ref: 85519d0e8bdf2af76ce642a7f9e1432ba5e824f6
dir: /tests/checkasm/checkasm.c/
/* * Copyright © 2018, VideoLAN and dav1d authors * Copyright © 2018, Two Orioles, LLC * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "tests/checkasm/checkasm.h" #include <math.h> #include <stdarg.h> #include <stdio.h> #include <string.h> #include "src/cpu.h" #ifdef _WIN32 #include <windows.h> #define COLOR_RED FOREGROUND_RED #define COLOR_GREEN FOREGROUND_GREEN #define COLOR_YELLOW (FOREGROUND_RED|FOREGROUND_GREEN) static unsigned get_seed(void) { return GetTickCount(); } #else #include <unistd.h> #include <signal.h> #include <time.h> #ifdef __APPLE__ #include <mach/mach_time.h> #endif #define COLOR_RED 1 #define COLOR_GREEN 2 #define COLOR_YELLOW 3 static unsigned get_seed(void) { #ifdef __APPLE__ return (unsigned) mach_absolute_time(); #elif defined(HAVE_CLOCK_GETTIME) struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return (unsigned) (1000000000ULL * ts.tv_sec + ts.tv_nsec); #endif } #endif /* List of tests to invoke */ static const struct { const char *name; void (*func)(void); } tests[] = { { "msac", checkasm_check_msac }, #if CONFIG_8BPC { "cdef_8bpc", checkasm_check_cdef_8bpc }, { "filmgrain_8bpc", checkasm_check_filmgrain_8bpc }, { "ipred_8bpc", checkasm_check_ipred_8bpc }, { "itx_8bpc", checkasm_check_itx_8bpc }, { "loopfilter_8bpc", checkasm_check_loopfilter_8bpc }, { "looprestoration_8bpc", checkasm_check_looprestoration_8bpc }, { "mc_8bpc", checkasm_check_mc_8bpc }, #endif #if CONFIG_16BPC { "cdef_16bpc", checkasm_check_cdef_16bpc }, { "filmgrain_16bpc", checkasm_check_filmgrain_16bpc }, { "ipred_16bpc", checkasm_check_ipred_16bpc }, { "itx_16bpc", checkasm_check_itx_16bpc }, { "loopfilter_16bpc", checkasm_check_loopfilter_16bpc }, { "looprestoration_16bpc", checkasm_check_looprestoration_16bpc }, { "mc_16bpc", checkasm_check_mc_16bpc }, #endif { 0 } }; /* List of cpu flags to check */ static const struct { const char *name; const char *suffix; unsigned flag; } cpus[] = { #if ARCH_X86 { "SSE2", "sse2", DAV1D_X86_CPU_FLAG_SSE2 }, { "SSSE3", "ssse3", DAV1D_X86_CPU_FLAG_SSSE3 }, { "SSE4.1", "sse4", DAV1D_X86_CPU_FLAG_SSE41 }, { "AVX2", "avx2", DAV1D_X86_CPU_FLAG_AVX2 }, { "AVX-512 (Ice Lake)", "avx512icl", DAV1D_X86_CPU_FLAG_AVX512ICL }, #elif ARCH_AARCH64 || ARCH_ARM { "NEON", "neon", DAV1D_ARM_CPU_FLAG_NEON }, #elif ARCH_PPC64LE { "VSX", "vsx", DAV1D_PPC_CPU_FLAG_VSX }, #endif { 0 } }; typedef struct CheckasmFuncVersion { struct CheckasmFuncVersion *next; void *func; int ok; unsigned cpu; int iterations; uint64_t cycles; } CheckasmFuncVersion; /* Binary search tree node */ typedef struct CheckasmFunc { struct CheckasmFunc *child[2]; CheckasmFuncVersion versions; uint8_t color; /* 0 = red, 1 = black */ char name[1]; } CheckasmFunc; /* Internal state */ static struct { CheckasmFunc *funcs; CheckasmFunc *current_func; CheckasmFuncVersion *current_func_ver; const char *current_test_name; const char *bench_pattern; size_t bench_pattern_len; int num_checked; int num_failed; int nop_time; unsigned cpu_flag; const char *cpu_flag_name; const char *test_name; unsigned int seed; int bench_c; int verbose; int function_listing; #if ARCH_X86_64 void (*simd_warmup)(void); #endif } state; /* float compare support code */ typedef union { float f; uint32_t i; } intfloat; static uint32_t xs_state[4]; static void xor128_srand(unsigned int seed) { xs_state[0] = seed; xs_state[1] = ( seed & 0xffff0000) | (~seed & 0x0000ffff); xs_state[2] = (~seed & 0xffff0000) | ( seed & 0x0000ffff); xs_state[3] = ~seed; } // xor128 from Marsaglia, George (July 2003). "Xorshift RNGs". // Journal of Statistical Software. 8 (14). // doi:10.18637/jss.v008.i14. int xor128_rand(void) { const uint32_t x = xs_state[0]; const uint32_t t = x ^ (x << 11); xs_state[0] = xs_state[1]; xs_state[1] = xs_state[2]; xs_state[2] = xs_state[3]; uint32_t w = xs_state[3]; w = (w ^ (w >> 19)) ^ (t ^ (t >> 8)); xs_state[3] = w; return w >> 1; } static int is_negative(const intfloat u) { return u.i >> 31; } int float_near_ulp(const float a, const float b, const unsigned max_ulp) { intfloat x, y; x.f = a; y.f = b; if (is_negative(x) != is_negative(y)) { // handle -0.0 == +0.0 return a == b; } if (llabs((int64_t)x.i - y.i) <= max_ulp) return 1; return 0; } int float_near_ulp_array(const float *const a, const float *const b, const unsigned max_ulp, const int len) { for (int i = 0; i < len; i++) if (!float_near_ulp(a[i], b[i], max_ulp)) return 0; return 1; } int float_near_abs_eps(const float a, const float b, const float eps) { return fabsf(a - b) < eps; } int float_near_abs_eps_array(const float *const a, const float *const b, const float eps, const int len) { for (int i = 0; i < len; i++) if (!float_near_abs_eps(a[i], b[i], eps)) return 0; return 1; } int float_near_abs_eps_ulp(const float a, const float b, const float eps, const unsigned max_ulp) { return float_near_ulp(a, b, max_ulp) || float_near_abs_eps(a, b, eps); } int float_near_abs_eps_array_ulp(const float *const a, const float *const b, const float eps, const unsigned max_ulp, const int len) { for (int i = 0; i < len; i++) if (!float_near_abs_eps_ulp(a[i], b[i], eps, max_ulp)) return 0; return 1; } /* Print colored text to stderr if the terminal supports it */ static void color_printf(const int color, const char *const fmt, ...) { static int8_t use_color = -1; va_list arg; #ifdef _WIN32 static HANDLE con; static WORD org_attributes; if (use_color < 0) { CONSOLE_SCREEN_BUFFER_INFO con_info; con = GetStdHandle(STD_ERROR_HANDLE); if (con && con != INVALID_HANDLE_VALUE && GetConsoleScreenBufferInfo(con, &con_info)) { org_attributes = con_info.wAttributes; use_color = 1; } else use_color = 0; } if (use_color) SetConsoleTextAttribute(con, (org_attributes & 0xfff0) | (color & 0x0f)); #else if (use_color < 0) { const char *const term = getenv("TERM"); use_color = term && strcmp(term, "dumb") && isatty(2); } if (use_color) fprintf(stderr, "\x1b[%d;3%dm", (color & 0x08) >> 3, color & 0x07); #endif va_start(arg, fmt); vfprintf(stderr, fmt, arg); va_end(arg); if (use_color) { #ifdef _WIN32 SetConsoleTextAttribute(con, org_attributes); #else fprintf(stderr, "\x1b[0m"); #endif } } /* Deallocate a tree */ static void destroy_func_tree(CheckasmFunc *const f) { if (f) { CheckasmFuncVersion *v = f->versions.next; while (v) { CheckasmFuncVersion *next = v->next; free(v); v = next; } destroy_func_tree(f->child[0]); destroy_func_tree(f->child[1]); free(f); } } /* Allocate a zero-initialized block, clean up and exit on failure */ static void *checkasm_malloc(const size_t size) { void *const ptr = calloc(1, size); if (!ptr) { fprintf(stderr, "checkasm: malloc failed\n"); destroy_func_tree(state.funcs); exit(1); } return ptr; } /* Get the suffix of the specified cpu flag */ static const char *cpu_suffix(const unsigned cpu) { for (int i = (int)(sizeof(cpus) / sizeof(*cpus)) - 2; i >= 0; i--) if (cpu & cpus[i].flag) return cpus[i].suffix; return "c"; } #ifdef readtime static int cmp_nop(const void *a, const void *b) { return *(const uint16_t*)a - *(const uint16_t*)b; } /* Measure the overhead of the timing code (in decicycles) */ static int measure_nop_time(void) { uint16_t nops[10000]; int i, nop_sum = 0; for (i = 0; i < 10000; i++) { uint64_t t = readtime(); nops[i] = (uint16_t) (readtime() - t); } qsort(nops, 10000, sizeof(uint16_t), cmp_nop); for (i = 2500; i < 7500; i++) nop_sum += nops[i]; return nop_sum / 500; } /* Print benchmark results */ static void print_benchs(const CheckasmFunc *const f) { if (f) { print_benchs(f->child[0]); /* Only print functions with at least one assembly version */ if (state.bench_c || f->versions.cpu || f->versions.next) { const CheckasmFuncVersion *v = &f->versions; do { if (v->iterations) { int decicycles = (int) (10*v->cycles/v->iterations - state.nop_time) / 4; printf("%s_%s: %d.%d\n", f->name, cpu_suffix(v->cpu), decicycles/10, decicycles%10); } } while ((v = v->next)); } print_benchs(f->child[1]); } } #endif static void print_functions(const CheckasmFunc *const f) { if (f) { print_functions(f->child[0]); printf("%s\n", f->name); print_functions(f->child[1]); } } #define is_digit(x) ((x) >= '0' && (x) <= '9') /* ASCIIbetical sort except preserving natural order for numbers */ static int cmp_func_names(const char *a, const char *b) { const char *const start = a; int ascii_diff, digit_diff; for (; !(ascii_diff = *(const unsigned char*)a - *(const unsigned char*)b) && *a; a++, b++); for (; is_digit(*a) && is_digit(*b); a++, b++); if (a > start && is_digit(a[-1]) && (digit_diff = is_digit(*a) - is_digit(*b))) { return digit_diff; } return ascii_diff; } /* Perform a tree rotation in the specified direction and return the new root */ static CheckasmFunc *rotate_tree(CheckasmFunc *const f, const int dir) { CheckasmFunc *const r = f->child[dir^1]; f->child[dir^1] = r->child[dir]; r->child[dir] = f; r->color = f->color; f->color = 0; return r; } #define is_red(f) ((f) && !(f)->color) /* Balance a left-leaning red-black tree at the specified node */ static void balance_tree(CheckasmFunc **root) { CheckasmFunc *const f = *root; if (is_red(f->child[0]) && is_red(f->child[1])) { f->color ^= 1; f->child[0]->color = f->child[1]->color = 1; } else if (!is_red(f->child[0]) && is_red(f->child[1])) *root = rotate_tree(f, 0); /* Rotate left */ else if (is_red(f->child[0]) && is_red(f->child[0]->child[0])) *root = rotate_tree(f, 1); /* Rotate right */ } /* Get a node with the specified name, creating it if it doesn't exist */ static CheckasmFunc *get_func(CheckasmFunc **root, const char *const name) { CheckasmFunc *f = *root; if (f) { /* Search the tree for a matching node */ int cmp = cmp_func_names(name, f->name); if (cmp) { f = get_func(&f->child[cmp > 0], name); /* Rebalance the tree on the way up if a new node was inserted */ if (!f->versions.func) balance_tree(root); } } else { /* Allocate and insert a new node into the tree */ const size_t name_length = strlen(name); f = *root = checkasm_malloc(sizeof(CheckasmFunc) + name_length); memcpy(f->name, name, name_length + 1); } return f; } checkasm_context checkasm_context_buf; /* Crash handling: attempt to catch crashes and handle them * gracefully instead of just aborting abruptly. */ #ifdef _WIN32 static LONG NTAPI signal_handler(EXCEPTION_POINTERS *const e) { switch (e->ExceptionRecord->ExceptionCode) { case EXCEPTION_FLT_DIVIDE_BY_ZERO: case EXCEPTION_INT_DIVIDE_BY_ZERO: checkasm_fail_func("fatal arithmetic error"); break; case EXCEPTION_ILLEGAL_INSTRUCTION: case EXCEPTION_PRIV_INSTRUCTION: checkasm_fail_func("illegal instruction"); break; case EXCEPTION_ACCESS_VIOLATION: case EXCEPTION_ARRAY_BOUNDS_EXCEEDED: case EXCEPTION_DATATYPE_MISALIGNMENT: case EXCEPTION_IN_PAGE_ERROR: case EXCEPTION_STACK_OVERFLOW: checkasm_fail_func("segmentation fault"); break; default: return EXCEPTION_CONTINUE_SEARCH; } checkasm_load_context(); return EXCEPTION_CONTINUE_EXECUTION; /* never reached, but shuts up gcc */ } #else static void signal_handler(const int s) { checkasm_set_signal_handler_state(0); checkasm_fail_func(s == SIGFPE ? "fatal arithmetic error" : s == SIGILL ? "illegal instruction" : "segmentation fault"); checkasm_load_context(); } #endif /* Perform tests and benchmarks for the specified * cpu flag if supported by the host */ static void check_cpu_flag(const char *const name, unsigned flag) { const unsigned old_cpu_flag = state.cpu_flag; flag |= old_cpu_flag; dav1d_set_cpu_flags_mask(flag); state.cpu_flag = dav1d_get_cpu_flags(); if (!flag || state.cpu_flag != old_cpu_flag) { state.cpu_flag_name = name; for (int i = 0; tests[i].func; i++) { if (state.test_name && strcmp(tests[i].name, state.test_name)) continue; xor128_srand(state.seed); state.current_test_name = tests[i].name; tests[i].func(); } } } /* Print the name of the current CPU flag, but only do it once */ static void print_cpu_name(void) { if (state.cpu_flag_name) { color_printf(COLOR_YELLOW, "%s:\n", state.cpu_flag_name); state.cpu_flag_name = NULL; } } int main(int argc, char *argv[]) { (void)func_new, (void)func_ref; state.seed = get_seed(); int ret = 0; while (argc > 1) { if (!strncmp(argv[1], "--help", 6)) { fprintf(stdout, "checkasm [options] <random seed>\n" " <random seed> Numeric value to seed the rng\n" "Options:\n" " --test=<test_name> Test only <test_name>\n" " --bench=<pattern> Test and benchmark the functions matching <pattern>\n" " --list-functions List available functions\n" " --list-tests List available tests\n" " --bench-c Benchmark the C-only functions\n" " --verbose -v Print failures verbosely\n"); return 0; } else if (!strncmp(argv[1], "--bench-c", 9)) { state.bench_c = 1; } else if (!strncmp(argv[1], "--bench", 7)) { #ifndef readtime fprintf(stderr, "checkasm: --bench is not supported on your system\n"); return 1; #endif if (argv[1][7] == '=') { state.bench_pattern = argv[1] + 8; state.bench_pattern_len = strlen(state.bench_pattern); } else state.bench_pattern = ""; } else if (!strncmp(argv[1], "--test=", 7)) { state.test_name = argv[1] + 7; } else if (!strcmp(argv[1], "--list-functions")) { state.function_listing = 1; } else if (!strcmp(argv[1], "--list-tests")) { for (int i = 0; tests[i].name; i++) printf("%s\n", tests[i].name); return 0; } else if (!strcmp(argv[1], "--verbose") || !strcmp(argv[1], "-v")) { state.verbose = 1; } else { state.seed = (unsigned int) strtoul(argv[1], NULL, 10); } argc--; argv++; } fprintf(stderr, "checkasm: using random seed %u\n", state.seed); dav1d_init_cpu(); #if ARCH_X86_64 void checkasm_warmup_avx2(void); void checkasm_warmup_avx512(void); unsigned cpu_flags = dav1d_get_cpu_flags(); if (cpu_flags & DAV1D_X86_CPU_FLAG_AVX512ICL) state.simd_warmup = checkasm_warmup_avx512; else if (cpu_flags & DAV1D_X86_CPU_FLAG_AVX2) state.simd_warmup = checkasm_warmup_avx2; else state.simd_warmup = NULL; checkasm_simd_warmup(); #endif check_cpu_flag(NULL, 0); if (state.function_listing) { print_functions(state.funcs); } else { for (int i = 0; cpus[i].flag; i++) check_cpu_flag(cpus[i].name, cpus[i].flag); if (!state.num_checked) { fprintf(stderr, "checkasm: no tests to perform\n"); } else if (state.num_failed) { fprintf(stderr, "checkasm: %d of %d tests have failed\n", state.num_failed, state.num_checked); ret = 1; } else { fprintf(stderr, "checkasm: all %d tests passed\n", state.num_checked); #ifdef readtime if (state.bench_pattern) { state.nop_time = measure_nop_time(); printf("nop: %d.%d\n", state.nop_time/10, state.nop_time%10); print_benchs(state.funcs); } #endif } } destroy_func_tree(state.funcs); return ret; } /* Decide whether or not the specified function needs to be tested and * allocate/initialize data structures if needed. Returns a pointer to a * reference function if the function should be tested, otherwise NULL */ void *checkasm_check_func(void *const func, const char *const name, ...) { char name_buf[256]; va_list arg; va_start(arg, name); const int name_length = vsnprintf(name_buf, sizeof(name_buf), name, arg); va_end(arg); if (!func || name_length <= 0 || (size_t)name_length >= sizeof(name_buf)) return NULL; state.current_func = get_func(&state.funcs, name_buf); if (state.function_listing) /* Save function names without running tests */ return NULL; state.funcs->color = 1; CheckasmFuncVersion *v = &state.current_func->versions; void *ref = func; if (v->func) { CheckasmFuncVersion *prev; do { /* Only test functions that haven't already been tested */ if (v->func == func) return NULL; if (v->ok) ref = v->func; prev = v; } while ((v = v->next)); v = prev->next = checkasm_malloc(sizeof(CheckasmFuncVersion)); } v->func = func; v->ok = 1; v->cpu = state.cpu_flag; state.current_func_ver = v; xor128_srand(state.seed); if (state.cpu_flag || state.bench_c) state.num_checked++; return ref; } /* Decide whether or not the current function needs to be benchmarked */ int checkasm_bench_func(void) { return !state.num_failed && state.bench_pattern && !strncmp(state.current_func->name, state.bench_pattern, state.bench_pattern_len); } /* Indicate that the current test has failed, return whether verbose printing * is requested. */ int checkasm_fail_func(const char *const msg, ...) { if (state.current_func_ver->cpu && state.current_func_ver->ok) { va_list arg; print_cpu_name(); fprintf(stderr, " %s_%s (", state.current_func->name, cpu_suffix(state.current_func_ver->cpu)); va_start(arg, msg); vfprintf(stderr, msg, arg); va_end(arg); fprintf(stderr, ")\n"); state.current_func_ver->ok = 0; state.num_failed++; } return state.verbose; } /* Update benchmark results of the current function */ void checkasm_update_bench(const int iterations, const uint64_t cycles) { state.current_func_ver->iterations += iterations; state.current_func_ver->cycles += cycles; } /* Print the outcome of all tests performed since * the last time this function was called */ void checkasm_report(const char *const name, ...) { static int prev_checked, prev_failed; static size_t max_length; if (state.num_checked > prev_checked) { int pad_length = (int) max_length + 4; va_list arg; print_cpu_name(); pad_length -= fprintf(stderr, " - %s.", state.current_test_name); va_start(arg, name); pad_length -= vfprintf(stderr, name, arg); va_end(arg); fprintf(stderr, "%*c", imax(pad_length, 0) + 2, '['); if (state.num_failed == prev_failed) color_printf(COLOR_GREEN, "OK"); else color_printf(COLOR_RED, "FAILED"); fprintf(stderr, "]\n"); prev_checked = state.num_checked; prev_failed = state.num_failed; } else if (!state.cpu_flag) { /* Calculate the amount of padding required * to make the output vertically aligned */ size_t length = strlen(state.current_test_name); va_list arg; va_start(arg, name); length += vsnprintf(NULL, 0, name, arg); va_end(arg); if (length > max_length) max_length = length; } } void checkasm_set_signal_handler_state(const int enabled) { #ifdef _WIN32 if (enabled) AddVectoredExceptionHandler(0, signal_handler); else RemoveVectoredExceptionHandler(signal_handler); #else void (*const handler)(int) = enabled ? signal_handler : SIG_DFL; signal(SIGBUS, handler); signal(SIGFPE, handler); signal(SIGILL, handler); signal(SIGSEGV, handler); #endif } #define DEF_CHECKASM_CHECK_FUNC(type, fmt) \ int checkasm_check_##type(const char *const file, const int line, \ const type *buf1, ptrdiff_t stride1, \ const type *buf2, ptrdiff_t stride2, \ const int w, int h, const char *const name) \ { \ stride1 /= sizeof(*buf1); \ stride2 /= sizeof(*buf2); \ int y = 0; \ for (y = 0; y < h; y++) \ if (memcmp(&buf1[y*stride1], &buf2[y*stride2], w*sizeof(*buf1))) \ break; \ if (y == h) \ return 0; \ if (!checkasm_fail_func("%s:%d", file, line)) \ return 1; \ fprintf(stderr, "%s:\n", name); \ while (h--) { \ for (int x = 0; x < w; x++) \ fprintf(stderr, " " fmt, buf1[x]); \ fprintf(stderr, " "); \ for (int x = 0; x < w; x++) \ fprintf(stderr, " " fmt, buf2[x]); \ fprintf(stderr, " "); \ for (int x = 0; x < w; x++) \ fprintf(stderr, "%c", buf1[x] != buf2[x] ? 'x' : '.'); \ buf1 += stride1; \ buf2 += stride2; \ fprintf(stderr, "\n"); \ } \ return 1; \ } DEF_CHECKASM_CHECK_FUNC(uint8_t, "%02x") DEF_CHECKASM_CHECK_FUNC(uint16_t, "%04x") DEF_CHECKASM_CHECK_FUNC(int16_t, "%6d") DEF_CHECKASM_CHECK_FUNC(int32_t, "%9d") #if ARCH_X86_64 void checkasm_simd_warmup(void) { if (state.simd_warmup) state.simd_warmup(); } #endif