/* * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * FFmpeg is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "avassert.h" #include "intmath.h" #include "cpu.h" #include "qsort.h" #include "bprint.h" #include "tx_priv.h" #define TYPE_IS(type, x) \ (((x) == AV_TX_FLOAT_ ## type) || \ ((x) == AV_TX_DOUBLE_ ## type) || \ ((x) == AV_TX_INT32_ ## type)) /* Calculates the modular multiplicative inverse */ static av_always_inline int mulinv(int n, int m) { n = n % m; for (int x = 1; x < m; x++) if (((n * x) % m) == 1) return x; av_assert0(0); /* Never reached */ return 0; } int ff_tx_gen_pfa_input_map(AVTXContext *s, FFTXCodeletOptions *opts, int d1, int d2) { const int sl = d1*d2; s->map = av_malloc(s->len*sizeof(*s->map)); if (!s->map) return AVERROR(ENOMEM); for (int k = 0; k < s->len; k += sl) { if (s->inv || (opts && opts->map_dir == FF_TX_MAP_SCATTER)) { for (int m = 0; m < d2; m++) for (int n = 0; n < d1; n++) s->map[k + ((m*d1 + n*d2) % (sl))] = m*d1 + n; } else { for (int m = 0; m < d2; m++) for (int n = 0; n < d1; n++) s->map[k + m*d1 + n] = (m*d1 + n*d2) % (sl); } if (s->inv) for (int w = 1; w <= ((sl) >> 1); w++) FFSWAP(int, s->map[k + w], s->map[k + sl - w]); } s->map_dir = opts ? opts->map_dir : FF_TX_MAP_GATHER; return 0; } /* Guaranteed to work for any n, m where gcd(n, m) == 1 */ int ff_tx_gen_compound_mapping(AVTXContext *s, FFTXCodeletOptions *opts, int inv, int n, int m) { int *in_map, *out_map; const int len = n*m; /* Will not be equal to s->len for MDCTs */ int m_inv, n_inv; /* Make sure the numbers are coprime */ if (av_gcd(n, m) != 1) return AVERROR(EINVAL); m_inv = mulinv(m, n); n_inv = mulinv(n, m); if (!(s->map = av_malloc(2*len*sizeof(*s->map)))) return AVERROR(ENOMEM); in_map = s->map; out_map = s->map + len; /* Ruritanian map for input, CRT map for output, can be swapped */ if (opts && opts->map_dir == FF_TX_MAP_SCATTER) { for (int j = 0; j < m; j++) { for (int i = 0; i < n; i++) { in_map[(i*m + j*n) % len] = j*n + i; out_map[(i*m*m_inv + j*n*n_inv) % len] = i*m + j; } } } else { for (int j = 0; j < m; j++) { for (int i = 0; i < n; i++) { in_map[j*n + i] = (i*m + j*n) % len; out_map[(i*m*m_inv + j*n*n_inv) % len] = i*m + j; } } } if (inv) { for (int i = 0; i < m; i++) { int *in = &in_map[i*n + 1]; /* Skip the DC */ for (int j = 0; j < ((n - 1) >> 1); j++) FFSWAP(int, in[j], in[n - j - 2]); } } s->map_dir = opts ? opts->map_dir : FF_TX_MAP_GATHER; return 0; } static inline int split_radix_permutation(int i, int len, int inv) { len >>= 1; if (len <= 1) return i & 1; if (!(i & len)) return split_radix_permutation(i, len, inv) * 2; len >>= 1; return split_radix_permutation(i, len, inv) * 4 + 1 - 2*(!(i & len) ^ inv); } int ff_tx_gen_ptwo_revtab(AVTXContext *s, FFTXCodeletOptions *opts) { int len = s->len; if (!(s->map = av_malloc(len*sizeof(*s->map)))) return AVERROR(ENOMEM); if (opts && opts->map_dir == FF_TX_MAP_SCATTER) { for (int i = 0; i < s->len; i++) s->map[-split_radix_permutation(i, len, s->inv) & (len - 1)] = i; } else { for (int i = 0; i < s->len; i++) s->map[i] = -split_radix_permutation(i, len, s->inv) & (len - 1); } s->map_dir = opts ? opts->map_dir : FF_TX_MAP_GATHER; return 0; } int ff_tx_gen_inplace_map(AVTXContext *s, int len) { int *src_map, out_map_idx = 0; if (!s->sub || !s->sub->map) return AVERROR(EINVAL); if (!(s->map = av_mallocz(len*sizeof(*s->map)))) return AVERROR(ENOMEM); src_map = s->sub->map; /* The first coefficient is always already in-place */ for (int src = 1; src < s->len; src++) { int dst = src_map[src]; int found = 0; if (dst <= src) continue; /* This just checks if a closed loop has been encountered before, * and if so, skips it, since to fully permute a loop we must only * enter it once. */ do { for (int j = 0; j < out_map_idx; j++) { if (dst == s->map[j]) { found = 1; break; } } dst = src_map[dst]; } while (dst != src && !found); if (!found) s->map[out_map_idx++] = src; } s->map[out_map_idx++] = 0; return 0; } static void parity_revtab_generator(int *revtab, int n, int inv, int offset, int is_dual, int dual_high, int len, int basis, int dual_stride, int inv_lookup) { len >>= 1; if (len <= basis) { int k1, k2, stride, even_idx, odd_idx; is_dual = is_dual && dual_stride; dual_high = is_dual & dual_high; stride = is_dual ? FFMIN(dual_stride, len) : 0; even_idx = offset + dual_high*(stride - 2*len); odd_idx = even_idx + len + (is_dual && !dual_high)*len + dual_high*len; for (int i = 0; i < len; i++) { k1 = -split_radix_permutation(offset + i*2 + 0, n, inv) & (n - 1); k2 = -split_radix_permutation(offset + i*2 + 1, n, inv) & (n - 1); if (inv_lookup) { revtab[even_idx++] = k1; revtab[odd_idx++] = k2; } else { revtab[k1] = even_idx++; revtab[k2] = odd_idx++; } if (stride && !((i + 1) % stride)) { even_idx += stride; odd_idx += stride; } } return; } parity_revtab_generator(revtab, n, inv, offset, 0, 0, len >> 0, basis, dual_stride, inv_lookup); parity_revtab_generator(revtab, n, inv, offset + (len >> 0), 1, 0, len >> 1, basis, dual_stride, inv_lookup); parity_revtab_generator(revtab, n, inv, offset + (len >> 0) + (len >> 1), 1, 1, len >> 1, basis, dual_stride, inv_lookup); } int ff_tx_gen_split_radix_parity_revtab(AVTXContext *s, int len, int inv, FFTXCodeletOptions *opts, int basis, int dual_stride) { basis >>= 1; if (len < basis) return AVERROR(EINVAL); if (!(s->map = av_mallocz(len*sizeof(*s->map)))) return AVERROR(ENOMEM); av_assert0(!dual_stride || !(dual_stride & (dual_stride - 1))); av_assert0(dual_stride <= basis); parity_revtab_generator(s->map, len, inv, 0, 0, 0, len, basis, dual_stride, opts ? opts->map_dir == FF_TX_MAP_GATHER : FF_TX_MAP_GATHER); s->map_dir = opts ? opts->map_dir : FF_TX_MAP_GATHER; return 0; } static void reset_ctx(AVTXContext *s, int free_sub) { if (!s) return; if (s->sub) for (int i = 0; i < TX_MAX_SUB; i++) reset_ctx(&s->sub[i], free_sub + 1); if (s->cd_self && s->cd_self->uninit) s->cd_self->uninit(s); if (free_sub) av_freep(&s->sub); av_freep(&s->map); av_freep(&s->exp); av_freep(&s->tmp); /* Nothing else needs to be reset, it gets overwritten if another * ff_tx_init_subtx() call is made. */ s->nb_sub = 0; s->opaque = NULL; memset(s->fn, 0, sizeof(*s->fn)); } void ff_tx_clear_ctx(AVTXContext *s) { reset_ctx(s, 0); } av_cold void av_tx_uninit(AVTXContext **ctx) { if (!(*ctx)) return; reset_ctx(*ctx, 1); av_freep(ctx); } static av_cold int ff_tx_null_init(AVTXContext *s, const FFTXCodelet *cd, uint64_t flags, FFTXCodeletOptions *opts, int len, int inv, const void *scale) { /* Can only handle one sample+type to one sample+type transforms */ if (TYPE_IS(MDCT, s->type) || TYPE_IS(RDFT, s->type)) return AVERROR(EINVAL); return 0; } /* Null transform when the length is 1 */ static void ff_tx_null(AVTXContext *s, void *_out, void *_in, ptrdiff_t stride) { memcpy(_out, _in, stride); } static const FFTXCodelet ff_tx_null_def = { .name = NULL_IF_CONFIG_SMALL("null"), .function = ff_tx_null, .type = TX_TYPE_ANY, .flags = AV_TX_UNALIGNED | FF_TX_ALIGNED | FF_TX_OUT_OF_PLACE | AV_TX_INPLACE, .factors[0] = TX_FACTOR_ANY, .min_len = 1, .max_len = 1, .init = ff_tx_null_init, .cpu_flags = FF_TX_CPU_FLAGS_ALL, .prio = FF_TX_PRIO_MAX, }; static const FFTXCodelet * const ff_tx_null_list[] = { &ff_tx_null_def, NULL, }; /* Array of all compiled codelet lists. Order is irrelevant. */ static const FFTXCodelet * const * const codelet_list[] = { ff_tx_codelet_list_float_c, ff_tx_codelet_list_double_c, ff_tx_codelet_list_int32_c, ff_tx_null_list, #if HAVE_X86ASM ff_tx_codelet_list_float_x86, #endif #if ARCH_AARCH64 ff_tx_codelet_list_float_aarch64, #endif }; static const int codelet_list_num = FF_ARRAY_ELEMS(codelet_list); static const int cpu_slow_mask = AV_CPU_FLAG_SSE2SLOW | AV_CPU_FLAG_SSE3SLOW | AV_CPU_FLAG_ATOM | AV_CPU_FLAG_SSSE3SLOW | AV_CPU_FLAG_AVXSLOW | AV_CPU_FLAG_SLOW_GATHER; static const int cpu_slow_penalties[][2] = { { AV_CPU_FLAG_SSE2SLOW, 1 + 64 }, { AV_CPU_FLAG_SSE3SLOW, 1 + 64 }, { AV_CPU_FLAG_SSSE3SLOW, 1 + 64 }, { AV_CPU_FLAG_ATOM, 1 + 128 }, { AV_CPU_FLAG_AVXSLOW, 1 + 128 }, { AV_CPU_FLAG_SLOW_GATHER, 1 + 32 }, }; static int get_codelet_prio(const FFTXCodelet *cd, int cpu_flags, int len) { int prio = cd->prio; int max_factor = 0; /* If the CPU has a SLOW flag, and the instruction is also flagged * as being slow for such, reduce its priority */ for (int i = 0; i < FF_ARRAY_ELEMS(cpu_slow_penalties); i++) { if ((cpu_flags & cd->cpu_flags) & cpu_slow_penalties[i][0]) prio -= cpu_slow_penalties[i][1]; } /* Prioritize aligned-only codelets */ if ((cd->flags & FF_TX_ALIGNED) && !(cd->flags & AV_TX_UNALIGNED)) prio += 64; /* Codelets for specific lengths are generally faster */ if ((len == cd->min_len) && (len == cd->max_len)) prio += 64; /* Forward-only or inverse-only transforms are generally better */ if ((cd->flags & (FF_TX_FORWARD_ONLY | FF_TX_INVERSE_ONLY))) prio += 64; /* Larger factors are generally better */ for (int i = 0; i < TX_MAX_SUB; i++) max_factor = FFMAX(cd->factors[i], max_factor); if (max_factor) prio += 16*max_factor; return prio; } typedef struct FFTXLenDecomp { int len; int len2; int prio; const FFTXCodelet *cd; } FFTXLenDecomp; static int cmp_decomp(FFTXLenDecomp *a, FFTXLenDecomp *b) { return FFDIFFSIGN(b->prio, a->prio); } int ff_tx_decompose_length(int dst[TX_MAX_DECOMPOSITIONS], enum AVTXType type, int len, int inv) { int nb_decomp = 0; FFTXLenDecomp ld[TX_MAX_DECOMPOSITIONS]; int codelet_list_idx = codelet_list_num; const int cpu_flags = av_get_cpu_flags(); /* Loop through all codelets in all codelet lists to find matches * to the requirements */ while (codelet_list_idx--) { const FFTXCodelet * const * list = codelet_list[codelet_list_idx]; const FFTXCodelet *cd = NULL; while ((cd = *list++)) { int fl = len; int skip = 0, prio; int factors_product = 1, factors_mod = 0; if (nb_decomp >= TX_MAX_DECOMPOSITIONS) goto sort; /* Check if the type matches */ if (cd->type != TX_TYPE_ANY && type != cd->type) continue; /* Check direction for non-orthogonal codelets */ if (((cd->flags & FF_TX_FORWARD_ONLY) && inv) || ((cd->flags & (FF_TX_INVERSE_ONLY | AV_TX_FULL_IMDCT)) && !inv)) continue; /* Check if the CPU supports the required ISA */ if (cd->cpu_flags != FF_TX_CPU_FLAGS_ALL && !(cpu_flags & (cd->cpu_flags & ~cpu_slow_mask))) continue; for (int i = 0; i < TX_MAX_FACTORS; i++) { if (!cd->factors[i] || (fl == 1)) break; if (cd->factors[i] == TX_FACTOR_ANY) { factors_mod++; factors_product *= fl; } else if (!(fl % cd->factors[i])) { factors_mod++; if (cd->factors[i] == 2) { int b = ff_ctz(fl); fl >>= b; factors_product <<= b; } else { do { fl /= cd->factors[i]; factors_product *= cd->factors[i]; } while (!(fl % cd->factors[i])); } } } /* Disqualify if factor requirements are not satisfied or if trivial */ if ((factors_mod < cd->nb_factors) || (len == factors_product)) continue; if (av_gcd(factors_product, fl) != 1) continue; /* Check if length is supported and factorization was successful */ if ((factors_product < cd->min_len) || (cd->max_len != TX_LEN_UNLIMITED && (factors_product > cd->max_len))) continue; prio = get_codelet_prio(cd, cpu_flags, factors_product) * factors_product; /* Check for duplicates */ for (int i = 0; i < nb_decomp; i++) { if (factors_product == ld[i].len) { /* Update priority if new one is higher */ if (prio > ld[i].prio) ld[i].prio = prio; skip = 1; break; } } /* Add decomposition if unique */ if (!skip) { ld[nb_decomp].cd = cd; ld[nb_decomp].len = factors_product; ld[nb_decomp].len2 = fl; ld[nb_decomp].prio = prio; nb_decomp++; } } } if (!nb_decomp) return AVERROR(EINVAL); sort: AV_QSORT(ld, nb_decomp, FFTXLenDecomp, cmp_decomp); for (int i = 0; i < nb_decomp; i++) { if (ld[i].cd->nb_factors > 1) dst[i] = ld[i].len2; else dst[i] = ld[i].len; } return nb_decomp; } int ff_tx_gen_default_map(AVTXContext *s, FFTXCodeletOptions *opts) { s->map = av_malloc(s->len*sizeof(*s->map)); if (!s->map) return AVERROR(ENOMEM); s->map[0] = 0; /* DC is always at the start */ if (s->inv) /* Reversing the ACs flips the transform direction */ for (int i = 1; i < s->len; i++) s->map[i] = s->len - i; else for (int i = 1; i < s->len; i++) s->map[i] = i; s->map_dir = FF_TX_MAP_GATHER; return 0; } #if !CONFIG_SMALL static void print_flags(AVBPrint *bp, uint64_t f) { int prev = 0; const char *sep = ", "; av_bprintf(bp, "flags: ["); if ((f & FF_TX_ALIGNED) && ++prev) av_bprintf(bp, "aligned"); if ((f & AV_TX_UNALIGNED) && ++prev) av_bprintf(bp, "%sunaligned", prev > 1 ? sep : ""); if ((f & AV_TX_INPLACE) && ++prev) av_bprintf(bp, "%sinplace", prev > 1 ? sep : ""); if ((f & FF_TX_OUT_OF_PLACE) && ++prev) av_bprintf(bp, "%sout_of_place", prev > 1 ? sep : ""); if ((f & FF_TX_FORWARD_ONLY) && ++prev) av_bprintf(bp, "%sfwd_only", prev > 1 ? sep : ""); if ((f & FF_TX_INVERSE_ONLY) && ++prev) av_bprintf(bp, "%sinv_only", prev > 1 ? sep : ""); if ((f & FF_TX_PRESHUFFLE) && ++prev) av_bprintf(bp, "%spreshuf", prev > 1 ? sep : ""); if ((f & AV_TX_FULL_IMDCT) && ++prev) av_bprintf(bp, "%simdct_full", prev > 1 ? sep : ""); if ((f & FF_TX_ASM_CALL) && ++prev) av_bprintf(bp, "%sasm_call", prev > 1 ? sep : ""); av_bprintf(bp, "]"); } static void print_type(AVBPrint *bp, enum AVTXType type) { av_bprintf(bp, "%s", type == TX_TYPE_ANY ? "any" : type == AV_TX_FLOAT_FFT ? "fft_float" : type == AV_TX_FLOAT_MDCT ? "mdct_float" : type == AV_TX_FLOAT_RDFT ? "rdft_float" : type == AV_TX_DOUBLE_FFT ? "fft_double" : type == AV_TX_DOUBLE_MDCT ? "mdct_double" : type == AV_TX_DOUBLE_RDFT ? "rdft_double" : type == AV_TX_INT32_FFT ? "fft_int32" : type == AV_TX_INT32_MDCT ? "mdct_int32" : type == AV_TX_INT32_RDFT ? "rdft_int32" : "unknown"); } static void print_cd_info(const FFTXCodelet *cd, int prio, int len, int print_prio) { AVBPrint bp = { 0 }; av_bprint_init(&bp, 0, AV_BPRINT_SIZE_AUTOMATIC); av_bprintf(&bp, "%s - type: ", cd->name); print_type(&bp, cd->type); av_bprintf(&bp, ", len: "); if (!len) { if (cd->min_len != cd->max_len) av_bprintf(&bp, "[%i, ", cd->min_len); if (cd->max_len == TX_LEN_UNLIMITED) av_bprintf(&bp, "∞"); else av_bprintf(&bp, "%i", cd->max_len); } else { av_bprintf(&bp, "%i", len); } if (cd->factors[1]) { av_bprintf(&bp, "%s, factors", !len && cd->min_len != cd->max_len ? "]" : ""); if (!cd->nb_factors) av_bprintf(&bp, ": ["); else av_bprintf(&bp, "[%i]: [", cd->nb_factors); for (int i = 0; i < TX_MAX_FACTORS; i++) { if (i && cd->factors[i]) av_bprintf(&bp, ", "); if (cd->factors[i] == TX_FACTOR_ANY) av_bprintf(&bp, "any"); else if (cd->factors[i]) av_bprintf(&bp, "%i", cd->factors[i]); else break; } av_bprintf(&bp, "], "); } else { av_bprintf(&bp, "%s, factor: %i, ", !len && cd->min_len != cd->max_len ? "]" : "", cd->factors[0]); } print_flags(&bp, cd->flags); if (print_prio) av_bprintf(&bp, ", prio: %i", prio); av_log(NULL, AV_LOG_DEBUG, "%s\n", bp.str); } static void print_tx_structure(AVTXContext *s, int depth) { const FFTXCodelet *cd = s->cd_self; for (int i = 0; i <= depth; i++) av_log(NULL, AV_LOG_DEBUG, " "); print_cd_info(cd, cd->prio, s->len, 0); for (int i = 0; i < s->nb_sub; i++) print_tx_structure(&s->sub[i], depth + 1); } #endif /* CONFIG_SMALL */ typedef struct TXCodeletMatch { const FFTXCodelet *cd; int prio; } TXCodeletMatch; static int cmp_matches(TXCodeletMatch *a, TXCodeletMatch *b) { return FFDIFFSIGN(b->prio, a->prio); } /* We want all factors to completely cover the length */ static inline int check_cd_factors(const FFTXCodelet *cd, int len) { int matches = 0, any_flag = 0; for (int i = 0; i < TX_MAX_FACTORS; i++) { int factor = cd->factors[i]; if (factor == TX_FACTOR_ANY) { any_flag = 1; matches++; continue; } else if (len <= 1 || !factor) { break; } else if (factor == 2) { /* Fast path */ int bits_2 = ff_ctz(len); if (!bits_2) continue; /* Factor not supported */ len >>= bits_2; matches++; } else { int res = len % factor; if (res) continue; /* Factor not supported */ while (!res) { len /= factor; res = len % factor; } matches++; } } return (cd->nb_factors <= matches) && (any_flag || len == 1); } av_cold int ff_tx_init_subtx(AVTXContext *s, enum AVTXType type, uint64_t flags, FFTXCodeletOptions *opts, int len, int inv, const void *scale) { int ret = 0; AVTXContext *sub = NULL; TXCodeletMatch *cd_tmp, *cd_matches = NULL; unsigned int cd_matches_size = 0; int codelet_list_idx = codelet_list_num; int nb_cd_matches = 0; #if !CONFIG_SMALL AVBPrint bp = { 0 }; #endif /* We still accept functions marked with SLOW, even if the CPU is * marked with the same flag, but we give them lower priority. */ const int cpu_flags = av_get_cpu_flags(); /* Flags the transform wants */ uint64_t req_flags = flags; /* Flags the codelet may require to be present */ uint64_t inv_req_mask = AV_TX_FULL_IMDCT | FF_TX_PRESHUFFLE | FF_TX_ASM_CALL; /* Unaligned codelets are compatible with the aligned flag */ if (req_flags & FF_TX_ALIGNED) req_flags |= AV_TX_UNALIGNED; /* If either flag is set, both are okay, so don't check for an exact match */ if ((req_flags & AV_TX_INPLACE) && (req_flags & FF_TX_OUT_OF_PLACE)) req_flags &= ~(AV_TX_INPLACE | FF_TX_OUT_OF_PLACE); if ((req_flags & FF_TX_ALIGNED) && (req_flags & AV_TX_UNALIGNED)) req_flags &= ~(FF_TX_ALIGNED | AV_TX_UNALIGNED); /* Loop through all codelets in all codelet lists to find matches * to the requirements */ while (codelet_list_idx--) { const FFTXCodelet * const * list = codelet_list[codelet_list_idx]; const FFTXCodelet *cd = NULL; while ((cd = *list++)) { /* Check if the type matches */ if (cd->type != TX_TYPE_ANY && type != cd->type) continue; /* Check direction for non-orthogonal codelets */ if (((cd->flags & FF_TX_FORWARD_ONLY) && inv) || ((cd->flags & (FF_TX_INVERSE_ONLY | AV_TX_FULL_IMDCT)) && !inv)) continue; /* Check if the requested flags match from both sides */ if (((req_flags & cd->flags) != (req_flags)) || ((inv_req_mask & cd->flags) != (req_flags & inv_req_mask))) continue; /* Check if length is supported */ if ((len < cd->min_len) || (cd->max_len != -1 && (len > cd->max_len))) continue; /* Check if the CPU supports the required ISA */ if (cd->cpu_flags != FF_TX_CPU_FLAGS_ALL && !(cpu_flags & (cd->cpu_flags & ~cpu_slow_mask))) continue; /* Check for factors */ if (!check_cd_factors(cd, len)) continue; /* Realloc array and append */ cd_tmp = av_fast_realloc(cd_matches, &cd_matches_size, sizeof(*cd_tmp) * (nb_cd_matches + 1)); if (!cd_tmp) { av_free(cd_matches); return AVERROR(ENOMEM); } cd_matches = cd_tmp; cd_matches[nb_cd_matches].cd = cd; cd_matches[nb_cd_matches].prio = get_codelet_prio(cd, cpu_flags, len); nb_cd_matches++; } } #if !CONFIG_SMALL /* Print debugging info */ av_bprint_init(&bp, 0, AV_BPRINT_SIZE_AUTOMATIC); av_bprintf(&bp, "For transform of length %i, %s, ", len, inv ? "inverse" : "forward"); print_type(&bp, type); av_bprintf(&bp, ", "); print_flags(&bp, flags); av_bprintf(&bp, ", found %i matches%s", nb_cd_matches, nb_cd_matches ? ":" : "."); #endif /* No matches found */ if (!nb_cd_matches) return AVERROR(ENOSYS); /* Sort the list */ AV_QSORT(cd_matches, nb_cd_matches, TXCodeletMatch, cmp_matches); #if !CONFIG_SMALL av_log(NULL, AV_LOG_DEBUG, "%s\n", bp.str); for (int i = 0; i < nb_cd_matches; i++) { av_log(NULL, AV_LOG_DEBUG, " %i: ", i + 1); print_cd_info(cd_matches[i].cd, cd_matches[i].prio, 0, 1); } #endif if (!s->sub) { s->sub = sub = av_mallocz(TX_MAX_SUB*sizeof(*sub)); if (!sub) { ret = AVERROR(ENOMEM); goto end; } } /* Attempt to initialize each */ for (int i = 0; i < nb_cd_matches; i++) { const FFTXCodelet *cd = cd_matches[i].cd; AVTXContext *sctx = &s->sub[s->nb_sub]; sctx->len = len; sctx->inv = inv; sctx->type = type; sctx->flags = cd->flags | flags; sctx->cd_self = cd; s->fn[s->nb_sub] = cd->function; s->cd[s->nb_sub] = cd; ret = 0; if (cd->init) ret = cd->init(sctx, cd, flags, opts, len, inv, scale); if (ret >= 0) { if (opts && opts->map_dir != FF_TX_MAP_NONE && sctx->map_dir == FF_TX_MAP_NONE) { /* If a specific map direction was requested, and it doesn't * exist, create one.*/ sctx->map = av_malloc(len*sizeof(*sctx->map)); if (!sctx->map) { ret = AVERROR(ENOMEM); goto end; } for (int i = 0; i < len; i++) sctx->map[i] = i; } else if (opts && (opts->map_dir != sctx->map_dir)) { int *tmp = av_malloc(len*sizeof(*sctx->map)); if (!tmp) { ret = AVERROR(ENOMEM); goto end; } memcpy(tmp, sctx->map, len*sizeof(*sctx->map)); for (int i = 0; i < len; i++) sctx->map[tmp[i]] = i; av_free(tmp); } s->nb_sub++; goto end; } s->fn[s->nb_sub] = NULL; s->cd[s->nb_sub] = NULL; reset_ctx(sctx, 0); if (ret == AVERROR(ENOMEM)) break; } if (!s->nb_sub) av_freep(&s->sub); end: av_free(cd_matches); return ret; } av_cold int av_tx_init(AVTXContext **ctx, av_tx_fn *tx, enum AVTXType type, int inv, int len, const void *scale, uint64_t flags) { int ret; AVTXContext tmp = { 0 }; const double default_scale_d = 1.0; const float default_scale_f = 1.0f; if (!len || type >= AV_TX_NB || !ctx || !tx) return AVERROR(EINVAL); if (!(flags & AV_TX_UNALIGNED)) flags |= FF_TX_ALIGNED; if (!(flags & AV_TX_INPLACE)) flags |= FF_TX_OUT_OF_PLACE; if (!scale && ((type == AV_TX_FLOAT_MDCT) || (type == AV_TX_INT32_MDCT))) scale = &default_scale_f; else if (!scale && (type == AV_TX_DOUBLE_MDCT)) scale = &default_scale_d; ret = ff_tx_init_subtx(&tmp, type, flags, NULL, len, inv, scale); if (ret < 0) return ret; *ctx = &tmp.sub[0]; *tx = tmp.fn[0]; #if !CONFIG_SMALL av_log(NULL, AV_LOG_DEBUG, "Transform tree:\n"); print_tx_structure(*ctx, 0); #endif return ret; }