/* * Copyright (c) 2013 The WebM project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ /** * @file * VP9 SVC encoding support via libvpx */ #include #include #include #define VPX_DISABLE_CTRL_TYPECHECKS 1 #define VPX_CODEC_DISABLE_COMPAT 1 #include "vpx/svc_context.h" #include "vpx/vp8cx.h" #include "vpx/vpx_encoder.h" #ifdef __MINGW32__ char* strtok_r( char *str, const char *delim, char **nextp) { char *ret; if (str == NULL) { str = *nextp; } str += strspn(str, delim); if (*str == '\0') { return NULL; } ret = str; str += strcspn(str, delim); if (*str) { *str++ = '\0'; } *nextp = str; return ret; } #endif /* __MINGW32__ */ #ifdef _MSC_VER #define strdup _strdup #define strtok_r strtok_s #endif #define SVC_REFERENCE_FRAMES 8 #define SUPERFRAME_SLOTS (8) #define SUPERFRAME_BUFFER_SIZE (SUPERFRAME_SLOTS * sizeof(uint32_t) + 2) #define OPTION_BUFFER_SIZE 256 #define COMPONENTS 4 // psnr & sse statistics maintained for total, y, u, v static const char *DEFAULT_QUANTIZER_VALUES = "60,53,39,33,27"; static const char *DEFAULT_SCALE_FACTORS = "4/16,5/16,7/16,11/16,16/16"; typedef struct SvcInternal { char options[OPTION_BUFFER_SIZE]; // set by vpx_svc_set_options char quantizers[OPTION_BUFFER_SIZE]; // set by vpx_svc_set_quantizers char quantizers_keyframe[OPTION_BUFFER_SIZE]; // set by // vpx_svc_set_quantizers char scale_factors[OPTION_BUFFER_SIZE]; // set by vpx_svc_set_scale_factors // values extracted from option, quantizers int scaling_factor_num[VPX_SS_MAX_LAYERS]; int scaling_factor_den[VPX_SS_MAX_LAYERS]; int quantizer_keyframe[VPX_SS_MAX_LAYERS]; int quantizer[VPX_SS_MAX_LAYERS]; // accumulated statistics double psnr_sum[VPX_SS_MAX_LAYERS][COMPONENTS]; // total/Y/U/V uint64_t sse_sum[VPX_SS_MAX_LAYERS][COMPONENTS]; uint32_t bytes_sum[VPX_SS_MAX_LAYERS]; // codec encoding values int width; // width of highest layer int height; // height of highest layer int kf_dist; // distance between keyframes // state variables int encode_frame_count; int frame_within_gop; vpx_enc_frame_flags_t enc_frame_flags; int layers; int layer; int is_keyframe; size_t frame_size; size_t buffer_size; void *buffer; char message_buffer[2048]; vpx_codec_ctx_t *codec_ctx; } SvcInternal; // Superframe is used to generate an index of individual frames (i.e., layers) struct Superframe { int count; uint32_t sizes[SUPERFRAME_SLOTS]; uint32_t magnitude; uint8_t buffer[SUPERFRAME_BUFFER_SIZE]; size_t index_size; }; // One encoded frame layer struct LayerData { void *buf; // compressed data buffer size_t size; // length of compressed data struct LayerData *next; }; // create LayerData from encoder output static struct LayerData *ld_create(void *buf, size_t size) { struct LayerData *const layer_data = (struct LayerData *)malloc(sizeof(*layer_data)); if (layer_data == NULL) { return NULL; } layer_data->buf = malloc(size); if (layer_data->buf == NULL) { free(layer_data); return NULL; } memcpy(layer_data->buf, buf, size); layer_data->size = size; return layer_data; } // free LayerData static void ld_free(struct LayerData *layer_data) { if (layer_data) { if (layer_data->buf) { free(layer_data->buf); layer_data->buf = NULL; } free(layer_data); } } // add layer data to list static void ld_list_add(struct LayerData **list, struct LayerData *layer_data) { struct LayerData **p = list; while (*p != NULL) p = &(*p)->next; *p = layer_data; layer_data->next = NULL; } // get accumulated size of layer data static size_t ld_list_get_buffer_size(struct LayerData *list) { struct LayerData *p; size_t size = 0; for (p = list; p != NULL; p = p->next) { size += p->size; } return size; } // copy layer data to buffer static void ld_list_copy_to_buffer(struct LayerData *list, uint8_t *buffer) { struct LayerData *p; for (p = list; p != NULL; p = p->next) { buffer[0] = 1; memcpy(buffer, p->buf, p->size); buffer += p->size; } } // free layer data list static void ld_list_free(struct LayerData *list) { struct LayerData *p = list; while (p) { list = list->next; ld_free(p); p = list; } } static void sf_create_index(struct Superframe *sf) { uint8_t marker = 0xc0; int i; uint32_t mag, mask; uint8_t *bufp; if (sf->count == 0 || sf->count >= 8) return; // Add the number of frames to the marker byte marker |= sf->count - 1; // Choose the magnitude for (mag = 0, mask = 0xff; mag < 4; ++mag) { if (sf->magnitude < mask) break; mask <<= 8; mask |= 0xff; } marker |= mag << 3; // Write the index sf->index_size = 2 + (mag + 1) * sf->count; bufp = sf->buffer; *bufp++ = marker; for (i = 0; i < sf->count; ++i) { int this_sz = sf->sizes[i]; uint32_t j; for (j = 0; j <= mag; ++j) { *bufp++ = this_sz & 0xff; this_sz >>= 8; } } *bufp++ = marker; } static SvcInternal *get_svc_internal(SvcContext *svc_ctx) { if (svc_ctx == NULL) return NULL; if (svc_ctx->internal == NULL) { SvcInternal *const si = (SvcInternal *)malloc(sizeof(*si)); if (si != NULL) { memset(si, 0, sizeof(*si)); } svc_ctx->internal = si; } return (SvcInternal *)svc_ctx->internal; } static const SvcInternal *get_const_svc_internal(const SvcContext *svc_ctx) { if (svc_ctx == NULL) return NULL; return (const SvcInternal *)svc_ctx->internal; } static void svc_log_reset(SvcContext *svc_ctx) { SvcInternal *const si = (SvcInternal *)svc_ctx->internal; si->message_buffer[0] = '\0'; } static int svc_log(SvcContext *svc_ctx, int level, const char *fmt, ...) { char buf[512]; int retval = 0; va_list ap; SvcInternal *const si = get_svc_internal(svc_ctx); if (level > svc_ctx->log_level) { return retval; } va_start(ap, fmt); retval = vsnprintf(buf, sizeof(buf), fmt, ap); va_end(ap); if (svc_ctx->log_print) { printf("%s", buf); } else { strncat(si->message_buffer, buf, sizeof(si->message_buffer) - strlen(si->message_buffer) - 1); } if (level == SVC_LOG_ERROR) { si->codec_ctx->err_detail = si->message_buffer; } return retval; } static vpx_codec_err_t set_option_encoding_mode(SvcContext *svc_ctx, const char *value_str) { if (strcmp(value_str, "i") == 0) { svc_ctx->encoding_mode = INTER_LAYER_PREDICTION_I; } else if (strcmp(value_str, "alt-ip") == 0) { svc_ctx->encoding_mode = ALT_INTER_LAYER_PREDICTION_IP; } else if (strcmp(value_str, "ip") == 0) { svc_ctx->encoding_mode = INTER_LAYER_PREDICTION_IP; } else if (strcmp(value_str, "gf") == 0) { svc_ctx->encoding_mode = USE_GOLDEN_FRAME; } else { svc_log(svc_ctx, SVC_LOG_ERROR, "invalid encoding mode: %s", value_str); return VPX_CODEC_INVALID_PARAM; } return VPX_CODEC_OK; } static vpx_codec_err_t parse_quantizer_values(SvcContext *svc_ctx, const char *quantizer_values, const int is_keyframe) { char *input_string; char *token; const char *delim = ","; char *save_ptr; int found = 0; int i, q; vpx_codec_err_t res = VPX_CODEC_OK; SvcInternal *const si = get_svc_internal(svc_ctx); if (quantizer_values == NULL || strlen(quantizer_values) == 0) { if (is_keyframe) { // If there non settings for key frame, we will apply settings from // non key frame. So just simply return here. return VPX_CODEC_INVALID_PARAM; } input_string = strdup(DEFAULT_QUANTIZER_VALUES); } else { input_string = strdup(quantizer_values); } token = strtok_r(input_string, delim, &save_ptr); for (i = 0; i < svc_ctx->spatial_layers; ++i) { if (token != NULL) { q = atoi(token); if (q <= 0 || q > 100) { svc_log(svc_ctx, SVC_LOG_ERROR, "svc-quantizer-values: invalid value %s\n", token); res = VPX_CODEC_INVALID_PARAM; break; } token = strtok_r(NULL, delim, &save_ptr); found = i + 1; } else { q = 0; } if (is_keyframe) { si->quantizer_keyframe[i + VPX_SS_MAX_LAYERS - svc_ctx->spatial_layers] = q; } else { si->quantizer[i + VPX_SS_MAX_LAYERS - svc_ctx->spatial_layers] = q; } } if (res == VPX_CODEC_OK && found != svc_ctx->spatial_layers) { svc_log(svc_ctx, SVC_LOG_ERROR, "svc: quantizers: %d values required, but only %d specified\n", svc_ctx->spatial_layers, found); res = VPX_CODEC_INVALID_PARAM; } free(input_string); return res; } static void log_invalid_scale_factor(SvcContext *svc_ctx, const char *value) { svc_log(svc_ctx, SVC_LOG_ERROR, "svc scale-factors: invalid value %s\n", value); } static vpx_codec_err_t parse_scale_factors(SvcContext *svc_ctx, const char *scale_factors) { char *input_string; char *token; const char *delim = ","; char *save_ptr; int found = 0; int i; int64_t num, den; vpx_codec_err_t res = VPX_CODEC_OK; SvcInternal *const si = get_svc_internal(svc_ctx); if (scale_factors == NULL || strlen(scale_factors) == 0) { input_string = strdup(DEFAULT_SCALE_FACTORS); } else { input_string = strdup(scale_factors); } token = strtok_r(input_string, delim, &save_ptr); for (i = 0; i < svc_ctx->spatial_layers; ++i) { num = den = 0; if (token != NULL) { num = strtol(token, &token, 10); if (num <= 0) { log_invalid_scale_factor(svc_ctx, token); res = VPX_CODEC_INVALID_PARAM; break; } if (*token++ != '/') { log_invalid_scale_factor(svc_ctx, token); res = VPX_CODEC_INVALID_PARAM; break; } den = strtol(token, &token, 10); if (den <= 0) { log_invalid_scale_factor(svc_ctx, token); res = VPX_CODEC_INVALID_PARAM; break; } token = strtok_r(NULL, delim, &save_ptr); found = i + 1; } si->scaling_factor_num[i + VPX_SS_MAX_LAYERS - svc_ctx->spatial_layers] = (int)num; si->scaling_factor_den[i + VPX_SS_MAX_LAYERS - svc_ctx->spatial_layers] = (int)den; } if (res == VPX_CODEC_OK && found != svc_ctx->spatial_layers) { svc_log(svc_ctx, SVC_LOG_ERROR, "svc: scale-factors: %d values required, but only %d specified\n", svc_ctx->spatial_layers, found); res = VPX_CODEC_INVALID_PARAM; } free(input_string); return res; } /** * Parse SVC encoding options * Format: encoding-mode=,layers= * scale-factors=/,/,... * quantizers=,,... * svc_mode = [i|ip|alt_ip|gf] */ static vpx_codec_err_t parse_options(SvcContext *svc_ctx, const char *options) { char *input_string; char *option_name; char *option_value; char *input_ptr; int is_keyframe_qaunt_set = 0; vpx_codec_err_t res = VPX_CODEC_OK; if (options == NULL) return VPX_CODEC_OK; input_string = strdup(options); // parse option name option_name = strtok_r(input_string, "=", &input_ptr); while (option_name != NULL) { // parse option value option_value = strtok_r(NULL, " ", &input_ptr); if (option_value == NULL) { svc_log(svc_ctx, SVC_LOG_ERROR, "option missing value: %s\n", option_name); res = VPX_CODEC_INVALID_PARAM; break; } if (strcmp("encoding-mode", option_name) == 0) { res = set_option_encoding_mode(svc_ctx, option_value); if (res != VPX_CODEC_OK) break; } else if (strcmp("layers", option_name) == 0) { svc_ctx->spatial_layers = atoi(option_value); } else if (strcmp("scale-factors", option_name) == 0) { res = parse_scale_factors(svc_ctx, option_value); if (res != VPX_CODEC_OK) break; } else if (strcmp("quantizers", option_name) == 0) { res = parse_quantizer_values(svc_ctx, option_value, 0); if (res != VPX_CODEC_OK) break; if (!is_keyframe_qaunt_set) { SvcInternal *const si = get_svc_internal(svc_ctx); memcpy(get_svc_internal(svc_ctx)->quantizer_keyframe, si->quantizer, sizeof(si->quantizer)); } } else if (strcmp("quantizers-keyframe", option_name) == 0) { res = parse_quantizer_values(svc_ctx, option_value, 1); if (res != VPX_CODEC_OK) break; is_keyframe_qaunt_set = 1; } else { svc_log(svc_ctx, SVC_LOG_ERROR, "invalid option: %s\n", option_name); res = VPX_CODEC_INVALID_PARAM; break; } option_name = strtok_r(NULL, "=", &input_ptr); } free(input_string); return res; } vpx_codec_err_t vpx_svc_set_options(SvcContext *svc_ctx, const char *options) { SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || options == NULL || si == NULL) { return VPX_CODEC_INVALID_PARAM; } strncpy(si->options, options, sizeof(si->options)); si->options[sizeof(si->options) - 1] = '\0'; return VPX_CODEC_OK; } vpx_codec_err_t vpx_svc_set_quantizers(SvcContext *svc_ctx, const char *quantizers, const int is_for_keyframe) { SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || quantizers == NULL || si == NULL) { return VPX_CODEC_INVALID_PARAM; } if (is_for_keyframe) { strncpy(si->quantizers_keyframe, quantizers, sizeof(si->quantizers)); si->quantizers_keyframe[sizeof(si->quantizers_keyframe) - 1] = '\0'; } else { strncpy(si->quantizers, quantizers, sizeof(si->quantizers)); si->quantizers[sizeof(si->quantizers) - 1] = '\0'; } return VPX_CODEC_OK; } vpx_codec_err_t vpx_svc_set_scale_factors(SvcContext *svc_ctx, const char *scale_factors) { SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || scale_factors == NULL || si == NULL) { return VPX_CODEC_INVALID_PARAM; } strncpy(si->scale_factors, scale_factors, sizeof(si->scale_factors)); si->scale_factors[sizeof(si->scale_factors) - 1] = '\0'; return VPX_CODEC_OK; } vpx_codec_err_t vpx_svc_init(SvcContext *svc_ctx, vpx_codec_ctx_t *codec_ctx, vpx_codec_iface_t *iface, vpx_codec_enc_cfg_t *enc_cfg) { int max_intra_size_pct; vpx_codec_err_t res; SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || codec_ctx == NULL || iface == NULL || enc_cfg == NULL) { return VPX_CODEC_INVALID_PARAM; } if (si == NULL) return VPX_CODEC_MEM_ERROR; si->codec_ctx = codec_ctx; si->width = enc_cfg->g_w; si->height = enc_cfg->g_h; if (enc_cfg->kf_max_dist < 2) { svc_log(svc_ctx, SVC_LOG_ERROR, "key frame distance too small: %d\n", enc_cfg->kf_max_dist); return VPX_CODEC_INVALID_PARAM; } si->kf_dist = enc_cfg->kf_max_dist; if (svc_ctx->spatial_layers == 0) svc_ctx->spatial_layers = VPX_SS_DEFAULT_LAYERS; if (svc_ctx->spatial_layers < 1 || svc_ctx->spatial_layers > VPX_SS_MAX_LAYERS) { svc_log(svc_ctx, SVC_LOG_ERROR, "spatial layers: invalid value: %d\n", svc_ctx->spatial_layers); return VPX_CODEC_INVALID_PARAM; } // use SvcInternal value for number of layers to enable forcing single layer // for first frame si->layers = svc_ctx->spatial_layers; res = parse_quantizer_values(svc_ctx, si->quantizers, 0); if (res != VPX_CODEC_OK) return res; res = parse_quantizer_values(svc_ctx, si->quantizers_keyframe, 1); if (res != VPX_CODEC_OK) memcpy(si->quantizer_keyframe, si->quantizer, sizeof(si->quantizer)); res = parse_scale_factors(svc_ctx, si->scale_factors); if (res != VPX_CODEC_OK) return res; // parse aggregate command line options res = parse_options(svc_ctx, si->options); if (res != VPX_CODEC_OK) return res; // Assign target bitrate for each layer. We calculate the ratio // from the resolution for now. // TODO(Minghai): Optimize the mechanism of allocating bits after // implementing svc two pass rate control. if (si->layers > 1) { int i; float total = 0; float alloc_ratio[VPX_SS_MAX_LAYERS] = {0}; for (i = 0; i < si->layers; ++i) { int pos = i + VPX_SS_MAX_LAYERS - svc_ctx->spatial_layers; if (pos < VPX_SS_MAX_LAYERS && si->scaling_factor_den[pos] > 0) { alloc_ratio[i] = (float)(si->scaling_factor_num[pos] * 1.0 / si->scaling_factor_den[pos]); alloc_ratio[i] *= alloc_ratio[i]; total += alloc_ratio[i]; } } for (i = 0; i < si->layers; ++i) { if (total > 0) { enc_cfg->ss_target_bitrate[i] = (unsigned int) (enc_cfg->rc_target_bitrate * alloc_ratio[i] / total); } } } // modify encoder configuration enc_cfg->ss_number_layers = si->layers; enc_cfg->ts_number_layers = 1; // Temporal layers not used in this encoder. enc_cfg->kf_mode = VPX_KF_DISABLED; enc_cfg->g_pass = VPX_RC_ONE_PASS; // Lag in frames not currently supported enc_cfg->g_lag_in_frames = 0; // TODO(ivanmaltz): determine if these values need to be set explicitly for // svc, or if the normal default/override mechanism can be used enc_cfg->rc_dropframe_thresh = 0; enc_cfg->rc_end_usage = VPX_CBR; enc_cfg->rc_resize_allowed = 0; enc_cfg->rc_min_quantizer = 33; enc_cfg->rc_max_quantizer = 33; enc_cfg->rc_undershoot_pct = 100; enc_cfg->rc_overshoot_pct = 15; enc_cfg->rc_buf_initial_sz = 500; enc_cfg->rc_buf_optimal_sz = 600; enc_cfg->rc_buf_sz = 1000; enc_cfg->g_error_resilient = 1; // Initialize codec res = vpx_codec_enc_init(codec_ctx, iface, enc_cfg, VPX_CODEC_USE_PSNR); if (res != VPX_CODEC_OK) { svc_log(svc_ctx, SVC_LOG_ERROR, "svc_enc_init error\n"); return res; } vpx_codec_control(codec_ctx, VP9E_SET_SVC, 1); vpx_codec_control(codec_ctx, VP8E_SET_CPUUSED, 1); vpx_codec_control(codec_ctx, VP8E_SET_STATIC_THRESHOLD, 1); vpx_codec_control(codec_ctx, VP8E_SET_NOISE_SENSITIVITY, 1); vpx_codec_control(codec_ctx, VP8E_SET_TOKEN_PARTITIONS, 1); max_intra_size_pct = (int)(((double)enc_cfg->rc_buf_optimal_sz * 0.5) * ((double)enc_cfg->g_timebase.den / enc_cfg->g_timebase.num) / 10.0); vpx_codec_control(codec_ctx, VP8E_SET_MAX_INTRA_BITRATE_PCT, max_intra_size_pct); return VPX_CODEC_OK; } // SVC Algorithm flags - these get mapped to VP8_EFLAG_* defined in vp8cx.h // encoder should reference the last frame #define USE_LAST (1 << 0) // encoder should reference the alt ref frame #define USE_ARF (1 << 1) // encoder should reference the golden frame #define USE_GF (1 << 2) // encoder should copy current frame to the last frame buffer #define UPDATE_LAST (1 << 3) // encoder should copy current frame to the alt ref frame buffer #define UPDATE_ARF (1 << 4) // encoder should copy current frame to the golden frame #define UPDATE_GF (1 << 5) static int map_vp8_flags(int svc_flags) { int flags = 0; if (!(svc_flags & USE_LAST)) flags |= VP8_EFLAG_NO_REF_LAST; if (!(svc_flags & USE_ARF)) flags |= VP8_EFLAG_NO_REF_ARF; if (!(svc_flags & USE_GF)) flags |= VP8_EFLAG_NO_REF_GF; if (svc_flags & UPDATE_LAST) { // last is updated automatically } else { flags |= VP8_EFLAG_NO_UPD_LAST; } if (svc_flags & UPDATE_ARF) { flags |= VP8_EFLAG_FORCE_ARF; } else { flags |= VP8_EFLAG_NO_UPD_ARF; } if (svc_flags & UPDATE_GF) { flags |= VP8_EFLAG_FORCE_GF; } else { flags |= VP8_EFLAG_NO_UPD_GF; } return flags; } static void calculate_enc_frame_flags(SvcContext *svc_ctx) { vpx_enc_frame_flags_t flags = VPX_EFLAG_FORCE_KF; SvcInternal *const si = get_svc_internal(svc_ctx); const int is_keyframe = (si->frame_within_gop == 0); // keyframe layer zero is identical for all modes if (is_keyframe && si->layer == 0) { si->enc_frame_flags = VPX_EFLAG_FORCE_KF; return; } switch (svc_ctx->encoding_mode) { case ALT_INTER_LAYER_PREDICTION_IP: if (si->layer == 0) { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } else if (is_keyframe) { if (si->layer == si->layers - 1) { flags = map_vp8_flags(USE_ARF | UPDATE_LAST); } else { flags = map_vp8_flags(USE_ARF | UPDATE_LAST | UPDATE_GF); } } else { flags = map_vp8_flags(USE_LAST | USE_ARF | UPDATE_LAST); } break; case INTER_LAYER_PREDICTION_I: if (si->layer == 0) { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } else if (is_keyframe) { flags = map_vp8_flags(USE_ARF | UPDATE_LAST); } else { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } break; case INTER_LAYER_PREDICTION_IP: if (si->layer == 0) { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } else if (is_keyframe) { flags = map_vp8_flags(USE_ARF | UPDATE_LAST); } else { flags = map_vp8_flags(USE_LAST | USE_ARF | UPDATE_LAST); } break; case USE_GOLDEN_FRAME: if (2 * si->layers - SVC_REFERENCE_FRAMES <= si->layer) { if (si->layer == 0) { flags = map_vp8_flags(USE_LAST | USE_GF | UPDATE_LAST); } else if (is_keyframe) { flags = map_vp8_flags(USE_ARF | UPDATE_LAST | UPDATE_GF); } else { flags = map_vp8_flags(USE_LAST | USE_ARF | USE_GF | UPDATE_LAST); } } else { if (si->layer == 0) { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } else if (is_keyframe) { flags = map_vp8_flags(USE_ARF | UPDATE_LAST); } else { flags = map_vp8_flags(USE_LAST | UPDATE_LAST); } } break; default: svc_log(svc_ctx, SVC_LOG_ERROR, "unexpected encoding mode: %d\n", svc_ctx->encoding_mode); break; } si->enc_frame_flags = flags; } vpx_codec_err_t vpx_svc_get_layer_resolution(const SvcContext *svc_ctx, int layer, unsigned int *width, unsigned int *height) { int w, h, index, num, den; const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL || width == NULL || height == NULL) { return VPX_CODEC_INVALID_PARAM; } if (layer < 0 || layer >= si->layers) return VPX_CODEC_INVALID_PARAM; index = layer + VPX_SS_MAX_LAYERS - si->layers; num = si->scaling_factor_num[index]; den = si->scaling_factor_den[index]; if (num == 0 || den == 0) return VPX_CODEC_INVALID_PARAM; w = si->width * num / den; h = si->height * num / den; // make height and width even to make chrome player happy w += w % 2; h += h % 2; *width = w; *height = h; return VPX_CODEC_OK; } static void set_svc_parameters(SvcContext *svc_ctx, vpx_codec_ctx_t *codec_ctx) { int layer, layer_index; vpx_svc_parameters_t svc_params; SvcInternal *const si = get_svc_internal(svc_ctx); memset(&svc_params, 0, sizeof(svc_params)); svc_params.temporal_layer = 0; svc_params.spatial_layer = si->layer; svc_params.flags = si->enc_frame_flags; layer = si->layer; if (svc_ctx->encoding_mode == ALT_INTER_LAYER_PREDICTION_IP && si->frame_within_gop == 0) { // layers 1 & 3 don't exist in this mode, use the higher one if (layer == 0 || layer == 2) { layer += 1; } } if (VPX_CODEC_OK != vpx_svc_get_layer_resolution(svc_ctx, layer, &svc_params.width, &svc_params.height)) { svc_log(svc_ctx, SVC_LOG_ERROR, "vpx_svc_get_layer_resolution failed\n"); } layer_index = layer + VPX_SS_MAX_LAYERS - si->layers; if (vpx_svc_is_keyframe(svc_ctx)) { svc_params.min_quantizer = si->quantizer_keyframe[layer_index]; svc_params.max_quantizer = si->quantizer_keyframe[layer_index]; } else { svc_params.min_quantizer = si->quantizer[layer_index]; svc_params.max_quantizer = si->quantizer[layer_index]; } svc_params.distance_from_i_frame = si->frame_within_gop; // Use buffer i for layer i LST svc_params.lst_fb_idx = si->layer; // Use buffer i-1 for layer i Alt (Inter-layer prediction) if (si->layer != 0) { const int use_higher_layer = svc_ctx->encoding_mode == ALT_INTER_LAYER_PREDICTION_IP && si->frame_within_gop == 0; svc_params.alt_fb_idx = use_higher_layer ? si->layer - 2 : si->layer - 1; } if (svc_ctx->encoding_mode == ALT_INTER_LAYER_PREDICTION_IP) { svc_params.gld_fb_idx = si->layer + 1; } else { if (si->layer < 2 * si->layers - SVC_REFERENCE_FRAMES) svc_params.gld_fb_idx = svc_params.lst_fb_idx; else svc_params.gld_fb_idx = 2 * si->layers - 1 - si->layer; } svc_log(svc_ctx, SVC_LOG_DEBUG, "SVC frame: %d, layer: %d, %dx%d, q: %d\n", si->encode_frame_count, si->layer, svc_params.width, svc_params.height, svc_params.min_quantizer); if (svc_params.flags == VPX_EFLAG_FORCE_KF) { svc_log(svc_ctx, SVC_LOG_DEBUG, "flags == VPX_EFLAG_FORCE_KF\n"); } else { svc_log( svc_ctx, SVC_LOG_DEBUG, "Using: LST/GLD/ALT [%2d|%2d|%2d]\n", svc_params.flags & VP8_EFLAG_NO_REF_LAST ? -1 : svc_params.lst_fb_idx, svc_params.flags & VP8_EFLAG_NO_REF_GF ? -1 : svc_params.gld_fb_idx, svc_params.flags & VP8_EFLAG_NO_REF_ARF ? -1 : svc_params.alt_fb_idx); svc_log( svc_ctx, SVC_LOG_DEBUG, "Updating: LST/GLD/ALT [%2d|%2d|%2d]\n", svc_params.flags & VP8_EFLAG_NO_UPD_LAST ? -1 : svc_params.lst_fb_idx, svc_params.flags & VP8_EFLAG_NO_UPD_GF ? -1 : svc_params.gld_fb_idx, svc_params.flags & VP8_EFLAG_NO_UPD_ARF ? -1 : svc_params.alt_fb_idx); } vpx_codec_control(codec_ctx, VP9E_SET_SVC_PARAMETERS, &svc_params); } /** * Encode a frame into multiple layers * Create a superframe containing the individual layers */ vpx_codec_err_t vpx_svc_encode(SvcContext *svc_ctx, vpx_codec_ctx_t *codec_ctx, struct vpx_image *rawimg, vpx_codec_pts_t pts, int64_t duration, int deadline) { vpx_codec_err_t res; vpx_codec_iter_t iter; const vpx_codec_cx_pkt_t *cx_pkt; struct LayerData *cx_layer_list = NULL; struct LayerData *layer_data; struct Superframe superframe; SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || codec_ctx == NULL || rawimg == NULL || si == NULL) { return VPX_CODEC_INVALID_PARAM; } memset(&superframe, 0, sizeof(superframe)); svc_log_reset(svc_ctx); si->layers = svc_ctx->spatial_layers; if (si->frame_within_gop >= si->kf_dist || si->encode_frame_count == 0) { si->frame_within_gop = 0; } si->is_keyframe = (si->frame_within_gop == 0); si->frame_size = 0; svc_log(svc_ctx, SVC_LOG_DEBUG, "vpx_svc_encode layers: %d, frame_count: %d, frame_within_gop: %d\n", si->layers, si->encode_frame_count, si->frame_within_gop); // encode each layer for (si->layer = 0; si->layer < si->layers; ++si->layer) { if (svc_ctx->encoding_mode == ALT_INTER_LAYER_PREDICTION_IP && si->is_keyframe && (si->layer == 1 || si->layer == 3)) { svc_log(svc_ctx, SVC_LOG_DEBUG, "Skip encoding layer %d\n", si->layer); continue; } calculate_enc_frame_flags(svc_ctx); set_svc_parameters(svc_ctx, codec_ctx); res = vpx_codec_encode(codec_ctx, rawimg, pts, (uint32_t)duration, si->enc_frame_flags, deadline); if (res != VPX_CODEC_OK) { return res; } // save compressed data iter = NULL; while ((cx_pkt = vpx_codec_get_cx_data(codec_ctx, &iter))) { switch (cx_pkt->kind) { case VPX_CODEC_CX_FRAME_PKT: { const uint32_t frame_pkt_size = (uint32_t)(cx_pkt->data.frame.sz); si->bytes_sum[si->layer] += frame_pkt_size; svc_log(svc_ctx, SVC_LOG_DEBUG, "SVC frame: %d, layer: %d, size: %u\n", si->encode_frame_count, si->layer, frame_pkt_size); layer_data = ld_create(cx_pkt->data.frame.buf, (size_t)frame_pkt_size); if (layer_data == NULL) { svc_log(svc_ctx, SVC_LOG_ERROR, "Error allocating LayerData\n"); return VPX_CODEC_OK; } ld_list_add(&cx_layer_list, layer_data); // save layer size in superframe index superframe.sizes[superframe.count++] = frame_pkt_size; superframe.magnitude |= frame_pkt_size; break; } case VPX_CODEC_PSNR_PKT: { int i; svc_log(svc_ctx, SVC_LOG_DEBUG, "SVC frame: %d, layer: %d, PSNR(Total/Y/U/V): " "%2.3f %2.3f %2.3f %2.3f \n", si->encode_frame_count, si->layer, cx_pkt->data.psnr.psnr[0], cx_pkt->data.psnr.psnr[1], cx_pkt->data.psnr.psnr[2], cx_pkt->data.psnr.psnr[3]); svc_log(svc_ctx, SVC_LOG_DEBUG, "SVC frame: %d, layer: %d, SSE(Total/Y/U/V): " "%2.3f %2.3f %2.3f %2.3f \n", si->encode_frame_count, si->layer, cx_pkt->data.psnr.sse[0], cx_pkt->data.psnr.sse[1], cx_pkt->data.psnr.sse[2], cx_pkt->data.psnr.sse[3]); for (i = 0; i < COMPONENTS; i++) { si->psnr_sum[si->layer][i] += cx_pkt->data.psnr.psnr[i]; si->sse_sum[si->layer][i] += cx_pkt->data.psnr.sse[i]; } break; } default: { break; } } } } // add superframe index to layer data list sf_create_index(&superframe); layer_data = ld_create(superframe.buffer, superframe.index_size); ld_list_add(&cx_layer_list, layer_data); // get accumulated size of layer data si->frame_size = ld_list_get_buffer_size(cx_layer_list); if (si->frame_size == 0) return VPX_CODEC_ERROR; // all layers encoded, create single buffer with concatenated layers if (si->frame_size > si->buffer_size) { free(si->buffer); si->buffer = malloc(si->frame_size); if (si->buffer == NULL) { ld_list_free(cx_layer_list); return VPX_CODEC_MEM_ERROR; } si->buffer_size = si->frame_size; } // copy layer data into packet ld_list_copy_to_buffer(cx_layer_list, (uint8_t *)si->buffer); ld_list_free(cx_layer_list); svc_log(svc_ctx, SVC_LOG_DEBUG, "SVC frame: %d, kf: %d, size: %d, pts: %d\n", si->encode_frame_count, si->is_keyframe, (int)si->frame_size, (int)pts); ++si->frame_within_gop; ++si->encode_frame_count; return VPX_CODEC_OK; } const char *vpx_svc_get_message(const SvcContext *svc_ctx) { const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return NULL; return si->message_buffer; } void *vpx_svc_get_buffer(const SvcContext *svc_ctx) { const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return NULL; return si->buffer; } size_t vpx_svc_get_frame_size(const SvcContext *svc_ctx) { const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return 0; return si->frame_size; } int vpx_svc_get_encode_frame_count(const SvcContext *svc_ctx) { const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return 0; return si->encode_frame_count; } int vpx_svc_is_keyframe(const SvcContext *svc_ctx) { const SvcInternal *const si = get_const_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return 0; return si->is_keyframe; } void vpx_svc_set_keyframe(SvcContext *svc_ctx) { SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return; si->frame_within_gop = 0; } static double calc_psnr(double d) { if (d == 0) return 100; return -10.0 * log(d) / log(10.0); } // dump accumulated statistics and reset accumulated values const char *vpx_svc_dump_statistics(SvcContext *svc_ctx) { int number_of_frames, number_of_keyframes, encode_frame_count; int i, j; uint32_t bytes_total = 0; double scale[COMPONENTS]; double psnr[COMPONENTS]; double mse[COMPONENTS]; double y_scale; SvcInternal *const si = get_svc_internal(svc_ctx); if (svc_ctx == NULL || si == NULL) return NULL; svc_log_reset(svc_ctx); encode_frame_count = si->encode_frame_count; if (si->encode_frame_count <= 0) return vpx_svc_get_message(svc_ctx); svc_log(svc_ctx, SVC_LOG_INFO, "\n"); number_of_keyframes = encode_frame_count / si->kf_dist + 1; for (i = 0; i < si->layers; ++i) { number_of_frames = encode_frame_count; if (svc_ctx->encoding_mode == ALT_INTER_LAYER_PREDICTION_IP && (i == 1 || i == 3)) { number_of_frames -= number_of_keyframes; } svc_log(svc_ctx, SVC_LOG_INFO, "Layer %d Average PSNR=[%2.3f, %2.3f, %2.3f, %2.3f], Bytes=[%u]\n", i, (double)si->psnr_sum[i][0] / number_of_frames, (double)si->psnr_sum[i][1] / number_of_frames, (double)si->psnr_sum[i][2] / number_of_frames, (double)si->psnr_sum[i][3] / number_of_frames, si->bytes_sum[i]); // the following psnr calculation is deduced from ffmpeg.c#print_report y_scale = si->width * si->height * 255.0 * 255.0 * number_of_frames; scale[1] = y_scale; scale[2] = scale[3] = y_scale / 4; // U or V scale[0] = y_scale * 1.5; // total for (j = 0; j < COMPONENTS; j++) { psnr[j] = calc_psnr(si->sse_sum[i][j] / scale[j]); mse[j] = si->sse_sum[i][j] * 255.0 * 255.0 / scale[j]; } svc_log(svc_ctx, SVC_LOG_INFO, "Layer %d Overall PSNR=[%2.3f, %2.3f, %2.3f, %2.3f]\n", i, psnr[0], psnr[1], psnr[2], psnr[3]); svc_log(svc_ctx, SVC_LOG_INFO, "Layer %d Overall MSE=[%2.3f, %2.3f, %2.3f, %2.3f]\n", i, mse[0], mse[1], mse[2], mse[3]); bytes_total += si->bytes_sum[i]; // clear sums for next time si->bytes_sum[i] = 0; for (j = 0; j < COMPONENTS; ++j) { si->psnr_sum[i][j] = 0; si->sse_sum[i][j] = 0; } } // only display statistics once si->encode_frame_count = 0; svc_log(svc_ctx, SVC_LOG_INFO, "Total Bytes=[%u]\n", bytes_total); return vpx_svc_get_message(svc_ctx); } void vpx_svc_release(SvcContext *svc_ctx) { SvcInternal *si; if (svc_ctx == NULL) return; // do not use get_svc_internal as it will unnecessarily allocate an // SvcInternal if it was not already allocated si = (SvcInternal *)svc_ctx->internal; if (si != NULL) { free(si->buffer); free(si); svc_ctx->internal = NULL; } }