size_t n) { std::unordered_map set_a; std::unordered_map set_b; for (size_t i = 0; i < n; ++i) { set_a[a[i]]++; set_b[b[i]]++; } size_t diff = 0; for (const auto & p : set_a) { const int64_t na = p.second; const int64_t nb = set_b.find(p.first) != set_b.end() ? set_b.at(p.first) : 0; diff += std::abs(na - nb); } for (const auto & p : set_b) { if (set_a.find(p.first) == set_a.end()) { diff += p.second; } } return (double) diff / (2*n); } // maximum absolute asymmetry between a and b // asymmetry: (a - b) / (a + b) // This is more stable than relative error if one of the values fluctuates towards zero. // n: number of values to compare. // expected_vals: optional vector of expected values for a. If expected_vals is not empty, filter out all comparisons where // a does not match any of the expected values. Needed for noncontinuous gradients where the numerical calculation can fail. static double mean_abs_asymm(const float * a, const float * b, const size_t n, const std::vector & expected_vals) { double sum = 0.0f; size_t nvalid = 0; for (size_t i = 0; i < n; i++) { if (!expected_vals.empty()) { bool matches_any = false; for (const float & ev : expected_vals) { if (fabsf(a[i] - ev) < 1e-3f) { matches_any = true; break; } } if (!matches_any) { continue; } } const float asymm = (a[i] - b[i]) / (a[i] + b[i]); sum += fabsf(asymm); nvalid++; } return sum/nvalid; } // utils for printing the variables of the test cases static std::string var_to_str(const std::string & x) { return x; } template static std::string var_to_str(const T & x) { return std::to_string(x); } template static std::string var_to_str(const T (&x)[N]) { std::string s = "["; for (size_t i = 0; i < N; i++) { if (i > 0) { s += ","; } s += var_to_str(x[i]); } s += "]"; return s; } template static std::string var_to_str(const std::array & x) { std::string s = "["; for (size_t i = 0; i < N; i++) { if (i > 0) { s += ","; } s += var_to_str(x[i]); } s += "]"; return s; } static std::string var_to_str(ggml_type type) { return ggml_type_name(type); } static std::string var_to_str(ggml_prec prec) { return prec == GGML_PREC_F32 ? "f32" : "def"; } static std::string var_to_str(ggml_op_pool pool) { switch (pool) { case GGML_OP_POOL_AVG: return "avg"; case GGML_OP_POOL_MAX: return "max"; default: return std::to_string(pool); } } static std::string var_to_str(ggml_scale_mode mode) { std::string str; switch (mode & 0xFF) { case GGML_SCALE_MODE_NEAREST: str = "nearest"; break; case GGML_SCALE_MODE_BILINEAR: str = "bilinear"; break; case GGML_SCALE_MODE_BICUBIC: str = "bicubic"; break; default: str = std::to_string(mode); break; } if (mode & GGML_SCALE_FLAG_ALIGN_CORNERS) { str += "|align_corners"; } if (mode & GGML_SCALE_FLAG_ANTIALIAS) { str += "|antialias"; } return str; } #define VAR_TO_STR(x) (#x "=" + var_to_str(x)) #define VARS_TO_STR1(a) VAR_TO_STR(a) #define VARS_TO_STR2(a, b) VAR_TO_STR(a) + "," + VAR_TO_STR(b) #define VARS_TO_STR3(a, b, c) VAR_TO_STR(a) + "," + VARS_TO_STR2(b, c) #define VARS_TO_STR4(a, b, c, d) VAR_TO_STR(a) + "," + VARS_TO_STR3(b, c, d) #define VARS_TO_STR5(a, b, c, d, e) VAR_TO_STR(a) + "," + VARS_TO_STR4(b, c, d, e) #define VARS_TO_STR6(a, b, c, d, e, f) VAR_TO_STR(a) + "," + VARS_TO_STR5(b, c, d, e, f) #define VARS_TO_STR7(a, b, c, d, e, f, g) VAR_TO_STR(a) + "," + VARS_TO_STR6(b, c, d, e, f, g) #define VARS_TO_STR8(a, b, c, d, e, f, g, h) VAR_TO_STR(a) + "," + VARS_TO_STR7(b, c, d, e, f, g, h) #define VARS_TO_STR9(a, b, c, d, e, f, g, h, i) VAR_TO_STR(a) + "," + VARS_TO_STR8(b, c, d, e, f, g, h, i) #define VARS_TO_STR10(a, b, c, d, e, f, g, h, i, j) VAR_TO_STR(a) + "," + VARS_TO_STR9(b, c, d, e, f, g, h, i, j) #define VARS_TO_STR11(a, b, c, d, e, f, g, h, i, j, k) VAR_TO_STR(a) + "," + VARS_TO_STR10(b, c, d, e, f, g, h, i, j, k) #define VARS_TO_STR12(a, b, c, d, e, f, g, h, i, j, k, l) VAR_TO_STR(a) + "," + VARS_TO_STR11(b, c, d, e, f, g, h, i, j, k, l) #define VARS_TO_STR13(a, b, c, d, e, f, g, h, i, j, k, l, m) VAR_TO_STR(a) + "," + VARS_TO_STR12(b, c, d, e, f, g, h, i, j, k, l, m) #define VARS_TO_STR14(a, b, c, d, e, f, g, h, i, j, k, l, m, n) VAR_TO_STR(a) + "," + VARS_TO_STR13(b, c, d, e, f, g, h, i, j, k, l, m, n) #define VARS_TO_STR15(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) VAR_TO_STR(a) + "," + VARS_TO_STR14(b, c, d, e, f, g, h, i, j, k, l, m, n, o) #define VARS_TO_STR16(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) VAR_TO_STR(a) + "," + VARS_TO_STR15(b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) #ifdef GGML_USE_SYCL static bool inline _isinf(float f) { return (*(uint32_t *)&f & 0x7fffffff) == 0x7f800000; } #else static bool inline _isinf(float f) { return std::isinf(f); } #endif // accept FLT_MAX as infinity static bool isinf_or_max(float f) { return _isinf(f) || f == FLT_MAX || f == -FLT_MAX; } static bool ggml_is_view_op(enum ggml_op op) { return op == GGML_OP_VIEW || op == GGML_OP_RESHAPE || op == GGML_OP_PERMUTE || op == GGML_OP_TRANSPOSE; } static bool backend_has_feature(ggml_backend_t backend, const char * feature_name) { ggml_backend_dev_t dev = ggml_backend_get_device(backend); ggml_backend_reg_t reg = ggml_backend_dev_backend_reg(dev); auto get_features = (ggml_backend_get_features_t) ggml_backend_reg_get_proc_address(reg, "ggml_backend_get_features"); if (!get_features) { return false; } const ggml_backend_feature * features = get_features(reg); if (!features) { return false; } for (const ggml_backend_feature * f = features; f->name; ++f) { if (strcmp(f->name, feature_name) == 0 && strcmp(f->value, "1") == 0) { return true; } } return false; } enum test_mode { MODE_TEST, MODE_PERF, MODE_GRAD, MODE_SUPPORT, }; // Output format support similar to llama-bench enum output_formats { CONSOLE, SQL, CSV }; static const char * output_format_str(output_formats format) { switch (format) { case CONSOLE: return "console"; case SQL: return "sql"; case CSV: return "csv"; default: GGML_ABORT("invalid output format"); } } static bool output_format_from_str(const std::string & s, output_formats & format) { if (s == "console") { format = CONSOLE; } else if (s == "sql") { format = SQL; } else if (s == "csv") { format = CSV; } else { return false; } return true; } // Test result structure for SQL output struct test_result { std::string test_time; std::string build_commit; std::string backend_name; std::string op_name; std::string op_params; std::string test_mode; bool supported; bool passed; std::string error_message; double time_us; double flops; double bandwidth_gb_s; size_t memory_kb; int n_runs; std::string device_description; std::string backend_reg_name; test_result() { // Initialize with default values time_us = 0.0; flops = 0.0; bandwidth_gb_s = 0.0; memory_kb = 0; n_runs = 0; supported = false; passed = false; // Set test time time_t t = time(NULL); char buf[32]; std::strftime(buf, sizeof(buf), "%FT%TZ", gmtime(&t)); test_time = buf; // Set build info build_commit = ggml_commit(); } test_result(const std::string & backend_name, const std::string & op_name, const std::string & op_params, const std::string & test_mode, bool supported, bool passed, const std::string & error_message = "", double time_us = 0.0, double flops = 0.0, double bandwidth_gb_s = 0.0, size_t memory_kb = 0, int n_runs = 0, const std::string & device_description = "", const std::string & backend_reg_name = "") : backend_name(backend_name), op_name(op_name), op_params(op_params), test_mode(test_mode), supported(supported), passed(passed), error_message(error_message), time_us(time_us), flops(flops), bandwidth_gb_s(bandwidth_gb_s), memory_kb(memory_kb), n_runs(n_runs), device_description(device_description), backend_reg_name(backend_reg_name) { // Set test time time_t t = time(NULL); char buf[32]; std::strftime(buf, sizeof(buf), "%FT%TZ", gmtime(&t)); test_time = buf; // Set build info build_commit = ggml_commit(); } static const std::vector & get_fields() { static const std::vector fields = { "test_time", "build_commit", "backend_name", "op_name", "op_params", "test_mode", "supported", "passed", "error_message", "time_us", "flops", "bandwidth_gb_s", "memory_kb", "n_runs", "device_description", "backend_reg_name" }; return fields; } enum field_type { STRING, BOOL, INT, FLOAT }; static field_type get_field_type(const std::string & field) { if (field == "supported" || field == "passed") { return BOOL; } if (field == "memory_kb" || field == "n_runs") { return INT; } if (field == "time_us" || field == "flops" || field == "bandwidth_gb_s") { return FLOAT; } return STRING; } std::vector get_values() const { return { test_time, build_commit, backend_name, op_name, op_params, test_mode, std::to_string(supported), std::to_string(passed), error_message, std::to_string(time_us), std::to_string(flops), std::to_string(bandwidth_gb_s), std::to_string(memory_kb), std::to_string(n_runs), device_description, backend_reg_name }; } }; // Printer classes for different output formats enum class test_status_t { NOT_SUPPORTED, OK, FAIL, SKIPPED }; struct test_operation_info { std::string op_name; std::string op_params; std::string backend_name; test_status_t status = test_status_t::OK; std::string failure_reason; // Additional information fields that were previously in separate structs std::string error_component; std::string error_details; // Gradient info int64_t gradient_index = -1; std::string gradient_param_name; float gradient_value = 0.0f; // MAA error info double maa_error = 0.0; double maa_threshold = 0.0; // Flags for different types of information bool has_error = false; bool has_gradient_info = false; bool has_maa_error = false; bool is_compare_failure = false; bool is_large_tensor_skip = false; test_operation_info() = default; test_operation_info(const std::string & op_name, const std::string & op_params, const std::string & backend_name, test_status_t status = test_status_t::OK, const std::string & failure_reason = "") : op_name(op_name), op_params(op_params), backend_name(backend_name), status(status), failure_reason(failure_reason) {} // Set error information void set_error(const std::string & component, const std::string & details) { has_error = true; error_component = component; error_details = details; if (status == test_status_t::OK) { status = test_status_t::FAIL; } } // Set gradient information void set_gradient_info(int64_t index, const std::string & param_name, float value) { has_gradient_info = true; gradient_index = index; gradient_param_name = param_name; gradient_value = value; if (status == test_status_t::OK) { status = test_status_t::FAIL; } } // Set MAA error information void set_maa_error(double error, double threshold) { has_maa_error = true; maa_error = error; maa_threshold = threshold; if (status == test_status_t::OK) { status = test_status_t::FAIL; } } // Set compare failure void set_compare_failure() { is_compare_failure = true; if (status == test_status_t::OK) { status = test_status_t::FAIL; } } // Set large tensor skip void set_large_tensor_skip() { is_large_tensor_skip = true; } }; struct test_summary_info { size_t tests_passed; size_t tests_total; bool is_backend_summary = false; // true for backend summary, false for test summary test_summary_info() = default; test_summary_info(size_t tests_passed, size_t tests_total, bool is_backend_summary = false) : tests_passed(tests_passed), tests_total(tests_total), is_backend_summary(is_backend_summary) {} }; struct testing_start_info { size_t device_count; testing_start_info() = default; testing_start_info(size_t device_count) : device_count(device_count) {} }; struct backend_init_info { size_t device_index; size_t total_devices; std::string device_name; bool skipped = false; std::string skip_reason; std::string description; size_t memory_total_mb = 0; size_t memory_free_mb = 0; bool has_memory_info = false; backend_init_info() = default; backend_init_info(size_t device_index, size_t total_devices, const std::string & device_name, bool skipped = false, const std::string & skip_reason = "", const std::string & description = "", size_t memory_total_mb = 0, size_t memory_free_mb = 0, bool has_memory_info = false) : device_index(device_index), total_devices(total_devices), device_name(device_name), skipped(skipped), skip_reason(skip_reason), description(description), memory_total_mb(memory_total_mb), memory_free_mb(memory_free_mb), has_memory_info(has_memory_info) {} }; struct backend_status_info { std::string backend_name; test_status_t status; backend_status_info() = default; backend_status_info(const std::string & backend_name, test_status_t status) : backend_name(backend_name), status(status) {} }; struct overall_summary_info { size_t backends_passed; size_t backends_total; bool all_passed; overall_summary_info() = default; overall_summary_info(size_t backends_passed, size_t backends_total, bool all_passed) : backends_passed(backends_passed), backends_total(backends_total), all_passed(all_passed) {} }; struct printer { virtual ~printer() {} FILE * fout = stdout; virtual void print_header() {} virtual void print_test_result(const test_result & result) = 0; virtual void print_footer() {} virtual void print_operation(const test_operation_info & info) { (void) info; } virtual void print_summary(const test_summary_info & info) { (void) info; } virtual void print_testing_start(const testing_start_info & info) { (void) info; } virtual void print_backend_init(const backend_init_info & info) { (void) info; } virtual void print_backend_status(const backend_status_info & info) { (void) info; } virtual void print_overall_summary(const overall_summary_info & info) { (void) info; } virtual void print_failed_tests(const std::vector & failed_tests) { (void) failed_tests; } }; struct console_printer : public printer { void print_test_result(const test_result & result) override { if (result.test_mode == "test") { print_test_console(result); } else if (result.test_mode == "perf") { print_perf_console(result); } else if (result.test_mode == "support") { print_support_console(result); } } void print_operation(const test_operation_info & info) override { printf(" %s(%s): ", info.op_name.c_str(), info.op_params.c_str()); fflush(stdout); // Handle large tensor skip first if (info.is_large_tensor_skip) { printf("skipping large tensors for speed \n"); return; } // Handle not supported status if (info.status == test_status_t::NOT_SUPPORTED) { if (!info.failure_reason.empty()) { printf("not supported [%s]\n", info.failure_reason.c_str()); } else { printf("not supported [%s]\n", info.backend_name.c_str()); } return; } // Handle errors and additional information if (info.has_error) { if (info.error_component == "allocation") { fprintf(stderr, "failed to allocate tensors [%s] ", info.backend_name.c_str()); } else if (info.error_component == "backend") { fprintf(stderr, " Failed to initialize %s backend\n", info.backend_name.c_str()); } else { fprintf(stderr, "Error in %s: %s\n", info.error_component.c_str(), info.error_details.c_str()); } } // Handle gradient info if (info.has_gradient_info) { printf("[%s] nonfinite gradient at index %" PRId64 " (%s=%f) ", info.op_name.c_str(), info.gradient_index, info.gradient_param_name.c_str(), info.gradient_value); } // Handle MAA error if (info.has_maa_error) { printf("[%s] MAA = %.9f > %.9f ", info.op_name.c_str(), info.maa_error, info.maa_threshold); } // Handle compare failure if (info.is_compare_failure) { printf("compare failed "); } // Print final status if (info.status == test_status_t::OK) { printf("\033[1;32mOK\033[0m\n"); } else { printf("\033[1;31mFAIL\033[0m\n"); } } void print_summary(const test_summary_info & info) override { if (info.is_backend_summary) { printf("%zu/%zu backends passed\n", info.tests_passed, info.tests_total); } else { printf(" %zu/%zu tests passed\n", info.tests_passed, info.tests_total); } } void print_backend_status(const backend_status_info & info) override { printf(" Backend %s: ", info.backend_name.c_str()); if (info.status == test_status_t::OK) { printf("\033[1;32mOK\033[0m\n"); } else { printf("\033[1;31mFAIL\033[0m\n"); } } void print_testing_start(const testing_start_info & info) override { printf("Testing %zu devices\n\n", info.device_count); } void print_backend_init(const backend_init_info & info) override { printf("Backend %zu/%zu: %s\n", info.device_index + 1, info.total_devices, info.device_name.c_str()); if (info.skipped) { printf(" %s\n", info.skip_reason.c_str()); return; } if (!info.description.empty()) { printf(" Device description: %s\n", info.description.c_str()); } if (info.has_memory_info) { printf(" Device memory: %zu MB (%zu MB free)\n", info.memory_total_mb, info.memory_free_mb); } printf("\n"); } void print_overall_summary(const overall_summary_info & info) override { printf("%zu/%zu backends passed\n", info.backends_passed, info.backends_total); if (info.all_passed) { printf("\033[1;32mOK\033[0m\n"); } else { printf("\033[1;31mFAIL\033[0m\n"); } } void print_failed_tests(const std::vector & failed_tests) override { if (failed_tests.empty()) { return; } printf("\nFailing tests:\n"); for (const auto & test_name : failed_tests) { printf(" %s\n", test_name.c_str()); } } private: void print_test_console(const test_result & result) { printf(" %s(%s): ", result.op_name.c_str(), result.op_params.c_str()); fflush(stdout); if (!result.supported) { printf("not supported [%s] ", result.backend_name.c_str()); printf("\n"); return; } if (result.passed) { printf("\033[1;32mOK\033[0m\n"); } else { printf("\033[1;31mFAIL\033[0m\n"); } } void print_perf_console(const test_result & result) { int len = printf(" %s(%s): ", result.op_name.c_str(), result.op_params.c_str()); fflush(stdout); if (!result.supported) { printf("not supported\n"); return; } // align while also leaving some margin for variations in parameters int align = 8; int last = (len + align - 1) / align * align; if (last - len < 5) { last += align; } printf("%*s", last - len, ""); printf(" %8d runs - %8.2f us/run - ", result.n_runs, result.time_us); if (result.flops > 0) { auto format_flops = [](double flops) -> std::string { char buf[256]; if (flops >= 1e12) { snprintf(buf, sizeof(buf), "%6.2f TFLOP", flops / 1e12); } else if (flops >= 1e9) { snprintf(buf, sizeof(buf), "%6.2f GFLOP", flops / 1e9); } else if (flops >= 1e6) { snprintf(buf, sizeof(buf), "%6.2f MFLOP", flops / 1e6); } else { snprintf(buf, sizeof(buf), "%6.2f kFLOP", flops / 1e3); } return buf; }; uint64_t op_flops_per_run = result.flops * result.time_us / 1e6; printf("%s/run - \033[1;34m%sS\033[0m", format_flops(op_flops_per_run).c_str(), format_flops(result.flops).c_str()); } else { printf("%8zu kB/run - \033[1;34m%7.2f GB/s\033[0m", result.memory_kb, result.bandwidth_gb_s); } printf("\n"); } void print_support_console(const test_result & result) { printf(" %s(%s): ", result.op_name.c_str(), result.op_params.c_str()); fflush(stdout); if (result.supported) { printf("\033[1;32mSUPPORTED\033[0m\n"); } else { printf("\033[1;31mNOT SUPPORTED\033[0m\n"); } } }; struct sql_printer : public printer { static std::string get_sql_field_type(const std::string & field) { switch (test_result::get_field_type(field)) { case test_result::STRING: return "TEXT"; case test_result::BOOL: case test_result::INT: return "INTEGER"; case test_result::FLOAT: return "REAL"; default: GGML_ABORT("invalid field type"); } } void print_header() override { std::vector fields = test_result::get_fields(); fprintf(fout, "CREATE TABLE IF NOT EXISTS test_backend_ops (\n"); for (size_t i = 0; i < fields.size(); i++) { fprintf(fout, " %s %s%s\n", fields[i].c_str(), get_sql_field_type(fields[i]).c_str(), i < fields.size() - 1 ? "," : ""); } fprintf(fout, ");\n\n"); } void print_test_result(const test_result & result) override { fprintf(fout, "INSERT INTO test_backend_ops ("); std::vector fields = test_result::get_fields(); for (size_t i = 0; i < fields.size(); i++) { fprintf(fout, "%s%s", fields[i].c_str(), i < fields.size() - 1 ? ", " : ""); } fprintf(fout, ") VALUES ("); std::vector values = result.get_values(); for (size_t i = 0; i < values.size(); i++) { fprintf(fout, "'%s'%s", values[i].c_str(), i < values.size() - 1 ? ", " : ""); } fprintf(fout, ");\n"); } }; struct csv_printer : public printer { void print_header() override { std::vector fields = test_result::get_fields(); std::vector fields_csv = get_fields_csv(); for (size_t i = 0; i < fields.size(); i++) { if (std::find(std::begin(fields_csv), std::end(fields_csv), fields[i]) == std::end(fields_csv)) { continue; } printf("\"%s\"%s", fields[i].c_str(), i < fields.size() - 1 ? "," : ""); } printf("\n"); } void print_test_result(const test_result & result) override { std::vector values = result.get_values(); std::vector fields = test_result::get_fields(); std::vector fields_csv = get_fields_csv(); for (size_t i = 0; i < values.size(); i++) { if (std::find(std::begin(fields_csv), std::end(fields_csv), fields[i]) == std::end(fields_csv)) { continue; } // Escape quotes and wrap in quotes for CSV std::string escaped_value = values[i]; size_t pos = 0; while ((pos = escaped_value.find("\"", pos)) != std::string::npos) { escaped_value.replace(pos, 1, "\"\""); pos += 2; } printf("\"%s\"%s", escaped_value.c_str(), i < values.size() - 1 ? "," : ""); } printf("\n"); } static std::vector get_fields_csv() { return { "op_name", "op_params", "supported", "error_message", "test_mode", "backend_reg_name", "backend_name", }; } }; static std::unique_ptr create_printer(output_formats format) { switch (format) { case CONSOLE: return std::make_unique(); case SQL: return std::make_unique(); case CSV: return std::make_unique(); } GGML_ABORT("invalid output format"); } struct test_case { virtual ~test_case() {} virtual std::string op_desc(ggml_tensor * t) { return ggml_op_desc(t); } virtual std::string vars() { return ""; } virtual ggml_tensor * build_graph(ggml_context * ctx) = 0; virtual double max_nmse_err() { return 1e-7; } virtual double max_nmse_err(ggml_backend_t backend) { GGML_UNUSED(backend); return max_nmse_err(); } virtual double max_maa_err() { return 1e-4; } virtual double max_err() { return max_nmse_err(); } virtual double max_err(ggml_backend_t backend) { return max_nmse_err(backend); } virtual double err(const float * a, const float * b, size_t n) { return nmse(a, b, n); } virtual float grad_eps() { return 1e-1f; } // If false, estimate gradient with 2 points, neglects 3rd order derivative and higher. // If true, estimate gradient with 4 points, neglects 5th order derivative and higher. virtual bool grad_precise() { return false; } // Skip gradient checks if total number of gradients to be checked is larger than this (to speed up the tests). virtual int64_t grad_nmax() { return 10000; } // No effect if empty. // If not empty, skip all gradient checks where the numerical result does not match any of the values. // Needed for dealing with noncontinuous gradients (e.g. ReLU) where estimation using finite differences is unreliable. virtual std::vector grad_expect() { return {}; } virtual void initialize_tensors(ggml_context * ctx) { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != nullptr; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t); } } virtual size_t op_size(ggml_tensor * t) { size_t size = ggml_nbytes(t); // add source tensors for (int i = 0; i < GGML_MAX_SRC; i++) { if (t->src[i] != NULL) { size += ggml_nbytes(t->src[i]); } } return size; } virtual uint64_t op_flops(ggml_tensor * t) { GGML_UNUSED(t); return 0; } virtual bool run_whole_graph() { return false; } virtual std::vector fusion_test_nodes() { return {}; } ggml_cgraph * gf = nullptr; ggml_cgraph * gb = nullptr; static const int sentinel_size = 1024; test_mode mode; std::vector sentinels; std::string current_op_name; void add_sentinel(ggml_context * ctx) { if (mode == MODE_PERF || mode == MODE_GRAD || mode == MODE_SUPPORT) { return; } ggml_tensor * sentinel = ::ggml_new_tensor_1d(ctx, GGML_TYPE_F32, sentinel_size); ggml_format_name(sentinel, "sent_%zu", sentinels.size()); sentinels.push_back(sentinel); } // hijack ggml_new_tensor to add sentinels after each tensor to check for overflows in the backend ggml_tensor * ggml_new_tensor(ggml_context * ctx, ggml_type type, int n_dims, const int64_t * ne) { ggml_tensor * t = ::ggml_new_tensor(ctx, type, n_dims, ne); add_sentinel(ctx); return t; } ggml_tensor * ggml_new_tensor_1d(ggml_context * ctx, ggml_type type, int64_t ne0) { ggml_tensor * t = ::ggml_new_tensor_1d(ctx, type, ne0); add_sentinel(ctx); return t; } ggml_tensor * ggml_new_tensor_2d(ggml_context * ctx, ggml_type type, int64_t ne0, int64_t ne1) { ggml_tensor * t = ::ggml_new_tensor_2d(ctx, type, ne0, ne1); add_sentinel(ctx); return t; } ggml_tensor * ggml_new_tensor_3d(ggml_context * ctx, ggml_type type, int64_t ne0, int64_t ne1, int64_t ne2) { ggml_tensor * t = ::ggml_new_tensor_3d(ctx, type, ne0, ne1, ne2); add_sentinel(ctx); return t; } ggml_tensor * ggml_new_tensor_4d(ggml_context * ctx, ggml_type type, int64_t ne0, int64_t ne1, int64_t ne2, int64_t ne3) { ggml_tensor * t = ::ggml_new_tensor_4d(ctx, type, ne0, ne1, ne2, ne3); add_sentinel(ctx); return t; } // Checks an op against the test filter, which is a comma separated list of OP names or specific variations bool matches_filter(ggml_tensor * op, const char * op_names_filter) { if (op_names_filter) { const auto op_name = op_desc(op); const auto op_full_name = op_name + "(" + vars() + ")"; std::string_view filter(op_names_filter); while (!filter.empty()) { auto comma_pos = filter.find_first_of(','); const auto lparen_pos = filter.find_first_of('('); if (lparen_pos < comma_pos) { auto rparen_pos = filter.find_first_of(')'); comma_pos = filter.find_first_of(',', rparen_pos); const auto op_filter = filter.substr(0, comma_pos); if (op_filter == op_full_name) { return true; } } else { const auto op_filter = filter.substr(0, comma_pos); if (op_filter == op_name) { return true; } } filter = comma_pos != std::string_view::npos ? filter.substr(comma_pos + 1) : ""; } return false; } else { return true; } } test_status_t eval(ggml_backend_t backend1, ggml_backend_t backend2, const char * op_names_filter, printer * output_printer) { mode = MODE_TEST; ggml_init_params params = { /* .mem_size = */ ggml_tensor_overhead()*128 + ggml_graph_overhead(), /* .mem_base = */ NULL, /* .no_alloc = */ true, }; ggml_context * ctx = ggml_init(params); GGML_ASSERT(ctx); gf = ggml_new_graph(ctx); // pre-graph sentinel add_sentinel(ctx); ggml_tensor * out = build_graph(ctx); current_op_name = op_desc(out); if (!matches_filter(out, op_names_filter)) { //printf(" %s: skipping\n", op_desc(out).c_str()); ggml_free(ctx); return test_status_t::SKIPPED; } // check if the backends support the ops bool supported = true; for (ggml_backend_t backend : {backend1, backend2}) { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (!ggml_backend_supports_op(backend, t)) { supported = false; break; } } } if (!supported) { // Create test result for unsupported operation test_result result(ggml_backend_name(backend1), current_op_name, vars(), "test", false, false, "not supported"); if (output_printer) { output_printer->print_test_result(result); } ggml_free(ctx); return test_status_t::NOT_SUPPORTED; } // post-graph sentinel add_sentinel(ctx); // allocate ggml_backend_buffer_t buf = ggml_backend_alloc_ctx_tensors(ctx, backend1); if (buf == NULL) { printf("failed to allocate tensors [%s] ", ggml_backend_name(backend1)); ggml_free(ctx); return test_status_t::FAIL; } // build graph ggml_build_forward_expand(gf, out); // add sentinels as graph nodes so that they are checked in the callback for (ggml_tensor * sentinel : sentinels) { ggml_graph_add_node(gf, sentinel); } // randomize tensors initialize_tensors(ctx); // compare struct callback_userdata { bool ok; test_case * tc; ggml_backend_t backend1; ggml_backend_t backend2; }; callback_userdata ud { true, this, backend1, backend2, }; auto callback = [](int index, ggml_tensor * t1, ggml_tensor * t2, void * user_data) -> bool { callback_userdata * ud = (callback_userdata *) user_data; const char * bn1 = ggml_backend_name(ud->backend1); const char * bn2 = ggml_backend_name(ud->backend2); if (t1->op == GGML_OP_NONE) { // sentinels must be unchanged std::vector t1_data(ggml_nbytes(t1)); std::vector t2_data(ggml_nbytes(t2)); ggml_backend_tensor_get(t1, t1_data.data(), 0, ggml_nbytes(t1)); ggml_backend_tensor_get(t2, t2_data.data(), 0, ggml_nbytes(t2)); if (memcmp(t1_data.data(), t2_data.data(), ggml_nbytes(t1)) != 0) { printf("sentinel mismatch: %s ", t1->name); ud->ok = false; return true; } } std::vector f1 = tensor_to_float(t1); std::vector f2 = tensor_to_float(t2); for (size_t i = 0; i < f1.size(); i++) { // check for nans if (std::isnan(f1[i]) || std::isnan(f2[i])) { printf("[%s] NaN at index %zu (%s=%f %s=%f) ", ggml_op_desc(t1), i, bn1, f1[i], bn2, f2[i]); ud->ok = false; return true; } // check for infs: both must be inf of the same sign, or both must be finite if (isinf_or_max(f1[i]) || isinf_or_max(f2[i])) { if (isinf_or_max(f1[i]) && isinf_or_max(f2[i])) { if (std::signbit(f1[i]) != std::signbit(f2[i])) { printf("[%s] inf sign mismatch: %s=%f %s=%f ", ggml_op_desc(t1), bn1, f1[i], bn2, f2[i]); ud->ok = false; return true; } } else { printf("[%s] inf mismatch: %s=%f %s=%f ", ggml_op_desc(t1), bn1, f1[i], bn2, f2[i]); ud->ok = false; return true; } } } double err = ud->tc->err(f1.data(), f2.data(), f1.size()); if (err > ud->tc->max_err(ud->backend1)) { printf("[%s] ERR = %.9f > %.9f ", ggml_op_desc(t1), err, ud->tc->max_err(ud->backend1)); //for (int i = 0; i < (int) f1.size(); i++) { // printf("%5d %9.6f %9.6f, diff = %9.6f\n", i, f1[i], f2[i], f1[i] - f2[i]); //} //printf("\n"); //exit(1); ud->ok = false; } return true; GGML_UNUSED(index); }; std::vector fused_nodes_to_verify = fusion_test_nodes(); if (fused_nodes_to_verify.size() == 0 && run_whole_graph()) { fused_nodes_to_verify.push_back(out); } const bool cmp_ok = ggml_backend_compare_graph_backend(backend1, backend2, gf, callback, &ud, run_whole_graph() ? fused_nodes_to_verify.data() : nullptr, fused_nodes_to_verify.size()); ggml_backend_buffer_free(buf); ggml_free(ctx); // Create test result bool test_passed = ud.ok && cmp_ok; std::string error_msg = test_passed ? "" : (!cmp_ok ? "compare failed" : "test failed"); test_result result(ggml_backend_name(backend1), current_op_name, vars(), "test", supported, test_passed, error_msg); if (output_printer) { output_printer->print_test_result(result); } return test_passed ? test_status_t::OK : test_status_t::FAIL; } bool eval_perf(ggml_backend_t backend, const char * op_names_filter, printer * output_printer) { mode = MODE_PERF; static const size_t graph_nodes = 8192; ggml_init_params params = { /* .mem_size = */ ggml_tensor_overhead()*128 + ggml_graph_overhead_custom(graph_nodes, false), /* .mem_base = */ NULL, /* .no_alloc = */ true, }; ggml_context_ptr ctx(ggml_init(params)); // smart ptr GGML_ASSERT(ctx); ggml_tensor * out = build_graph(ctx.get()); current_op_name = op_desc(out); if (!matches_filter(out, op_names_filter)) { //printf(" %s: skipping\n", op_desc(out).c_str()); return true; } if (!ggml_backend_supports_op(backend, out)) { // Create test result for unsupported performance test test_result result(ggml_backend_name(backend), current_op_name, vars(), "perf", false, false, "not supported"); output_printer->print_test_result(result); return true; } // allocate ggml_backend_buffer_ptr buf(ggml_backend_alloc_ctx_tensors(ctx.get(), backend)); // smart ptr if (buf == NULL) { printf("failed to allocate tensors\n"); return false; } // randomize tensors initialize_tensors(ctx.get()); // build graph ggml_cgraph * gf = ggml_new_graph_custom(ctx.get(), graph_nodes, false); ggml_build_forward_expand(gf, out); // warmup run ggml_status status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } // determine number of runs int n_runs; bool is_cpu = ggml_backend_dev_type(ggml_backend_get_device(backend)) == GGML_BACKEND_DEVICE_TYPE_CPU; if (op_flops(out) > 0) { // based on flops const uint64_t GFLOP = 1000 * 1000 * 1000; const uint64_t target_flops_cpu = 8ULL * GFLOP; const uint64_t target_flops_gpu = 100ULL * GFLOP; uint64_t target_flops = is_cpu ? target_flops_cpu : target_flops_gpu; n_runs = (int)std::min(ggml_graph_size(gf) - ggml_graph_n_nodes(gf), target_flops / op_flops(out)) + 1; } else { // based on memory size const size_t GB = 1ULL << 30; const size_t target_size_cpu = 8 * GB; const size_t target_size_gpu = 32 * GB; size_t target_size = is_cpu ? target_size_cpu : target_size_gpu; n_runs = (int)std::min(ggml_graph_size(gf) - ggml_graph_n_nodes(gf), target_size / op_size(out)) + 1; } // duplicate the op for (int i = 1; i < n_runs; i++) { ggml_graph_add_node(gf, out); } // calculate memory size_t mem = n_runs * op_size(out); auto tensor_op_size = [](ggml_tensor * t) { size_t size = ggml_nbytes(t); // add source tensors for (int i = 0; i < GGML_MAX_SRC; i++) { if (t->src[i] != NULL) { size += ggml_nbytes(t->src[i]); } } return size; }; for (int i = 0; i < ggml_graph_n_nodes(gf); ++i) { if (ggml_is_view_op(ggml_graph_node(gf, i)->op) || ggml_graph_node(gf, i) == out) { continue; } mem += tensor_op_size(ggml_graph_node(gf, i)); } // run int64_t total_time_us = 0; int64_t total_mem = 0; int total_runs = 0; do { int64_t start_time = ggml_time_us(); ggml_status status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } int64_t end_time = ggml_time_us(); total_time_us += end_time - start_time; total_mem += mem; total_runs += n_runs; } while (total_time_us < 1000*1000); // run for at least 1 second // Create test result double avg_time_us = (double) total_time_us / total_runs; double calculated_flops = (op_flops(out) > 0) ? (op_flops(out) * total_runs) / (total_time_us / 1e6) : 0.0; double calculated_bandwidth = (op_flops(out) == 0) ? total_mem / (total_time_us / 1e6) / 1024.0 / 1024.0 / 1024.0 : 0.0; size_t calculated_memory_kb = op_size(out) / 1024; test_result result(ggml_backend_name(backend), current_op_name, vars(), "perf", true, true, "", avg_time_us, calculated_flops, calculated_bandwidth, calculated_memory_kb, total_runs); if (output_printer) { output_printer->print_test_result(result); } return true; } bool eval_support(ggml_backend_t backend, const char * op_names_filter, printer * output_printer) { mode = MODE_SUPPORT; static const size_t graph_nodes = 8192; ggml_init_params params = { /* .mem_size = */ ggml_tensor_overhead()*128 + ggml_graph_overhead_custom(graph_nodes, false), /* .mem_base = */ NULL, /* .no_alloc = */ true, }; ggml_context_ptr ctx(ggml_init(params)); // smart ptr GGML_ASSERT(ctx); gf = ggml_new_graph_custom(ctx.get(), graph_nodes, false); ggml_tensor * out = build_graph(ctx.get()); current_op_name = op_desc(out); if (!matches_filter(out, op_names_filter)) { return true; } bool supported = ggml_backend_supports_op(backend, out); std::string device_desc = ggml_backend_dev_description(ggml_backend_get_device(backend)); std::string backend_reg_name = ggml_backend_reg_name(ggml_backend_dev_backend_reg(ggml_backend_get_device(backend))); test_result result(ggml_backend_name(backend), current_op_name, vars(), "support", supported, supported, supported ? "yes" : "no", 0.0, 0.0, 0.0, 0, 0, device_desc, backend_reg_name); output_printer->print_test_result(result); return true; } bool eval_grad(ggml_backend_t backend, const char * op_names_filter, printer * output_printer) { mode = MODE_GRAD; const std::vector expect = grad_expect(); ggml_init_params params = { /* .mem_size = */ ggml_tensor_overhead()*128 + 2*ggml_graph_overhead_custom(GGML_DEFAULT_GRAPH_SIZE, true), /* .mem_base = */ NULL, /* .no_alloc = */ true, }; ggml_context_ptr ctx(ggml_init(params)); // smart ptr GGML_ASSERT(ctx); gf = ggml_new_graph_custom(ctx.get(), GGML_DEFAULT_GRAPH_SIZE, true); gb = ggml_new_graph_custom(ctx.get(), GGML_DEFAULT_GRAPH_SIZE, true); ggml_tensor * out = build_graph(ctx.get()); if (!matches_filter(out, op_names_filter) || out->op == GGML_OP_OPT_STEP_ADAMW) { return true; } if (out->type != GGML_TYPE_F32) { output_printer->print_operation(test_operation_info(op_desc(out), vars(), ggml_backend_name(backend), test_status_t::NOT_SUPPORTED, out->name + std::string("->type != FP32"))); return true; } // Print operation info first output_printer->print_operation(test_operation_info(op_desc(out), vars(), ggml_backend_name(backend))); // check if the backend supports the ops bool supported = true; bool any_params = false; std::string failure_reason; for (ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != NULL; t = ggml_get_next_tensor(ctx.get(), t)) { if (!ggml_backend_supports_op(backend, t)) { supported = false; failure_reason = ggml_backend_name(backend); break; } if ((t->flags & GGML_TENSOR_FLAG_PARAM)) { any_params = true; if (t->type != GGML_TYPE_F32) { supported = false; failure_reason = std::string(t->name) + "->type != FP32"; break; } } } if (!any_params) { supported = false; failure_reason = op_desc(out); } if (!supported) { output_printer->print_operation(test_operation_info(op_desc(out), vars(), ggml_backend_name(backend), test_status_t::NOT_SUPPORTED, failure_reason)); return true; } int64_t ngrads = 0; for (ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != NULL; t = ggml_get_next_tensor(ctx.get(), t)) { if (t->flags & GGML_TENSOR_FLAG_PARAM) { ngrads += ggml_nelements(t); } } if (ngrads > grad_nmax()) { test_operation_info info(op_desc(out), vars(), ggml_backend_name(backend)); info.set_large_tensor_skip(); output_printer->print_operation(info); return true; } if (!ggml_is_scalar(out)) { out = ggml_sum(ctx.get(), out); ggml_set_name(out, "sum_of_out"); } ggml_set_loss(out); ggml_build_forward_expand(gf, out); ggml_graph_cpy(gf, gb); ggml_build_backward_expand(ctx.get(), gb, nullptr); if (expect.size() != 1 || expect[0] != 0.0f) { GGML_ASSERT(ggml_graph_n_nodes(gb) > ggml_graph_n_nodes(gf)); for (ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != NULL; t = ggml_get_next_tensor(ctx.get(), t)) { GGML_ASSERT(!(t->flags & GGML_TENSOR_FLAG_PARAM) || ggml_graph_get_grad(gb, t)->op != GGML_OP_NONE); } } for (ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != NULL; t = ggml_get_next_tensor(ctx.get(), t)) { if (!ggml_backend_supports_op(backend, t)) { output_printer->print_operation(test_operation_info(op_desc(out), vars(), ggml_backend_name(backend), test_status_t::NOT_SUPPORTED, ggml_backend_name(backend))); supported = false; break; } if ((t->flags & GGML_TENSOR_FLAG_PARAM) && t->type != GGML_TYPE_F32) { output_printer->print_operation(test_operation_info(op_desc(out), vars(), ggml_backend_name(backend), test_status_t::NOT_SUPPORTED, std::string(t->name) + "->type != FP32")); supported = false; break; } } if (!supported) { return true; } // allocate ggml_backend_buffer_ptr buf(ggml_backend_alloc_ctx_tensors(ctx.get(), backend)); // smart ptr if (buf == NULL) { test_operation_info info(op_desc(out), vars(), ggml_backend_name(backend)); info.set_error("allocation", ""); output_printer->print_operation(info); return false; } initialize_tensors(ctx.get()); // Randomizes all tensors (including gradients). ggml_graph_reset(gb); // Sets gradients to 1 if loss, 0 otherwise. ggml_status status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } status = ggml_backend_graph_compute(backend, gb); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } bool ok = true; for (struct ggml_tensor * t = ggml_get_first_tensor(ctx.get()); t != nullptr; t = ggml_get_next_tensor(ctx.get(), t)) { if (!(t->flags & GGML_TENSOR_FLAG_PARAM)) { continue; } const char * bn = ggml_backend_name(backend); const int64_t ne = ggml_nelements(t); std::vector ga; struct ggml_tensor * grad = ggml_graph_get_grad(gb, t); if (grad) { ga = tensor_to_float(grad); } else { ga.resize(ne); // default value is 0.0f } for (int64_t i = 0; i < ne; ++i) { // gradient algebraic // check for nans if (!std::isfinite(ga[i])) { test_operation_info info(op_desc(out), vars(), ggml_backend_name(backend)); info.set_gradient_info(i, bn, ga[i]); output_printer->print_operation(info); ok = false; break; } } if (!ok) { break; } std::vector gn(ne); // gradient numeric GGML_ASSERT(ga.size() == gn.size()); std::vector x0 = tensor_to_float(t); // original t data GGML_ASSERT(ggml_is_scalar(out)); GGML_ASSERT(out->type == GGML_TYPE_F32); const float eps = grad_eps(); for (int64_t i = 0; i < ne; ++i) { const float xiu = x0[i] + 1.0f*eps; // x, index i, up const float xiuh = x0[i] + 0.5f*eps; // x, index i, up half const float xidh = x0[i] - 0.5f*eps; // x, index i, down half const float xid = x0[i] - 1.0f*eps; // x, index i, down float fu, fuh, fdh, fd; // output values for xiu, xiuh, xid, xidh ggml_backend_tensor_set(t, &xiu, i*sizeof(float), sizeof(float)); status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } ggml_backend_tensor_get(out, &fu, 0, ggml_nbytes(out)); ggml_backend_tensor_set(t, &xid, i*sizeof(float), sizeof(float)); status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } ggml_backend_tensor_get(out, &fd, 0, ggml_nbytes(out)); if (grad_precise()) { ggml_backend_tensor_set(t, &xiuh, i*sizeof(float), sizeof(float)); status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } ggml_backend_tensor_get(out, &fuh, 0, ggml_nbytes(out)); ggml_backend_tensor_set(t, &xidh, i*sizeof(float), sizeof(float)); status = ggml_backend_graph_compute(backend, gf); if (status != GGML_STATUS_SUCCESS) { fprintf(stderr, "%s: ggml_backend_graph_compute failed. status=%s \n", __func__, ggml_status_to_string(status)); return false; } ggml_backend_tensor_get(out, &fdh, 0, ggml_nbytes(out)); gn[i] = (8.0*(double)fuh + (double)fd - (8.0*(double)fdh + (double)fu)) / (6.0*(double)eps); } else { gn[i] = (fu - fd) / (2.0f*eps); } ggml_backend_tensor_set(t, x0.data(), 0, ggml_nbytes(t)); } const double err = mean_abs_asymm(gn.data(), ga.data(), gn.size(), expect); if (err > max_maa_err()) { test_operation_info info(op_desc(out), vars(), ggml_backend_name(backend)); info.set_maa_error(err, max_maa_err()); output_printer->print_operation(info); ok = false; break; } if (!ok) { break; } } // Create final test result test_operation_info final_info(op_desc(out), vars(), ggml_backend_name(backend)); if (!ok) { final_info.set_compare_failure(); } final_info.status = ok ? test_status_t::OK : test_status_t::FAIL; output_printer->print_operation(final_info); if (ok) { return true; } return false; } }; // #################################### // ## Section 2: GGML Op Definitions ## // #################################### // The following is an example showing the bare minimum for creating a test for a GGML op. // GGML_OP_EXAMPLE struct test_example : public test_case { // Always define these 2 or variants thereof: const ggml_type type; // The type of the input tensors. const std::array ne; // The shape of the input tensors. // For some ops it's necessary to define multiple types or shapes for the inputs. // Or they may need additional parameters. // Put all parameters needed to fully define the test into one of the VARS_TO_STR macros. // In most cases these are just the properties of the struct that you defined above. // This is needed for info prints. std::string vars() override { return VARS_TO_STR2(type, ne); } // Define a constructor for the struct. // In most cases it will be sufficient to have the same arguments as the struct has properties // and just use initializer lists. test_example(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} // Define how a simple GGML compute graph can be constructed for the new GGML op. ggml_tensor * build_graph(ggml_context * ctx) override { // Step 1: create input tensors that don't depend on any other tensors: ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); // Setting names is optional but it's useful for debugging. ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(b, "b"); // Step 2: use the op that you want to test in the GGML compute graph. ggml_tensor * out = ggml_add(ctx, a, b); // For this example we're just doing a simple addition. ggml_set_name(out, "out"); // Step 3: return the output tensor. return out; } // In order to also check the gradients for your op, add calls like ggml_set_param(a) // immediately after you create the tensors. // This is optional and only makes sense if a backward pass has actually been implemented for the new op. }; // GGML_OP_UNARY struct test_unary : public test_case { const ggml_unary_op op; const ggml_type type; const std::array ne_a; int v; // view (1 : non-contiguous a) std::string vars() override { return VARS_TO_STR3(type, ne_a, v); } test_unary(ggml_unary_op op, ggml_type type = GGML_TYPE_F32, std::array ne_a = {128, 2, 2, 2}, int v = 0) : op(op), type(type), ne_a(ne_a), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { const bool grad_supported = op == GGML_UNARY_OP_ABS || op == GGML_UNARY_OP_SGN || op == GGML_UNARY_OP_NEG || op == GGML_UNARY_OP_STEP || op == GGML_UNARY_OP_RELU || op == GGML_UNARY_OP_SILU || op == GGML_UNARY_OP_EXPM1 || op == GGML_UNARY_OP_SOFTPLUS; ggml_tensor * a; if (v & 1) { auto ne = ne_a; ne[0] *= 3; ne[1] *= 2; ne[2] *= 5; ne[3] *= 4; a = ggml_new_tensor(ctx, type, 4, ne.data()); if (grad_supported) { ggml_set_param(a); } ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); if (grad_supported) { ggml_set_param(a); } ggml_set_name(a, "a"); } ggml_tensor * out = ggml_unary(ctx, a, op); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // test extended range of values to check for NaNs in GELU init_tensor_uniform(t, -150.f, 150.f); } } float grad_eps() override { return 15.0f; } std::vector grad_expect() override { if (op == GGML_UNARY_OP_ABS) { return {-1.0f, 1.0f}; } if (op == GGML_UNARY_OP_SGN || op == GGML_UNARY_OP_STEP) { return {0.0f}; } if (op == GGML_UNARY_OP_RELU) { return {0.0f, 1.0f}; } return {}; } }; // GGML_OP_GLU struct test_glu : public test_case { const ggml_glu_op op; const ggml_type type; const std::array ne_a; int v; // view (1 : non-contiguous a) bool swapped; std::string vars() override { return VARS_TO_STR4(type, ne_a, v, swapped); } test_glu(ggml_glu_op op, ggml_type type = GGML_TYPE_F32, std::array ne_a = {128, 2, 2, 2}, int v = 0, bool swapped = false) : op(op), type(type), ne_a(ne_a), v(v), swapped(swapped) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a; if (v & 1) { auto ne = ne_a; ne[0] *= 3; a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); } ggml_tensor * out = ggml_glu(ctx, a, op, swapped); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // test extended range of values to check for NaNs in GELU init_tensor_uniform(t, -150.f, 150.f); } } }; struct test_glu_split : public test_case { const ggml_glu_op op; const ggml_type type; const std::array ne_a; int v; // view (1 : non-contiguous a) std::string vars() override { return VARS_TO_STR3(type, ne_a, v) + ",split"; } test_glu_split(ggml_glu_op op, ggml_type type = GGML_TYPE_F32, std::array ne_a = {128, 2, 2, 2}, int v = 0) : op(op), type(type), ne_a(ne_a), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a; ggml_tensor * b; if (v & 1) { auto ne = ne_a; ne[0] *= 3; a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(b); ggml_set_name(b, "b"); b = ggml_view_4d(ctx, b, ne_a[0], ne_a[1], ne_a[2], ne_a[3], b->nb[1], b->nb[2], b->nb[3], 0); ggml_set_name(a, "view_of_b"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_param(a); ggml_set_name(a, "a"); b = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_param(b); ggml_set_name(b, "b"); } ggml_tensor * out = ggml_glu_split(ctx, a, b, op); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // test extended range of values to check for NaNs in GELU init_tensor_uniform(t, -150.f, 150.f); } } }; struct test_swiglu_oai : public test_case { const ggml_type type; const std::array ne_a; int v; // view (1 : non-contiguous a) float alpha; float limit; std::string vars() override { return VARS_TO_STR5(type, ne_a, v, alpha, limit); } test_swiglu_oai(ggml_type type = GGML_TYPE_F32, std::array ne_a = {128, 2, 2, 2}, int v = 0, float alpha = 1.702f, float limit = 7.0f) : type(type), ne_a(ne_a), v(v), alpha(alpha), limit(limit) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a; ggml_tensor * b; if (v & 1) { auto ne = ne_a; ne[0] *= 3; a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(b); ggml_set_name(b, "b"); b = ggml_view_4d(ctx, b, ne_a[0], ne_a[1], ne_a[2], ne_a[3], b->nb[1], b->nb[2], b->nb[3], 0); ggml_set_name(a, "view_of_b"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_param(a); ggml_set_name(a, "a"); b = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_param(b); ggml_set_name(b, "b"); } ggml_tensor * out = ggml_swiglu_oai(ctx, a, b, alpha, limit); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // test extended range of values to check for NaNs in GELU init_tensor_uniform(t, -150.f, 150.f); } } }; // GGML_OP_GET_ROWS struct test_get_rows : public test_case { const ggml_type type; const int n; // cols const int m; // rows const int r; // rows to get const int be1; // batch size const int be2; // batch size const bool v; // view (non-contiguous src1) std::string vars() override { return VARS_TO_STR7(type, n, m, r, be1, be2, v); } test_get_rows(ggml_type type = GGML_TYPE_F32, int n = 10, int m = 5, int r = 3, int be1 = 1, int be2 = 1, bool v = false) : type(type), n(n), m(m), r(r), be1(be1), be2(be2), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * in = ggml_new_tensor_4d(ctx, type, n, m, be1, be2); ggml_set_name(in, "in"); ggml_tensor * rows = ggml_new_tensor_3d(ctx, GGML_TYPE_I32, r, be1, be2); ggml_set_name(rows, "rows"); if (v) { rows = ggml_view_3d(ctx, rows, r/2, be1, be2, rows->nb[1], rows->nb[2], 0); ggml_set_name(rows, "view_of_rows"); } const bool grad_supported = ggml_is_matrix(in) && ggml_is_vector(rows); if (grad_supported) { ggml_set_param(in); // rows is a constant input -> no gradients } ggml_tensor * out = ggml_get_rows(ctx, in, rows); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } // rows std::vector data(r*be1*be2); for (int i = 0; i < r*be1*be2; i++) { data[i] = rand() % m; } ggml_backend_tensor_set(t, data.data(), 0, r * be1 * be2 * sizeof(int)); } else { init_tensor_uniform(t); } } } }; // GGML_OP_GET_ROWS_BACK struct test_get_rows_back : public test_case { const ggml_type type; const int n; // cols const int m; // rows const int r; // rows to get const int b; // batch size const bool v; // view (non-contiguous src1) std::string vars() override { return VARS_TO_STR6(type, n, m, r, b, v); } test_get_rows_back(ggml_type type = GGML_TYPE_F32, int n = 10, int m = 5, int r = 3, int b = 1, bool v = false) : type(type), n(n), m(m), r(r), b(b), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * in_forward = ggml_new_tensor_3d(ctx, type, n, m, b); ggml_set_name(in_forward, "in_forward"); ggml_tensor * rows = ggml_new_tensor_2d(ctx, GGML_TYPE_I32, r, b); ggml_set_name(rows, "rows"); if (v) { rows = ggml_view_2d(ctx, rows, r/2, b, rows->nb[1], 0); ggml_set_name(rows, "view_of_rows"); } ggml_tensor * grad = ggml_new_tensor_3d(ctx, type, n, r, b); ggml_set_name(grad, "grad"); ggml_tensor * out = ggml_get_rows_back(ctx, grad, rows, in_forward); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } // rows std::vector data(r*b); for (int i = 0; i < r*b; i++) { data[i] = rand() % m; } ggml_backend_tensor_set(t, data.data(), 0, r * b * sizeof(int)); } else { init_tensor_uniform(t); } } } }; static void init_set_rows_row_ids(ggml_tensor * t, int num_rows) { std::random_device rd; std::default_random_engine rng(rd()); for (int i2 = 0; i2 < t->ne[2]; i2++) { for (int i1 = 0; i1 < t->ne[1]; i1++) { // generate a shuffled subset of row indices std::vector data(num_rows); for (int i = 0; i < num_rows; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); data.resize(t->ne[0]); const size_t offs = i1*t->nb[1] + i2*t->nb[2]; if (t->type == GGML_TYPE_I32) { // TODO: Make a template or something std::vector data_i32(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data_i32[i] = static_cast(data[i]); } ggml_backend_tensor_set(t, data_i32.data(), offs, t->ne[0]*sizeof(int32_t)); } else { ggml_backend_tensor_set(t, data.data(), offs, t->ne[0]*sizeof(int64_t)); } } } } // GGML_OP_SET_ROWS struct test_set_rows : public test_case { const ggml_type type; const ggml_type type_idx; const std::array ne; const std::array nr23; // broadcast only dims 2 and 3 const int r; // rows to set const bool v; // view (non-contiguous src1) std::string vars() override { return VARS_TO_STR6(type, type_idx, ne, nr23, r, v); } test_set_rows(ggml_type type, ggml_type type_idx, std::array ne, std::array nr23, int r, bool v = false) : type(type), type_idx(type_idx), ne(ne), nr23(nr23), r(r), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * dst = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2]*nr23[0], ne[3]*nr23[1]); ggml_set_name(dst, "dst"); ggml_tensor * src = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, ne[0], r, ne[2]*nr23[0], ne[3]*nr23[1]); ggml_set_name(src, "src"); ggml_tensor * row_idxs = ggml_new_tensor_3d(ctx, type_idx, r, ne[2], ne[3]); ggml_set_name(row_idxs, "row_idxs"); if (v) { src = ggml_view_4d(ctx, src, ne[0], r/2, ne[2]*nr23[0], ne[3]*nr23[1], src->nb[1], src->nb[2], src->nb[3], 0); row_idxs = ggml_view_3d(ctx, row_idxs, r/2, ne[2], ne[3], row_idxs->nb[1], row_idxs->nb[2], 0); ggml_set_name(row_idxs, "view_of_rows"); } ggml_tensor * out = ggml_set_rows(ctx, dst, src, row_idxs); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I64 || t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } init_set_rows_row_ids(t, ne[1]); } else { init_tensor_uniform(t); } } } double max_nmse_err() override { if (type == GGML_TYPE_Q4_0 || type == GGML_TYPE_Q4_1 || type == GGML_TYPE_IQ4_NL || type == GGML_TYPE_Q5_0 || type == GGML_TYPE_Q5_1 || type == GGML_TYPE_Q8_0) { // estimate what the max nmse error would be if one quantized value is // off by one. The test values are distributed in [-1,1], so it'll be // roughly (2.0 / 2^bits)^2, divided by the mean square value of the reference, // which is roughly 0.25 times the number of elements. double err_estimate = 1.0f/8.0f; if (type == GGML_TYPE_Q5_0 || type == GGML_TYPE_Q5_1) { err_estimate /= 2.0f; } if (type == GGML_TYPE_Q8_0) { err_estimate /= 8.0f; } err_estimate *= err_estimate; err_estimate /= 0.25f*float(ne[0] * r * ne[2]*nr23[0] * ne[3]*nr23[1]); return err_estimate; } return 1e-7; } }; // GGML_OP_ROPE + GGML_OP_VIEW + GGML_OP_SET_ROWS struct test_rope_set_rows : public test_case { const ggml_type type; const ggml_type type_idx; const std::array ne_a; int mode; const int n_ctx{512}; const int n_dims{128}; std::string vars() override { return VARS_TO_STR4(type, type_idx, ne_a, mode); } std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "ROPE_SET_ROWS"; } bool run_whole_graph() override { return true; } test_rope_set_rows(ggml_type type, ggml_type type_idx, std::array ne_a, int mode) : type(type), type_idx(type_idx), ne_a(ne_a), mode(mode) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, ne_a[0], ne_a[1], ne_a[2], 1); ggml_set_name(a, "a"); const bool is_mrope = mode & GGML_ROPE_TYPE_MROPE; const bool is_vision = mode == GGML_ROPE_TYPE_VISION; ggml_tensor * pos; if (is_mrope || is_vision) { pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, ne_a[2] * 4); } else { pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, ne_a[2]); } ggml_set_name(pos, "pos"); float fs = 1.4245f; float ef = 0.7465f; float af = 1.4245f; ggml_tensor * freq = nullptr; ggml_tensor * rope = nullptr; if (is_mrope) { if (is_vision) { GGML_ASSERT(n_dims/4 > 0); int rope_sections[4] = {n_dims/4, n_dims/4, 0, 0}; // Vision-RoPE only use first two dimension for image (x, y) coordinate rope = ggml_rope_multi(ctx, a, pos, freq, n_dims/2, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } else { GGML_ASSERT(n_dims/3 > 0); int rope_sections[4] = {n_dims/3, n_dims/3, n_dims/3, 0}; rope = ggml_rope_multi(ctx, a, pos, freq, n_dims, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } else { rope = ggml_rope(ctx, a, pos, ne_a[0], mode); } ggml_tensor * view = ggml_view_2d(ctx, rope, ne_a[0] * ne_a[1], ne_a[2], rope->nb[2], 0); ggml_tensor * dst = ggml_new_tensor_4d(ctx, type, ne_a[0] * ne_a[1], ne_a[2] * ne_a[3], 1, 1); ggml_set_name(dst, "dst"); ggml_tensor * row_idxs = ggml_new_tensor_3d(ctx, type_idx, ne_a[2], 1, 1); ggml_set_name(row_idxs, "row_idxs"); ggml_tensor * out = ggml_set_rows(ctx, dst, view, row_idxs); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (strcmp(t->name, "row_idxs") == 0) { if (ggml_is_view_op(t->op)) { continue; } init_set_rows_row_ids(t, ne_a[2]); } else if (t->type == GGML_TYPE_I32) { // pos const int num_pos_ids = (mode & GGML_ROPE_TYPE_MROPE) ? ne_a[2] * 4 : ne_a[2]; std::vector data(num_pos_ids); for (int i = 0; i < num_pos_ids; i++) { data[i] = rand() % n_ctx; } ggml_backend_tensor_set(t, data.data(), 0, num_pos_ids * sizeof(int)); } else { if (t->ne[0] == n_dims/2) { // frequency factors in the range [0.9f, 1.1f] init_tensor_uniform(t, 0.9f, 1.1f); } else { init_tensor_uniform(t); } } } } }; // GGML_OP_RMS_NORM + GGML_OP_MUL + GGML_OP_ROPE (+ GGML_OP_VIEW + GGML_OP_SET_ROWS) struct test_rms_norm_mul_rope : public test_case { const std::array ne; const float eps; const bool multi_add; // test a sequence of adds feeding into rms_norm const bool set_rows; int mode; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "RMS_NORM_MUL_ROPE"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR5(ne, eps, multi_add, set_rows, mode); } test_rms_norm_mul_rope(std::array ne, float eps = 1e-6f, bool multi_add = false, bool set_rows = false, int mode = GGML_ROPE_TYPE_NORMAL) : ne(ne), eps(eps), multi_add(multi_add), set_rows(set_rows), mode(mode) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, ne[0], ne[1], ne[2], 1); ggml_tensor * b = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, ne[0], ne[1], ne[2], 1); ggml_tensor * c = ggml_new_tensor_4d(ctx, GGML_TYPE_F32, ne[0], ne[1], ne[2], 1); if (multi_add) { a = ggml_add(ctx, ggml_add(ctx, a, b), c); } a = ggml_mul(ctx, ggml_rms_norm(ctx, a, eps), b); ggml_tensor * pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, ne[2]); ggml_tensor * rope = ggml_rope(ctx, a, pos, ne[0], mode); ggml_tensor * out; if (set_rows) { ggml_tensor * view = ggml_view_2d(ctx, rope, ne[0] * ne[1], ne[2], rope->nb[2], 0); ggml_tensor * dst = ggml_new_tensor_4d(ctx, GGML_TYPE_F16, ne[0] * ne[1], ne[2] * ne[3], 1, 1); ggml_set_name(dst, "dst"); ggml_tensor * row_idxs = ggml_new_tensor_3d(ctx, GGML_TYPE_I64, ne[2], 1, 1); ggml_set_name(row_idxs, "row_idxs"); out = ggml_set_rows(ctx, dst, view, row_idxs); ggml_set_name(out, "out"); } else { out = rope; } return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I64 || t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } init_set_rows_row_ids(t, ne[2]); } else { init_tensor_uniform(t); } } } }; // GGML_OP_ARGMAX struct test_argmax : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_argmax(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 100, 1, 1}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_argmax(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_F32) { // initialize with unique values to avoid ties for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(float)); } } else { init_tensor_uniform(t); } } } double max_nmse_err() override { return 0.0; } }; // GGML_OP_COUNT_EQUAL struct test_count_equal : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_count_equal(ggml_type type = GGML_TYPE_F32, std::array ne = {4, 500, 1, 1}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * a_argmax = ggml_argmax(ctx, a); ggml_set_name(a_argmax, "a_argmax"); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(b, "b"); ggml_tensor * b_argmax = ggml_argmax(ctx, b); ggml_set_name(b_argmax, "b_argmax"); ggml_tensor * out = ggml_count_equal(ctx, a_argmax, b_argmax); ggml_set_name(out, "out"); return out; } double max_nmse_err() override { return 0.0; } void initialize_tensors(ggml_context * ctx) override { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_F32) { // initialize with unique values to avoid ties for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(float)); } } else { init_tensor_uniform(t); } } } }; // GGML_OP_REPEAT struct test_repeat : public test_case { const ggml_type type; const std::array ne; const std::array nr; std::string vars() override { return VARS_TO_STR3(type, ne, nr); } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) * 2; } test_repeat(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, std::array nr = {2, 2, 2, 2}) : type(type), ne(ne), nr(nr) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * target = ggml_new_tensor_4d(ctx, type, ne[0]*nr[0], ne[1]*nr[1], ne[2]*nr[2], ne[3]*nr[3]); ggml_set_name(target, "target"); ggml_tensor * src = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(src); ggml_set_name(src, "src"); ggml_tensor * out = ggml_repeat(ctx, src, target); ggml_set_name(out, "out"); return out; } }; // GGML_OP_REPEAT_BACK struct test_repeat_back : public test_case { const ggml_type type; const std::array ne; const std::array nr; const bool v; // whether src is a noncontiguous view std::string vars() override { return VARS_TO_STR4(type, ne, nr, v); } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) * 2; } test_repeat_back(ggml_type type = GGML_TYPE_F32, std::array ne = {8, 6, 4, 2}, std::array nr = {2, 2, 2, 2}, bool v = false) : type(type), ne(ne), nr(nr), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * src = ggml_new_tensor_4d(ctx, type, ne[0]*nr[0], ne[1]*nr[1], ne[2]*nr[2], ne[3]*nr[3]); ggml_set_name(src, "src"); if (v) { GGML_ASSERT(ne[0] % 2 == 0); GGML_ASSERT(ne[1] % 2 == 0); GGML_ASSERT(ne[2] % 2 == 0); GGML_ASSERT(ne[3] % 2 == 0); GGML_ASSERT(nr[0] % 2 == 0 || nr[0] == 1); GGML_ASSERT(nr[1] % 2 == 0 || nr[1] == 1); GGML_ASSERT(nr[2] % 2 == 0 || nr[2] == 1); GGML_ASSERT(nr[3] % 2 == 0 || nr[3] == 1); const int64_t ne00 = nr[0] == 1 ? src->ne[0] : src->ne[0] / 2; const int64_t ne01 = nr[1] == 1 ? src->ne[1] : src->ne[1] / 2; const int64_t ne02 = nr[2] == 1 ? src->ne[2] : src->ne[2] / 2; const int64_t ne03 = nr[3] == 1 ? src->ne[3] : src->ne[3] / 2; src = ggml_view_4d(ctx, src, ne00, ne01, ne02, ne03, src->nb[1], src->nb[2], src->nb[3], 0); } ggml_tensor * target = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(target, "target"); ggml_tensor * out = ggml_repeat_back(ctx, src, target); ggml_set_name(out, "out"); return out; } }; // GGML_OP_DUP struct test_dup : public test_case { const ggml_type type; const std::array ne; const std::array permute; bool _use_permute; std::string vars() override { std::string v = VARS_TO_STR2(type, ne); if (_use_permute) v += "," + VAR_TO_STR(permute); return v; } test_dup(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 20, 1}, std::array permute = {0, 0, 0, 0}) : type(type), ne(ne), permute(permute), _use_permute(permute[0] + permute[1] + permute[2] + permute[3] > 0) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * src = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(src); ggml_set_name(src, "src"); if (_use_permute) { src = ggml_permute(ctx, src, permute[0], permute[1], permute[2], permute[3]); ggml_set_name(src, "src_permuted"); } ggml_tensor * out = ggml_dup(ctx, src); ggml_set_name(out, "out"); return out; } }; // GGML_OP_SET struct test_set : public test_case { const ggml_type type_src; const ggml_type type_dst; const std::array ne; const int dim; const bool inplace; std::string vars() override { return VARS_TO_STR5(type_src, type_dst, ne, dim, inplace); } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) + ggml_nbytes(t->src[0]); } test_set(ggml_type type_src = GGML_TYPE_F32, ggml_type type_dst = GGML_TYPE_F32, std::array ne = {6, 5, 4, 3}, int dim = 1, bool inplace = false) : type_src(type_src), type_dst(type_dst), ne(ne), dim(dim), inplace(inplace) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * src = ggml_new_tensor(ctx, type_src, 4, ne.data()); ggml_set_param(src); ggml_set_name(src, "src"); auto ne_dst = ne; for (int i = 0; i < dim; ++i) { ne_dst[i] *= 2; } ggml_tensor * dst = ggml_new_tensor(ctx, type_dst, 4, ne_dst.data()); ggml_set_param(dst); ggml_set_name(dst, "dst"); size_t offset = 0; for (int i = 0; i < dim; ++i) { offset += ((ne_dst[i] - ne[i])/2)*dst->nb[i]; } ggml_tensor * out; if (inplace) { out = ggml_set_inplace(ctx, dst, src, // The backward pass requires setting a contiguous region: src->nb[1], src->nb[2], src->nb[3], offset); } else { out = ggml_set(ctx, dst, src, // The backward pass requires setting a contiguous region: src->nb[1], src->nb[2], src->nb[3], offset); } ggml_set_name(out, "out"); return out; } }; // GGML_OP_CPY struct test_cpy : public test_case { const ggml_type type_src; const ggml_type type_dst; const std::array ne; const std::array permute_src; const std::array permute_dst; bool _src_use_permute; bool _dst_use_permute; bool _src_transpose; std::string vars() override { return VARS_TO_STR6(type_src, type_dst, ne, permute_src, permute_dst, _src_transpose); } double max_nmse_err() override { if (type_src == type_dst) { return 0.0; } if (type_dst == GGML_TYPE_Q4_0 || type_dst == GGML_TYPE_Q4_1 || type_dst == GGML_TYPE_IQ4_NL || type_dst == GGML_TYPE_Q5_0 || type_dst == GGML_TYPE_Q5_1 || type_dst == GGML_TYPE_Q8_0) { // estimate what the max nmse error would be if one quantized value is // off by one. The test values are distributed in [-150,150], so it'll be // roughly (150*2.0 / 2^bits)^2, divided by the mean square value of the reference, // which is roughly 0.25*150^2 times the number of elements. double err_estimate = 1.0f/8.0f * 150.0f; if (type_dst == GGML_TYPE_IQ4_NL) { // iq4_nl values are a bit more spread out err_estimate *= 2.0f; } if (type_dst == GGML_TYPE_Q5_0 || type_dst == GGML_TYPE_Q5_1) { err_estimate /= 2.0f; } if (type_dst == GGML_TYPE_Q8_0) { err_estimate /= 8.0f; } err_estimate *= err_estimate; err_estimate /= (150.0f*150.0f*0.25f)*float(ne[0] * ne[1] * ne[2] * ne[3]); return err_estimate; } return 1e-6; } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) + ggml_nbytes(t->src[0]); } test_cpy(ggml_type type_src = GGML_TYPE_F32, ggml_type type_dst = GGML_TYPE_F32, std::array ne = {10, 10, 10, 1}, std::array permute_src = {0, 0, 0, 0}, std::array permute_dst = {0, 0, 0, 0}, bool transpose_src = false) : type_src(type_src), type_dst(type_dst), ne(ne), permute_src(permute_src), permute_dst(permute_dst), _src_use_permute(permute_src[0] + permute_src[1] + permute_src[2] + permute_src[3] > 0), _dst_use_permute(permute_dst[0] + permute_dst[1] + permute_dst[2] + permute_dst[3] > 0), _src_transpose(transpose_src){} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * src = ggml_new_tensor(ctx, type_src, 4, ne.data()); ggml_set_param(src); ggml_set_name(src, "src"); if (_src_use_permute) { src = ggml_permute(ctx, src, permute_src[0], permute_src[1], permute_src[2], permute_src[3]); ggml_set_name(src, "src_permuted"); } if (_src_transpose) { src = ggml_transpose(ctx, src); ggml_set_name(src, "src_transposed"); } ggml_tensor * dst = ggml_new_tensor(ctx, type_dst, 4, src->ne); ggml_set_name(dst, "dst"); if (_dst_use_permute) { dst = ggml_permute(ctx, dst, permute_dst[0], permute_dst[1], permute_dst[2], permute_dst[3]); ggml_set_name(dst, "dst_permuted"); } ggml_tensor * out = ggml_cpy(ctx, src, dst); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // test extended range of values to check if casting between f32 and i32 is consistent init_tensor_uniform(t, -150.f, 150.f); } } }; // GGML_OP_CONT struct test_cont : public test_case { const ggml_type type; const std::array ne; bool use_view_slice; std::string vars() override { return VARS_TO_STR3(type, ne, use_view_slice); } test_cont(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 10, 1}, bool use_view_slice = false) : type(type), ne(ne), use_view_slice(use_view_slice) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * src = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(src); ggml_set_name(src, "src"); ggml_tensor * dst; if (use_view_slice) { dst = ggml_view_4d(ctx, src, src->ne[0], 1, src->ne[2], src->ne[3], src->nb[1], src->nb[2], src->nb[3], src->nb[0] * (src->ne[1] - 1)); ggml_set_name(dst, "src_view_slice"); } else { dst = ggml_transpose(ctx, src); ggml_set_name(dst, "src_transposed"); } ggml_tensor * out = ggml_cont(ctx, dst); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ADD // GGML_OP_SUB // GGML_OP_MUL // GGML_OP_DIV struct test_bin_bcast : public test_case { using op_t = ggml_tensor * (*) (ggml_context *, ggml_tensor *, ggml_tensor *); op_t op; const ggml_type type; const std::array ne; const std::array nr; int nf; // number of fused ops, nf == 1 -> single op (no fusion) bool perm1; // permute src1? bool src_overlap; // src0 and src1 are overlapping views of the same buffer bool run_whole_graph() override { return nf > 1; } std::string vars() override { return VARS_TO_STR5(type, ne, nr, nf, perm1); } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) * 3; } test_bin_bcast(op_t op, ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 1, 1}, std::array nr = {1, 2, 1, 1}, int nf = 1, bool perm1 = false, bool src_overlap = false) : op(op), type(type), ne(ne), nr(nr), nf(nf), perm1(perm1), src_overlap(src_overlap) {} ggml_tensor * build_graph(ggml_context * ctx) override { GGML_ASSERT(nf <= 16); ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0]*nr[0], ne[1]*nr[1], ne[2]*nr[2], ne[3]*nr[3]); ggml_set_name(a, "a"); ggml_tensor * b[16]; for (int i = 0; i < nf; ++i) { if (perm1) { const int p[4] = { 1, 2, 0, 3 }; // hardcoded for now b[i] = ggml_new_tensor_4d(ctx, type, ne[p[0]], ne[p[1]], ne[p[2]], ne[p[3]]); b[i] = ggml_permute(ctx, b[i], p[0], p[1], p[2], p[3]); } else if (src_overlap) { b[i] = ggml_view_4d(ctx, a, ne[0], ne[1], ne[2], 2 * (ne[3] / 3), a->nb[1], a->nb[2], a->nb[3], (ne[3] / 3) * a->nb[3]); } else { b[i] = ggml_new_tensor(ctx, type, 4, ne.data()); } ggml_set_name(b[i], (std::string("b") + std::to_string(i)).c_str()); } // The backward pass supports broadcasting only for GGML_ADD: const bool grad_supported = op == ggml_add && ggml_are_same_shape(a, b[0]) && nf == 1 && !perm1; if (grad_supported) { ggml_set_param(a); ggml_set_param(b[0]); } ggml_tensor *out; if (src_overlap) { out = ggml_view_4d(ctx, a, ne[0], ne[1], ne[2], 2 * (ne[3] / 3), a->nb[1], a->nb[2], a->nb[3], 0); } else { out = a; } for (int i = 0; i < nf; ++i) { out = op(ctx, out, b[i]); } ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (op == ggml_mul || op == ggml_div) { // MUL and DIV have numerical issues around zero: init_tensor_uniform(t, 0.9f, 1.1f); } else { init_tensor_uniform(t); } } } float grad_eps() override { return 0.1f * (op == ggml_mul ? ne[0]*ne[1]*ne[2]*ne[3] : 1); } bool grad_precise() override { return op == ggml_div; } double max_maa_err() override { return op == ggml_add ? 1e-4 : 1e-3; } }; // GGML_OP_ADD_ID struct test_add_id : public test_case { const ggml_type type_a; const ggml_type type_b; const int64_t n_embd; const int64_t n_experts; const int64_t n_experts_used; const int64_t n_token; std::string vars() override { return VARS_TO_STR6(type_a, type_b, n_embd, n_experts, n_experts_used, n_token); } size_t op_size(ggml_tensor * t) override { return ggml_nbytes(t) + ggml_nbytes(t->src[0]) + ggml_nbytes(t->src[2]); } test_add_id(ggml_type type_a = GGML_TYPE_F32, ggml_type type_b = GGML_TYPE_F32, int64_t n_embd = 128, int64_t n_experts = 16, int64_t n_experts_used = 8, int64_t n_token = 10) : type_a(type_a), type_b(type_b), n_embd(n_embd), n_experts(n_experts), n_experts_used(n_experts_used), n_token(n_token) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_3d(ctx, type_a, n_embd, n_experts_used, n_token); ggml_tensor * b = ggml_new_tensor_2d(ctx, type_b, n_embd, n_experts); ggml_tensor * ids = ggml_new_tensor_2d(ctx, GGML_TYPE_I32, n_experts, n_token); if (n_experts_used != n_experts) { ids = ggml_view_2d(ctx, ids, n_experts_used, n_token, ids->nb[1], 0); ggml_set_name(ids, "view_of_ids"); } ggml_tensor * out = ggml_add_id(ctx, a, b, ids); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } std::random_device rd; std::default_random_engine rng(rd()); // ids for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i % n_experts; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(int32_t)); } } else { init_tensor_uniform(t); } } } }; // GGML_OP_ADD1 struct test_add1 : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_add1(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * b = ggml_new_tensor_1d(ctx, type, 1); // ggml_set_param(b); // TODO: implement ggml_set_name(b, "b"); ggml_tensor * out = ggml_add1(ctx, a, b); ggml_set_name(out, "out"); return out; } float grad_eps() override { return 0.1f * ne[0]*ne[1]*ne[2]*ne[3]; } }; // GGML_OP_SCALE struct test_scale : public test_case { const ggml_type type; const std::array ne; float scale; float bias; bool inplace; std::string vars() override { return VARS_TO_STR5(type, ne, scale, bias, inplace); } test_scale(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 10, 10}, float scale = 2.0f, float bias = 0.0f, bool inplace = false) : type(type), ne(ne), scale(scale), bias(bias), inplace(inplace) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out; if (inplace) { out = ggml_scale_bias_inplace(ctx, a, scale, bias); } else { out = ggml_scale_bias(ctx, a, scale, bias); } ggml_set_name(out, "out"); return out; } }; // GGML_OP_SCALE + GGML_UNARY_OP_TANH + GGML_OP_SCALE struct test_softcap : public test_case { const ggml_type type; const std::array ne; float softcap; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "SOFTCAP"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR3(type, ne, softcap); } test_softcap(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 10, 10}, float softcap = 30.0f) : type(type), ne(ne), softcap(softcap) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_scale(ctx, ggml_tanh(ctx, ggml_scale(ctx, a, 1.0f / softcap)), softcap); ggml_set_name(out, "out"); return out; } }; // GGML_OP_SILU_BACK struct test_silu_back : public test_case { const ggml_type type; const std::array ne; float eps; std::string vars() override { return VARS_TO_STR3(type, ne, eps); } test_silu_back(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, float eps = 1e-6f) : type(type), ne(ne), eps(eps) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * grad = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(grad, "grad"); ggml_tensor * out = ggml_silu_back(ctx, a, grad); ggml_set_name(out, "out"); return out; } bool grad_precise() override { return true; } }; // GGML_OP_NORM struct test_norm : public test_case { const ggml_type type; const std::array ne; const bool v; // whether a is a non-contiguous view const float eps; std::string vars() override { return VARS_TO_STR4(type, ne, v, eps); } test_norm(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, bool v = false, float eps = 1e-6f) : type(type), ne(ne), v(v), eps(eps) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); if (v) { a = ggml_view_4d(ctx, a, a->ne[0]/2, a->ne[1]/2, a->ne[2]/2, a->ne[3]/2, a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view of a"); } ggml_tensor * out = ggml_norm(ctx, a, eps); ggml_set_name(out, "out"); return out; } }; // GGML_OP_NORM + GGML_OP_MUL + GGML_OP_ADD struct test_norm_mul_add : public test_case { const ggml_type type; const std::array ne; float eps; const bool broadcast; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "NORM_MUL_ADD"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR4(type, ne, eps, broadcast); } test_norm_mul_add(ggml_type type = GGML_TYPE_F32, std::array ne = {128, 2, 1, 1}, float eps = 1e-5f, bool broadcast = false) : type(type), ne(ne), eps(eps), broadcast(broadcast) {} ggml_tensor * build_graph(ggml_context * ctx) override { std::array broadcast_dims = {ne[0], ne[1] * 2, ne[2] * 2, ne[3] * 2}; ggml_tensor * a = ggml_new_tensor(ctx, type, 4, broadcast ? broadcast_dims.data() : ne.data()); ggml_tensor * w = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_param(w); ggml_set_param(b); ggml_set_name(a, "a"); ggml_set_name(w, "w"); ggml_set_name(b, "b"); // Use a, w and b early to avoid OP_NONE in graph a = ggml_add(ctx, ggml_add(ctx, a, w), b); ggml_tensor * n = ggml_norm(ctx, a, eps); ggml_tensor * m = ggml_mul(ctx, n, w); ggml_tensor * out = ggml_add(ctx, m, b); ggml_set_name(out, "out"); return out; } }; // GGML_OP_RMS_NORM struct test_rms_norm : public test_case { const ggml_type type; const std::array ne; const bool v; // whether a is a non-contiguous view const float eps; const bool inplace; // whether to do the operation inplace std::string vars() override { return VARS_TO_STR5(type, ne, v, eps, inplace); } test_rms_norm(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, bool v = false, float eps = 1e-6f, bool inplace = false) : type(type), ne(ne), v(v), eps(eps), inplace(inplace) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); if (v) { a = ggml_view_4d(ctx, a, a->ne[0]/2, a->ne[1]/2, a->ne[2]/2, a->ne[3]/2, a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view of a"); } ggml_tensor * out; if (inplace) { out = ggml_rms_norm_inplace(ctx, a, eps); } else { out = ggml_rms_norm(ctx, a, eps); } ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.f, 10.f); } } float grad_eps() override { return 1.0f; } bool grad_precise() override { return true; } }; // GGML_OP_RMS_NORM_BACK struct test_rms_norm_back : public test_case { const ggml_type type; const std::array ne; const float eps; std::string vars() override { return VARS_TO_STR3(type, ne, eps); } test_rms_norm_back(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, float eps = 1e-6f) : type(type), ne(ne), eps(eps) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(b, "b"); ggml_tensor * out = ggml_rms_norm_back(ctx, a, b, eps); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.f, 10.f); } } }; // GGML_OP_RMS_NORM + GGML_OP_MUL + GGML_OP_ADD struct test_rms_norm_mul_add : public test_case { const ggml_type type; const std::array ne; const float eps; const bool broadcast; const bool multi_add; // test a sequence of adds feeding into rms_norm std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "RMS_NORM_MUL_ADD"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR5(type, ne, eps, broadcast, multi_add); } test_rms_norm_mul_add(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, float eps = 1e-6f, bool broadcast = false, bool multi_add = false) : type(type), ne(ne), eps(eps), broadcast(broadcast), multi_add(multi_add) {} ggml_tensor * build_graph(ggml_context * ctx) override { std::array broadcast_dims = {ne[0]*2, ne[1]*3, ne[2]*3, ne[3]*4}; ggml_tensor * a = ggml_new_tensor(ctx, type, 4, broadcast ? broadcast_dims.data() : ne.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_tensor * c = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_set_param(b); ggml_set_name(b, "b"); ggml_set_param(c); ggml_set_name(c, "c"); // Use a, b and c early, so we don't end up with an OP_NONE between rms_norm and mul a = ggml_add(ctx, ggml_add(ctx, a, b), c); if (multi_add) { a = ggml_add(ctx, ggml_add(ctx, a, b), c); } ggml_tensor * out = ggml_add(ctx, ggml_mul(ctx, ggml_rms_norm(ctx, a, eps), b), c); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.f, 10.f); } } float grad_eps() override { return 1.0f; } bool grad_precise() override { return true; } }; // GGML_OP_ADD + GGML_OP_RMS_NORM (fused operation) struct test_add_rms_norm : public test_case { const ggml_type type; const std::array ne; const float eps; const bool broadcast; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "ADD_RMS_NORM"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR4(type, ne, eps, broadcast); } test_add_rms_norm(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 5, 4, 3}, float eps = 1e-6f, bool broadcast = false) : type(type), ne(ne), eps(eps), broadcast(broadcast) {} ggml_tensor * build_graph(ggml_context * ctx) override { std::array broadcast_dims = {ne[0]*2, ne[1]*3, ne[2]*3, ne[3]*4}; ggml_tensor * a = ggml_new_tensor(ctx, type, 4, broadcast ? broadcast_dims.data() : ne.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_set_param(b); ggml_set_name(b, "b"); // ADD operation followed by RMS_NORM ggml_tensor * add_result = ggml_add(ctx, a, b); ggml_set_name(add_result, "add_result"); ggml_tensor * out = ggml_rms_norm(ctx, add_result, eps); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.f, 10.f); } } float grad_eps() override { return 1.0f; } bool grad_precise() override { return true; } }; // GGML_OP_SSM_CONV struct test_ssm_conv : public test_case { const ggml_type type; const std::array ne_a; const std::array ne_b; std::string vars() override { return VARS_TO_STR3(type, ne_a, ne_b); } test_ssm_conv(ggml_type type = GGML_TYPE_F32, std::array ne_a = {10, 10, 10, 1}, std::array ne_b = {3, 3, 1, 1}) : type(type), ne_a(ne_a), ne_b(ne_b) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne_b.data()); ggml_tensor * out = ggml_ssm_conv(ctx, a, b); return out; } }; // GGML_OP_SSM_SCAN struct test_ssm_scan : public test_case { const ggml_type type; const int64_t d_state; const int64_t head_dim; const int64_t n_head; const int64_t n_group; const int64_t n_seq_tokens; const int64_t n_seqs; std::string vars() override { return VARS_TO_STR7(type, d_state, head_dim, n_head, n_group, n_seq_tokens, n_seqs); } test_ssm_scan(ggml_type type = GGML_TYPE_F32, int64_t d_state = 32, int64_t head_dim = 1, // non-zero for Mamba-2 int64_t n_head = 32, int64_t n_group = 1, int64_t n_seq_tokens = 32, int64_t n_seqs = 32) : type(type), d_state(d_state), head_dim(head_dim), n_head(n_head), n_group(n_group), n_seq_tokens(n_seq_tokens), n_seqs(n_seqs) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * s = ggml_new_tensor_4d(ctx, type, d_state, head_dim, n_head, n_seqs); ggml_tensor * x = ggml_new_tensor_4d(ctx, type, head_dim, n_head, n_seq_tokens, n_seqs); ggml_tensor * dt = ggml_new_tensor_3d(ctx, type, n_head, n_seq_tokens, n_seqs); ggml_tensor * A = ggml_new_tensor_2d(ctx, type, (head_dim > 1) ? 1 : d_state, n_head); ggml_tensor * B = ggml_new_tensor_4d(ctx, type, d_state, n_group, n_seq_tokens, n_seqs); ggml_tensor * C = ggml_new_tensor_4d(ctx, type, d_state, n_group, n_seq_tokens, n_seqs); ggml_tensor * ids = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, n_seqs); ggml_tensor * out = ggml_ssm_scan(ctx, s, x, dt, A, B, C, ids); return out; } // similar to test_mul_mat_id void initialize_tensors(ggml_context * ctx) override { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } // ids for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(int32_t)); } } else { init_tensor_uniform(t); } } } }; // GGML_OP_RWKV_WKV6 struct test_rwkv_wkv6 : public test_case { const ggml_type type; const int64_t head_count; const int64_t head_size; const int64_t n_seq_tokens; const int64_t n_seqs; std::string vars() override { return VARS_TO_STR5(type, head_count, head_size, n_seq_tokens, n_seqs); } test_rwkv_wkv6(ggml_type type = GGML_TYPE_F32, int64_t head_count = 32, int64_t head_size = 64, int64_t n_seq_tokens = 32, int64_t n_seqs = 32) : type(type), head_count(head_count), head_size(head_size), n_seq_tokens(n_seq_tokens), n_seqs(n_seqs) {} ggml_tensor * build_graph(ggml_context * ctx) override { const int64_t n_tokens = n_seq_tokens * n_seqs; ggml_tensor * r = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * k = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * v = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * tf = ggml_new_tensor(ctx, type, 2, std::vector{ head_size, head_count }.data()); ggml_tensor * td = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * s = ggml_new_tensor(ctx, type, 2, std::vector{ head_size * head_size * head_count, n_seqs }.data()); ggml_tensor * out = ggml_rwkv_wkv6(ctx, k, v, r, tf, td, s); return out; } }; // GGML_OP_GATED_DELTA_NET struct test_gated_delta_net : public test_case { const ggml_type type; const int64_t head_count; const int64_t head_size; const int64_t n_seq_tokens; const int64_t n_seqs; const int v_repeat; const bool permuted; const bool kda; std::string vars() override { return VARS_TO_STR8(type, head_count, head_size, n_seq_tokens, n_seqs, v_repeat, permuted, kda); } test_gated_delta_net(ggml_type type = GGML_TYPE_F32, int64_t head_count = 4, int64_t head_size = 16, int64_t n_seq_tokens = 1, int64_t n_seqs = 1, int v_repeat = 1, bool permuted = false, bool kda = false) : type(type), head_count(head_count), head_size(head_size), n_seq_tokens(n_seq_tokens), n_seqs(n_seqs), v_repeat(v_repeat), permuted(permuted), kda(kda) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * q; ggml_tensor * k; ggml_tensor * v; if (permuted) { // create with dims 1 and 2 swapped, then permute back to get non-contiguous layout q = ggml_permute(ctx, ggml_new_tensor_4d(ctx, type, head_size, n_seq_tokens, head_count, n_seqs), 0, 2, 1, 3); k = ggml_permute(ctx, ggml_new_tensor_4d(ctx, type, head_size, n_seq_tokens, head_count, n_seqs), 0, 2, 1, 3); v = ggml_permute(ctx, ggml_new_tensor_4d(ctx, type, head_size, n_seq_tokens, head_count * v_repeat, n_seqs), 0, 2, 1, 3); } else { q = ggml_new_tensor_4d(ctx, type, head_size, head_count, n_seq_tokens, n_seqs); k = ggml_new_tensor_4d(ctx, type, head_size, head_count, n_seq_tokens, n_seqs); v = ggml_new_tensor_4d(ctx, type, head_size, head_count * v_repeat, n_seq_tokens, n_seqs); } const int64_t g_ne0 = kda ? head_size : 1; ggml_tensor * g = ggml_new_tensor_4d(ctx, type, g_ne0, head_count * v_repeat, n_seq_tokens, n_seqs); ggml_tensor * beta = ggml_new_tensor_4d(ctx, type, 1, head_count * v_repeat, n_seq_tokens, n_seqs); ggml_tensor * state = ggml_new_tensor_2d(ctx, type, head_size * v_repeat * head_size * head_count, n_seqs); ggml_tensor * out = ggml_gated_delta_net(ctx, q, k, v, g, beta, state); return out; } }; // GGML_OP_GATED_LINEAR_ATTN struct test_gla : public test_case { const ggml_type type; const int64_t head_count; const int64_t head_size; const int64_t n_seq_tokens; const int64_t n_seqs; std::string vars() override { return VARS_TO_STR5(type, head_count, head_size, n_seq_tokens, n_seqs); } test_gla(ggml_type type = GGML_TYPE_F32, int64_t head_count = 32, int64_t head_size = 64, int64_t n_seq_tokens = 32, int64_t n_seqs = 32) : type(type), head_count(head_count), head_size(head_size), n_seq_tokens(n_seq_tokens), n_seqs(n_seqs) {} ggml_tensor * build_graph(ggml_context * ctx) override { const int64_t n_tokens = n_seq_tokens * n_seqs; ggml_tensor * q = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * k = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * v = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * g = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * s = ggml_new_tensor(ctx, type, 2, std::vector{ head_size * head_size * head_count, n_seqs }.data()); ggml_tensor * out = ggml_gated_linear_attn(ctx, k, v, q, g, s, pow(head_size, -0.5)); return out; } }; // GGML_OP_RWKV_WKV7 struct test_rwkv_wkv7 : public test_case { const ggml_type type; const int64_t head_count; const int64_t head_size; const int64_t n_seq_tokens; const int64_t n_seqs; std::string vars() override { return VARS_TO_STR5(type, head_count, head_size, n_seq_tokens, n_seqs); } test_rwkv_wkv7(ggml_type type = GGML_TYPE_F32, int64_t head_count = 32, int64_t head_size = 64, int64_t n_seq_tokens = 32, int64_t n_seqs = 32) : type(type), head_count(head_count), head_size(head_size), n_seq_tokens(n_seq_tokens), n_seqs(n_seqs) {} ggml_tensor * build_graph(ggml_context * ctx) override { const int64_t n_tokens = n_seq_tokens * n_seqs; ggml_tensor * r = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * w = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * k = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * v = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * a = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 3, std::vector{ head_size, head_count, n_tokens }.data()); // Outputs may become NaN with long seqlen without these normalization a = ggml_l2_norm(ctx, a, 1e-7F); b = ggml_l2_norm(ctx, b, 1e-7F); ggml_tensor * s = ggml_new_tensor(ctx, type, 2, std::vector{ head_size * head_size * head_count, n_seqs }.data()); ggml_tensor * out = ggml_rwkv_wkv7(ctx, r, w, k, v, a, b, s); return out; } }; // GGML_OP_MUL_MAT struct test_mul_mat : public test_case { const ggml_type type_a; const ggml_type type_b; const int64_t m; const int64_t n; const int64_t k; const std::array bs; // dims 3 and 4 const std::array nr; // repeat in dims 3 and 4 const std::array per; // permutation of dimensions const int64_t k_v; // size of k in memory, resulting in a non-contiguous view for k_v > k, no view for k_v == 0 const uint32_t o; // number of outputs std::string vars() override { return VARS_TO_STR10(type_a, type_b, m, n, k, bs, nr, per, k_v, o); } double max_nmse_err() override { return 5e-4; } double max_nmse_err(ggml_backend_t backend) override { // for blackwell we quantize activations to mxfp4 instead of q8_1 so we add higher tolerance if (type_a == GGML_TYPE_MXFP4 && backend_has_feature(backend, "BLACKWELL_NATIVE_FP4")) { return 2e-2; } return max_nmse_err(); } int64_t grad_nmax() override { return 20000; } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); return 2 * m * n * k * bs[0] * nr[0] * bs[1] * nr[1]; } test_mul_mat(ggml_type type_a = GGML_TYPE_F32, ggml_type type_b = GGML_TYPE_F32, int64_t m = 32, int64_t n = 32, int64_t k = 32, std::array bs = {10, 10}, std::array nr = {2, 2}, std::array per = {0, 1, 2, 3}, int64_t k_v = 0, uint32_t o = 1) : type_a(type_a), type_b(type_b), m(m), n(n), k(k), bs(bs), nr(nr), per(per), k_v(k_v), o(o) {} ggml_tensor * build_graph(ggml_context * ctx) override { // C^T = A * B^T: (k, m) * (k, n) => (m, n) ggml_tensor * a; ggml_tensor * b; const int npermuted = (per[0] != 0) + (per[1] != 1) + (per[2] != 2) + (per[3] != 3); if (npermuted > 0) { GGML_ASSERT(npermuted == 2); GGML_ASSERT(k_v == 0); // not handled GGML_ASSERT(!ggml_is_quantized(type_a) || per[0] == 0); GGML_ASSERT(!ggml_is_quantized(type_b) || per[0] == 0); // Create tensors with the permuted dimensions, then permute them back to the dimensions given by m,n,k. const int64_t ne_a[4] = {k, m, bs[0], bs[1]}; const int64_t ne_b[4] = {k, n, bs[0]*nr[0], bs[1]*nr[1]}; a = ggml_new_tensor_4d(ctx, type_a, ne_a[per[0]], ne_a[per[1]], ne_a[per[2]], ne_a[per[3]]); b = ggml_new_tensor_4d(ctx, type_b, ne_b[per[0]], ne_b[per[1]], ne_b[per[2]], ne_b[per[3]]); if (!ggml_is_quantized(type_a)) { if (bs[1] == 1 && nr[1] == 1) { ggml_set_param(a); } ggml_set_param(b); } ggml_set_name(a, "a"); ggml_set_name(b, "b"); a = ggml_permute(ctx, a, per[0], per[1], per[2], per[3]); b = ggml_permute(ctx, b, per[0], per[1], per[2], per[3]); ggml_set_name(a, "a_permuted"); ggml_set_name(b, "b_permuted"); } else { const int64_t k_physical = k_v == 0 ? k : k_v; a = ggml_new_tensor_4d(ctx, type_a, k_physical, m, bs[0], bs[1]); b = ggml_new_tensor_4d(ctx, type_b, k_physical, n, bs[0]*nr[0], bs[1]*nr[1]); if (!ggml_is_quantized(type_a)) { if (bs[1] == 1 && nr[1] == 1) { ggml_set_param(a); } ggml_set_param(b); } if (k_v != 0) { GGML_ASSERT(k_v > k); a = ggml_view_4d(ctx, a, k, m, bs[0], bs[1], a->nb[1], a->nb[2], a->nb[3], 0); b = ggml_view_4d(ctx, b, k, n, bs[0]*nr[0], bs[1]*nr[1], b->nb[1], b->nb[2], b->nb[3], 0); } ggml_set_name(a, "a"); ggml_set_name(b, "b"); } ggml_tensor * out = ggml_mul_mat(ctx, a, b); ggml_set_name(out, "out"); for (uint32_t i = 1; i < o; ++i) { ggml_tensor * out2 = ggml_mul_mat(ctx, a, b); ggml_set_name(out2, "out2"); out = ggml_add(ctx, out, out2); } return out; } bool run_whole_graph() override { return o > 1; } std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return ggml_op_name(GGML_OP_MUL_MAT); } }; static void init_mul_mat_id_tensors(ggml_context * ctx, int n_mats) { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { if (ggml_is_view_op(t->op)) { continue; } // ids for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i % n_mats; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(int32_t)); } } else { init_tensor_uniform(t); } } } // GGML_OP_MUL_MAT_ID struct test_mul_mat_id : public test_case { const ggml_type type_a; const ggml_type type_b; const int n_mats; const int n_used; const bool b; // broadcast b matrix const int64_t m; const int64_t n; const int64_t k; std::string vars() override { return VARS_TO_STR8(type_a, type_b, n_mats, n_used, b, m, n, k); } double max_nmse_err() override { return 5e-4; } double max_nmse_err(ggml_backend_t backend) override { // for blackwell we quantize activations to mxfp4 instead of q8_1 so we add higher tolerance if (type_a == GGML_TYPE_MXFP4 && backend_has_feature(backend, "BLACKWELL_NATIVE_FP4")) { return 2e-2; } return max_nmse_err(); } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); return 2 * m * k * n * n_used; } test_mul_mat_id(ggml_type type_a = GGML_TYPE_F32, ggml_type type_b = GGML_TYPE_F32, int n_mats = 8, int n_used = 2, bool b = false, int64_t m = 32, int64_t n = 32, int64_t k = 32) : type_a(type_a), type_b(type_b), n_mats(n_mats), n_used(n_used), b(b), m(m), n(n), k(k) { GGML_ASSERT(n_used <= n_mats); } ggml_tensor * build_graph(ggml_context * ctx) override { // C^T = A * B^T: (k, m) * (k, n) => (m, n) ggml_tensor * as = ggml_new_tensor_3d(ctx, type_a, k, m, n_mats); ggml_set_name(as, "as"); ggml_tensor * ids = ggml_new_tensor_2d(ctx, GGML_TYPE_I32, n_mats, n); ggml_set_name(ids, "ids"); if (n_used != n_mats) { ids = ggml_view_2d(ctx, ids, n_used, n, ids->nb[1], 0); ggml_set_name(ids, "view_of_ids"); } ggml_tensor * b = ggml_new_tensor_3d(ctx, type_b, k, this->b ? 1 : n_used, n); ggml_set_name(b, "b"); ggml_tensor * out = ggml_mul_mat_id(ctx, as, b, ids); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { init_mul_mat_id_tensors(ctx, n_mats); } }; // GGML_OP_MUL_MAT_ID + GGML_OP_ADD or GGML_OP_MUL struct test_mul_mat_id_fusion : public test_case { const ggml_type type_a; const ggml_type type_b; const int n_mats; const int n_used; const bool b; // broadcast b matrix const int64_t m; const int64_t n; const int64_t k; const uint32_t o; // number of outputs const bool mul; std::string vars() override { return VARS_TO_STR10(type_a, type_b, n_mats, n_used, b, m, n, k, o, mul); } double max_nmse_err() override { return 5e-4; } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); return 2 * m * k * n * n_used; } test_mul_mat_id_fusion(ggml_type type_a = GGML_TYPE_F32, ggml_type type_b = GGML_TYPE_F32, int n_mats = 8, int n_used = 2, bool b = false, int64_t m = 32, int64_t n = 32, int64_t k = 32, uint32_t o = 1, bool mul = false) : type_a(type_a), type_b(type_b), n_mats(n_mats), n_used(n_used), b(b), m(m), n(n), k(k), o(o), mul(mul) { GGML_ASSERT(n_used <= n_mats); } ggml_tensor * build_graph(ggml_context * ctx) override { // C^T = A * B^T: (k, m) * (k, n) => (m, n) ggml_tensor * as = ggml_new_tensor_3d(ctx, type_a, k, m, n_mats); ggml_set_name(as, "as"); ggml_tensor * ids = ggml_new_tensor_2d(ctx, GGML_TYPE_I32, n_mats, n); ggml_set_name(ids, "ids"); if (n_used != n_mats) { ids = ggml_view_2d(ctx, ids, n_used, n, ids->nb[1], 0); ggml_set_name(ids, "view_of_ids"); } ggml_tensor * b = ggml_new_tensor_3d(ctx, type_b, k, this->b ? 1 : n_used, n); ggml_set_name(b, "b"); ggml_tensor * out = ggml_mul_mat_id(ctx, as, b, ids); ggml_set_name(out, "out"); for (uint32_t i = 1; i < o; ++i) { ggml_tensor * a2 = ggml_new_tensor_3d(ctx, type_a, k, m, n_mats); ggml_tensor * out2 = ggml_mul_mat_id(ctx, a2, b, ids); ggml_set_name(out2, "out2"); out = ggml_add(ctx, out, out2); } if (mul) { std::array ne { 1, out->ne[1], out->ne[2], out->ne[3] }; ne[0] = 1; ggml_tensor * m = ggml_new_tensor(ctx, out->type, 4, ne.data()); out = ggml_mul(ctx, out, m); } return out; } void initialize_tensors(ggml_context * ctx) override { init_mul_mat_id_tensors(ctx, n_mats); } bool run_whole_graph() override { return true; } std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "MUL_MAT_ID_FUSION"; } }; // GGML_OP_OUT_PROD struct test_out_prod : public test_case { const ggml_type type_a; const ggml_type type_b; const int64_t m; const int64_t n; const int64_t k; const std::array bs; // dims 3 and 4 const std::array nr; // repeat in dims 3 and 4 const bool trans_b; std::string vars() override { return VARS_TO_STR8(type_a, type_b, m, n, k, bs, nr, trans_b); } double max_nmse_err() override { return 5e-4; } test_out_prod(ggml_type type_a = GGML_TYPE_F32, ggml_type type_b = GGML_TYPE_F32, int64_t m = 32, int64_t n = 32, int64_t k = 32, std::array bs = {10, 10}, std::array nr = {2, 2}, bool trans_b = false) : type_a(type_a), type_b(type_b), m(m), n(n), k(k), bs(bs), nr(nr), trans_b(trans_b) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type_a, m, k, bs[0], bs[1]); ggml_set_name(a, "a"); ggml_tensor * b; if (trans_b) { b = ggml_new_tensor_4d(ctx, type_b, k, n, bs[0]*nr[0], bs[1]*nr[1]); b = ggml_transpose(ctx, b); } else { b = ggml_new_tensor_4d(ctx, type_b, n, k, bs[0]*nr[0], bs[1]*nr[1]); } ggml_set_name(b, "b"); ggml_tensor * out = ggml_out_prod(ctx, a, b); ggml_set_name(out, "out"); return out; } }; // GGML_OP_SQR struct test_sqr : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_sqr(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_sqr(ctx, a); ggml_set_name(out, "out"); return out; } float grad_eps() override { return 0.1f * 0.25f*ne[0]*ne[1]*ne[2]*ne[3]; // 10% of expected value of sum. } }; // GGML_OP_SQRT struct test_sqrt : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_sqrt(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 3, 3, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_sqrt(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { // fill with positive values for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, 50.0f, 100.0f); } } float grad_eps() override { return 20.0f; } bool grad_precise() override { return true; } }; // GGML_OP_LOG struct test_log : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_log(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_log(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { // log(1) == 0, cluster values there to keep the sum low for better precision in the backward pass: init_tensor_uniform(t, 0.9f, 1.1f); } } bool grad_precise() override { return true; } }; // GGML_OP_SIN struct test_sin : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_sin(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_sin(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -6.5f, 6.5f); // Covers interval [-2*pi, 2*pi]. } } double max_maa_err() override { return 1e-3; } float grad_eps() override { return 0.2f; } bool grad_precise() override { return true; } }; // GGML_OP_COS struct test_cos : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_cos(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_cos(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -6.5f, 6.5f); // Covers interval [-2*pi, 2*pi]. } } double max_maa_err() override { return 1e-3; } float grad_eps() override { return 0.2f; } bool grad_precise() override { return true; } }; // GGML_OP_CLAMP struct test_clamp : public test_case { const ggml_type type; const std::array ne; float min; float max; std::string vars() override { return VARS_TO_STR4(type, ne, min, max); } test_clamp(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, float min = -0.5f, float max = 0.5f) : type(type), ne(ne), min(min), max(max) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_clamp(ctx, a, min, max); ggml_set_name(out, "out"); return out; } float grad_eps() override { return 1e-2f; } std::vector grad_expect() override { return {0.0f, 1.0f}; } }; // GGML_OP_FLOOR struct test_floor : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_floor(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_floor(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.0f, 10.0f); } } }; // GGML_OP_CEIL struct test_ceil : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_ceil(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_ceil(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.0f, 10.0f); } } }; // GGML_OP_ROUND struct test_round : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_round(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_round(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.0f, 10.0f); } } }; // GGML_OP_TRUNC struct test_trunc : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_trunc(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 2, 2, 2}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_trunc(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -10.0f, 10.0f); } } }; // GGML_OP_DIAG_MASK_INF struct test_diag_mask_inf : public test_case { const ggml_type type; const std::array ne; const int n_past; std::string vars() override { return VARS_TO_STR3(type, ne, n_past); } test_diag_mask_inf(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 10, 3, 2}, int n_past = 5) : type(type), ne(ne), n_past(n_past) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_diag_mask_inf(ctx, a, n_past); ggml_set_name(out, "out"); return out; } }; // GGML_OP_SOFT_MAX struct test_soft_max : public test_case { const ggml_type type; const std::array ne; const bool mask; const bool sinks; const ggml_type m_prec; const std::array nr23; // broadcast only dims 2 and 3 const float scale; const float max_bias; const bool inplace; std::string vars() override { return VARS_TO_STR9(type, ne, mask, sinks, m_prec, nr23, scale, max_bias, inplace); } // the 1024 test with bias occasionally fails: // SOFT_MAX(type=f32,ne=[1024,16,1,1],mask=1,scale=1.000000,max_bias=8.000000): [SOFT_MAX] NMSE = 0.000000103 > 0.000000100 FAIL virtual double max_nmse_err() override { return 1e-6; } test_soft_max(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, bool mask = false, bool sinks = false, ggml_type m_prec = GGML_TYPE_F32, std::array nr23 = {1, 1}, float scale = 1.0f, float max_bias = 0.0f, bool inplace = false) : type(type), ne(ne), mask(mask), sinks(sinks), m_prec(m_prec), nr23(nr23), scale(scale), max_bias(max_bias), inplace(inplace) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2]*nr23[0], ne[3]*nr23[1]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * mask = nullptr; if (this->mask) { mask = ggml_new_tensor_4d(ctx, m_prec, ne[0], ne[1], ne[2], ne[3]); ggml_set_name(mask, "mask"); } ggml_tensor * sinks = nullptr; if (this->sinks) { sinks = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, ne[2]*nr23[0]); ggml_set_name(sinks, "sinks"); } ggml_tensor * out; if (inplace) { out = ggml_soft_max_ext_inplace(ctx, a, mask, scale, max_bias); } else { out = ggml_soft_max_ext(ctx, a, mask, scale, max_bias); } ggml_soft_max_add_sinks(out, sinks); ggml_set_name(out, "out"); return out; } bool grad_precise() override { return true; } }; // GGML_OP_SOFT_MAX_BACK struct test_soft_max_back : public test_case { const ggml_type type; const std::array ne; const float scale; const float max_bias; std::string vars() override { return VARS_TO_STR4(type, ne, scale, max_bias); } test_soft_max_back(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, float scale = 1.0f, float max_bias = 0.0f) : type(type), ne(ne), scale(scale), max_bias(max_bias) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_soft_max_ext_back(ctx, a, b, scale, max_bias); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ROPE + GGML_OP_ROPE_BACK struct test_rope : public test_case { const ggml_type type; const std::array ne_a; int n_dims; int mode; int n_ctx; // used to generate positions float fs; // freq_scale float ef; // ext_factor float af; // attn_factor bool ff; int v; // view (1 : non-contiguous a) bool forward; bool inplace; std::string vars() override { // forward can be inferred from the op, does not need to be printed return VARS_TO_STR11(type, ne_a, n_dims, mode, n_ctx, fs, ef, af, ff, v, inplace); } test_rope(ggml_type type = GGML_TYPE_F32, std::array ne_a = {10, 5, 3, 1}, int n_dims = 10, int mode = GGML_ROPE_TYPE_NORMAL, int n_ctx = 512, float fs = 1.0f, float ef = 0.0f, float af = 0.0f, bool ff = false, int v = 0, bool forward = true, bool inplace = false) : type(type), ne_a(ne_a), n_dims(n_dims), mode(mode), n_ctx(n_ctx), fs(fs), ef(ef), af(af), ff(ff), v(v), forward(forward), inplace(inplace) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a; if (v & 1) { auto ne = ne_a; ne[0] *= 2; ne[1] *= 4; ne[2] *= 3; a = ggml_new_tensor(ctx, type, 4, ne.data()); if (forward) { ggml_set_param(a); } ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); if (forward) { ggml_set_param(a); } ggml_set_name(a, "a"); } const bool is_mrope = mode & GGML_ROPE_TYPE_MROPE; const bool is_vision = mode == GGML_ROPE_TYPE_VISION; ggml_tensor * pos; if (is_mrope || is_vision) { pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, ne_a[2] * 4); } else { pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, ne_a[2]); } ggml_set_name(pos, "pos"); ggml_tensor * freq = nullptr; if (ff) { freq = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_dims/2); ggml_set_name(freq, "freq"); } ggml_tensor * out; if (is_mrope) { if (is_vision) { GGML_ASSERT(n_dims/4 > 0); int rope_sections[4] = {n_dims/4, n_dims/4, 0, 0}; // Vision-RoPE only use first two dimension for image (x, y) coordinate if (forward) { if (inplace) { out = ggml_rope_multi_inplace(ctx, a, pos, freq, n_dims/2, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } else { out = ggml_rope_multi(ctx, a, pos, freq, n_dims/2, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } else { out = ggml_rope_multi_back(ctx, a, pos, freq, n_dims/2, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } else { GGML_ASSERT(n_dims/3 > 0); int rope_sections[4] = {n_dims/3, n_dims/3, n_dims/3, 0}; if (forward) { if (inplace) { out = ggml_rope_multi_inplace(ctx, a, pos, freq, n_dims, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } else { out = ggml_rope_multi(ctx, a, pos, freq, n_dims, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } else { out = ggml_rope_multi_back(ctx, a, pos, freq, n_dims, rope_sections, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } } else { if (forward) { if (inplace) { out = ggml_rope_ext_inplace(ctx, a, pos, freq, n_dims, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } else { out = ggml_rope_ext(ctx, a, pos, freq, n_dims, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } } else { out = ggml_rope_ext_back(ctx, a, pos, freq, n_dims, mode, 0, 10000.0f, fs, ef, af, 1.0f, 1.0f); } // TODO: add test with a non-contiguous view as input ; this case is needed for build_rope_2d in clip.cpp } ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { // pos const int num_pos_ids = (mode & GGML_ROPE_TYPE_MROPE) ? ne_a[2] * 4 : ne_a[2]; std::vector data(num_pos_ids); for (int i = 0; i < num_pos_ids; i++) { data[i] = rand() % n_ctx; } ggml_backend_tensor_set(t, data.data(), 0, num_pos_ids * sizeof(int)); } else { if (t->ne[0] == n_dims/2) { // frequency factors in the range [0.9f, 1.1f] init_tensor_uniform(t, 0.9f, 1.1f); } else { init_tensor_uniform(t); } } } } double max_maa_err() override { return 1e-3; } bool grad_precise() override { return true; } }; // GGML_OP_POOL2D struct test_pool2d : public test_case { enum ggml_op_pool pool_type; const ggml_type type_input; const std::array ne_input; // kernel size const int k0; const int k1; // stride const int s0; const int s1; // padding const int p0; const int p1; std::string vars() override { return VARS_TO_STR9(pool_type, type_input, ne_input, k0, k1, s0, s1, p0, p1); } test_pool2d(ggml_op_pool pool_type = GGML_OP_POOL_AVG, ggml_type type_input = GGML_TYPE_F32, std::array ne_input = {10, 10, 3, 1}, // [input_width, input_height, input_channels, 1] int k0 = 3, int k1 = 3, int s0 = 1, int s1 = 1, int p0 = 1, int p1 = 1) : pool_type(pool_type), type_input(type_input), ne_input(ne_input), k0(k0), k1(k1), s0(s0), s1(s1), p0(p0), p1(p1) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, type_input, 4, ne_input.data()); ggml_set_param(input); ggml_set_name(input, "input"); ggml_tensor * out = ggml_pool_2d(ctx, input, pool_type, k0, k1, s0, s1, p0, p1); ggml_set_name(out, "out"); return out; } }; // GGML_OP_POOL1D struct test_pool1d : public test_case { enum ggml_op_pool pool_type; const ggml_type type_input; const std::array ne_input; const int k0; const int s0; const int p0; std::string vars() override { return VARS_TO_STR6(pool_type, type_input, ne_input, k0, s0, p0); } test_pool1d(ggml_op_pool pool_type = GGML_OP_POOL_AVG, ggml_type type_input = GGML_TYPE_F32, std::array ne_input = {10, 1, 1, 1}, int k0 = 3, int s0 = 3, int p0 = 0) : pool_type(pool_type), type_input(type_input), ne_input(ne_input), k0(k0), s0(s0), p0(p0) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, type_input, 4, ne_input.data()); ggml_set_param(input); ggml_set_name(input, "input"); ggml_tensor * out = ggml_pool_1d(ctx, input, pool_type, k0, s0, p0); ggml_set_name(out, "out"); return out; } }; // GGML_OP_CONV_TRANSPOSE_1D struct test_conv_transpose_1d : public test_case { const std::array ne_input; const std::array ne_kernel; const int s0; // stride const int p0; // padding const int d0; // dilation std::string vars() override { return VARS_TO_STR5(ne_input, ne_kernel, s0, p0, d0); } test_conv_transpose_1d(std::array ne_input = {197, 32, 1, 1}, // [input_width, input_channels, 1 /* assert in cpu kernel*/, 1 (should be batch)] std::array ne_kernel = {16, 32, 32, 1}, // [kernel_width, output_channels, input_channels, 1 (should be batch)] int s0 = 1, int p0 = 0, int d0 = 1) : ne_input(ne_input), ne_kernel(ne_kernel), s0(s0), p0(p0), d0(d0) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_input.data()); ggml_set_name(input, "input"); ggml_tensor * kernel = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); ggml_tensor * out = ggml_conv_transpose_1d(ctx, kernel, input, s0, p0, d0); ggml_set_name(out, "out"); return out; } }; // GGML_OP_CONV_TRANSPOSE_2D struct test_conv_transpose_2d : public test_case { // Dimensions const std::array ne_input; const std::array ne_kernel; const int stride; // Types const ggml_type kernel_type; std::string vars() override { return VARS_TO_STR4(kernel_type, ne_input, ne_kernel, stride); } double max_nmse_err() override { return 5e-4; // The default 1e-7 is too small for Vulkan. } test_conv_transpose_2d( std::array ne_input = {10, 10, 3, 1}, // [input_width, input_height, input_channels, 1] std::array ne_kernel = {3, 3, 3, 1}, // [kernel_width, kernel_height, input_channels, 1] int stride = 1, ggml_type kernel_type = GGML_TYPE_F16 ) : ne_input(ne_input), ne_kernel(ne_kernel), stride(stride), kernel_type(kernel_type) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_input.data()); ggml_set_name(input, "input"); ggml_tensor * kernel = ggml_new_tensor(ctx, kernel_type, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); ggml_tensor * out = ggml_conv_transpose_2d_p0(ctx, kernel, input, stride); ggml_set_name(out, "out"); return out; } }; // GGML_OP_IM2COL struct test_im2col : public test_case { const ggml_type type_input; const ggml_type type_kernel; const ggml_type dst_type; const std::array ne_input; const std::array ne_kernel; // stride const int s0; const int s1; // padding const int p0; const int p1; // dilation const int d0; const int d1; // mode const bool is_2D; std::string vars() override { return VARS_TO_STR12(type_input, type_kernel, dst_type, ne_input, ne_kernel, s0, s1, p0, p1, d0, d1, is_2D); } test_im2col(ggml_type type_input = GGML_TYPE_F32, ggml_type type_kernel = GGML_TYPE_F16, ggml_type dst_type = GGML_TYPE_F32, std::array ne_input = {10, 10, 3, 1}, // [input_width, input_height, input_channels, 1] std::array ne_kernel = {3, 3, 3, 1}, // [kernel_width, kernel_height, input_channels, 1] int s0 = 1, int s1 = 1, int p0 = 1, int p1 = 1, int d0 = 1, int d1 = 1, bool is_2D = true) : type_input(type_input), type_kernel(type_kernel), dst_type(dst_type), ne_input(ne_input), ne_kernel(ne_kernel), s0(s0), s1(s1), p0(p0), p1(p1), d0(d0), d1(d1), is_2D(is_2D) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, type_input, 4, ne_input.data()); ggml_set_param(input); ggml_set_name(input, "input"); ggml_tensor * kernel = ggml_new_tensor(ctx, type_kernel, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); ggml_tensor * out = ggml_im2col(ctx, kernel, input, s0, s1, p0, p1, d0, d1, is_2D, dst_type); ggml_set_name(out, "out"); return out; } }; // GGML_OP_IM2COL_3D struct test_im2col_3d : public test_case { const ggml_type type_input; const ggml_type type_kernel; const ggml_type dst_type; const std::array ne_input; const std::array ne_kernel; // stride const int s0; const int s1; const int s2; // padding const int p0; const int p1; const int p2; // dilation const int d0; const int d1; const int d2; const int64_t IC; const bool v; std::string vars() override { return VARS_TO_STR16(type_input, type_kernel, dst_type, ne_input, ne_kernel, IC, s0, s1, s2, p0, p1, p2, d0, d1, d2, v); } test_im2col_3d(ggml_type type_input = GGML_TYPE_F32, ggml_type type_kernel = GGML_TYPE_F16, ggml_type dst_type = GGML_TYPE_F32, std::array ne_input = {10, 10, 10, 9}, // [OC*IC, KD, KH, KW] std::array ne_kernel = {3, 3, 3, 1}, // [N*IC, ID, IH, IW] int64_t IC = 3, int s0 = 1, int s1 = 1, int s2 = 1, int p0 = 1, int p1 = 1, int p2 = 1, int d0 = 1, int d1 = 1, int d2 = 1, bool v = false) : type_input(type_input), type_kernel(type_kernel), dst_type(dst_type), ne_input(ne_input), ne_kernel(ne_kernel), s0(s0), s1(s1), s2(s2), p0(p0), p1(p1), p2(p2), d0(d0), d1(d1), d2(d2), IC(IC), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, type_input, 4, ne_input.data()); ggml_set_param(input); ggml_set_name(input, "input"); if (v) { input = ggml_view_4d(ctx, input, ne_input[0] - 2, ne_input[1] - 2, ne_input[2] - 2, ne_input[3] - 2, input->nb[1], input->nb[2], input->nb[3], 0); ggml_set_name(input, "view_of_input"); } ggml_tensor * kernel = ggml_new_tensor(ctx, type_kernel, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); ggml_tensor * out = ggml_im2col_3d(ctx, kernel, input, IC, s0, s1, s2, p0, p1, p2, d0, d1, d2, dst_type); ggml_set_name(out, "out"); return out; } }; // CONV_2D struct test_conv_2d : public test_case { const std::array ne_input; const std::array ne_kernel; const ggml_type type_kernel; const int stride0; const int stride1; const int padding0; const int padding1; const int dilation0; const int dilation1; // Whether the inputs are contiguous in the channel dim or the width dim const bool cwhn; // If true, the direct CONV_2D will be used in the graph, otherwise it // uses ggml_conv_2d: // * if the program is called with -o CONV_2D_DIRECT_IMPL, the // CONV_2D graph will be built, while // * if the program is called with -o CONV_2D_INDIRECT_IMPL, the // IM2COL -> MUL_MM graph will be built. std::string vars() override { return VARS_TO_STR10(ne_input, ne_kernel, type_kernel, stride0, stride1, padding0, padding1, dilation0, dilation1, cwhn); } double max_nmse_err() override { return 5e-4; } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); // Just counting matmul costs: // KxCRS @ CRSxNPQ = KxNPQ --> KxNPQx(CRS+CRS-1) flops // Copied from ggml.c: int64_t ggml_calc_conv_output_size(int64_t ins, int64_t ks, int s, int p, int d) auto calc_conv_output_size = [](int64_t ins, int64_t ks, int s, int p, int d) -> int64_t { return (ins + 2 * p - d * (ks - 1) - 1) / s + 1; }; int64_t W = ne_input[0]; int64_t H = ne_input[1]; int64_t KW = ne_kernel[0]; int64_t KH = ne_kernel[1]; int64_t Cin = ne_kernel[2]; int64_t Cout = ne_kernel[3]; int64_t N = ne_input[3]; int64_t OH = calc_conv_output_size(H, KH, stride0, padding0, dilation0); int64_t OW = calc_conv_output_size(W, KW, stride0, padding0, dilation0); int64_t K = Cout; int64_t CRS = Cin * KH * KW; int64_t NPQ = N * OH * OW; return K * NPQ * (2 * CRS - 1); } test_conv_2d(std::array ne_input = { 64, 64, 16, 1 }, std::array ne_kernel = { 3, 3, 1, 16 }, ggml_type type_kernel = GGML_TYPE_F32, int stride0 = 1, int stride1 = 1, int padding0 = 0, int padding1 = 0, int dilation0 = 1, int dilation1 = 1, bool cwhn = false) : ne_input(ne_input), ne_kernel(ne_kernel), type_kernel(type_kernel), stride0(stride0), stride1(stride1), padding0(padding0), padding1(padding1), dilation0(dilation0), dilation1(dilation1), cwhn(cwhn) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_input.data()); ggml_set_name(input, "input"); ggml_tensor * kernel = ggml_new_tensor(ctx, type_kernel, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); if (cwhn) { // change memory layout to channel-most-contiguous (CWHN), // then permute it back so NE matches the original input input = ggml_cont(ctx, ggml_permute(ctx, input, 1, 2, 0, 3)); input = ggml_permute(ctx, input, 2, 0, 1, 3); kernel = ggml_cont(ctx, ggml_permute(ctx, kernel, 2, 3, 1, 0)); kernel = ggml_permute(ctx, kernel, 3, 2, 0, 1); } ggml_tensor * out = ggml_conv_2d_direct(ctx, kernel, input, stride0, stride1, padding0, padding1, dilation0, dilation1); ggml_set_name(out, "out"); return out; } }; // GGML_OP_CONV_2D_DW struct test_conv_2d_dw : public test_case { const std::array ne_input; const std::array ne_kernel; const int stride; const int padding; const int dilation; const bool cwhn; std::string vars() override { return VARS_TO_STR6(ne_input, ne_kernel, stride, padding, dilation, cwhn); } test_conv_2d_dw(std::array ne_input = {64, 64, 16, 1}, std::array ne_kernel = {3, 3, 1, 16}, int stride = 1, int padding = 0, int dilation = 1, bool cwhn = false) : ne_input(ne_input), ne_kernel(ne_kernel), stride(stride), padding(padding), dilation(dilation), cwhn(cwhn) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * input = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_input.data()); ggml_set_name(input, "input"); ggml_tensor * kernel = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_kernel.data()); ggml_set_name(kernel, "kernel"); if (cwhn) { // change memory layout to channel-most-contiguous (CWHN), // then permute it back so NE matches the original input input = ggml_cont(ctx, ggml_permute(ctx, input, 1, 2, 0, 3)); input = ggml_permute(ctx, input, 2, 0, 1, 3); kernel = ggml_cont(ctx, ggml_permute(ctx, kernel, 2, 3, 1, 0)); kernel = ggml_permute(ctx, kernel, 3, 2, 0, 1); } ggml_tensor * out = ggml_conv_2d_dw_direct( ctx, kernel, input, stride, stride, padding, padding, dilation, dilation); ggml_set_name(out, "out"); return out; } }; // GGML_OP_CONV_3D struct test_conv_3d : public test_case { // Logical 5D dimensions const int64_t N, IC, ID, IH, IW; const int64_t OC, KD, KH, KW; // Conv params const int s0, s1, s2; const int p0, p1, p2; const int d0, d1, d2; // Types const ggml_type type_kernel; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "CONV_3D"; } std::string vars() override { return VARS_TO_STR11(N, IC, ID, IH, IW, OC, KD, KH, KW, s0, s1) + "," + VARS_TO_STR8(s2, p0, p1, p2, d0, d1, d2, type_kernel); } double max_nmse_err() override { return 5e-4; } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); auto calc_conv_output_size = [](int64_t ins, int64_t ks, int s, int p, int d) -> int64_t { return (ins + 2 * p - d * (ks - 1) - 1) / s + 1; }; const int64_t OD = calc_conv_output_size(ID, KD, s2, p2, d2); const int64_t OH = calc_conv_output_size(IH, KH, s1, p1, d1); const int64_t OW = calc_conv_output_size(IW, KW, s0, p0, d0); return (uint64_t)N * OC * OD * OH * OW * (2 * IC * KD * KH * KW - 1); } test_conv_3d( int64_t N, int64_t IC, int64_t ID, int64_t IH, int64_t IW, int64_t OC, int64_t KD, int64_t KH, int64_t KW, int s0, int s1, int s2, int p0, int p1, int p2, int d0, int d1, int d2, ggml_type type_kernel ) : N(N), IC(IC), ID(ID), IH(IH), IW(IW), OC(OC), KD(KD), KH(KH), KW(KW), s0(s0), s1(s1), s2(s2), p0(p0), p1(p1), p2(p2), d0(d0), d1(d1), d2(d2), type_kernel(type_kernel) {} ggml_tensor * build_graph(ggml_context * ctx) override { // GGML input tensor is packed as [W, H, D, C*N] const int64_t ne_input[] = {IW, IH, ID, IC * N}; ggml_tensor * input = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne_input); ggml_set_name(input, "input"); // GGML kernel tensor is packed as [KW, KH, KD, IC*OC] const int64_t ne_kernel[] = {KW, KH, KD, IC * OC}; ggml_tensor * kernel = ggml_new_tensor(ctx, type_kernel, 4, ne_kernel); ggml_set_name(kernel, "kernel"); ggml_tensor * out = ggml_conv_3d_direct(ctx, kernel, input, s0, s1, s2, p0, p1, p2, d0, d1, d2, (int)IC, (int)N, (int)OC); ggml_set_name(out, "out"); return out; } }; // GGML_OP_CONCAT struct test_concat : public test_case { const ggml_type type; const std::array ne_a; const int64_t ne_b_d; const int dim; const int v; // view (1 << 0: non-cont a, 1 << 1: non-cont b) std::string vars() override { return VARS_TO_STR5(type, ne_a, ne_b_d, dim, v); } test_concat(ggml_type type = GGML_TYPE_F32, std::array ne_a = {10, 5, 5, 5}, int64_t ne_b_d = 5, int dim = 2, int v = 0) : type(type), ne_a(ne_a), ne_b_d(ne_b_d), dim(dim), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { auto ne_b = ne_a; ne_b[dim] = ne_b_d; ggml_tensor * a; if (v & 1) { auto ne = ne_a; ne[0] *= 2; ne[1] *= 4; ne[2] *= 3; a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); a = ggml_view_4d(ctx, a, ne_a[0], ne_a[1], ne_a[2], ne_a[3], a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view_of_a"); } else { a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); } ggml_tensor * b; if (v & 2) { auto ne = ne_b; ne[0] *= 3; ne[1] *= 2; ne[2] *= 4; b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(b, "b"); b = ggml_view_4d(ctx, b, ne_b[0], ne_b[1], ne_b[2], ne_b[3], b->nb[1], b->nb[2], b->nb[3], 0); ggml_set_name(b, "view_of_b"); } else { b = ggml_new_tensor(ctx, type, 4, ne_b.data()); ggml_set_name(b, "b"); } ggml_tensor * out = ggml_concat(ctx, a, b, dim); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ARGSORT struct test_argsort : public test_case { const ggml_type type; const std::array ne; ggml_sort_order order; std::string vars() override { return VARS_TO_STR3(type, ne, order); } test_argsort(ggml_type type = GGML_TYPE_F32, std::array ne = {16, 10, 10, 10}, ggml_sort_order order = GGML_SORT_ORDER_ASC) : type(type), ne(ne), order(order) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_argsort(ctx, a, order); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { // indices std::vector data(ggml_nelements(t)); for (int i = 0; i < ggml_nelements(t); i++) { data[i] = rand(); } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), 0, ne[0]*ne[1]*ne[2]*ne[3] * sizeof(int)); } else if (t->type == GGML_TYPE_F32) { // initialize with unique values to avoid ties for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(float)); } } else { GGML_ABORT("fatal error"); } } } }; // GGML_OP_TOP_K struct test_top_k : public test_case { const ggml_type type; const std::array ne; const int k; const bool ties; ggml_tensor * input {}; std::string vars() override { return VARS_TO_STR4(type, ne, k, ties); } test_top_k(ggml_type type = GGML_TYPE_F32, std::array ne = {16, 10, 10, 10}, int k = 4, bool ties = false) : type(type), ne(ne), k(k), ties(ties) {} double max_err() override { return 0.0; } // When there are ties, only validate the final result. // The logic in err can't handle the sentinel tensors. bool run_whole_graph() override { return ties; } double err(const float * a, const float * b, size_t n) override { // When there are no ties, we expect the exact same set of indices, // but possibly in a different order. When there are ties, the indices // can be different but the input values they correspond to should be // the same. The logic for ties could work for non-ties, but only for // the output tensor, not for the sentinel tensors. if (ties) { std::vector src(ggml_nelements(input)); ggml_backend_tensor_get(input, src.data(), 0, ggml_nelements(input) * ggml_type_size(type)); double diff = 0.0f; GGML_ASSERT(n == (size_t)(ggml_nrows(input) * k)); int64_t cols = input->ne[0]; std::vector ia(k); std::vector ib(k); std::vector asrc(k); std::vector bsrc(k); for (int64_t r = 0; r < ggml_nrows(input); r++) { // Convert indices for the row back to integer for (int64_t c = 0; c < k; c++) { ia[c] = (int32_t)a[r * k + c]; ib[c] = (int32_t)b[r * k + c]; } // The src values for each row should match. for (int64_t c = 0; c < k; c++) { asrc[c] = src[r * cols + ia[c]]; bsrc[c] = src[r * cols + ib[c]]; } diff += jdst(asrc.data(), bsrc.data(), k); // There should be no duplicate indices std::sort(ia.begin(), ia.end()); std::sort(ib.begin(), ib.end()); if (std::adjacent_find(ia.begin(), ia.end()) != ia.end()) { diff += 1; } if (std::adjacent_find(ib.begin(), ib.end()) != ib.end()) { diff += 1; } } return diff; } else { std::vector ia(n); std::vector ib(n); double diff = 0.0f; for (size_t i = 0; i < n; i++) { ia[i] = (int32_t) a[i]; ib[i] = (int32_t) b[i]; // penalize the result if the data is not integer valued diff += std::fabs(a[i] - ia[i]); diff += std::fabs(b[i] - ib[i]); } return diff + jdst(ia.data(), ib.data(), n); } } ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); // Save 'a' for err() input = a; ggml_tensor * out = ggml_top_k(ctx, a, k); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { std::random_device rd; std::default_random_engine rng(rd()); for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { int tie_denom = std::max(1, std::min(10, k / 2)); for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int i = 0; i < t->ne[0]; i++) { if (ties) { // integer division to introduce duplicates data[i] = i / tie_denom; } else { data[i] = i; } } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(float)); } } } }; enum MoeGatingFunc { GATING_FUNC_SOFTMAX, GATING_FUNC_SIGMOID, GATING_FUNC_SOFTMAX_WEIGHT, }; struct test_topk_moe : public test_case { const std::array ne; const int n_expert_used; const bool with_norm; const bool bias_probs; const MoeGatingFunc gating_func; const float scale_w; ggml_tensor * weights {}; ggml_tensor * selected_experts {}; test_topk_moe(std::array ne = { 10, 5, 1, 1 }, int n_expert_used = 1, bool with_norm = false, bool bias_probs = false, MoeGatingFunc gating_func = GATING_FUNC_SOFTMAX, float scale_w = 0.0f) : ne(ne), n_expert_used(n_expert_used), with_norm(with_norm), bias_probs(bias_probs), gating_func(gating_func), scale_w(scale_w) { GGML_ASSERT(n_expert_used <= ne[0]); } std::string vars() override { return VARS_TO_STR6(ne, n_expert_used, with_norm, bias_probs, gating_func, scale_w); } std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "TOPK_MOE"; } bool run_whole_graph() override { return true; } ggml_tensor * build_graph(ggml_context * ctx) override { const int n_expert = ne[0]; const int n_tokens = ne[1]; ggml_tensor * logits = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne.data()); ggml_tensor * probs = (gating_func == GATING_FUNC_SOFTMAX) ? ggml_soft_max(ctx, logits) : (gating_func == GATING_FUNC_SIGMOID) ? ggml_sigmoid(ctx, logits) : logits; ggml_set_name(probs, "probs"); ggml_tensor * selection_probs = probs; if (bias_probs) { ggml_tensor * exp_probs_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, ne[0]); ggml_set_name(exp_probs_b, "exp_probs_b"); selection_probs = ggml_add(ctx, probs, exp_probs_b); ggml_set_name(selection_probs, "selection_probs"); } selected_experts = ggml_argsort_top_k(ctx, selection_probs, n_expert_used); // [n_expert_used, n_tokens] ggml_set_name(selected_experts, "selected_experts"); weights = ggml_get_rows(ctx, ggml_reshape_3d(ctx, probs, 1, n_expert, n_tokens), selected_experts); // [1, n_expert_used, n_tokens] ggml_set_name(weights, "weights"); if (gating_func == GATING_FUNC_SOFTMAX_WEIGHT) { weights = ggml_reshape_2d(ctx, weights, n_expert_used, n_tokens); weights = ggml_soft_max(ctx, weights); // [n_expert_used, n_tokens] weights = ggml_reshape_3d(ctx, weights, 1, n_expert_used, n_tokens); } if (with_norm) { weights = ggml_reshape_2d(ctx, weights, n_expert_used, n_tokens); ggml_tensor * weights_sum = ggml_sum_rows(ctx, weights); // [1, n_tokens] ggml_set_name(weights_sum, "weights_sum"); weights_sum = ggml_clamp(ctx, weights_sum, 6.103515625e-5, INFINITY); weights = ggml_div(ctx, weights, weights_sum); // [n_expert_used, n_tokens] weights = ggml_reshape_3d(ctx, weights, 1, n_expert_used, n_tokens); } if (scale_w) { weights = ggml_scale(ctx, weights, scale_w); } ggml_set_name(weights, "weights"); return weights; } // Verify two outputs std::vector fusion_test_nodes() override { return { selected_experts, weights }; } // allow output in arbitrary order double err(const float * a, const float * b, size_t n) override { std::vector a2(n); std::vector b2(n); for (size_t i = 0; i < n; ++i) { a2[i] = a[i]; b2[i] = b[i]; } std::sort(a2.begin(), a2.end()); std::sort(b2.begin(), b2.end()); return nmse(a2.data(), b2.data(), n); } }; struct test_mul_mat_vec_fusion : public test_case { const ggml_type type; const ggml_glu_op glu_op; const int64_t m; const int64_t n; const int64_t k; const bool use_id; const int n_mats; const int n_used; const bool b; // broadcast b matrix (only for use_id) const bool with_bias; const bool with_gate; std::array batch_dims; test_mul_mat_vec_fusion(ggml_type type, ggml_glu_op op, int64_t m, int64_t n, int64_t k, bool use_id = false, int n_mats = 1, int n_used = 1, bool b = false, bool with_bias = false, bool with_gate = true, std::array batch_dims = {4, 2}) : type(type), glu_op(op), m(m), n(n), k(k), use_id(use_id), n_mats(n_mats), n_used(n_used), b(b), with_bias(with_bias), with_gate(with_gate), batch_dims(batch_dims) { if (use_id) { GGML_ASSERT(n_used <= n_mats); } } std::string vars() override { return VARS_TO_STR12(type, glu_op, m, n, k, use_id, n_mats, n_used, b, with_bias, with_gate, batch_dims); } std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "MUL_MAT_VEC_FUSION"; } bool run_whole_graph() override { return true; } ggml_tensor * build_gate(ggml_context * ctx, ggml_tensor * ffn_gate, ggml_tensor * ffn_up) { ggml_tensor * out = nullptr; if (with_gate) { if (glu_op == GGML_GLU_OP_SWIGLU_OAI) { constexpr float alpha = 1.702f; constexpr float limit = 7.0f; out = ggml_swiglu_oai(ctx, ffn_gate, ffn_up, alpha, limit); } else { out = ggml_glu_split(ctx, ffn_gate, ffn_up, glu_op); } } return out; } ggml_tensor * build_graph(ggml_context * ctx) override { if (!use_id) { const int channels = batch_dims[0]; const int samples = batch_dims[1]; std::array ne = { k, m, channels, samples }; std::array ne0 = { k, n, channels, samples }; ggml_tensor * cur = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne.data()); ggml_tensor * gate = with_gate ? ggml_new_tensor(ctx, type, 4, ne0.data()) : nullptr; ggml_tensor * up = ggml_new_tensor(ctx, type, 4, ne0.data()); ggml_tensor * ffn_up = ggml_mul_mat(ctx, up, cur); if (with_bias) { std::array bias_ne = { ffn_up->ne[0], 1, channels, samples }; ggml_tensor * up_bias = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, bias_ne.data()); ffn_up = ggml_add(ctx, ffn_up, up_bias); } ggml_tensor * ffn_gate = with_gate ? ggml_mul_mat(ctx, gate, cur) : nullptr; if (with_bias && with_gate) { std::array bias_ne = { ffn_gate->ne[0], 1, channels, samples }; ggml_tensor * gate_bias = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, bias_ne.data()); ffn_gate = ggml_add(ctx, ffn_gate, gate_bias); } ggml_tensor * out = with_gate ? build_gate(ctx, ffn_gate, ffn_up) : ffn_up; std::array bias2_ne = { out->ne[0], 1, channels, samples }; ggml_tensor * bias2 = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, bias2_ne.data()); out = ggml_add(ctx, out, bias2); ggml_set_name(out, "out"); return out; } else { ggml_tensor * gates = ggml_new_tensor_3d(ctx, type, k, n, n_mats); ggml_tensor * ups = ggml_new_tensor_3d(ctx, type, k, n, n_mats); ggml_tensor * ids = ggml_new_tensor_2d(ctx, GGML_TYPE_I32, n_mats, m); if (n_used != n_mats) { ids = ggml_view_2d(ctx, ids, n_used, m, ids->nb[1], 0); } ggml_tensor * cur = ggml_new_tensor_3d(ctx, GGML_TYPE_F32, k, this->b ? 1 : n_used, m); ggml_set_name(cur, "cur"); ggml_tensor * ffn_up = ggml_mul_mat_id(ctx, ups, cur, ids); if (with_bias) { ggml_tensor * up_bias_param = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, ffn_up->ne[0], n_mats); ffn_up = ggml_add_id(ctx, ffn_up, up_bias_param, ids); } ggml_tensor * ffn_gate = with_gate? ggml_mul_mat_id(ctx, gates, cur, ids) : nullptr; if (with_bias && with_gate) { ggml_tensor * gate_bias_param = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, ffn_gate->ne[0], n_mats); ffn_gate = ggml_add_id(ctx, ffn_gate, gate_bias_param, ids); } ggml_tensor * out = with_gate ? build_gate(ctx, ffn_gate, ffn_up) : ffn_up; std::array scale_ne { 1, out->ne[1], out->ne[2], out->ne[3] }; ggml_tensor * scale = ggml_new_tensor(ctx, out->type, 4, scale_ne.data()); out = ggml_mul(ctx, out, scale); ggml_set_name(out, "out"); return out; } } void initialize_tensors(ggml_context * ctx) override { if (!use_id) { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t); } } else { init_mul_mat_id_tensors(ctx, n_mats); } } double max_nmse_err() override { return 5e-3; } }; // GGML_OP_SUM struct test_sum : public test_case { const ggml_type type; const std::array ne; const std::array permute; bool _use_permute; std::string vars() override { std::string v = VARS_TO_STR2(type, ne); if (_use_permute) v += "," + VAR_TO_STR(permute); return v; } test_sum(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, std::array permute = {0, 0, 0, 0}) : type(type), ne(ne), permute(permute), _use_permute(permute[0] + permute[1] + permute[2] + permute[3] > 0) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); if (_use_permute) { a = ggml_permute(ctx, a, permute[0], permute[1], permute[2], permute[3]); ggml_set_name(a, "a_permuted"); } ggml_tensor * out = ggml_sum(ctx, a); ggml_set_name(out, "out"); return out; } float grad_eps() override { return 0.1f * sqrtf(ne[0]*ne[1]*ne[2]*ne[3]); } // Don't center the distribution around zero. Helps to avoid catastrophic cancellation. void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != nullptr; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -0.9f, 1.1f); } } }; // GGML_OP_SUM_ROWS struct test_sum_rows : public test_case { const ggml_type type; const std::array ne; const bool permute; const bool slice; std::string vars() override { return VARS_TO_STR4(type, ne, permute, slice); } test_sum_rows(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}, bool permute = false, bool slice = false) : type(type), ne(ne), permute(permute), slice(slice) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); if (slice) { a = ggml_view_4d(ctx, a, ne[0], ne[1], ne[2] / 2, ne[3] - 1, a->nb[1], a->nb[2] * 2, a->nb[3], /*offset=*/a->nb[3]); } if (permute) { a = ggml_permute(ctx, a, 0, 2, 3, 1); } ggml_tensor * out = ggml_sum_rows(ctx, a); ggml_set_name(out, "out"); return out; } }; // GGML_OP_MEAN struct test_mean : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_mean(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_mean(ctx, a); ggml_set_name(out, "out"); return out; } float grad_eps() override { return 0.1f * ne[0]*ne[1]*ne[2]*ne[3]; } // Don't center the distribution around zero. Helps to avoid catastrophic cancellation. void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != nullptr; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -0.9f, 1.1f); } } }; // GGML_OP_UPSCALE struct test_upscale : public test_case { const ggml_type type; const std::array ne; const int32_t scale_factor; const bool transpose; const ggml_scale_mode mode; std::string vars() override { return VARS_TO_STR5(type, ne, scale_factor, mode, transpose); } test_upscale(ggml_type type = GGML_TYPE_F32, std::array ne = {512, 512, 3, 1}, int32_t scale_factor = 2, ggml_scale_mode mode = GGML_SCALE_MODE_NEAREST, bool transpose = false) : type(type), ne(ne), scale_factor(scale_factor), transpose(transpose), mode(mode) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); if (transpose) { a = ggml_transpose(ctx, a); ggml_set_name(a, "a_transposed"); } ggml_tensor * out = ggml_upscale(ctx, a, scale_factor, mode); ggml_set_name(out, "out"); return out; } }; // GGML_OP_UPSCALE (via ggml_interpolate) struct test_interpolate : public test_case { const ggml_type type; const std::array ne; const std::array ne_tgt; const ggml_scale_mode mode = GGML_SCALE_MODE_NEAREST; std::string vars() override { return VARS_TO_STR4(type, ne, ne_tgt, mode); } test_interpolate(ggml_type type = GGML_TYPE_F32, std::array ne = {2, 5, 7, 11}, std::array ne_tgt = {5, 7, 11, 13}, ggml_scale_mode mode = GGML_SCALE_MODE_NEAREST) : type(type), ne(ne), ne_tgt(ne_tgt), mode(mode) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_interpolate(ctx, a, ne_tgt[0], ne_tgt[1],ne_tgt[2], ne_tgt[3], mode); ggml_set_name(out, "out"); return out; } }; // GGML_OP_GROUP_NORM struct test_group_norm : public test_case { const ggml_type type; const std::array ne; const int32_t num_groups; const float eps; std::string vars() override { return VARS_TO_STR4(type, ne, num_groups, eps); } test_group_norm(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 64, 320, 1}, int32_t num_groups = 32, float eps = 1e-6f) : type(type), ne(ne), num_groups(num_groups), eps(eps) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_group_norm(ctx, a, num_groups, eps); ggml_set_name(out, "out"); return out; } }; // GGML_OP_GROUP_NORM + GGML_OP_MUL + GGML_OP_ADD struct test_group_norm_mul_add : public test_case { const ggml_type type; const std::array ne; int num_groups; float eps; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "GROUP_NORM_MUL_ADD"; } bool run_whole_graph() override { return true; } std::string vars() override { return VARS_TO_STR4(type, ne, num_groups, eps); } test_group_norm_mul_add(ggml_type type = GGML_TYPE_F32, std::array ne = {128, 1, 1, 1}, int num_groups = 4, float eps = 1e-5f) : type(type), ne(ne), num_groups(num_groups), eps(eps) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_tensor * w = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_tensor * b = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(a); ggml_set_param(w); ggml_set_param(b); ggml_set_name(a, "a"); ggml_set_name(w, "w"); ggml_set_name(b, "b"); ggml_tensor * n = ggml_group_norm(ctx, a, num_groups, eps); ggml_tensor * m = ggml_mul(ctx, n, w); ggml_tensor * out = ggml_add(ctx, m, b); ggml_set_name(out, "out"); return out; } }; // GGML_OP_L2_NORM struct test_l2_norm : public test_case { const ggml_type type; const std::array ne; const float eps; bool v; std::string vars() override { return VARS_TO_STR4(type, ne, eps, v); } test_l2_norm(ggml_type type = GGML_TYPE_F32, std::array ne = {64, 64, 320, 1}, float eps = 1e-12f, bool v = false) : type(type), ne(ne), eps(eps), v(v) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(a, "a"); if (v) { a = ggml_view_4d(ctx, a, a->ne[0]/2, a->ne[1]/2, a->ne[2]/2, a->ne[3]/2, a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view of a"); } ggml_tensor * out = ggml_l2_norm(ctx, a, eps); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ACC struct test_acc : public test_case { const ggml_type type; const std::array ne_a; const std::array ne_b; const int64_t stride_dim; std::string vars() override { return VARS_TO_STR4(type, ne_a, ne_b, stride_dim); } test_acc(ggml_type type = GGML_TYPE_F32, std::array ne_a = {256, 17, 2, 3}, std::array ne_b = {256, 16, 2, 3}, uint64_t stride_dim = -1) : type(type), ne_a(ne_a), ne_b(ne_b), stride_dim(stride_dim) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * b; if (stride_dim == 1 || stride_dim == 2 || stride_dim == 3) { // Create a larger tensor and take a view at a non-zero offset. // This tests that the backend correctly handles b's data offset std::array ne_b_pad = {ne_b[0], ne_b[1], ne_b[2], ne_b[3]}; ne_b_pad[stride_dim] += 1; ggml_tensor * b_pad = ggml_new_tensor(ctx, type, 4, ne_b_pad.data()); ggml_set_param(b_pad); ggml_set_name(b_pad, "b_pad"); // View that skips the first row, so b has a non-zero byte offset b = ggml_view_4d(ctx, b_pad, ne_b[0], ne_b[1], ne_b[2], ne_b[3], b_pad->nb[1], b_pad->nb[2], b_pad->nb[3], b_pad->nb[1]); } else { b = ggml_new_tensor(ctx, type, 4, ne_b.data()); ggml_set_param(b); } ggml_set_name(b, "b"); // When ne_b[0] < ne_a[0], a->nb[1] != b->nb[1], so the stride // parameters to ggml_acc don't match b's natural stride. ggml_tensor * out = ggml_acc(ctx, a, b, a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(out, "out"); return out; } }; // GGML_OP_PAD struct test_pad : public test_case { const ggml_type type; const std::array ne_a; const int pad_0; const int pad_1; const bool circular; std::string vars() override { return VARS_TO_STR5(type, ne_a, pad_0, pad_1, circular); } test_pad(ggml_type type = GGML_TYPE_F32, std::array ne_a = {512, 512, 1, 1}, int pad_0 = 1, int pad_1 = 1, bool circular = false) : type(type), ne_a(ne_a), pad_0(pad_0), pad_1(pad_1), circular(circular) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); ggml_tensor * out = circular ? ggml_pad_circular(ctx, a, pad_0, pad_1, 0, 0) : ggml_pad(ctx, a, pad_0, pad_1, 0, 0); ggml_set_name(out, "out"); return out; } }; // GGML_OP_PAD (with extension) struct test_pad_ext : public test_case { const ggml_type type; const std::array ne_a; const int lp0; const int rp0; const int lp1; const int rp1; const int lp2; const int rp2; const int lp3; const int rp3; const int tfrm; // 0 - none, 1 - non-cont, 2 - perm const bool circular; std::string vars() override { return VARS_TO_STR12(type, ne_a, lp0, rp0, lp1, rp1, lp2, rp2, lp3, rp3, tfrm, circular); } test_pad_ext(ggml_type type = GGML_TYPE_F32, std::array ne_a = {512, 512, 3, 1}, int lp0 = 1, int rp0 = 1, int lp1 = 1, int rp1 = 1, int lp2 = 1, int rp2 = 1, int lp3 = 1, int rp3 = 1, int tfrm = 0, bool circular = false) : type(type), ne_a(ne_a), lp0(lp0), rp0(rp0), lp1(lp1), rp1(rp1), lp2(lp2), rp2(rp2), lp3(lp3), rp3(rp3), tfrm(tfrm), circular(circular) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); if (tfrm == 1) { a = ggml_view_4d(ctx, a, (a->ne[0] + 1) / 2, (a->ne[1] + 1) / 2, (a->ne[2] + 1) / 2, (a->ne[3] + 1) / 2, a->nb[1], a->nb[2], a->nb[3], 0); ggml_set_name(a, "view of a"); } else if (tfrm == 2) { a = ggml_permute(ctx, a, 2, 1, 0, 3); ggml_set_name(a, "permuted a"); } ggml_tensor * out = circular ? ggml_pad_ext_circular(ctx, a, lp0, rp0, lp1, rp1, lp2, rp2, lp3, rp3) : ggml_pad_ext (ctx, a, lp0, rp0, lp1, rp1, lp2, rp2, lp3, rp3); ggml_set_name(out, "out"); return out; } }; // GGML_OP_PAD_REFLECT_1D struct test_pad_reflect_1d : public test_case { const ggml_type type; const std::array ne_a; const int pad_0; const int pad_1; std::string vars() override { return VARS_TO_STR4(type, ne_a, pad_0, pad_1); } test_pad_reflect_1d(ggml_type type = GGML_TYPE_F32, std::array ne_a = {512, 34, 2, 1}, int pad_0 = 10, int pad_1 = 9) : type(type), ne_a(ne_a), pad_0(pad_0), pad_1(pad_1) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 2, ne_a.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_pad_reflect_1d(ctx, a, pad_0, pad_1); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ROLL struct test_roll : public test_case { const int shift0; const int shift1; const int shift3; const int shift4; std::string vars() override { return VARS_TO_STR4(shift0, shift1, shift3, shift4); } test_roll(int shift0 = 3, int shift1 = -2, int shift3 = 1, int shift4 = -1) : shift0(shift0), shift1(shift1), shift3(shift3), shift4(shift4) {} ggml_tensor * build_graph(ggml_context * ctx) override { int64_t ne[4] = {10, 5, 4, 3}; ggml_tensor * a = ggml_new_tensor(ctx, GGML_TYPE_F32, 4, ne); ggml_set_name(a, "a"); ggml_tensor * out = ggml_roll(ctx, a, shift0, shift1, shift3, shift4); ggml_set_name(out, "out"); return out; } }; // GGML_OP_ARANGE struct test_arange : public test_case { const ggml_type type; const float start; const float stop; const float step; std::string vars() override { return VARS_TO_STR4(type, start, stop, step); } test_arange(ggml_type type = GGML_TYPE_F32, float start = 0.f, float stop = 10.f, float step = 1.f) : type(type), start(start), stop(stop), step(step) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * out = ggml_arange(ctx, start, stop, step); ggml_set_name(out, "out"); return out; } }; // GGML_OP_TIMESTEP_EMBEDDING struct test_timestep_embedding : public test_case { const ggml_type type; const std::array ne_a; const int dim; const int max_period; std::string vars() override { return VARS_TO_STR4(type, ne_a, dim, max_period); } test_timestep_embedding(ggml_type type = GGML_TYPE_F32, std::array ne_a = {2, 1, 1, 1}, int dim = 320, int max_period=10000) : type(type), ne_a(ne_a), dim(dim), max_period(max_period) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_timestep_embedding(ctx, a, dim, max_period); ggml_set_name(out, "out"); return out; } }; // GGML_OP_LEAKY_RELU struct test_leaky_relu : public test_case { const ggml_type type; const std::array ne_a; const float negative_slope; std::string vars() override { return VARS_TO_STR3(type, ne_a, negative_slope); } test_leaky_relu(ggml_type type = GGML_TYPE_F32, std::array ne_a = {10, 5, 4, 3}, float negative_slope = 0.1f) : type(type), ne_a(ne_a), negative_slope(negative_slope) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor(ctx, type, 4, ne_a.data()); ggml_set_name(a, "a"); ggml_tensor * out = ggml_leaky_relu(ctx, a, negative_slope, true); ggml_set_name(out, "out"); return out; } }; // GGML_OP_FLASH_ATTN_EXT struct test_flash_attn_ext : public test_case { const int64_t hsk; // K head size const int64_t hsv; // V head size const int64_t nh; // num heads const std::array nr23; // repeat in dim 2 and 3, tests for grouped-query attention const int64_t kv; // kv size const int64_t nb; // batch size const bool mask; // use mask const bool sinks; // use sinks const float max_bias; // ALiBi const float logit_softcap; // Gemma 2 const ggml_prec prec; const ggml_type type_KV; std::array permute; std::string vars() override { return VARS_TO_STR13(hsk, hsv, nh, nr23, kv, nb, mask, sinks, max_bias, logit_softcap, prec, type_KV, permute); } double max_nmse_err() override { return 5e-4; } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); // Just counting matmul costs: // Q*K^T is nb x hsk x kv, P*V is nb x kv x hsv, per head return (2 * nh*nr23[0] * nb * (hsk + hsv) * kv)*nr23[1]; } test_flash_attn_ext(int64_t hsk = 128, int64_t hsv = 128, int64_t nh = 32, std::array nr23 = {1, 1}, int64_t kv = 96, int64_t nb = 8, bool mask = true, bool sinks = false, float max_bias = 0.0f, float logit_softcap = 0.0f, ggml_prec prec = GGML_PREC_F32, ggml_type type_KV = GGML_TYPE_F16, std::array permute = {0, 1, 2, 3}) : hsk(hsk), hsv(hsv), nh(nh), nr23(nr23), kv(kv), nb(nb), mask(mask), sinks(sinks), max_bias(max_bias), logit_softcap(logit_softcap), prec(prec), type_KV(type_KV), permute(permute) {} ggml_tensor * build_graph(ggml_context * ctx) override { const int64_t hsk_padded = GGML_PAD(hsk, ggml_blck_size(type_KV)); const int64_t hsv_padded = GGML_PAD(hsv, ggml_blck_size(type_KV)); auto const &create_permuted = [&](ggml_type type, int64_t ne0, int64_t ne1, int64_t ne2, int64_t ne3, bool is_view) -> ggml_tensor * { int64_t ne[4] = {ne0, ne1, ne2, ne3}; int64_t ne_perm[4]; for (int i = 0; i < 4; ++i) { ne_perm[permute[i]] = ne[i]; } ggml_tensor * t; if (is_view) { ggml_tensor * t0 = ggml_new_tensor_4d(ctx, type, ne_perm[0], 2*ne_perm[1], ne_perm[2], ne_perm[3]); t = ggml_view_4d(ctx, t0, ne_perm[0], ne_perm[1], ne_perm[2], ne_perm[3], t0->nb[1], t0->nb[2], t0->nb[3], 0); } else { t = ggml_new_tensor_4d(ctx, type, ne_perm[0], ne_perm[1], ne_perm[2], ne_perm[3]); } if (permute != std::array{0, 1, 2, 3}) { t = ggml_permute(ctx, t, permute[0], permute[1], permute[2], permute[3]); } return t; }; ggml_tensor * q = create_permuted(GGML_TYPE_F32, hsk_padded, nb, nh*nr23[0], nr23[1], false); ggml_set_name(q, "q"); ggml_tensor * k = create_permuted(type_KV, hsk_padded, kv, nh, nr23[1], true); // the K tensor is usually a view of the K cache ggml_set_name(k, "k"); ggml_tensor * v = nullptr; if (hsk_padded == 576 && hsv_padded == 512) { // TODO: this branch should become a separate test case parameter instead of hardcoding this for these head shapes // in this branch, the V cache is sub-view of the K cache. this is used by some MLA-based models // for more info: // - https://github.com/ggml-org/llama.cpp/pull/13435 // - https://github.com/ggml-org/llama.cpp/pull/18953#issuecomment-3774948392 // - https://github.com/ggml-org/llama.cpp/pull/18986 v = ggml_view_4d(ctx, k, hsv_padded, kv, nh, nr23[1], k->nb[1], k->nb[2], k->nb[3], 0); } else { v = create_permuted(type_KV, hsv_padded, kv, nh, nr23[1], true); // the V tensor is usually a view of the V cache } ggml_set_name(v, "v"); ggml_tensor * m = nullptr; if (mask) { m = ggml_new_tensor_4d(ctx, GGML_TYPE_F16, kv, nb, 1, nr23[1]); ggml_set_name(m, "m"); } ggml_tensor * s = nullptr; if (sinks) { s = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, q->ne[2]); ggml_set_name(s, "s"); } ggml_tensor * out = ggml_flash_attn_ext(ctx, q, k, v, m, 1.0f/sqrtf(hsk), max_bias, logit_softcap); ggml_flash_attn_ext_add_sinks(out, s); ggml_flash_attn_ext_set_prec (out, prec); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (strcmp(t->name, "s") == 0) { // make the sink values more noticeable in order to trigger a test failure when the implementation is wrong init_tensor_uniform(t, -10.0f, 10.0f); } else if (strcmp(t->name, "m") == 0) { init_tensor_kq_mask(t); } else { init_tensor_uniform(t); } } } bool grad_precise() override { return true; } }; // GGML_OP_CROSS_ENTROPY_LOSS struct test_cross_entropy_loss : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_cross_entropy_loss(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * logits = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_param(logits); ggml_set_name(logits, "logits"); ggml_tensor * labels = ggml_new_tensor(ctx, type, 4, ne.data()); // The labels are assumed to be constant -> no gradients. ggml_set_name(labels, "labels"); // Ensure labels add up to 1: labels = ggml_soft_max(ctx, labels); ggml_set_name(labels, "labels_normalized"); ggml_tensor * out = ggml_cross_entropy_loss(ctx, logits, labels); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { // For larger abs. diffs between logits softmax is more linear, therefore more precise num. gradients. for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -100.0f, 100.0f); } } float grad_eps() override { return 1.0f; } bool grad_precise() override { return true; } }; // GGML_OP_CROSS_ENTROPY_LOSS_BACK struct test_cross_entropy_loss_back : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_cross_entropy_loss_back(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * grad = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, 1); ggml_set_name(grad, "grad"); ggml_tensor * logits = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(logits, "logits"); ggml_tensor * labels = ggml_new_tensor(ctx, type, 4, ne.data()); ggml_set_name(labels, "labels"); // Ensure labels add up to 1: labels = ggml_soft_max(ctx, labels); ggml_set_name(labels, "labels_normalized"); ggml_tensor * out = ggml_cross_entropy_loss_back(ctx, grad, logits, labels); ggml_set_name(out, "out"); return out; } }; // GGML_OP_OPT_STEP_ADAMW struct test_opt_step_adamw : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_opt_step_adamw(ggml_type type = GGML_TYPE_F32, std::array ne = {10, 5, 4, 3}) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); // Despite tensor a having gradients the output tensor will not. ggml_set_name(a, "a"); ggml_tensor * grad = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_name(grad, "grad"); ggml_tensor * grad_m = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_name(grad_m, "grad_m"); ggml_tensor * grad_v = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_name(grad_v, "grad_v"); ggml_tensor * adamw_params = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, 7); ggml_set_name(adamw_params, "adamw_params"); ggml_tensor * out = ggml_opt_step_adamw(ctx, a, grad, grad_m, grad_v, adamw_params); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, 0.0f, 1.0f); // grad_v and adamw_params need non-negative values. } } bool grad_precise() override { return true; } }; // GGML_OP_OPT_STEP_SGD struct test_opt_step_sgd : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_opt_step_sgd(ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 5, 4, 3 }) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); // Despite tensor a having gradients the output tensor will not. ggml_set_name(a, "a"); ggml_tensor * grad = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_name(grad, "grad"); ggml_tensor * sgd_params = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, 2); ggml_set_name(sgd_params, "sgd_params"); ggml_tensor * out = ggml_opt_step_sgd(ctx, a, grad, sgd_params); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, 0.0f, 1.0f); // sgd_params need non-negative values. } } bool grad_precise() override { return true; } }; // GGML_OP_CUMSUM struct test_cumsum : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_cumsum(ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 5, 4, 3 }) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_cumsum(ctx, a); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -1.0f, 1.0f); } } }; // GGML_OP_XIELU struct test_xielu : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_xielu(ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 5, 4, 3 }) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); ggml_set_name(a, "a"); float alpha_n = 4.0f; float alpha_p = 20.0f; float beta = 0.5f; float eps = 0.0000001f; ggml_tensor * out = ggml_xielu(ctx, a, alpha_n, alpha_p, beta, eps); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -1.0f, 1.0f); } } }; // GGML_OP_TRI struct test_tri : public test_case { const ggml_type type; const std::array ne; const ggml_tri_type tri_type; std::string vars() override { return VARS_TO_STR3(type, ne, tri_type); } test_tri(ggml_tri_type tri_type, ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 10, 4, 3 }) : type(type), ne(ne), tri_type(tri_type) { GGML_ASSERT(ne[0] == ne[1]); } ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_tri(ctx, a, tri_type); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { init_tensor_uniform(t, -1.0f, 1.0f); } } }; // GGML_OP_FILL struct test_fill : public test_case { const ggml_type type; const std::array ne; float c; std::string vars() override { return VARS_TO_STR3(type, ne, c); } test_fill(float c, ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 10, 4, 3 }) : type(type), ne(ne), c(c) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_fill(ctx, a, c); ggml_set_name(out, "out"); return out; } }; // GGML_OP_SOLVE_TRI struct test_solve_tri : public test_case { const ggml_type type; const std::array ne_lhs; const std::array ne_rhs; std::string vars() override { return VARS_TO_STR3(type, ne_lhs, ne_rhs); } uint64_t op_flops(ggml_tensor * t) override { GGML_UNUSED(t); int64_t n = ne_lhs[0]; int64_t k = ne_rhs[0]; int64_t batch = ne_lhs[2] * ne_lhs[3]; // n * (n + 1) / 2 non-zero elements of lhs, 2 flops each, for each col of rhs return n * (n + 1) * k * batch; } test_solve_tri(ggml_type type = GGML_TYPE_F32, std::array ne_lhs = { 10, 10, 4, 3 }, std::array ne_rhs = { 3, 10, 4, 3 } ) : type(type), ne_lhs(ne_lhs), ne_rhs(ne_rhs) {} ggml_tensor * build_graph(ggml_context * ctx) override { ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne_lhs[0], ne_lhs[1], ne_lhs[2], ne_lhs[3]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * b = ggml_new_tensor_4d(ctx, type, ne_rhs[0], ne_rhs[1], ne_rhs[2], ne_rhs[3]); ggml_set_param(b); ggml_set_name(b, "b"); ggml_tensor * out = ggml_solve_tri(ctx, a, b, true, true, false); ggml_set_name(out, "out"); return out; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (strcmp(t->name, "a") == 0) { // note: avoid zeros in the diagonal init_tensor_tril(t, 0.1, 1.0f); } else { init_tensor_uniform(t, -1.0f, 1.0f); } } } }; // GGML_OP_DIAG struct test_diag : public test_case { const ggml_type type; const std::array ne; std::string vars() override { return VARS_TO_STR2(type, ne); } test_diag(ggml_type type = GGML_TYPE_F32, std::array ne = { 10, 1, 4, 3 }) : type(type), ne(ne) {} ggml_tensor * build_graph(ggml_context * ctx) override { GGML_ASSERT(ne[1] == 1); ggml_tensor * a = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); ggml_set_param(a); ggml_set_name(a, "a"); ggml_tensor * out = ggml_diag(ctx, a); ggml_set_name(out, "out"); return out; } }; // Deserializable generic test case struct input_tensor { ggml_type type; std::array ne; std::array nb; // strides (0 = use default contiguous strides) }; static bool is_non_contiguous(const input_tensor & src) { if (src.nb[0] == 0) { return false; } const size_t default_nb0 = ggml_type_size(src.type); const size_t default_nb1 = default_nb0 * (src.ne[0] / ggml_blck_size(src.type)); const size_t default_nb2 = default_nb1 * src.ne[1]; const size_t default_nb3 = default_nb2 * src.ne[2]; return src.nb[0] != default_nb0 || src.nb[1] != default_nb1 || src.nb[2] != default_nb2 || src.nb[3] != default_nb3; } static std::string var_to_str(const std::vector& sources) { std::ostringstream oss; bool first = true; for (const auto& src : sources) { if (!first) oss << ","; oss << ggml_type_name(src.type) << "[" << src.ne[0] << "," << src.ne[1] << "," << src.ne[2] << "," << src.ne[3] << "]"; if (is_non_contiguous(src)) { oss << "nb[" << src.nb[0] << "," << src.nb[1] << "," << src.nb[2] << "," << src.nb[3] << "]"; } first = false; } return oss.str(); } static std::string var_to_str(const std::array& params) { std::ostringstream oss; oss << "["; bool first = true; for (size_t i = 0; i < params.size(); ++i) { if (params[i] != 0) { if (!first) oss << ","; oss << i << ":" << params[i]; first = false; } } oss << "]"; return oss.str(); } struct test_generic_op : public test_case { const ggml_op op; const ggml_type type; const std::array ne; const std::array op_params; const std::vector sources; const std::string name; std::string vars() override { if (name.empty()) { return VARS_TO_STR4(type, ne, op_params, sources); } return VARS_TO_STR5(name, type, ne, op_params, sources); } test_generic_op(ggml_op op, ggml_type type, std::array ne, std::array op_params, std::vector sources, std::string name = "") : op(op), type(type), ne(ne), op_params(op_params), sources(sources), name(std::move(name)) {} ggml_tensor * build_graph(ggml_context * ctx) override { const size_t source_count = std::min(sources.size(), (size_t)GGML_MAX_SRC); std::array source_tensors; for (size_t i = 0; i < source_count; ++i) { const input_tensor& src = sources[i]; if (is_non_contiguous(src)) { size_t total_size; const size_t blck_size = ggml_blck_size(src.type); if (blck_size == 1) { total_size = ggml_type_size(src.type); for (int d = 0; d < 4; d++) { total_size += (src.ne[d] - 1) * src.nb[d]; } } else { total_size = src.ne[0] * src.nb[0] / blck_size; for (int d = 1; d < 4; d++) { total_size += (src.ne[d] - 1) * src.nb[d]; } } // Convert bytes to elements, padded to block size for quantized types const size_t type_size = ggml_type_size(src.type); size_t backing_elements = (total_size * blck_size + type_size - 1) / type_size; backing_elements = ((backing_elements + blck_size - 1) / blck_size) * blck_size; ggml_tensor * backing = ggml_new_tensor_1d(ctx, src.type, backing_elements); source_tensors[i] = ggml_view_4d(ctx, backing, src.ne[0], src.ne[1], src.ne[2], src.ne[3], src.nb[1], src.nb[2], src.nb[3], 0); // nb[0] does not get set by view_4d, so set it manually source_tensors[i]->nb[0] = src.nb[0]; } else { source_tensors[i] = ggml_new_tensor_4d(ctx, src.type, src.ne[0], src.ne[1], src.ne[2], src.ne[3]); } } // Ops with an inplace flag create a view of src[0] as their output. bool inplace = false; if (op == GGML_OP_SET || op == GGML_OP_ACC) { inplace = op_params[4] != 0; } else if (op == GGML_OP_ADD_REL_POS) { inplace = op_params[0] != 0; } ggml_tensor * out; if (inplace && source_count > 0) { out = ggml_view_tensor(ctx, source_tensors[0]); } else { out = ggml_new_tensor_4d(ctx, type, ne[0], ne[1], ne[2], ne[3]); } out->op = op; for (size_t i = 0; i < source_count; ++i) { out->src[i] = source_tensors[i]; } memcpy(out->op_params, op_params.data(), GGML_MAX_OP_PARAMS); ggml_set_name(out, "out"); return out; } double max_nmse_err() override { switch (op) { case GGML_OP_MUL_MAT: case GGML_OP_MUL_MAT_ID: case GGML_OP_OUT_PROD: case GGML_OP_CONV_TRANSPOSE_2D: case GGML_OP_IM2COL: case GGML_OP_CONV_2D: case GGML_OP_CONV_3D: case GGML_OP_SET_ROWS: case GGML_OP_CPY: return 5e-4; case GGML_OP_SOFT_MAX: return 1e-6; case GGML_OP_RWKV_WKV7: return 5e-3; case GGML_OP_FLASH_ATTN_EXT: { // Scale error with kv length to account for accumulating floating point error const int64_t kv = sources[1].ne[1]; return 5e-4 * std::max(1.0, kv / 20000.0); } default: return 1e-7; } } void initialize_tensors(ggml_context * ctx) override { ggml_tensor * out = ggml_get_tensor(ctx, "out"); std::random_device rd; std::default_random_engine rng(rd()); for (size_t i = 0; i < sources.size() && i < GGML_MAX_SRC; i++) { ggml_tensor * t = out->src[i]; if (!t) { break; } // FLASH_ATTN_EXT: src[3] is the KQ mask if (op == GGML_OP_FLASH_ATTN_EXT && i == 3) { init_tensor_kq_mask(t); continue; } if (t->type == GGML_TYPE_I32 || t->type == GGML_TYPE_I64) { if (op == GGML_OP_GET_ROWS || op == GGML_OP_GET_ROWS_BACK) { const int64_t num_rows = sources[0].ne[1]; const int64_t nels = ggml_nelements(t); std::vector data(nels); std::uniform_int_distribution dist(0, num_rows - 1); for (int64_t i = 0; i < nels; i++) { data[i] = dist(rng); } ggml_backend_tensor_set(t, data.data(), 0, nels * sizeof(int32_t)); } else if (op == GGML_OP_SET_ROWS) { init_set_rows_row_ids(t, ne[1]); } else if (op == GGML_OP_ROPE) { const int mode = op_params[2]; const int64_t nels = (mode & GGML_ROPE_TYPE_MROPE) ? ne[2] * 4 : ne[2]; std::vector data(nels); std::uniform_int_distribution dist(0, ne[2] - 1); for (int64_t i = 0; i < nels; i++) { data[i] = dist(rng); } ggml_backend_tensor_set(t, data.data(), 0, nels * sizeof(int32_t)); } else if (op == GGML_OP_MUL_MAT_ID || op == GGML_OP_ADD_ID) { const int64_t n_expert = (op == GGML_OP_MUL_MAT_ID) ? sources[0].ne[2] : sources[1].ne[1]; for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int32_t i = 0; i < t->ne[0]; i++) { data[i] = i % n_expert; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(int32_t)); } } else if (op == GGML_OP_SSM_SCAN) { for (int64_t r = 0; r < ggml_nrows(t); r++) { std::vector data(t->ne[0]); for (int32_t i = 0; i < t->ne[0]; i++) { data[i] = i; } std::shuffle(data.begin(), data.end(), rng); ggml_backend_tensor_set(t, data.data(), r * t->nb[1], t->ne[0] * sizeof(int32_t)); } } else { init_tensor_uniform(t); } } else { init_tensor_uniform(t); } } } }; enum llm_norm_type { LLM_NORM, LLM_NORM_RMS, }; struct llama_hparams { uint32_t n_vocab; uint32_t n_embd; uint32_t n_head; uint32_t n_head_kv; static constexpr uint32_t n_layer = 1; uint32_t n_rot; uint32_t n_embd_head; // dimension of values (d_v) uint32_t n_ff; float f_norm_eps; float f_norm_rms_eps; // cparams static constexpr uint32_t n_ctx = 512; // user-specified context size static constexpr uint32_t n_ctx_orig = n_ctx; // batch int32_t n_tokens; // llm_build_context static constexpr int32_t n_kv = 32; // size of KV cache to consider (n_kv <= n_ctx static constexpr int32_t kv_head = 1; // index of where we store new KV data in the cache uint32_t n_embd_gqa() const { // dimension of key embeddings across all k-v heads return n_embd_head * n_head_kv; } }; // LLM base class struct test_llm : public test_case { llama_hparams hp; protected: test_llm(llama_hparams hp) : hp(std::move(hp)) { } public: struct ggml_tensor * llm_build_norm( struct ggml_context * ctx, struct ggml_tensor * cur, struct ggml_tensor * mw, struct ggml_tensor * mb, llm_norm_type type) { switch (type) { case LLM_NORM: cur = ggml_norm (ctx, cur, hp.f_norm_eps); break; case LLM_NORM_RMS: cur = ggml_rms_norm(ctx, cur, hp.f_norm_rms_eps); break; } cur = ggml_mul(ctx, cur, mw); if (mb) { cur = ggml_add(ctx, cur, mb); } return cur; } void llm_build_kv_store( struct ggml_context * ctx, struct ggml_tensor * k_l, struct ggml_tensor * v_l, struct ggml_tensor * k_cur, struct ggml_tensor * v_cur) { // compute the transposed [n_tokens, n_embd] V matrix struct ggml_tensor * v_cur_t = ggml_transpose(ctx, ggml_reshape_2d(ctx, v_cur, hp.n_embd_gqa(), hp.n_tokens)); struct ggml_tensor * k_cache_view = ggml_view_1d(ctx, k_l, hp.n_tokens*hp.n_embd_gqa(), (ggml_row_size(k_l->type, hp.n_embd_gqa()))*hp.kv_head); struct ggml_tensor * v_cache_view = ggml_view_2d(ctx, v_l, hp.n_tokens, hp.n_embd_gqa(), ( hp.n_ctx)*ggml_element_size(v_l), (hp.kv_head)*ggml_element_size(v_l)); // important: storing RoPE-ed version of K in the KV cache! ggml_cpy(ctx, k_cur, k_cache_view); ggml_cpy(ctx, v_cur_t, v_cache_view); } struct ggml_tensor * llm_build_kqv( struct ggml_context * ctx, struct ggml_tensor * k_l, struct ggml_tensor * v_l, struct ggml_tensor * q_cur, struct ggml_tensor * kq_mask, float kq_scale) { struct ggml_tensor * q = ggml_permute(ctx, q_cur, 0, 2, 1, 3); struct ggml_tensor * k = ggml_view_3d(ctx, k_l, hp.n_embd_head, hp.n_kv, hp.n_head_kv, ggml_row_size(k_l->type, hp.n_embd_gqa()), ggml_row_size(k_l->type, hp.n_embd_head), 0); struct ggml_tensor * kq = ggml_mul_mat(ctx, k, q); kq = ggml_soft_max_ext(ctx, kq, kq_mask, kq_scale, 0.0f); // split cached v into n_head heads struct ggml_tensor * v = ggml_view_3d(ctx, v_l, hp.n_kv, hp.n_embd_head, hp.n_head_kv, ggml_element_size(v_l)*hp.n_ctx, ggml_element_size(v_l)*hp.n_ctx*hp.n_embd_head, 0); struct ggml_tensor * kqv = ggml_mul_mat(ctx, v, kq); struct ggml_tensor * kqv_merged = ggml_permute(ctx, kqv, 0, 2, 1, 3); struct ggml_tensor * cur = ggml_cont_2d(ctx, kqv_merged, hp.n_embd_head*hp.n_head, hp.n_tokens); struct ggml_tensor * wo = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_embd); cur = ggml_mul_mat(ctx, wo, cur); return cur; } void initialize_tensors(ggml_context * ctx) override { for (ggml_tensor * t = ggml_get_first_tensor(ctx); t != NULL; t = ggml_get_next_tensor(ctx, t)) { if (t->type == GGML_TYPE_I32) { // pos std::vector data(hp.n_tokens); for (int i = 0; i < hp.n_tokens; i++) { data[i] = rand() % hp.n_ctx; } ggml_backend_tensor_set(t, data.data(), 0, hp.n_tokens * sizeof(int)); } else { init_tensor_uniform(t); } } } }; // Llama struct test_llama : public test_llm { static constexpr float freq_base = 10000.0f; static constexpr float freq_scale = 1.0f; static constexpr float ext_factor = 0.0f; static constexpr float attn_factor = 1.0f; static constexpr float beta_fast = 32.0f; static constexpr float beta_slow = 1.0f; bool fused; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "LLAMA"; } std::string vars() override { auto n_tokens = hp.n_tokens; return VARS_TO_STR1(n_tokens); } double max_nmse_err() override { return 2e-3; } bool run_whole_graph() override { return fused; } test_llama(int n_tokens = 1, bool fused = false) : test_llm({ /*n_vocab =*/ 32000, /*n_embd =*/ 3200, /*n_head =*/ 32, /*n_head_kv =*/ 32, /*n_rot =*/ 100, /*n_embd_head =*/ 100, /*n_ff =*/ 8640, /*f_norm_eps =*/ 0.f, /*f_norm_rms_eps =*/ 1e-5f, /*n_tokens =*/ n_tokens, }) , fused(fused) { } ggml_tensor * build_graph(ggml_context * ctx) override { struct ggml_tensor * cur; struct ggml_tensor * inpL; inpL = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, hp.n_embd, hp.n_tokens); // inp_pos - contains the positions struct ggml_tensor * inp_pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, hp.n_tokens); // KQ_mask (mask for 1 head, it will be broadcasted to all heads) struct ggml_tensor * KQ_mask = ggml_new_tensor_3d(ctx, GGML_TYPE_F16, hp.n_kv, hp.n_tokens, 1); ggml_tensor * k_l = ggml_new_tensor_1d(ctx, GGML_TYPE_F16, 1638400); ggml_tensor * v_l = ggml_new_tensor_1d(ctx, GGML_TYPE_F16, 1638400); for (uint32_t il = 0; il < hp.n_layer; ++il) { struct ggml_tensor * inpSA = inpL; // norm ggml_tensor * attn_norm = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); cur = llm_build_norm(ctx, inpL, attn_norm, nullptr, LLM_NORM_RMS); // self-attention { ggml_tensor * wq = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_embd); ggml_tensor * wk = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_embd_gqa()); ggml_tensor * wv = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_embd_gqa()); // compute Q and K and RoPE them struct ggml_tensor * Qcur = ggml_mul_mat(ctx, wq, cur); struct ggml_tensor * Kcur = ggml_mul_mat(ctx, wk, cur); struct ggml_tensor * Vcur = ggml_mul_mat(ctx, wv, cur); Qcur = ggml_rope_ext( ctx, ggml_reshape_3d(ctx, Qcur, hp.n_embd_head, hp.n_head, hp.n_tokens), inp_pos, nullptr, hp.n_rot, 0, hp.n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); Kcur = ggml_rope_ext( ctx, ggml_reshape_3d(ctx, Kcur, hp.n_embd_head, hp.n_head_kv, hp.n_tokens), inp_pos, nullptr, hp.n_rot, 0, hp.n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); llm_build_kv_store(ctx, k_l, v_l, Kcur, Vcur); cur = llm_build_kqv(ctx, k_l, v_l, Qcur, KQ_mask, 1.0f/sqrtf(float(hp.n_embd_head))); } struct ggml_tensor * ffn_inp = ggml_add(ctx, cur, inpSA); // feed-forward network ggml_tensor * ffn_norm = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); cur = llm_build_norm(ctx, ffn_inp, ffn_norm, nullptr, LLM_NORM_RMS); ggml_tensor * ffn_gate = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_ff); ggml_tensor * ffn_down = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_ff, hp.n_embd); ggml_tensor * ffn_up = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_ff); struct ggml_tensor * tmp = ggml_mul_mat(ctx, ffn_up, cur); cur = ggml_mul_mat(ctx, ffn_gate, cur); cur = ggml_silu(ctx, cur); cur = ggml_mul(ctx, cur, tmp); cur = ggml_mul_mat(ctx, ffn_down, cur); cur = ggml_add(ctx, cur, ffn_inp); // input for next layer inpL = cur; } cur = inpL; ggml_tensor * output_norm = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); cur = llm_build_norm(ctx, cur, output_norm, nullptr, LLM_NORM_RMS); // lm_head ggml_tensor * output = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_vocab); cur = ggml_mul_mat(ctx, output, cur); return cur; } }; // Falcon struct test_falcon : public test_llm { static constexpr float freq_base = 10000.0f; static constexpr float freq_scale = 1.0f; static constexpr float ext_factor = 0.0f; static constexpr float attn_factor = 1.0f; static constexpr float beta_fast = 32.0f; static constexpr float beta_slow = 1.0f; std::string op_desc(ggml_tensor * t) override { GGML_UNUSED(t); return "FALCON"; } std::string vars() override { auto n_tokens = hp.n_tokens; return VARS_TO_STR1(n_tokens); } double max_nmse_err() override { return 2e-3; } test_falcon(int n_tokens = 1) : test_llm({ /*n_vocab =*/ 32000, /*n_embd =*/ 3200, /*n_head =*/ 50, /*n_head_kv =*/ 1, /*n_rot =*/ 64, /*n_embd_head =*/ 64, /*n_ff =*/ 8640, /*f_norm_eps =*/ 1e-5f, /*f_norm_rms_eps =*/ 0.f, /*n_tokens =*/ n_tokens, }) { } ggml_tensor * build_graph(ggml_context * ctx) override { struct ggml_tensor * cur; struct ggml_tensor * inpL; inpL = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, hp.n_embd, hp.n_tokens); // inp_pos - contains the positions struct ggml_tensor * inp_pos = ggml_new_tensor_1d(ctx, GGML_TYPE_I32, hp.n_tokens); // KQ_mask (mask for 1 head, it will be broadcasted to all heads) struct ggml_tensor * KQ_mask = ggml_new_tensor_3d(ctx, GGML_TYPE_F16, hp.n_kv, hp.n_tokens, 1); ggml_tensor * k_l = ggml_new_tensor_1d(ctx, GGML_TYPE_F16, 1638400); ggml_tensor * v_l = ggml_new_tensor_1d(ctx, GGML_TYPE_F16, 1638400); for (uint32_t il = 0; il < hp.n_layer; ++il) { // norm ggml_tensor * attn_norm_w = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); ggml_tensor * attn_norm_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); ggml_tensor * attn_norm = llm_build_norm(ctx, inpL, attn_norm_w, attn_norm_b, LLM_NORM); // self-attention { cur = attn_norm; ggml_tensor * wqkv = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_embd + 2*hp.n_embd_gqa()); cur = ggml_mul_mat(ctx, wqkv, cur); struct ggml_tensor * Qcur = ggml_cont(ctx, ggml_view_2d(ctx, cur, hp.n_embd, hp.n_tokens, cur->nb[1], 0*sizeof(float)*(hp.n_embd))); struct ggml_tensor * Kcur = ggml_cont(ctx, ggml_view_2d(ctx, cur, hp.n_embd_gqa(), hp.n_tokens, cur->nb[1], 1*sizeof(float)*(hp.n_embd))); struct ggml_tensor * Vcur = ggml_cont(ctx, ggml_view_2d(ctx, cur, hp.n_embd_gqa(), hp.n_tokens, cur->nb[1], 1*sizeof(float)*(hp.n_embd + hp.n_embd_gqa()))); Qcur = ggml_reshape_3d(ctx, Qcur, hp.n_embd_head, hp.n_head, hp.n_tokens); Kcur = ggml_reshape_3d(ctx, Kcur, hp.n_embd_head, hp.n_head_kv, hp.n_tokens); // using mode = 2 for neox mode Qcur = ggml_rope_ext( ctx, Qcur, inp_pos, nullptr, hp.n_rot, 2, hp.n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); Kcur = ggml_rope_ext( ctx, Kcur, inp_pos, nullptr, hp.n_rot, 2, hp.n_ctx_orig, freq_base, freq_scale, ext_factor, attn_factor, beta_fast, beta_slow ); llm_build_kv_store(ctx, k_l, v_l, Kcur, Vcur); cur = llm_build_kqv(ctx, k_l, v_l, Qcur, KQ_mask, 1.0f/sqrtf(float(hp.n_embd_head))); } struct ggml_tensor * ffn_inp = cur; // feed forward { ggml_tensor * ffn_up = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_embd, hp.n_ff); ggml_tensor * ffn_down = ggml_new_tensor_2d(ctx, GGML_TYPE_Q4_0, hp.n_ff, hp.n_embd); cur = attn_norm; cur = ggml_mul_mat(ctx, ffn_up, cur); cur = ggml_gelu(ctx, cur); cur = ggml_mul_mat(ctx, ffn_down, cur); } cur = ggml_add(ctx, cur, ffn_inp); cur = ggml_add(ctx, cur, inpL); // input for next layer inpL = cur; } cur = inpL; ggml_tensor * output_norm = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); ggml_tensor * output_norm_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, hp.n_embd); cur = llm_build_norm(ctx, cur, output_norm, output_norm_b, LLM_NORM); // lm_head ggml_tensor * output = ggml_new_tensor_2d(ctx, GGML_TYPE_Q8_0, hp.n_embd, hp.n_vocab); cur = ggml_mul_mat(ctx, output, cur); return cur; } }; // ########################################### // ## Section 3: GGML Op Test Instantiation ## // ########################################### static const ggml_type all_types[] = { GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_BF16, GGML_TYPE_Q4_0, GGML_TYPE_Q4_1, GGML_TYPE_Q5_0, GGML_TYPE_Q5_1, GGML_TYPE_Q8_0, GGML_TYPE_MXFP4, GGML_TYPE_NVFP4, GGML_TYPE_Q2_K, GGML_TYPE_Q3_K, GGML_TYPE_Q4_K, GGML_TYPE_Q5_K, GGML_TYPE_Q6_K, // GGML_TYPE_TQ1_0, GGML_TYPE_TQ2_0, // TODO: implement for all backends GGML_TYPE_IQ2_XXS, GGML_TYPE_IQ2_XS, GGML_TYPE_IQ2_S, GGML_TYPE_IQ3_XXS, GGML_TYPE_IQ1_S, GGML_TYPE_IQ1_M, GGML_TYPE_IQ4_NL, GGML_TYPE_IQ3_S, GGML_TYPE_IQ4_XS, }; static const ggml_type base_types[] = { GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_Q8_0, // for I8MM tests GGML_TYPE_Q4_0, GGML_TYPE_Q4_1, // for I8MM tests GGML_TYPE_Q4_K, GGML_TYPE_MXFP4, GGML_TYPE_NVFP4, // TODO: or "other" GGML_TYPE_IQ2_XXS }; static const ggml_type other_types[] = { GGML_TYPE_Q4_1, GGML_TYPE_Q5_0, GGML_TYPE_Q5_1, GGML_TYPE_Q8_0, GGML_TYPE_Q2_K, GGML_TYPE_Q3_K, GGML_TYPE_Q5_K, GGML_TYPE_Q6_K, // GGML_TYPE_TQ1_0, GGML_TYPE_TQ2_0, // TODO: implement for all backends GGML_TYPE_IQ2_XS, GGML_TYPE_IQ2_S, GGML_TYPE_IQ3_XXS, GGML_TYPE_IQ1_S, GGML_TYPE_IQ1_M, GGML_TYPE_IQ4_NL, GGML_TYPE_IQ3_S, GGML_TYPE_IQ4_XS, GGML_TYPE_BF16, }; #ifdef _MSC_VER // Workaround long compile time with msvc #pragma optimize("", off) #endif // Test cases for evaluation: should try to cover edge cases while using small input sizes to keep the runtime low static std::vector> make_test_cases_eval() { std::vector> test_cases; std::default_random_engine rng(0); // unary ops for (ggml_type type : {GGML_TYPE_F16, GGML_TYPE_F32}) { for (int v : {0, 1}) { for (int op = 0; op < GGML_UNARY_OP_COUNT; op++) { if (op == GGML_UNARY_OP_XIELU) { continue; // need extra params, separate test } test_cases.emplace_back(new test_unary((ggml_unary_op) op, type, { 128, 2, 2, 2 }, v)); test_cases.emplace_back(new test_unary((ggml_unary_op) op, type, { 5, 7, 11, 13 }, v)); } } } // glu ops for (ggml_type type : {GGML_TYPE_F16, GGML_TYPE_F32}) { for (int v : {0, 1}) { for (int op = 0; op < GGML_GLU_OP_COUNT; op++) { if (op == GGML_GLU_OP_SWIGLU_OAI) { // SWIGLU_OAI is handled separately continue; } for (bool swapped : {false, true}) { test_cases.emplace_back(new test_glu((ggml_glu_op) op, type, { 128, 2, 2, 2 }, v, swapped)); test_cases.emplace_back(new test_glu((ggml_glu_op) op, type, { 5, 7, 11, 13 }, v, swapped)); } test_cases.emplace_back(new test_glu_split((ggml_glu_op) op, type, { 128, 2, 2, 2 }, v)); test_cases.emplace_back(new test_glu_split((ggml_glu_op) op, type, { 5, 7, 11, 13 }, v)); } } } for (int v : {0, 1}) { for (float alpha : {.5f, 1.702f}) { for (float limit : {2.0f, 7.0f}) { test_cases.emplace_back(new test_swiglu_oai(GGML_TYPE_F32, { 128, 2, 2, 2 }, v, alpha, limit)); } } } for (ggml_type type : {GGML_TYPE_F32, GGML_TYPE_Q4_0}) { test_cases.emplace_back(new test_get_rows(type, 300*256, 5, 4, 1, 2, false)); test_cases.emplace_back(new test_get_rows(type, 256, 80000, 70000, 2, 1, false)); test_cases.emplace_back(new test_get_rows(type, 256, 5, 4, 700, 100, false)); } test_cases.emplace_back(new test_get_rows(GGML_TYPE_F32, 1, 8, 2, 1, 1, false)); for (ggml_type type : all_types) { for (int b : {1, 7}) { for (bool v : {false, true}) { test_cases.emplace_back(new test_get_rows(type, 256, 5, 4, b, 1, v)); } } } for (int b : {1, 7}) { for (bool v : {false, true}) { test_cases.emplace_back(new test_get_rows(GGML_TYPE_I32, 256, 5, 4, b, 1, v)); } } test_cases.emplace_back(new test_get_rows_back(GGML_TYPE_F32, 1, 8, 2, 1, false)); for (ggml_type type : all_types) { for (bool v : {false, true}) { test_cases.emplace_back(new test_get_rows_back(type, 256, 5, 4, 1, v)); } } for (bool v : {false, true}) { test_cases.emplace_back(new test_get_rows_back(GGML_TYPE_I32, 256, 5, 4, 1, v)); } test_cases.emplace_back(new test_set_rows(GGML_TYPE_F32, GGML_TYPE_I64, { 1, 8, 1, 3 }, { 1, 1 }, 2, false)); test_cases.emplace_back(new test_set_rows(GGML_TYPE_F32, GGML_TYPE_I32, { 1, 8, 1, 3 }, { 1, 1 }, 2, false)); test_cases.emplace_back(new test_set_rows(GGML_TYPE_Q8_0, GGML_TYPE_I32, { 256, 5, 1, 3 }, { 1, 1, }, 1, false)); for (ggml_type type : all_types) { for (int b : {1, 7}) { for (bool v : {false, true}) { test_cases.emplace_back(new test_set_rows(type, GGML_TYPE_I64, { 256, 5, b, 3 }, { 1, 1, }, 1, v)); test_cases.emplace_back(new test_set_rows(type, GGML_TYPE_I64, { 256, 11, 1, b }, { 2, 3, }, 7, v)); test_cases.emplace_back(new test_set_rows(type, GGML_TYPE_I64, { 3*ggml_blck_size(type), 3, b, 1 }, { 2, 3, }, 2, v)); if (ggml_blck_size(type) == 1) { test_cases.emplace_back(new test_set_rows(type, GGML_TYPE_I64, { 31, 3, b, 1 }, { 2, 3, }, 2, v)); test_cases.emplace_back(new test_set_rows(type, GGML_TYPE_I64, { 33, 5, 1, b }, { 2, 3, }, 1, v)); } } } } for (int mode : { GGML_ROPE_TYPE_NORMAL, GGML_ROPE_TYPE_NEOX, GGML_ROPE_TYPE_MROPE, GGML_ROPE_TYPE_VISION }) { for (ggml_type type : {GGML_TYPE_F16, GGML_TYPE_F32}) { for (int ne2 : {1, 8, 512}) { test_cases.emplace_back(new test_rope_set_rows(type, GGML_TYPE_I64, { 128, 32, ne2, 1 }, mode)); test_cases.emplace_back(new test_rope_set_rows(type, GGML_TYPE_I64, { 128, 32, ne2, 3 }, mode)); } } } for (ggml_type type_input : {GGML_TYPE_F32}) { for (ggml_op_pool pool_type : {GGML_OP_POOL_AVG, GGML_OP_POOL_MAX}) { for (int k0 : {1, 3}) { for (int k1 : {1, 3}) { for (int s0 : {1, 2}) { for (int s1 : {1, 2}) { for (int p0 : {0, 1}) { for (int p1 : {0, 1}) { test_cases.emplace_back(new test_pool2d(pool_type, type_input, {10, 10, 3, 1}, k0, k1, s0, s1, p0, p1)); } } } } } } } } for (ggml_type type_input : {GGML_TYPE_F32}) { for (ggml_op_pool pool_type : {GGML_OP_POOL_AVG, GGML_OP_POOL_MAX}) { for (int k0 : {1, 3}) { for (int s0 : {1, 2}) { for (int p0 : {0, 1}) { test_cases.emplace_back(new test_pool1d(pool_type, type_input, { 10, 3, 2, 1 }, k0, s0, p0)); test_cases.emplace_back(new test_pool1d(pool_type, type_input, { 11, 1, 3, 2 }, k0, s0, p0)); test_cases.emplace_back(new test_pool1d(pool_type, type_input, { 128, 2, 1, 3 }, k0, s0, p0)); } } } } } #if 0 // >4GB im2col destination. Too slow to run by default. // Test cases taken from Wan2.1 T2V 1.3B. test_cases.emplace_back(new test_im2col (GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {832, 480, 192, 4}, {3, 3, 192, 96}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col_3d(GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {834, 482, 6, 96}, {3, 3,3, 9216}, 96, 1, 1, 1, 0, 0, 0, 1, 1, 1, false)); #endif // im2col 1D test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {3000, 128, 1, 1}, {3, 128, 1280, 1}, 1, 0, 1, 0, 1, 0, false)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F32, {3000, 128, 1, 1}, {3, 128, 1280, 1}, 1, 0, 1, 0, 1, 0, false)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {3000, 128, 1, 1}, {3, 128, 1280, 1}, 1, 0, 1, 0, 1, 0, false)); for (int s0 : {1, 3}) { for (int p0 : {0, 3}) { for (int d0 : {1, 3}) { test_cases.emplace_back(new test_im2col( GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {20, 2, 2, 1}, {3, 2, 2, 1}, s0, 0, p0, 0, d0, 0, false)); } } } // im2col 2D test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F32)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16)); for (int s0 : {1, 3}) { for (int s1 : {1, 3}) { for (int p0 : {0, 3}) { for (int p1 : {0, 3}) { for (int d0 : {1, 3}) { for (int d1 : {1, 3}) { test_cases.emplace_back(new test_im2col( GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {20, 20, 2, 2}, {3, 3, 2, 2}, s0, s1, p0, p1, d0, d1, true)); } } } } } } // extra tests for im2col 2D test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 1, 32}, {3, 3, 1, 32}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 2, 32}, {3, 3, 2, 32}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 1, 1024}, {3, 3, 1, 1024}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 2, 1024}, {3, 3, 2, 1024}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 1, 2048}, {3, 3, 1, 2048}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 2, 2048}, {3, 3, 2, 2048}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 1, 2560}, {3, 3, 1, 2560}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {12, 12, 2, 2560}, {3, 3, 2, 2560}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {5, 5, 1, 32}, {3, 4, 1, 32}, 1, 1, 0, 0, 1, 1, true)); test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {2, 2, 1536, 729}, {2, 2, 1536, 4096}, 1, 1, 0, 0, 1, 1, true)); // im2col 3D test_cases.emplace_back(new test_im2col_3d(GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32)); test_cases.emplace_back(new test_im2col_3d(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F32)); test_cases.emplace_back(new test_im2col_3d(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16)); for (int s0 : {1, 3}) { for (int s1 : {1, 3}) { for (int s2 : {1, 3}) { for (int p0 : {0, 3}) { for (int p1 : {0, 3}) { for (int p2 : {0, 3}) { for (int d0 : {1, 3}) { for (int d1 : {1, 3}) { for (int d2 : {1, 3}) { for (int IC : {1, 3}) { for (bool v : {false, true}) { test_cases.emplace_back(new test_im2col_3d( GGML_TYPE_F32, GGML_TYPE_F32, GGML_TYPE_F32, {20, 20, 10, 3}, {3, 3, 3, 3}, IC, s0, s1, s2, p0, p1, p2, d0, d1, d2, v)); } } } } } } } } } } } // Conv_2D test cases #ifdef DETAILED_TESTS // Probably we do not have enough time to execute these in the pipeline. uint32_t iwh_idx = 0; uint32_t kwh_idx = 1; uint32_t Cout_idx = 2; uint32_t Cin_idx = 3; uint32_t B_idx = 4; std::vector> cases = { //{IWH, KWH, Cout, Cin, B} // K=CRS=NPQ=4096 conv_2d matmul performance {19, 4, 4096, 256, 16}, // K=128, CRS=128, NPQ=4096 { 19, 4, 128, 8, 16}, // K=130, CRS=128, NPQ=4096 { 19, 4, 130, 8, 16}, // Edge case: K x CRS is small { 19, 2, 4, 4, 16}, // A ConvNet's first layer { 224, 3, 8, 3, 1 }, // A ConvNet's first layer with 2x2 convolution, and 1 channel { 224, 2, 8, 1, 1 }, // A ConvNet's first layer with 2x2 convolution, and 1 channel, several images in the batch { 224, 2, 8, 1, 8 }, // A middle layer of a ConvNet { 58, 3, 64, 32, 1 }, // A middle layer of a ConvNet, several images in the batch { 58, 3, 64, 32, 8 }, // A deep layer of a ConvNet, several images in the batch { 16, 3, 256, 128, 8 } }; for (auto kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (auto act_case : cases) { test_cases.emplace_back(new test_conv_2d( { act_case[iwh_idx], act_case[iwh_idx], act_case[Cin_idx], act_case[B_idx] }, { act_case[kwh_idx], act_case[kwh_idx], act_case[Cin_idx], act_case[Cout_idx] }, kernel_type, 1, 1, 0, 0, 1, 1, false)); } } #endif // CONV_2D: auto calc_conv_output_size = [](int64_t ins, int64_t ks, int s, int p, int d) -> int64_t { return (ins + 2 * p - d * (ks - 1) - 1) / s + 1; }; //uint32_t s0 = 3; uint32_t s1 = 5; uint32_t p0 = 5; //uint32_t p1 = 2; uint32_t d0 = 2; uint32_t d1 = 4; for (uint32_t s0 : { 1, 3 }) { for (uint32_t p1 : { 2, 5 }) { for (uint32_t Cin : { 1, 25 }) { for (uint32_t Cout : { 1, 12 }) { for (uint32_t KH : { 1, 2, 3, 11 }) { for (uint32_t KW : { 1, 2, 3, 11 }) { for (uint32_t H : { 1, 133 }) { for (uint32_t W : { 1, 141 }) { if (calc_conv_output_size(W, KW, s0, p0, d0) > 0 && calc_conv_output_size(H, KH, s1, p1, d1) > 0) { for (auto kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { test_cases.emplace_back(new test_conv_2d( { W, H, Cin, 2 }, { KW, KH, Cin, Cout }, kernel_type, s0, s1, p0, p1, d0, d1, false)); } } } } } } } } } } // sycl backend will limit task global_range < MAX_INT // test cases for 2D im2col with large input W and H (occurs in stable-diffusion) // however these cases need to alloc more memory which may fail in some devices (Intel Arc770, etc.) // these cases are verified (pass) in Intel(R) Data Center GPU Max 1100 (sycl backend) and NV A30 (cuda backend) // test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F16, {1024, 1024, 256, 1}, {3, 3, 256, 1}, 1, 1, 1, 1, 1, 1, true)); // test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F32, {1024, 1024, 256, 1}, {3, 3, 256, 1}, 1, 1, 1, 1, 1, 1, true)); test_cases.emplace_back(new test_conv_2d_dw({17, 34, 9, 1}, {3, 3, 1, 9}, 1, 0, 1, false)); test_cases.emplace_back(new test_conv_2d_dw({17, 34, 9, 1}, {3, 3, 1, 9}, 1, 0, 1, true)); test_cases.emplace_back(new test_conv_2d_dw({32, 8, 64, 1}, {3, 3, 1, 64}, 2, 1, 1, false)); test_cases.emplace_back(new test_conv_2d_dw({32, 8, 64, 1}, {3, 3, 1, 64}, 2, 1, 1, true)); // CONV_3D auto calc_conv_output_size_3d = [](int64_t ins, int64_t ks, int s, int p, int d) -> int64_t { return (ins + 2 * p - d * (ks - 1) - 1) / s + 1; }; for (ggml_type kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (int N : {1, 2}) { for (int IC : {1, 3}) { for (int OC : {1, 4}) { for (int s0 : {1, 2}) { for (int p1 : {0, 1}) { for (int d2 : {1, 2}) { int64_t IW = 20, IH = 22, ID = 18; int64_t KW = 3, KH = 3, KD = 3; int s1 = s0, s2 = s0; int p0 = p1, p2 = p1; int d0 = d2, d1 = d2; if (calc_conv_output_size_3d(IW, KW, s0, p0, d0) <= 0 || calc_conv_output_size_3d(IH, KH, s1, p1, d1) <= 0 || calc_conv_output_size_3d(ID, KD, s2, p2, d2) <= 0) { continue; } test_cases.emplace_back(new test_conv_3d( N, IC, ID, IH, IW, OC, KD, KH, KW, s0, s1, s2, p0, p1, p2, d0, d1, d2, kernel_type)); // Asymmetric kernel and params int64_t asym_KW = 5, asym_KH = 1, asym_KD = 3; int asym_s0 = 2, asym_s1 = 1, asym_s2 = 1; int asym_p0 = 2, asym_p1 = 0, asym_p2 = 1; int asym_d0 = 1, asym_d1 = 1, asym_d2 = 2; if (calc_conv_output_size_3d(IW, asym_KW, asym_s0, asym_p0, asym_d0) <= 0 || calc_conv_output_size_3d(IH, asym_KH, asym_s1, asym_p1, asym_d1) <= 0 || calc_conv_output_size_3d(ID, asym_KD, asym_s2, asym_p2, asym_d2) <= 0) { continue; } test_cases.emplace_back(new test_conv_3d( N, IC, ID, IH, IW, OC, asym_KD, asym_KH, asym_KW, asym_s0, asym_s1, asym_s2, asym_p0, asym_p1, asym_p2, asym_d0, asym_d1, asym_d2, kernel_type)); } } } } } } // Case with kernel size 1 test_cases.emplace_back(new test_conv_3d(1, 4, 8, 8, 8, 8, 1, 1, 1, 1, 1, 1, 0, 0, 0, 1, 1, 1, kernel_type)); } for(uint32_t Cout : {1, 9}){ for(uint32_t Cin : {1, 7}){ for(uint32_t K : {1, 3, 1337}){ for(uint32_t L : {1, 2, 13}){ for(uint32_t s0: {1, 2, 3}){ test_cases.emplace_back(new test_conv_transpose_1d({L,Cin,1,1}, {K,Cout,Cin,1}, s0, 0, 1)); } } } } } test_cases.emplace_back(new test_conv_transpose_1d()); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {2,3,2,1}, 3, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {2,3,2,1}, 2, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {2,3,2,1}, 1, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {3,2,2,1}, 2, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {3,2,2,1}, 1, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({3,2,1,1}, {3,1,2,1}, 1, 0, 1)); test_cases.emplace_back(new test_conv_transpose_1d({2,1,1,1}, {3,1,1,1}, 1, 0, 1)); for (ggml_type kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { test_cases.emplace_back(new test_conv_transpose_2d({3, 2, 3, 1}, {2, 2, 1, 3}, 1, kernel_type)); test_cases.emplace_back(new test_conv_transpose_2d({10, 10, 9, 1}, {3, 3, 1, 9}, 2, kernel_type)); test_cases.emplace_back(new test_conv_transpose_2d({129, 63, 35, 1}, {3, 3, 48, 35}, 1, kernel_type)); } test_cases.emplace_back(new test_count_equal(GGML_TYPE_F32, {4, 500, 1, 1})); test_cases.emplace_back(new test_count_equal(GGML_TYPE_F32, {4, 5000, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {32, 1, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {32, 513, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {100, 10, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {1024, 10, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {1024, 12, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {2000, 10, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {5438, 3, 1, 1})); for (int ne3 : {1, 3}) { // CUDA backward pass only supports ne3 == 1 test_cases.emplace_back(new test_repeat(GGML_TYPE_F32, {10, 5, 4, ne3}, {1, 1, 1, 1})); test_cases.emplace_back(new test_repeat(GGML_TYPE_F32, {10, 5, 4, ne3}, {2, 1, 1, 1})); test_cases.emplace_back(new test_repeat(GGML_TYPE_F32, {10, 5, 4, ne3}, {1, 2, 1, 1})); test_cases.emplace_back(new test_repeat(GGML_TYPE_F32, {10, 5, 4, ne3}, {1, 1, 2, 1})); test_cases.emplace_back(new test_repeat(GGML_TYPE_F32, {10, 5, 4, ne3}, {1, 1, 1, 2})); test_cases.emplace_back(new test_repeat(GGML_TYPE_I32, {10, 5, 4, ne3}, {2, 1, 1, 1})); test_cases.emplace_back(new test_repeat(GGML_TYPE_I16, {10, 5, 4, ne3}, {1, 1, 1, 2})); } for (bool view : {false, true}) { test_cases.emplace_back(new test_repeat_back(GGML_TYPE_F32, {8, 6, 4, 2}, {1, 1, 1, 1}, view)); test_cases.emplace_back(new test_repeat_back(GGML_TYPE_F32, {8, 6, 4, 2}, {2, 1, 1, 1}, view)); test_cases.emplace_back(new test_repeat_back(GGML_TYPE_F32, {8, 6, 4, 2}, {1, 2, 1, 1}, view)); test_cases.emplace_back(new test_repeat_back(GGML_TYPE_F32, {8, 6, 4, 2}, {1, 1, 2, 1}, view)); test_cases.emplace_back(new test_repeat_back(GGML_TYPE_F32, {8, 6, 4, 2}, {1, 1, 1, 2}, view)); } test_cases.emplace_back(new test_dup(GGML_TYPE_F32)); test_cases.emplace_back(new test_dup(GGML_TYPE_F16)); test_cases.emplace_back(new test_dup(GGML_TYPE_I32)); test_cases.emplace_back(new test_dup(GGML_TYPE_I16)); test_cases.emplace_back(new test_dup(GGML_TYPE_F32, {10, 10, 5, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_dup(GGML_TYPE_F16, {10, 10, 5, 1}, {0, 2, 1, 3})); // dup by rows test_cases.emplace_back(new test_dup(GGML_TYPE_F32, {10, 10, 5, 1}, {1, 0, 2, 3})); test_cases.emplace_back(new test_dup(GGML_TYPE_F16, {10, 10, 5, 1}, {1, 0, 2, 3})); // dup dst not-contiguous test_cases.emplace_back(new test_dup(GGML_TYPE_I16, {10, 8, 3, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_dup(GGML_TYPE_I16, {10, 8, 3, 1}, {1, 2, 0, 3})); for (int dim = 1; dim < GGML_MAX_DIMS; ++dim) { test_cases.emplace_back(new test_set(GGML_TYPE_F32, GGML_TYPE_F32, {6, 5, 4, 3}, dim, false)); test_cases.emplace_back(new test_set(GGML_TYPE_F32, GGML_TYPE_F32, {6, 5, 4, 3}, dim, true)); } for (int dim = 1; dim < GGML_MAX_DIMS; ++dim) { test_cases.emplace_back(new test_set(GGML_TYPE_I32, GGML_TYPE_I32, {6, 5, 4, 3}, dim, false)); test_cases.emplace_back(new test_set(GGML_TYPE_I32, GGML_TYPE_I32, {6, 5, 4, 3}, dim, true)); } // same-type copy for (ggml_type type : all_types) { const auto nk = ggml_blck_size(type); for (int k = 1; k < 4; ++k) { test_cases.emplace_back(new test_cpy(type, type, {k*nk, 2, 3, 4})); test_cases.emplace_back(new test_cpy(type, type, {k*nk, 2, 3, 4}, {0, 2, 1, 3})); test_cases.emplace_back(new test_cpy(type, type, {k*nk, 2, 3, 4}, {0, 3, 1, 2}, {0, 2, 1, 3})); } } for (ggml_type type_src : {GGML_TYPE_F16, GGML_TYPE_BF16, GGML_TYPE_F32}) { for (ggml_type type_dst : all_types) { test_cases.emplace_back(new test_cpy(type_src, type_dst, {256, 4, 4, 4})); test_cases.emplace_back(new test_cpy(type_src, type_dst, {256, 2, 3, 4}, {0, 2, 1, 3})); // cpy by rows } } for (ggml_type type_src : all_types) { for (ggml_type type_dst : {GGML_TYPE_F32}) { test_cases.emplace_back(new test_cpy(type_src, type_dst, {256, 4, 4, 4})); test_cases.emplace_back(new test_cpy(type_src, type_dst, {256, 2, 3, 4}, {0, 2, 1, 3})); // cpy by rows } } for (ggml_type type_src : {GGML_TYPE_F16, GGML_TYPE_F32}) { for (ggml_type type_dst : {GGML_TYPE_F16, GGML_TYPE_F32}) { test_cases.emplace_back(new test_cpy(type_src, type_dst, {256, 2, 3, 4}, {1, 0, 2, 3})); // cpy not-contiguous } } test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_I32, {256, 2, 3, 4})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_I32, {256, 2, 3, 4}, {1, 0, 2, 3})); test_cases.emplace_back(new test_cpy(GGML_TYPE_I32, GGML_TYPE_F32, {256, 2, 3, 4})); test_cases.emplace_back(new test_cpy(GGML_TYPE_I32, GGML_TYPE_F32, {256, 2, 3, 4}, {1, 0, 2, 3})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {256, 4, 3, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {256, 4, 3, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {256, 4, 3, 3}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_BF16, GGML_TYPE_BF16, {256, 4, 3, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {256, 4, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {256, 4, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_BF16, GGML_TYPE_BF16, {256, 4, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_I32, GGML_TYPE_I32, {256, 4, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_I32, GGML_TYPE_I32, {256, 1, 4, 1}, {1, 2, 0, 3}, {0, 0, 0, 0})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {256, 1, 4, 1}, {1, 2, 0, 3}, {0, 0, 0, 0})); for (ggml_type type_dst : { GGML_TYPE_F32, GGML_TYPE_I32, GGML_TYPE_F16, GGML_TYPE_BF16 }) { for (bool use_view_slice : { true, false }) { for (std::array ne : std::initializer_list>{ {2, 1, 1, 1}, {2, 1, 3, 5}, {2, 3, 5, 7}, {1, 4, 4, 1}, {1, 8, 17, 1}, {10, 10, 10, 1} }) { if (use_view_slice && (type_dst == GGML_TYPE_F16 || type_dst == GGML_TYPE_BF16)) { continue; // TODO: add after WebGPU is fixed } test_cases.emplace_back(new test_cont(type_dst, ne, use_view_slice)); } } } auto add_test_bin_bcast = [&](ggml_type type, std::array ne, std::array nr, bool perm1 = false, bool src_overlap = false) { for (auto op : {ggml_add, ggml_sub, ggml_mul, ggml_div}) { test_cases.emplace_back(new test_bin_bcast(op, type, ne, nr, 1, perm1, src_overlap)); } }; for (ggml_type type : {GGML_TYPE_F16, GGML_TYPE_F32}) { for (bool perm1 : {false, true}) { add_test_bin_bcast(type, {1, 1, 8, 1}, {1, 1, 1, 1}, perm1); add_test_bin_bcast(type, {1, 1, 1, 1}, {32, 1, 1, 1}, perm1); add_test_bin_bcast(type, {1, 1, 320, 320}, {1, 1, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 1, 1}, {1, 1, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 1}, {1, 1, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 1, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {2, 1, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 2, 1, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 1, 2, 1}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 1, 1, 2}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 1, 2, 2}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {1, 2, 2, 2}, perm1); add_test_bin_bcast(type, {10, 5, 4, 3}, {2, 2, 2, 2}, perm1); } // src_overlap add_test_bin_bcast(type, {10, 5, 4, 6}, {1, 1, 1, 1}, false, true); add_test_bin_bcast(type, {10, 5, 4, 5}, {1, 1, 1, 1}, false, true); add_test_bin_bcast(type, {1, 1, 120, 120}, {1, 1, 1, 1}, false, true); add_test_bin_bcast(type, {1, 1, 4, 320}, {1, 1, 1, 1}, false, true); // test case for k_bin_bcast_unravel in CUDA backend add_test_bin_bcast(type, {1, 1, 65536, 1}, {256, 1, 1, 1}); // stable diffusion add_test_bin_bcast(type, {1280, 1, 1, 1}, {1, 1, 1, 1}); add_test_bin_bcast(type, {1280, 1, 1, 1}, {1, 16, 16, 1}); add_test_bin_bcast(type, {1280, 16, 16, 1}, {1, 1, 1, 1}); add_test_bin_bcast(type, {1280, 1, 1, 1}, {1, 256, 1, 1}); add_test_bin_bcast(type, {1, 1, 1280, 1}, {16, 16, 1, 1}); add_test_bin_bcast(type, {16, 16, 1280, 1}, {1, 1, 1, 1}); add_test_bin_bcast(type, {1, 1, 1920, 1}, {16, 16, 1, 1}); add_test_bin_bcast(type, {1, 1, 2560, 1}, {16, 16, 1, 1}); add_test_bin_bcast(type, {1, 1, 1280, 1}, {32, 32, 1, 1}); add_test_bin_bcast(type, {1, 1, 1920, 1}, {32, 32, 1, 1}); add_test_bin_bcast(type, {1, 1, 640, 1}, {32, 32, 1, 1}); add_test_bin_bcast(type, {5120, 1, 1, 1}, {1, 256, 1, 1}); add_test_bin_bcast(type, {640, 1, 1, 1}, {1, 1, 1, 1}); add_test_bin_bcast(type, {64, 262144, 1, 1}, {1, 1, 1, 1}); //add_test_bin_bcast(type, {3, 3, 2560, 1280}, {1, 1, 1, 1}); //add_test_bin_bcast(type, {3, 3, 2560, 1280}, {2, 1, 1, 1}); } // single inplace tests, especially important for WebGPU backend since kernels for inplace vs. not are different test_cases.emplace_back(new test_bin_bcast(ggml_add_inplace, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 1}, 16)); test_cases.emplace_back(new test_bin_bcast(ggml_mul_inplace, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 1}, 16)); test_cases.emplace_back(new test_bin_bcast(ggml_sub_inplace, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 1}, 16)); test_cases.emplace_back(new test_bin_bcast(ggml_div_inplace, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 1}, 16)); // fusion test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {10, 5, 4, 3}, {2, 1, 1, 1}, 2)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 2, 1, 1}, 3)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {10, 5, 4, 3}, {1, 1, 2, 1}, 4)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 2}, 5)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {10, 5, 4, 3}, {1, 1, 2, 2}, 6)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {10, 5, 4, 3}, {1, 2, 2, 2}, 7)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {16, 5, 4, 3}, {2, 2, 2, 2}, 8)); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {16, 5, 4, 3}, {1, 1, 1, 1}, 16)); test_cases.emplace_back(new test_add1()); test_cases.emplace_back(new test_add1(GGML_TYPE_F32, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_scale()); test_cases.emplace_back(new test_scale(GGML_TYPE_F32, {10, 10, 10, 10}, 2.0f, 1.0f)); test_cases.emplace_back(new test_scale(GGML_TYPE_F32, {10, 10, 10, 10}, 2.0f, 1.0f, true)); // inplace test test_cases.emplace_back(new test_scale(GGML_TYPE_F32, {100, 10, 10, 10}, 2.0f, 1.0f)); test_cases.emplace_back(new test_softcap(GGML_TYPE_F32, {10, 10, 10, 10}, 50.0f)); test_cases.emplace_back(new test_silu_back()); for (float eps : { 0.0f, 1e-6f, 1e-4f, 1e-1f, 10.f }) { for (uint32_t n : { 64, 1025 }) { for (bool v : { false, true }) { test_cases.emplace_back(new test_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, v, eps)); test_cases.emplace_back(new test_rms_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, v, eps)); } test_cases.emplace_back(new test_rms_norm_back(GGML_TYPE_F32, { n, 5, 4, 3 }, eps)); test_cases.emplace_back(new test_l2_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, false)); test_cases.emplace_back(new test_l2_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, true)); } } // in-place tests test_cases.emplace_back(new test_rms_norm(GGML_TYPE_F32, {64, 5, 4, 3}, false, 1e-6f, true)); for (float eps : { 0.0f, 1e-6f, 1e-4f, 1e-1f, 1.0f }) { for (uint32_t n : { 64, 1025 }) { test_cases.emplace_back(new test_rms_norm_mul_add(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, false)); test_cases.emplace_back(new test_rms_norm_mul_add(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, true)); test_cases.emplace_back(new test_norm_mul_add(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, false)); test_cases.emplace_back(new test_norm_mul_add(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, true)); test_cases.emplace_back(new test_add_rms_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, false)); test_cases.emplace_back(new test_add_rms_norm(GGML_TYPE_F32, { n, 5, 4, 3 }, eps, true)); } } for (uint32_t n : {1, 511, 1025, 8192, 33*512}) { for (bool multi_add : {false, true}) { test_cases.emplace_back(new test_rms_norm_mul_add(GGML_TYPE_F32, {n, 1, 1, 1}, 1e-6f, false, multi_add)); } test_cases.emplace_back(new test_add_rms_norm(GGML_TYPE_F32, {n, 1, 1, 1}, 1e-6f, false)); } for (auto multi_add : {false, true}) { for (auto set_rows : {false, true}) { for (auto rope : {GGML_ROPE_TYPE_NORMAL, GGML_ROPE_TYPE_NEOX}) { test_cases.emplace_back(new test_rms_norm_mul_rope({768, 1, 1, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({768, 3, 1, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({768, 3, 5, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({128, 32, 2, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({128, 4, 2, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({128, 32, 50, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({128, 4, 50, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({8192, 2, 2, 1}, 1e-6f, multi_add, set_rows, rope)); test_cases.emplace_back(new test_rms_norm_mul_rope({8192, 2, 2, 1}, 1e-6f, multi_add, set_rows, rope)); } } } for (int64_t d_conv : {3, 4, 9}) { for (int64_t d_inner: {1024, 1536, 2048}) { test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {d_conv, d_inner, 1, 1}, {d_conv, d_inner, 1, 1})); test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {2 * d_conv, d_inner, 1, 1}, {d_conv, d_inner, 1, 1})); test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {d_conv, d_inner, 4, 1}, {d_conv, d_inner, 1, 1})); // long token (n_t > 32, exercises the long_token kernel path) test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {d_conv - 1 + 64, d_inner, 1, 1}, {d_conv, d_inner, 1, 1})); test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {d_conv - 1 + 64, d_inner, 4, 1}, {d_conv, d_inner, 1, 1})); } } test_cases.emplace_back(new test_ssm_scan(GGML_TYPE_F32, 16, 1, 1024, 1, 32, 4)); // Mamba-1 test_cases.emplace_back(new test_ssm_scan(GGML_TYPE_F32, 128, 64, 16, 2, 32, 4)); // Mamba-2 test_cases.emplace_back(new test_ssm_scan(GGML_TYPE_F32, 256, 64, 8, 2, 32, 4)); // Falcon-H1 test_cases.emplace_back(new test_rwkv_wkv6(GGML_TYPE_F32, 32, 64, 1, 1)); test_cases.emplace_back(new test_rwkv_wkv6(GGML_TYPE_F32, 32, 64, 32, 1)); test_cases.emplace_back(new test_rwkv_wkv6(GGML_TYPE_F32, 32, 64, 32, 4)); test_cases.emplace_back(new test_rwkv_wkv6(GGML_TYPE_F32, 32, 64, 128, 4)); test_cases.emplace_back(new test_rwkv_wkv7(GGML_TYPE_F32, 32, 64, 1, 1)); test_cases.emplace_back(new test_rwkv_wkv7(GGML_TYPE_F32, 32, 64, 32, 1)); test_cases.emplace_back(new test_rwkv_wkv7(GGML_TYPE_F32, 32, 64, 32, 4)); test_cases.emplace_back(new test_rwkv_wkv7(GGML_TYPE_F32, 32, 64, 128, 4)); test_cases.emplace_back(new test_gla(GGML_TYPE_F32, 32, 64, 1, 1)); test_cases.emplace_back(new test_gla(GGML_TYPE_F32, 32, 64, 32, 1)); test_cases.emplace_back(new test_gla(GGML_TYPE_F32, 32, 64, 32, 4)); test_cases.emplace_back(new test_gla(GGML_TYPE_F32, 32, 64, 128, 4)); #if 0 // > 4GB A matrix. Too slow to be enabled by default. test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F16, 900000, 3, 2592, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F16, 1700000, 96, 2592, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F16, 1700000, 3, 2592, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F16, 1700000, 1, 2592, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_Q8_0, GGML_TYPE_F32, 128, 128, false, 8192, 2, 5120)); // Llama-4-Maverick-17B-128E-PAB-Q8_0 test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_Q8_0, GGML_TYPE_F32, 128, 128, false, 8192, 1, 5120)); // Llama-4-Maverick-17B-128E-PAB-Q8_0 test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q8_0, GGML_TYPE_F32, 8192, 1, 5120, {128, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q8_0, GGML_TYPE_F32, 8192, 512, 5120, {128, 1}, {1, 1})); #endif for (ggml_type type_a : all_types) { for (int i = 1; i < 10; ++i) { test_cases.emplace_back(new test_mul_mat(type_a, GGML_TYPE_F32, 16, i, 256, { 1, 1}, {1, 1})); } } #if 0 { // Test paths in OpenCL std::vector ns = {32, 64, 128, 256, 512, 1024, 4096}; std::vector ks = {896, 1536, 4096}; for (auto n : ns) { for (auto k : ks) { test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q8_0, GGML_TYPE_F32, 1024, n, k, {1, 1}, {1, 1})); } } } #endif #if 1 for (ggml_type type_a : base_types) { for (ggml_type type_b : {GGML_TYPE_F32, GGML_TYPE_F16}) { std::vector ks = { 256 }; if (ggml_blck_size(type_a) == 1) { ks.push_back(4); } for (auto k : ks) { // test cases without permutation test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {1, 1}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {1, 1}, {1, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 1}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 2}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 2}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 2}, {1, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {3, 2}, {2, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {1, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {1, 1}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {1, 1}, {1, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 1}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 2}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 2}, {2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 2}, {1, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {3, 2}, {2, 2})); // test cases with permutation test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {2, 3}, {1, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {2, 3}, {1, 1}, {0, 1, 3, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, k, {2, 3}, {1, 1}, {0, 3, 2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 8, k, {2, 3}, {1, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 8, k, {2, 3}, {1, 1}, {0, 1, 3, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 8, k, {2, 3}, {1, 1}, {0, 3, 2, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {2, 3}, {1, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {2, 3}, {1, 1}, {0, 1, 3, 2})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, k, {2, 3}, {1, 1}, {0, 3, 2, 1})); } // test cases with large ne00/ne10 to cover stream-k fixup test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, 1024, {3, 2}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 8, 1024, {3, 2}, {1, 1})); test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 16, 1024, {3, 2}, {1, 1})); // test cases with large batch size test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 8, 256, {1536, 1}, {1, 1})); } } for (ggml_type type_a : other_types) { for (ggml_type type_b : {GGML_TYPE_F32}) { if (ggml_blck_size(type_a) != 256) { test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, ggml_blck_size(type_a), {1, 1}, {1, 1})); } test_cases.emplace_back(new test_mul_mat(type_a, type_b, 16, 1, 256, {1, 1}, {1, 1})); } } #else // m = a rows // n = b rows // k = cols std::uniform_int_distribution<> dist_m(1, 128); std::uniform_int_distribution<> dist_n(16, 128); std::uniform_int_distribution<> dist_k(1, 16); for (int i = 0; i < 1000; i++) { for (ggml_type type_a : all_types) { for (ggml_type type_b : {GGML_TYPE_F32}) { int m = dist_m(rng); int n = dist_n(rng); int k = dist_k(rng) * ggml_blck_size(type_a); test_cases.emplace_back(new test_mul_mat(type_a, type_b, m, n, k, { 1, 1}, {1, 1})); } } } #endif test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 2, 128, { 8, 1}, {1, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 83, 2, 128, { 8, 1}, {4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 2, 64, { 8, 1}, {4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 83, 2, 64, { 8, 1}, {4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 45, 128, { 8, 1}, {4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 128, 45, 64, { 8, 1}, {4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 1056, 1, 193, {1, 1}, {4, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 1056, 1, 67, {1, 1}, {4, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F32, GGML_TYPE_F32, 16, 32, 32, { 1, 1}, {1, 1}, {0, 1, 2, 3}, 64, 3)); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F32, GGML_TYPE_F32, 64, 77, 77, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q4_0, GGML_TYPE_F32, 576, 512, 576, {1,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q4_0, GGML_TYPE_F32, 1, 2048, 8192, {1, 1}, {1, 1})); for (ggml_type type_a : all_types) { test_cases.emplace_back(new test_mul_mat(type_a, GGML_TYPE_F32, 1, 64, 256, {1, 1}, {1, 1})); } test_cases.emplace_back(new test_mul_mat(GGML_TYPE_Q8_0, GGML_TYPE_F32, 6, 4096, 5120, {1, 1}, {1, 1})); #if 0 // test the mat-mat path for Metal for (int k = 1; k < 512; ++k) { test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 127, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F32, GGML_TYPE_F32, 64, 127, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 77, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F32, GGML_TYPE_F32, 64, 77, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 64, 128, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F32, GGML_TYPE_F32, 64, 128, k, {12,1}, {1,1})); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 16, 16, false, 50, 200, k)); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 16, 16, true, 50, 200, k)); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F32, GGML_TYPE_F32, 16, 16, false, 50, 200, k)); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F32, GGML_TYPE_F32, 16, 16, true, 50, 200, k)); } #endif for (auto bs2 : {1,3}) { for (auto bs : {1,2,4,8}) { for (auto nr : {1,4}) { for (uint32_t m = 0; m < 2; ++m) { for (uint32_t k = 0; k < 2; ++k) { for (ggml_type type: {GGML_TYPE_F16, GGML_TYPE_BF16, GGML_TYPE_F32}) { test_cases.emplace_back(new test_mul_mat(type, GGML_TYPE_F32, 1056 + m, 1, 128 + k, {bs, bs2}, {nr, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(type, GGML_TYPE_F32, 128 + m, 1, 1056 + k, {bs, bs2}, {nr, 1}, {0, 1, 2, 3}, 2*1056 + k)); } } } } } } // sycl backend will limit task global_range < MAX_INT // test case for f16-type-convert-to-fp32 kernel with large k under fp32 compute dtype (occurs in stable-diffusion) // however this case needs to alloc more memory which may fail in some devices (Intel Arc770, etc.) // this case is verified (pass) in Intel(R) Data Center GPU Max 1100 (sycl backend) and NV A30 (cuda backend) // test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F16, 512, 262144, 9216, {1, 1}, {1, 1})); // test large experts*tokens for (bool b : {false, true}) { test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 16, 16, b, 32, 1024, 16)); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 2, 2, b, 32, 8192, 64)); test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 16, 16, b, 50, 200, 64)); } test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_F16, GGML_TYPE_F32, 1, 1, false, 8, 16, 1)); test_cases.emplace_back(new test_mul_mat_id_fusion(GGML_TYPE_F16, GGML_TYPE_F32, 16, 16, false, 32, 32, 32, 3)); // gpt-oss issue with Vulkan mmq_id test_cases.emplace_back(new test_mul_mat_id(GGML_TYPE_MXFP4, GGML_TYPE_F32, 32, 2, false, 2880, 32, 2880)); for (ggml_type type_a : base_types) { for (ggml_type type_b : {GGML_TYPE_F32 /*, GGML_TYPE_F16 */}) { for (int n_mats : {4, 8}) { for (int n_used : {1, 2, 4}) { for (bool b : {false, true}) { for (int n : {1, 4, 5, 17, 32, 129}) { int m = 512; int k = 256; test_cases.emplace_back(new test_mul_mat_id(type_a, type_b, n_mats, n_used, b, m, n, k)); } } } } } } for (ggml_type type_a : other_types) { for (ggml_type type_b : {GGML_TYPE_F32 /*, GGML_TYPE_F16 */}) { for (int n_mats : {4}) { for (int n_used : {2}) { for (bool b : {false}) { for (int n : {1, 32}) { int m = 512; int k = 256; test_cases.emplace_back(new test_mul_mat_id(type_a, type_b, n_mats, n_used, b, m, n, k)); } } } } } } for (int bs : {1, 4, 512}) { for (ggml_type type_a : {GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_Q4_0, GGML_TYPE_Q4_K}) { for (ggml_type type_b : {GGML_TYPE_F32}) { // test with mul after (ffn_moe_weighted) test_cases.emplace_back(new test_mul_mat_id_fusion(type_a, type_b, 128, 8, false, 768, bs, 2048, 1, true)); } } } for (ggml_type type_a : base_types) { for (ggml_type type_b : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (int n : {1, 16}) { for (int k : {1, 16}) { for (int bs2 : {1, 3}) { for (int bs3 : {1, 3}) { for (int nr2 : {1, 2}) { for (int nr3 : {1, 2}) { test_cases.emplace_back(new test_out_prod(type_a, type_b, 256, n, k, {bs2, bs3}, {nr2, nr3})); } } } } } } } } // add_id for (ggml_type type_a : {GGML_TYPE_F32}) { for (ggml_type type_b : {GGML_TYPE_F32}) { for (int n_mats : {4, 8}) { for (int n_used : {1, 2, 4}) { for (int n_embd : {32, 129}) { for (int n_token : {1, 32, 129}) { test_cases.emplace_back(new test_add_id(type_a, type_b, n_embd, n_mats, n_used, n_token)); } } } } } } for (ggml_type type : {GGML_TYPE_F16, GGML_TYPE_F32}) { test_cases.emplace_back(new test_sqr (type)); test_cases.emplace_back(new test_sqrt (type)); test_cases.emplace_back(new test_log (type)); test_cases.emplace_back(new test_sin (type)); test_cases.emplace_back(new test_cos (type)); test_cases.emplace_back(new test_clamp (type)); test_cases.emplace_back(new test_leaky_relu(type)); test_cases.emplace_back(new test_floor (type)); test_cases.emplace_back(new test_ceil (type)); test_cases.emplace_back(new test_round (type)); test_cases.emplace_back(new test_trunc (type)); test_cases.emplace_back(new test_sqr (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_sqr (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_sqrt (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_sqrt (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_log (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_log (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_sin (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_sin (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_cos (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_cos (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_clamp (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_clamp (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_leaky_relu(type, {7, 1, 5, 3})); test_cases.emplace_back(new test_leaky_relu(type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_floor (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_floor (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_ceil (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_ceil (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_round (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_round (type, {1024, 1024, 1, 1})); test_cases.emplace_back(new test_trunc (type, {7, 1, 5, 3})); test_cases.emplace_back(new test_trunc (type, {1024, 1024, 1, 1})); } test_cases.emplace_back(new test_diag_mask_inf(GGML_TYPE_F32, {10, 10, 1, 1}, 5)); test_cases.emplace_back(new test_diag_mask_inf(GGML_TYPE_F32, {10, 10, 3, 1}, 5)); test_cases.emplace_back(new test_diag_mask_inf(GGML_TYPE_F32, {10, 10, 3, 2}, 5)); #if 0 std::uniform_int_distribution<> dist_ne1(1, 50); int exponent = 1; while (exponent < (1 << 17)) { std::uniform_int_distribution<> dist_ne0(exponent, 2*exponent); for (int n = 0; n < 10; ++n) { int64_t ne0 = dist_ne0(rng); int64_t ne1 = dist_ne1(rng); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, GGML_TYPE_F32, {ne0, ne1, 1, 1}, n/2 == 0, 0.1f, ne0 < 1000 ? 4.0f : 0.0f)); } exponent <<= 1; } #endif for (bool mask : {false, true}) { for (bool sinks : {false, true}) { for (float max_bias : {0.0f, 8.0f}) { if (!mask && max_bias > 0.0f) continue; for (float scale : {1.0f, 0.1f}) { for (int64_t ne0 : {16, 1024}) { for (int64_t ne1 : {16, 1024}) { if (mask) { for (ggml_type m_prec : {GGML_TYPE_F32, GGML_TYPE_F16}) { test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0, ne1, 1, 1}, mask, sinks, m_prec, {1, 1}, scale, max_bias)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0-1, ne1-1, 1, 1}, mask, sinks, m_prec, {1, 1}, scale, max_bias)); if (ne0 <= 32 && ne1 <= 32) { test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0, ne1, 1, 3}, mask, sinks, m_prec, {3, 1}, scale, max_bias)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0-1, ne1-1, 1, 1}, mask, sinks, m_prec, {2, 3}, scale, max_bias)); } } } else { /* The precision of mask here doesn't matter as boolean mask is false */ test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0, ne1, 1, 1}, mask, sinks, GGML_TYPE_F32, {1, 1}, scale, max_bias)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {ne0-1, ne1-1, 1, 1}, mask, sinks, GGML_TYPE_F32, {1, 1}, scale, max_bias)); } } } } } // inplace tests test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {16, 2, 32, 1}, mask, sinks, GGML_TYPE_F32, {1, 1}, 0.1f, 0.0f, true)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {16, 2, 32, 1}, mask, sinks, GGML_TYPE_F16, {1, 1}, 0.1f, 0.0f, true)); } } test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {16, 2, 32, 1}, true, true, GGML_TYPE_F32, {1, 1}, 0.1f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {16, 2, 32, 1}, true, false, GGML_TYPE_F16, {1, 1}, 0.1f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {16, 2, 32, 1}, false, true, GGML_TYPE_F32, {1, 1}, 0.1f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {32, 2, 32, 1}, true, true, GGML_TYPE_F32, {1, 1}, 0.1f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {32, 2, 32, 1}, true, false, GGML_TYPE_F16, {1, 1}, 0.1f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {32, 2, 32, 1}, true, true, GGML_TYPE_F32, {1, 1}, 0.1f, 8.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {32, 2, 32, 1}, true, true, GGML_TYPE_F16, {1, 1}, 0.1f, 8.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {200001, 2, 3, 1}, true, true, GGML_TYPE_F32, {1, 1}, 0.1f, 8.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {200001, 2, 3, 1}, true, true, GGML_TYPE_F16, {1, 1}, 0.1f, 8.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {200000, 1, 1, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {200000, 4, 1, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {643251, 3, 1, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); for (float max_bias : {0.0f, 8.0f}) { for (float scale : {1.0f, 0.1f}) { for (int64_t ne0 : {16, 1024}) { for (int64_t ne1 : {16, 1024}) { test_cases.emplace_back(new test_soft_max_back(GGML_TYPE_F32, {ne0, ne1, 1, 1}, scale, max_bias)); test_cases.emplace_back(new test_soft_max_back(GGML_TYPE_F32, {ne0-1, ne1-1, 1, 1}, scale, max_bias)); test_cases.emplace_back(new test_soft_max_back(GGML_TYPE_F32, {ne0, ne1, 2, 3}, scale, max_bias)); } } } } for (bool fw : {true, false}) { // fw == forward bool all = true; for (float fs : { 1.0f, 1.4245f }) { for (float ef : { 0.0f, 0.7465f }) { for (float af : { 1.0f, 1.4245f }) { for (ggml_type type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (bool ff : {false, true}) { // freq_factors for (float v : { 0, 1 }) { test_cases.emplace_back(new test_rope(type, {128, 32, 2, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); // llama 7B if (all) { test_cases.emplace_back(new test_rope(type, {128, 40, 2, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); // llama 13B test_cases.emplace_back(new test_rope(type, {128, 52, 2, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); // llama 30B test_cases.emplace_back(new test_rope(type, {128, 64, 2, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); // llama 65B test_cases.emplace_back(new test_rope(type, {16, 16, 8192, 1}, 16, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); } if (all) { test_cases.emplace_back(new test_rope(type, { 64, 1, 2, 1}, 64, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (falcon 7B) test_cases.emplace_back(new test_rope(type, { 64, 71, 2, 1}, 64, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (falcon 7B) test_cases.emplace_back(new test_rope(type, { 64, 8, 2, 1}, 64, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (falcon 40B) test_cases.emplace_back(new test_rope(type, { 80, 32, 2, 1}, 20, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, { 80, 32, 2, 1}, 32, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, { 80, 32, 4, 1}, 32, GGML_ROPE_TYPE_NORMAL, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, { 80, 32, 2, 1}, 20, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (stablelm) test_cases.emplace_back(new test_rope(type, { 80, 32, 2, 1}, 32, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (phi-2) test_cases.emplace_back(new test_rope(type, { 80, 32, 4, 1}, 32, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (phi-2) test_cases.emplace_back(new test_rope(type, { 16, 16, 8192, 1}, 16, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); } if (all) { test_cases.emplace_back(new test_rope(type, {128, 12, 2, 1}, 128, GGML_ROPE_TYPE_MROPE, 512, fs, ef, af, ff, v, fw)); // rope_multi,m-rope (qwen2vl 2B) test_cases.emplace_back(new test_rope(type, {128, 28, 2, 1}, 128, GGML_ROPE_TYPE_MROPE, 512, fs, ef, af, ff, v, fw)); // rope_multi,m-rope (qwen2vl 7B) test_cases.emplace_back(new test_rope(type, {128, 12, 2, 1}, 20, GGML_ROPE_TYPE_MROPE, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, {128, 28, 2, 1}, 32, GGML_ROPE_TYPE_MROPE, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, {128, 12, 2, 1}, 128, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); // rope_multi,imrope (qwen3vl 2B) test_cases.emplace_back(new test_rope(type, {128, 28, 2, 1}, 128, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); // rope_multi,imrope (qwen3vl 7B) test_cases.emplace_back(new test_rope(type, {128, 12, 2, 1}, 20, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, {128, 28, 2, 1}, 32, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); test_cases.emplace_back(new test_rope(type, { 80, 16, 2, 1}, 80, GGML_ROPE_TYPE_VISION, 512, fs, ef, af, ff, v, fw)); // rope_multi,m-rope (qwen2vl ViT) test_cases.emplace_back(new test_rope(type, {128, 16, 2, 1}, 128, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); // rope_multi,m-rope (qwen3vl) test_cases.emplace_back(new test_rope(type, {16, 16, 8192, 1}, 16, GGML_ROPE_TYPE_IMROPE, 512, fs, ef, af, ff, v, fw)); } test_cases.emplace_back(new test_rope(type, { 64, 128, 2, 1}, 64, GGML_ROPE_TYPE_NEOX, 512, fs, ef, af, ff, v, fw)); // neox (falcon 40B) } } all = false; } } } } } // single inplace test per type/mode/ff for (ggml_type type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (int mode : {GGML_ROPE_TYPE_NORMAL, GGML_ROPE_TYPE_NEOX, GGML_ROPE_TYPE_MROPE, GGML_ROPE_TYPE_IMROPE, GGML_ROPE_TYPE_VISION}) { for (bool ff : {false, true}) { test_cases.emplace_back(new test_rope(type, {128, 32, 2, 1}, 128, mode, 512, 1.4245f, 0.7465f, 1.4245f, ff, 0, true, true)); test_cases.emplace_back(new test_rope(type, {128, 32, 2, 1}, 128, mode, 512, 1.4245f, 0.7465f, 1.4245f, ff, 1, true, true)); test_cases.emplace_back(new test_rope(type, {128, 32, 2, 3}, 128, mode, 512, 1.4245f, 0.7465f, 1.4245f, ff, 1, true, true)); } } } for (int v : { 0, 1, 2, 3 }) { for (int dim : { 0, 1, 2, 3, }) { test_cases.emplace_back(new test_concat(GGML_TYPE_F32, {11, 12, 13, 14}, 7, dim, v)); test_cases.emplace_back(new test_concat(GGML_TYPE_I32, {11, 12, 13, 14}, 7, dim, v)); } } for (ggml_sort_order order : {GGML_SORT_ORDER_ASC, GGML_SORT_ORDER_DESC}) { for (uint32_t i = 4; i <= 1024*1024; i *= 2) { test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {i-1, 1, 1, 1})); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {i, 1, 1, 1})); } test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {16, 10, 10, 10}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {60, 10, 10, 10}, order)); // qwen test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {1023, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {1024, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {1025, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {1025, 256, 1, 1}, order)); // test ceildiv in CUDA's CUB's DeviceSegmentedSort test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {2047, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {2048, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {2049, 2, 1, 3}, order)); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {2, 8, 8192, 1}, order)); // bailingmoe2 (group selection) } for (int n = 1; n < 5; ++n) { for (int k = 1; k <= n; ++k) { test_cases.emplace_back(new test_top_k(GGML_TYPE_F32, {n, 2, 1, 3}, k, true)); } } for (int i = 0; i < 20; ++i) { for (int k : {1, 2, 3, 7, 15, 100, 500, 1023, 9999}) { if (k <= 1< 0.0f) continue; for (float logit_softcap : {0.0f, 10.0f}) { if (hsk != 128 && logit_softcap != 0.0f) continue; for (int nh : { 1, 4 }) { if (nh == 1 && hsk != 320 && hsk != 576) continue; for (int nr3 : { 1, 3, }) { if (hsk > 64 && nr3 > 1) continue; // skip broadcast for large head sizes for (int nr2 : { 1, 4, 12, 20, 32 }) { if (nr2 == 12 && hsk != 128) continue; if (nr2 == 20 && (nh != 1 || hsk != 576)) continue; if (nr2 == 32 && (nh != 1 || hsk != 320)) continue; //for (int kv : { 1, 17, 31, 33, 61, 113, 65, 127, 129, 130, 255, 260, 371, 380, 407, 512, 1024, }) { for (int kv : { 113, 512, 1024, }) { if (nr2 != 1 && kv != 512) continue; for (int nb : { 1, 3, 32, 75, }) { for (ggml_prec prec : {GGML_PREC_F32, GGML_PREC_DEFAULT}) { if (hsk != 128 && prec == GGML_PREC_DEFAULT) continue; for (ggml_type type_KV : {GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_BF16, GGML_TYPE_Q8_0, GGML_TYPE_Q4_0}) { if (type_KV != GGML_TYPE_F16 && hsk != 64 && hsk != 72) continue; test_cases.emplace_back(new test_flash_attn_ext( hsk, hsv, nh, {nr2, nr3}, kv, nb, mask, sinks, max_bias, logit_softcap, prec, type_KV)); // run fewer test cases permuted if (mask == true && max_bias == 0.0f && logit_softcap == 0 && kv == 512) { test_cases.emplace_back(new test_flash_attn_ext( hsk, hsv, nh, {nr2, nr3}, kv, nb, mask, sinks, max_bias, logit_softcap, prec, type_KV, {0, 2, 1, 3})); } } } } } } } } } } } } } } test_cases.emplace_back(new test_cross_entropy_loss (GGML_TYPE_F32, { 10, 5, 4, 3})); test_cases.emplace_back(new test_cross_entropy_loss (GGML_TYPE_F32, {30000, 1, 1, 1})); test_cases.emplace_back(new test_cross_entropy_loss_back(GGML_TYPE_F32, { 10, 5, 4, 3})); test_cases.emplace_back(new test_cross_entropy_loss_back(GGML_TYPE_F32, {30000, 1, 1, 1})); test_cases.emplace_back(new test_opt_step_adamw(GGML_TYPE_F32, {10, 5, 4, 3})); test_cases.emplace_back(new test_opt_step_sgd(GGML_TYPE_F32, {10, 5, 4, 3})); for (ggml_type type : base_types) { for (bool with_gate : {false, true}) { for (bool use_id : {false, true}) { for (bool b : {false, true}) { if (!use_id && b) { continue; } for (bool with_bias : {false, true}) { if (!with_gate && !with_bias) { continue; } for (ggml_glu_op glu_op : {GGML_GLU_OP_SWIGLU, GGML_GLU_OP_GEGLU}) { if (!with_bias && glu_op == GGML_GLU_OP_SWIGLU_OAI) { continue; } if (!with_gate && glu_op != GGML_GLU_OP_SWIGLU) { continue; } test_cases.emplace_back(new test_mul_mat_vec_fusion(type, glu_op, 1, 32, 256, use_id, 16, 8, b, with_bias, with_gate)); test_cases.emplace_back(new test_mul_mat_vec_fusion(type, glu_op, 1, 32, 256, use_id, 16, 8, b, with_bias, with_gate, {1, 1})); } } } } } } for (auto gate : {GATING_FUNC_SOFTMAX, GATING_FUNC_SIGMOID, GATING_FUNC_SOFTMAX_WEIGHT}) { for (bool with_norm : {false, true}) { for (bool bias_probs : {false, true}) { for (float scale_w : {0.0f, 2.0f}) { test_cases.emplace_back(new test_topk_moe({8, 22, 1, 1}, 4, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({31, 22, 1, 1}, 8, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({32, 22, 1, 1}, 8, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({40, 22, 1, 1}, 8, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({71, 22, 1, 1}, 8, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({128, 1, 1, 1}, 128, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({129, 1, 1, 1}, 128, with_norm, bias_probs, gate, scale_w)); test_cases.emplace_back(new test_topk_moe({160, 4, 1, 1}, 160, with_norm, bias_probs, gate, scale_w)); } } } } test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 1, 1)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 16, 1, 1)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 16, 1, 1, 1, true, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 16, 1, 1, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 16, 64, 1, 2)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 1)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 2)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 8, 32, 4, 2, 2)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 2, 1, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 1, 1, true)); // KDA (vector gate) test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 1, 1, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 1, 2, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 16, 1, 2, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 32, 4, 1, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 2, 1, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 8, 32, 4, 2, 2, false, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 64, 4, 2, 1, true, true)); test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 16, 4, 2, 1, true, true)); #if 0 // these tests are disabled to save execution time, sbut they can be handy for debugging test_cases.emplace_back(new test_llama(2, true)); test_cases.emplace_back(new test_llama(1)); test_cases.emplace_back(new test_llama(2)); test_cases.emplace_back(new test_falcon(1)); test_cases.emplace_back(new test_falcon(2)); #endif return test_cases; } #ifdef _MSC_VER #pragma optimize("", on) #endif // Test cases for performance evaluation: should be representative of real-world use cases static std::vector> make_test_cases_perf() { std::vector> test_cases; // Conv2d: K=CRS=NPQ=4096 matmul performance uint32_t iwh_idx = 0; uint32_t kwh_idx = 1; uint32_t Cout_idx = 2; uint32_t Cin_idx = 3; uint32_t B_idx = 4; std::vector> cases = { //{IWH, KWH, Cout, Cin, B} // K=CRS=NPQ=4096 conv2d matmul performance {19, 4, 4096, 256, 16}, // K=128, CRS=128, NPQ=4096 { 19, 4, 128, 8, 16}, // K=130, CRS=128, NPQ=4096 { 19, 4, 130, 8, 16}, // Edge case: K x CRS is small { 19, 2, 4, 4, 16}, // A ConvNet's first layer { 224, 3, 8, 3, 1 }, // A ConvNet's first layer with 2x2 convolution, and 1 channel { 224, 2, 8, 1, 1 }, // A ConvNet's first layer with 2x2 convolution, and 1 channel, several images in the batch { 224, 2, 8, 1, 8 }, // A middle layer of a ConvNet { 58, 3, 64, 32, 1 }, // A middle layer of a ConvNet, several images in the batch { 58, 3, 64, 32, 8 }, // A deep layer of a ConvNet, several images in the batch { 16, 3, 512, 128, 8 }, // High resolution output (large NPQ) {1536, 3, 64, 32, 1 }, }; for (auto kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (auto act_case : cases) { // Direct CONV_2D test_cases.emplace_back(new test_conv_2d( { act_case[iwh_idx], act_case[iwh_idx], act_case[Cin_idx], act_case[B_idx] }, { act_case[kwh_idx], act_case[kwh_idx], act_case[Cin_idx], act_case[Cout_idx] }, kernel_type, 1, 1, 0, 0, 1, 1, false)); } } test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {4096, 1, 1, 1}, {1, 1, 1, 1})); test_cases.emplace_back(new test_bin_bcast(ggml_add, GGML_TYPE_F32, {4096, 1, 1, 1}, {1, 512, 1, 1})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F16, {512, 3072, 1, 1})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {8192, 512, 2, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {3072, 512, 2, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_Q4_0, {8192, 512, 2, 1})); test_cases.emplace_back(new test_cpy(GGML_TYPE_Q4_0, GGML_TYPE_F32, {8192, 512, 2, 1})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {768*1024, 256, 1, 1}, {1, 0, 2, 3}, {0, 0, 0, 0})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {768*1024, 256, 1, 1}, {1, 0, 2, 3}, {0, 0, 0, 0})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {768, 1024, 256, 1}, {1, 0, 2, 3}, {0, 0, 0, 0})); test_cases.emplace_back(new test_cpy(GGML_TYPE_BF16, GGML_TYPE_BF16, {768, 1024, 256, 1}, {1, 0, 2, 3}, {0, 0, 0, 0})); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {768*1024, 256, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F32, GGML_TYPE_F32, {768, 1024, 256, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {768*1024, 256, 1, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_F16, GGML_TYPE_F16, {768, 1024, 256, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_cpy(GGML_TYPE_BF16, GGML_TYPE_BF16, {768, 1024, 256, 1}, {0, 0, 0, 0}, {0, 0, 0, 0}, true)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {4096, 4096, 5, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {12888, 256, 5, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {77, 4096, 5, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {1024, 1024, 10, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {77, 1024, 10, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {256, 256, 20, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {64, 64, 20, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {77, 64, 20, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {32, 10, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {1024, 10, 1, 1})); test_cases.emplace_back(new test_argmax(GGML_TYPE_F32, {32000, 512, 1, 1})); test_cases.emplace_back(new test_pad_reflect_1d(GGML_TYPE_F32, {512, 34, 2, 1})); test_cases.emplace_back(new test_pad_reflect_1d(GGML_TYPE_F32, {3000, 80, 1, 1})); test_cases.emplace_back(new test_pad_reflect_1d(GGML_TYPE_F32, {3000, 80, 4, 1})); test_cases.emplace_back(new test_pad_reflect_1d(GGML_TYPE_F32, {3000, 384, 1, 1})); test_cases.emplace_back(new test_pad_reflect_1d(GGML_TYPE_F32, {3000, 384, 4, 1})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 16416, 1, 128, {8, 1}, {4, 1}, {0, 2, 1, 3})); test_cases.emplace_back(new test_mul_mat(GGML_TYPE_F16, GGML_TYPE_F32, 128, 1, 16416, {8, 1}, {4, 1}, {0, 1, 2, 3}, 2*16416)); test_cases.emplace_back(new test_solve_tri(GGML_TYPE_F32, { 64, 64, 4, 4 }, { 32, 64, 4, 4 })); test_cases.emplace_back(new test_solve_tri(GGML_TYPE_F32, { 128, 128, 4, 2 }, { 32, 128, 4, 2 })); // qwen3next with CHUNK_SIZE 64 test_cases.emplace_back(new test_solve_tri(GGML_TYPE_F32, { 64, 64, 8, 32 }, { 64, 64, 8, 32 })); // qwen3next with CHUNK_SIZE 128 test_cases.emplace_back(new test_solve_tri(GGML_TYPE_F32, { 128, 128, 4, 32 }, { 128, 128, 4, 32 })); test_cases.emplace_back(new test_solve_tri(GGML_TYPE_F32, { 256, 256, 4, 2 }, { 128, 256, 4, 2 })); test_cases.emplace_back(new test_tri(GGML_TRI_TYPE_LOWER, GGML_TYPE_F32, { 256, 256, 4, 4 })); test_cases.emplace_back(new test_tri(GGML_TRI_TYPE_UPPER_DIAG, GGML_TYPE_F32, { 1024, 1024, 8, 4 })); test_cases.emplace_back(new test_cumsum(GGML_TYPE_F32, { 128, 128, 4, 4 })); test_cases.emplace_back(new test_cumsum(GGML_TYPE_F32, { 2048, 16, 5, 4 })); test_cases.emplace_back(new test_cumsum(GGML_TYPE_F32, { 20000, 10, 4, 1 })); for (int bs : {1, 2, 3, 4, 5, 8, 512}) { for (ggml_type type_a : all_types) { for (ggml_type type_b : {GGML_TYPE_F32}) { test_cases.emplace_back(new test_mul_mat(type_a, type_b, 4096, bs, 14336, {1, 1}, {1, 1})); } } } // qwen3-30b-a3b for (int bs : {1, 4, 8, 32, 64, 128, 256, 512}) { for (ggml_type type_a : {GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_Q4_0, GGML_TYPE_Q8_0, GGML_TYPE_Q4_K, GGML_TYPE_Q6_K, GGML_TYPE_IQ2_XS}) { for (ggml_type type_b : {GGML_TYPE_F32}) { test_cases.emplace_back(new test_mul_mat_id(type_a, type_b, 128, 8, false, 768, bs, 2048)); test_cases.emplace_back(new test_mul_mat_id_fusion(type_a, type_b, 128, 8, false, 768, bs, 2048, 1)); } } } for (int bs : {1, 4, 8, 32, 64, 128, 256, 512}) { for (ggml_type type_a : {GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_Q4_0, GGML_TYPE_Q8_0, GGML_TYPE_Q4_K, GGML_TYPE_Q6_K, GGML_TYPE_IQ2_XS}) { for (ggml_type type_b : {GGML_TYPE_F32}) { test_cases.emplace_back(new test_mul_mat_id(type_a, type_b, 32, 4, false, 1792, bs, 2048)); test_cases.emplace_back(new test_mul_mat_id_fusion(type_a, type_b, 32, 4, false, 1792, bs, 2048, 1)); } } } // gpt-oss-20b for (int bs : {1, 4, 8, 512}) { for (ggml_type type_a : {GGML_TYPE_MXFP4}) { for (ggml_type type_b : {GGML_TYPE_F32}) { test_cases.emplace_back(new test_mul_mat_id(type_a, type_b, 32, 4, false, 2880, bs, 2880)); test_cases.emplace_back(new test_mul_mat_id_fusion(type_a, type_b, 32, 4, false, 2880, bs, 2880, 1)); } } } for (int K : {3, 5}) { for (int IC : {256, 2560}) { for (int IW_IH : {32, 64, 256}) { if (IC == 2560 && IW_IH == 256) { // too big continue; } test_cases.emplace_back(new test_im2col(GGML_TYPE_F32, GGML_TYPE_F16, GGML_TYPE_F32, {IW_IH, IW_IH, IC, 1}, {K, K, IC, 1}, 1, 1, 1, 1, 1, 1, true)); } } } // Qwen3-VL-8B https://github.com/ggml-org/llama.cpp/issues/17012 test_cases.emplace_back(new test_flash_attn_ext(72, 72, 16, {1, 1}, 5776, 5776, false, false, 0, 0, GGML_PREC_F32, GGML_TYPE_F16)); test_cases.emplace_back(new test_flash_attn_ext(64, 64, 8, {8, 1}, 7680, 1, true, false, 0, 0, GGML_PREC_F32, GGML_TYPE_F16)); test_cases.emplace_back(new test_flash_attn_ext(64, 64, 8, {8, 1}, 7680, 4, true, false, 0, 0, GGML_PREC_F32, GGML_TYPE_F16)); for (int kv : { 4096, 8192, 16384, }) { for (int hs : { 64, 128, }) { for (int nr : { 1, 4, }) { test_cases.emplace_back(new test_flash_attn_ext(hs, hs, 8, {nr, 1}, kv, 1, true, false, 0, 0, GGML_PREC_F32, GGML_TYPE_F16)); } } } for (int col : {8192, 16384, 32768, 65536, 131072, 262144, 524288}) { for (int rows : {1, 4, 16}){ test_cases.emplace_back(new test_soft_max(GGML_TYPE_F32, {col, rows, 1, 1}, false, false, GGML_TYPE_F32, {1, 1}, 1.0f, 0.0f)); } } test_cases.emplace_back(new test_conv_2d_dw({512, 512, 256, 1}, {3, 3, 1, 256}, 1, 1, 1, false)); test_cases.emplace_back(new test_conv_2d_dw({512, 512, 256, 1}, {3, 3, 1, 256}, 1, 1, 1, true)); for (ggml_type kernel_type : {GGML_TYPE_F32, GGML_TYPE_F16}) { test_cases.emplace_back(new test_conv_transpose_2d({256, 256, 256, 1}, {3, 3, 16, 256}, 1, kernel_type)); test_cases.emplace_back(new test_conv_transpose_2d({16, 16, 16, 1}, {3, 3, 8, 16}, 1, kernel_type)); test_cases.emplace_back(new test_conv_transpose_2d({10, 10, 9, 1}, {3, 3, 1, 9}, 2, kernel_type)); } test_cases.emplace_back(new test_mean(GGML_TYPE_F32, {256, 256, 3, 1})); for (int n_token : {1, 512}) { test_cases.emplace_back(new test_add_id(GGML_TYPE_F32, GGML_TYPE_F32, 2880, 128, 4, n_token)); test_cases.emplace_back(new test_add_id(GGML_TYPE_F32, GGML_TYPE_F32, 2880, 32, 4, n_token)); } for (bool fw : {true, false}) { // fw == forward for (ggml_type type : {GGML_TYPE_F32, GGML_TYPE_F16}) { for (bool ff : {false, true}) { // freq_factors for (float v : { 0, 1 }) { test_cases.emplace_back(new test_rope(type, {128, 32, 512, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // llama 7B test_cases.emplace_back(new test_rope(type, {128, 64, 512, 1}, 128, GGML_ROPE_TYPE_NORMAL, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // llama 65B test_cases.emplace_back(new test_rope(type, { 80, 32, 512, 1}, 20, GGML_ROPE_TYPE_NEOX, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // neox (stablelm) test_cases.emplace_back(new test_rope(type, { 64, 8, 512, 1}, 64, GGML_ROPE_TYPE_NEOX, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // neox (falcon 40B) test_cases.emplace_back(new test_rope(type, {128, 12, 512, 1}, 128, GGML_ROPE_TYPE_MROPE, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // rope_multi,m-rope (qwen2vl 2B) test_cases.emplace_back(new test_rope(type, {128, 12, 512, 1}, 128, GGML_ROPE_TYPE_IMROPE, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // rope_multi,imrope (qwen3vl 2B) test_cases.emplace_back(new test_rope(type, { 80, 16, 2, 1}, 80, GGML_ROPE_TYPE_VISION, 512, 1.0f, 0.0f, 1.0f, ff, v, fw)); // rope_multi,m-rope (qwen2vl ViT) } } } } std::vector> reduce_rows_cases = { { 8192, 1, 1, 1 }, { 8192, 8192, 1, 1 }, { 128, 8192, 1, 1 }, }; for (auto it: reduce_rows_cases){ test_cases.emplace_back(new test_mean(GGML_TYPE_F32, it)); test_cases.emplace_back(new test_sum_rows(GGML_TYPE_F32, it)); test_cases.emplace_back(new test_sum(GGML_TYPE_F32, it)); } test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {65000, 16, 1, 1})); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {200000, 1, 1, 1})); test_cases.emplace_back(new test_argsort(GGML_TYPE_F32, {200000, 16, 1, 1})); test_cases.emplace_back(new test_top_k(GGML_TYPE_F32, {2, 1, 1, 1}, 1)); for (auto k : {1, 10, 40, 400}) { for (auto nrows : {1, 16}) { for (auto cols : {k, 1000, 65000, 200000}) { test_cases.emplace_back(new test_top_k(GGML_TYPE_F32, {cols, nrows, 1, 1}, k)); } } } for (auto nrows : {1, 4, 8, 16}) { for (auto cols : {128, 1024, 4096, 8192, 16384, 32768, 65536, 131072, 200000, 2000000}) { test_cases.emplace_back(new test_cumsum(GGML_TYPE_F32, {cols, nrows, 1, 1})); } } // Examples from granite-4.0-h-1b/ggml-model-Q8_0.gguf test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {515, 3328, 1, 1}, {4, 3328, 1, 1})); // prefill test_cases.emplace_back(new test_ssm_conv(GGML_TYPE_F32, {4, 3328, 1, 1}, {4, 3328, 1, 1})); // generate test_cases.emplace_back(new test_ssm_scan(GGML_TYPE_F32, 128, 64, 48, 1, 512, 1)); // prefill test_cases.emplace_back(new test_ssm_scan(GGML_TYPE_F32, 128, 64, 48, 1, 1, 1)); // generate // acc test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 1, 1}, {256, 16, 1, 1}, -1)); test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 2, 3}, {256, 16, 2, 3}, -1)); test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 2, 3}, {128, 16, 2, 3}, -1)); test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 2, 3}, {256, 16, 2, 3}, 1)); test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 2, 3}, {128, 16, 2, 3}, 2)); test_cases.emplace_back(new test_acc(GGML_TYPE_F32, {256, 17, 2, 3}, {64, 16, 2, 3}, 3)); // GATED_DELTA_NET: realistic model configurations // TG: n_seq_tokens=1 (autoregressive) test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 1, 1)); // Qwen3.5-like: 32 heads, d=128 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 16, 64, 1, 1)); // smaller model test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 1, 1, 1, false, true)); // KDA // PP: n_seq_tokens=64,256 (prompt processing) test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 64, 1)); // PP-64 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 256, 1)); // PP-256 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 512, 1)); // PP-512 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 1024, 1)); // PP-1024 // Small model configs (fewer heads = less GPU occupancy for autoregressive) test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 128, 64, 1)); // 4h PP-64 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 128, 256, 1)); // 4h PP-256 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 128, 512, 1)); // 4h PP-512 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 4, 128, 1024, 1)); // 4h PP-1024 test_cases.emplace_back(new test_gated_delta_net(GGML_TYPE_F32, 32, 128, 64, 1, 1, false, true)); // KDA PP-64 return test_cases; } static std::vector> make_test_cases_from_file(const char * path) { std::ifstream f(path); if (!f.is_open()) { throw std::runtime_error("Unable to read test file"); } std::vector> test_cases; std::string line; while (std::getline(f, line)) { std::istringstream iss(line); ggml_op op; ggml_type type; std::array ne; std::array op_params = {}; std::string name; uint64_t tmp; iss >> tmp; op = (ggml_op)tmp; iss >> tmp; type = (ggml_type)tmp; for (size_t i = 0; i < 4; i++) { iss >> ne[i]; } iss >> tmp; for (size_t i = 0; i < tmp && i < op_params.size(); i++) { iss >> op_params[i]; } iss >> tmp; size_t num_src = std::min((uint64_t)GGML_MAX_SRC, tmp); std::vector sources(num_src); for (size_t i = 0; i < num_src; i++) { input_tensor& src = sources[i]; iss >> tmp; src.type = (ggml_type)tmp; for (size_t i = 0; i < 4; i++) { iss >> src.ne[i]; } for (size_t i = 0; i < 4; i++) { iss >> src.nb[i]; } } iss >> name; if (name.length() == 1 && name[0] == '-') { name = ""; } test_cases.emplace_back(new test_generic_op(op, type, ne, op_params, sources, std::move(name))); } return test_cases; } static bool test_backend(ggml_backend_t backend, test_mode mode, const char * op_names_filter, const char * params_filter, printer * output_printer, const char * test_file_path) { auto filter_test_cases = [](std::vector> & test_cases, const char * params_filter) { if (params_filter == nullptr) { return; } std::regex params_filter_regex(params_filter); for (auto it = test_cases.begin(); it != test_cases.end();) { if (!std::regex_search((*it)->vars(), params_filter_regex)) { it = test_cases.erase(it); continue; } it++; } }; std::vector> test_cases; if (test_file_path == nullptr) { switch (mode) { case MODE_TEST: case MODE_GRAD: case MODE_SUPPORT: test_cases = make_test_cases_eval(); break; case MODE_PERF: test_cases = make_test_cases_perf(); break; } } else { test_cases = make_test_cases_from_file(test_file_path); } filter_test_cases(test_cases, params_filter); if (mode == MODE_TEST) { ggml_backend_t backend_cpu = ggml_backend_init_by_type(GGML_BACKEND_DEVICE_TYPE_CPU, NULL); if (backend_cpu == NULL) { test_operation_info info("", "", "CPU"); info.set_error("backend", "Failed to initialize CPU backend"); output_printer->print_operation(info); return false; } // Use reference implementation on the CPU backend for comparison using ggml_backend_cpu_set_use_ref_t = void (*)(ggml_backend_t, bool); auto * reg = ggml_backend_dev_backend_reg(ggml_backend_get_device(backend_cpu)); auto * set_use_ref = (ggml_backend_cpu_set_use_ref_t) ggml_backend_reg_get_proc_address(reg, "ggml_backend_cpu_set_use_ref"); if (set_use_ref) { set_use_ref(backend_cpu, true); } size_t n_ok = 0; size_t tests_run = 0; std::vector failed_tests; for (auto & test : test_cases) { test_status_t status = test->eval(backend, backend_cpu, op_names_filter, output_printer); if (status == test_status_t::SKIPPED || status == test_status_t::NOT_SUPPORTED) { continue; } tests_run++; if (status == test_status_t::OK) { n_ok++; } else if (status == test_status_t::FAIL) { failed_tests.push_back(test->current_op_name + "(" + test->vars() + ")"); } } output_printer->print_summary(test_summary_info(n_ok, tests_run, false)); output_printer->print_failed_tests(failed_tests); ggml_backend_free(backend_cpu); return n_ok == tests_run; } if (mode == MODE_GRAD) { size_t n_ok = 0; for (auto & test : test_cases) { if (test->eval_grad(backend, op_names_filter, output_printer)) { n_ok++; } } output_printer->print_summary(test_summary_info(n_ok, test_cases.size(), false)); return n_ok == test_cases.size(); } if (mode == MODE_PERF) { for (auto & test : test_cases) { test->eval_perf(backend, op_names_filter, output_printer); } return true; } if (mode == MODE_SUPPORT) { // Filter out fusion cases test_cases.erase( std::remove_if(test_cases.begin(), test_cases.end(), [](const std::unique_ptr & tc) { return tc->run_whole_graph(); }), test_cases.end() ); for (auto & test : test_cases) { test->eval_support(backend, op_names_filter, output_printer); } return true; } GGML_ABORT("fatal error"); } static void list_all_ops() { printf("GGML operations:\n"); std::set all_ops; for (int i = 1; i < GGML_OP_COUNT; i++) { all_ops.insert(ggml_op_name((enum ggml_op)i)); } for (int i = 0; i < GGML_UNARY_OP_COUNT; i++) { all_ops.insert(ggml_unary_op_name((enum ggml_unary_op)i)); } for (int i = 0; i < GGML_GLU_OP_COUNT; i++) { all_ops.insert(ggml_glu_op_name((enum ggml_glu_op)i)); } for (const auto & op : all_ops) { printf(" %s\n", op.c_str()); } printf("\nTotal: %zu operations\n", all_ops.size()); } static void show_test_coverage() { std::set all_ops; for (int i = 1; i < GGML_OP_COUNT; i++) { auto op = (enum ggml_op)i; if (op == GGML_OP_VIEW || op == GGML_OP_RESHAPE || op == GGML_OP_PERMUTE || op == GGML_OP_TRANSPOSE || op == GGML_OP_CONT || op == GGML_OP_GLU || op == GGML_OP_UNARY) { continue; } all_ops.insert(ggml_op_name(op)); } for (int i = 0; i < GGML_UNARY_OP_COUNT; i++) { all_ops.insert(ggml_unary_op_name((enum ggml_unary_op)i)); } for (int i = 0; i < GGML_GLU_OP_COUNT; i++) { all_ops.insert(ggml_glu_op_name((enum ggml_glu_op)i)); } auto test_cases = make_test_cases_eval(); // Filter out fusion cases test_cases.erase( std::remove_if(test_cases.begin(), test_cases.end(), [](const std::unique_ptr & tc) { return tc->run_whole_graph(); }), test_cases.end() ); std::set tested_ops; ggml_init_params params = { /* .mem_size = */ ggml_tensor_overhead()*128 + ggml_graph_overhead(), /* .mem_base = */ NULL, /* .no_alloc = */ true, }; for (auto & test_case : test_cases) { ggml_context * ctx = ggml_init(params); if (ctx) { test_case->mode = MODE_TEST; ggml_tensor * out = test_case->build_graph(ctx); if (out && out->op != GGML_OP_NONE) { if (out->op == GGML_OP_UNARY) { tested_ops.insert(ggml_unary_op_name(ggml_get_unary_op(out))); } else if (out->op == GGML_OP_GLU) { tested_ops.insert(ggml_glu_op_name(ggml_get_glu_op(out))); } else { tested_ops.insert(ggml_op_name(out->op)); } } ggml_free(ctx); } } std::set covered_ops; std::set