aom/aomenc.c

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84 KiB
C
Исходник Обычный вид История

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/*
* Copyright (c) 2016, Alliance for Open Media. All rights reserved
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*
* This source code is subject to the terms of the BSD 2 Clause License and
* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
* was not distributed with this source code in the LICENSE file, you can
* obtain it at www.aomedia.org/license/software. If the Alliance for Open
* Media Patent License 1.0 was not distributed with this source code in the
* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
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*/
#include "./aomenc.h"
#include "./aom_config.h"
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#include <assert.h>
#include <limits.h>
#include <math.h>
#include <stdarg.h>
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#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#if CONFIG_LIBYUV
#include "third_party/libyuv/include/libyuv/scale.h"
#endif
#include "aom/aom_encoder.h"
#if CONFIG_DECODERS
#include "aom/aom_decoder.h"
#endif
#include "./args.h"
#include "./ivfenc.h"
#include "./tools_common.h"
#if CONFIG_AV1_ENCODER
#include "aom/aomcx.h"
#endif
#if CONFIG_AV1_DECODER
#include "aom/aomdx.h"
#endif
#include "./aomstats.h"
#include "./rate_hist.h"
#include "./warnings.h"
#include "aom/aom_integer.h"
#include "aom_ports/aom_timer.h"
#include "aom_ports/mem_ops.h"
#if CONFIG_WEBM_IO
#include "./webmenc.h"
#endif
#include "./y4minput.h"
/* Swallow warnings about unused results of fread/fwrite */
static size_t wrap_fread(void *ptr, size_t size, size_t nmemb, FILE *stream) {
return fread(ptr, size, nmemb, stream);
}
#define fread wrap_fread
static size_t wrap_fwrite(const void *ptr, size_t size, size_t nmemb,
FILE *stream) {
return fwrite(ptr, size, nmemb, stream);
}
#define fwrite wrap_fwrite
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static const char *exec_name;
static void warn_or_exit_on_errorv(aom_codec_ctx_t *ctx, int fatal,
const char *s, va_list ap) {
if (ctx->err) {
const char *detail = aom_codec_error_detail(ctx);
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vfprintf(stderr, s, ap);
fprintf(stderr, ": %s\n", aom_codec_error(ctx));
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if (detail) fprintf(stderr, " %s\n", detail);
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if (fatal) exit(EXIT_FAILURE);
}
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}
static void ctx_exit_on_error(aom_codec_ctx_t *ctx, const char *s, ...) {
va_list ap;
va_start(ap, s);
warn_or_exit_on_errorv(ctx, 1, s, ap);
va_end(ap);
}
static void warn_or_exit_on_error(aom_codec_ctx_t *ctx, int fatal,
const char *s, ...) {
va_list ap;
va_start(ap, s);
warn_or_exit_on_errorv(ctx, fatal, s, ap);
va_end(ap);
}
static int read_frame(struct AvxInputContext *input_ctx, aom_image_t *img) {
FILE *f = input_ctx->file;
y4m_input *y4m = &input_ctx->y4m;
int shortread = 0;
if (input_ctx->file_type == FILE_TYPE_Y4M) {
if (y4m_input_fetch_frame(y4m, f, img) < 1) return 0;
} else {
shortread = read_yuv_frame(input_ctx, img);
}
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return !shortread;
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}
static int file_is_y4m(const char detect[4]) {
if (memcmp(detect, "YUV4", 4) == 0) {
return 1;
}
return 0;
}
static int fourcc_is_ivf(const char detect[4]) {
if (memcmp(detect, "DKIF", 4) == 0) {
return 1;
}
return 0;
}
static const arg_def_t debugmode =
ARG_DEF("D", "debug", 0, "Debug mode (makes output deterministic)");
static const arg_def_t outputfile =
ARG_DEF("o", "output", 1, "Output filename");
static const arg_def_t use_yv12 =
ARG_DEF(NULL, "yv12", 0, "Input file is YV12 ");
static const arg_def_t use_i420 =
ARG_DEF(NULL, "i420", 0, "Input file is I420 (default)");
static const arg_def_t use_i422 =
ARG_DEF(NULL, "i422", 0, "Input file is I422");
static const arg_def_t use_i444 =
ARG_DEF(NULL, "i444", 0, "Input file is I444");
static const arg_def_t use_i440 =
ARG_DEF(NULL, "i440", 0, "Input file is I440");
static const arg_def_t codecarg = ARG_DEF(NULL, "codec", 1, "Codec to use");
static const arg_def_t passes =
ARG_DEF("p", "passes", 1, "Number of passes (1/2)");
static const arg_def_t pass_arg =
ARG_DEF(NULL, "pass", 1, "Pass to execute (1/2)");
static const arg_def_t fpf_name =
ARG_DEF(NULL, "fpf", 1, "First pass statistics file name");
#if CONFIG_FP_MB_STATS
static const arg_def_t fpmbf_name =
ARG_DEF(NULL, "fpmbf", 1, "First pass block statistics file name");
#endif
static const arg_def_t limit =
ARG_DEF(NULL, "limit", 1, "Stop encoding after n input frames");
static const arg_def_t skip =
ARG_DEF(NULL, "skip", 1, "Skip the first n input frames");
static const arg_def_t deadline =
ARG_DEF("d", "deadline", 1, "Deadline per frame (usec)");
static const arg_def_t good_dl =
ARG_DEF(NULL, "good", 0, "Use Good Quality Deadline");
static const arg_def_t rt_dl =
ARG_DEF(NULL, "rt", 0, "Use Realtime Quality Deadline");
static const arg_def_t quietarg =
ARG_DEF("q", "quiet", 0, "Do not print encode progress");
static const arg_def_t verbosearg =
ARG_DEF("v", "verbose", 0, "Show encoder parameters");
static const arg_def_t psnrarg =
ARG_DEF(NULL, "psnr", 0, "Show PSNR in status line");
static const struct arg_enum_list test_decode_enum[] = {
{ "off", TEST_DECODE_OFF },
{ "fatal", TEST_DECODE_FATAL },
{ "warn", TEST_DECODE_WARN },
{ NULL, 0 }
};
static const arg_def_t recontest = ARG_DEF_ENUM(
NULL, "test-decode", 1, "Test encode/decode mismatch", test_decode_enum);
static const arg_def_t framerate =
ARG_DEF(NULL, "fps", 1, "Stream frame rate (rate/scale)");
static const arg_def_t use_webm =
ARG_DEF(NULL, "webm", 0, "Output WebM (default when WebM IO is enabled)");
static const arg_def_t use_ivf = ARG_DEF(NULL, "ivf", 0, "Output IVF");
static const arg_def_t out_part =
ARG_DEF("P", "output-partitions", 0,
"Makes encoder output partitions. Requires IVF output!");
static const arg_def_t q_hist_n =
ARG_DEF(NULL, "q-hist", 1, "Show quantizer histogram (n-buckets)");
static const arg_def_t rate_hist_n =
ARG_DEF(NULL, "rate-hist", 1, "Show rate histogram (n-buckets)");
static const arg_def_t disable_warnings =
ARG_DEF(NULL, "disable-warnings", 0,
"Disable warnings about potentially incorrect encode settings.");
static const arg_def_t disable_warning_prompt =
ARG_DEF("y", "disable-warning-prompt", 0,
"Display warnings, but do not prompt user to continue.");
#if CONFIG_AOM_HIGHBITDEPTH
static const arg_def_t test16bitinternalarg = ARG_DEF(
NULL, "test-16bit-internal", 0, "Force use of 16 bit internal buffer");
static const struct arg_enum_list bitdepth_enum[] = {
{ "8", AOM_BITS_8 }, { "10", AOM_BITS_10 }, { "12", AOM_BITS_12 }, { NULL, 0 }
};
static const arg_def_t bitdeptharg = ARG_DEF_ENUM(
"b", "bit-depth", 1,
"Bit depth for codec (8 for version <=1, 10 or 12 for version 2)",
bitdepth_enum);
static const arg_def_t inbitdeptharg =
ARG_DEF(NULL, "input-bit-depth", 1, "Bit depth of input");
#endif
static const arg_def_t *main_args[] = { &debugmode,
&outputfile,
&codecarg,
&passes,
&pass_arg,
&fpf_name,
&limit,
&skip,
&deadline,
&good_dl,
&rt_dl,
&quietarg,
&verbosearg,
&psnrarg,
&use_webm,
&use_ivf,
&out_part,
&q_hist_n,
&rate_hist_n,
&disable_warnings,
&disable_warning_prompt,
&recontest,
NULL };
static const arg_def_t usage =
ARG_DEF("u", "usage", 1, "Usage profile number to use");
static const arg_def_t threads =
ARG_DEF("t", "threads", 1, "Max number of threads to use");
static const arg_def_t profile =
ARG_DEF(NULL, "profile", 1, "Bitstream profile number to use");
static const arg_def_t width = ARG_DEF("w", "width", 1, "Frame width");
static const arg_def_t height = ARG_DEF("h", "height", 1, "Frame height");
#if CONFIG_WEBM_IO
static const struct arg_enum_list stereo_mode_enum[] = {
{ "mono", STEREO_FORMAT_MONO },
{ "left-right", STEREO_FORMAT_LEFT_RIGHT },
{ "bottom-top", STEREO_FORMAT_BOTTOM_TOP },
{ "top-bottom", STEREO_FORMAT_TOP_BOTTOM },
{ "right-left", STEREO_FORMAT_RIGHT_LEFT },
{ NULL, 0 }
};
static const arg_def_t stereo_mode = ARG_DEF_ENUM(
NULL, "stereo-mode", 1, "Stereo 3D video format", stereo_mode_enum);
#endif
static const arg_def_t timebase = ARG_DEF(
NULL, "timebase", 1, "Output timestamp precision (fractional seconds)");
static const arg_def_t error_resilient =
ARG_DEF(NULL, "error-resilient", 1, "Enable error resiliency features");
static const arg_def_t lag_in_frames =
ARG_DEF(NULL, "lag-in-frames", 1, "Max number of frames to lag");
static const arg_def_t *global_args[] = { &use_yv12,
&use_i420,
&use_i422,
&use_i444,
&use_i440,
&usage,
&threads,
&profile,
&width,
&height,
#if CONFIG_WEBM_IO
&stereo_mode,
#endif
&timebase,
&framerate,
&error_resilient,
#if CONFIG_AOM_HIGHBITDEPTH
&test16bitinternalarg,
&bitdeptharg,
#endif
&lag_in_frames,
NULL };
static const arg_def_t dropframe_thresh =
ARG_DEF(NULL, "drop-frame", 1, "Temporal resampling threshold (buf %)");
static const arg_def_t resize_allowed =
ARG_DEF(NULL, "resize-allowed", 1, "Spatial resampling enabled (bool)");
static const arg_def_t resize_width =
ARG_DEF(NULL, "resize-width", 1, "Width of encoded frame");
static const arg_def_t resize_height =
ARG_DEF(NULL, "resize-height", 1, "Height of encoded frame");
static const arg_def_t resize_up_thresh =
ARG_DEF(NULL, "resize-up", 1, "Upscale threshold (buf %)");
static const arg_def_t resize_down_thresh =
ARG_DEF(NULL, "resize-down", 1, "Downscale threshold (buf %)");
static const struct arg_enum_list end_usage_enum[] = { { "vbr", AOM_VBR },
{ "cbr", AOM_CBR },
{ "cq", AOM_CQ },
{ "q", AOM_Q },
{ NULL, 0 } };
static const arg_def_t end_usage =
ARG_DEF_ENUM(NULL, "end-usage", 1, "Rate control mode", end_usage_enum);
static const arg_def_t target_bitrate =
ARG_DEF(NULL, "target-bitrate", 1, "Bitrate (kbps)");
static const arg_def_t min_quantizer =
ARG_DEF(NULL, "min-q", 1, "Minimum (best) quantizer");
static const arg_def_t max_quantizer =
ARG_DEF(NULL, "max-q", 1, "Maximum (worst) quantizer");
static const arg_def_t undershoot_pct =
ARG_DEF(NULL, "undershoot-pct", 1, "Datarate undershoot (min) target (%)");
static const arg_def_t overshoot_pct =
ARG_DEF(NULL, "overshoot-pct", 1, "Datarate overshoot (max) target (%)");
static const arg_def_t buf_sz =
ARG_DEF(NULL, "buf-sz", 1, "Client buffer size (ms)");
static const arg_def_t buf_initial_sz =
ARG_DEF(NULL, "buf-initial-sz", 1, "Client initial buffer size (ms)");
static const arg_def_t buf_optimal_sz =
ARG_DEF(NULL, "buf-optimal-sz", 1, "Client optimal buffer size (ms)");
static const arg_def_t *rc_args[] = {
&dropframe_thresh, &resize_allowed, &resize_width, &resize_height,
&resize_up_thresh, &resize_down_thresh, &end_usage, &target_bitrate,
&min_quantizer, &max_quantizer, &undershoot_pct, &overshoot_pct,
&buf_sz, &buf_initial_sz, &buf_optimal_sz, NULL
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};
static const arg_def_t bias_pct =
ARG_DEF(NULL, "bias-pct", 1, "CBR/VBR bias (0=CBR, 100=VBR)");
static const arg_def_t minsection_pct =
ARG_DEF(NULL, "minsection-pct", 1, "GOP min bitrate (% of target)");
static const arg_def_t maxsection_pct =
ARG_DEF(NULL, "maxsection-pct", 1, "GOP max bitrate (% of target)");
static const arg_def_t *rc_twopass_args[] = { &bias_pct, &minsection_pct,
&maxsection_pct, NULL };
static const arg_def_t kf_min_dist =
ARG_DEF(NULL, "kf-min-dist", 1, "Minimum keyframe interval (frames)");
static const arg_def_t kf_max_dist =
ARG_DEF(NULL, "kf-max-dist", 1, "Maximum keyframe interval (frames)");
static const arg_def_t kf_disabled =
ARG_DEF(NULL, "disable-kf", 0, "Disable keyframe placement");
static const arg_def_t *kf_args[] = { &kf_min_dist, &kf_max_dist, &kf_disabled,
NULL };
static const arg_def_t noise_sens =
ARG_DEF(NULL, "noise-sensitivity", 1, "Noise sensitivity (frames to blur)");
static const arg_def_t sharpness =
ARG_DEF(NULL, "sharpness", 1, "Loop filter sharpness (0..7)");
static const arg_def_t static_thresh =
ARG_DEF(NULL, "static-thresh", 1, "Motion detection threshold");
static const arg_def_t auto_altref =
ARG_DEF(NULL, "auto-alt-ref", 1, "Enable automatic alt reference frames");
static const arg_def_t arnr_maxframes =
ARG_DEF(NULL, "arnr-maxframes", 1, "AltRef max frames (0..15)");
static const arg_def_t arnr_strength =
ARG_DEF(NULL, "arnr-strength", 1, "AltRef filter strength (0..6)");
static const struct arg_enum_list tuning_enum[] = {
{ "psnr", AOM_TUNE_PSNR }, { "ssim", AOM_TUNE_SSIM }, { NULL, 0 }
};
static const arg_def_t tune_ssim =
ARG_DEF_ENUM(NULL, "tune", 1, "Material to favor", tuning_enum);
static const arg_def_t cq_level =
ARG_DEF(NULL, "cq-level", 1, "Constant/Constrained Quality level");
static const arg_def_t max_intra_rate_pct =
ARG_DEF(NULL, "max-intra-rate", 1, "Max I-frame bitrate (pct)");
#if CONFIG_AV1_ENCODER
static const arg_def_t cpu_used_av1 =
ARG_DEF(NULL, "cpu-used", 1, "CPU Used (-8..8)");
static const arg_def_t tile_cols =
ARG_DEF(NULL, "tile-columns", 1, "Number of tile columns to use, log2");
static const arg_def_t tile_rows =
ARG_DEF(NULL, "tile-rows", 1,
"Number of tile rows to use, log2 (set to 0 while threads > 1)");
#if CONFIG_DEPENDENT_HORZTILES
static const arg_def_t tile_dependent_rows =
ARG_DEF(NULL, "tile-dependent-rows", 1, "Enable dependent Tile rows");
#endif
#if CONFIG_LOOPFILTERING_ACROSS_TILES
static const arg_def_t tile_loopfilter = ARG_DEF(
NULL, "tile-loopfilter", 1, "Enable loop filter across tile boundary");
#endif // CONFIG_LOOPFILTERING_ACROSS_TILES
static const arg_def_t lossless =
ARG_DEF(NULL, "lossless", 1, "Lossless mode (0: false (default), 1: true)");
#if CONFIG_AOM_QM
static const arg_def_t enable_qm =
ARG_DEF(NULL, "enable-qm", 1,
"Enable quantisation matrices (0: false (default), 1: true)");
static const arg_def_t qm_min = ARG_DEF(
NULL, "qm-min", 1, "Min quant matrix flatness (0..15), default is 8");
static const arg_def_t qm_max = ARG_DEF(
NULL, "qm-max", 1, "Max quant matrix flatness (0..15), default is 16");
#endif
#if CONFIG_TILE_GROUPS
static const arg_def_t num_tg = ARG_DEF(
NULL, "num-tile-groups", 1, "Maximum number of tile groups, default is 1");
static const arg_def_t mtu_size =
ARG_DEF(NULL, "mtu-size", 1,
"MTU size for a tile group, default is 0 (no MTU targeting), "
"overrides maximum number of tile groups");
#endif
#if CONFIG_TEMPMV_SIGNALING
static const arg_def_t disable_tempmv = ARG_DEF(
NULL, "disable-tempmv", 1, "Disable temporal mv prediction (default is 0)");
#endif
static const arg_def_t frame_parallel_decoding =
ARG_DEF(NULL, "frame-parallel", 1,
"Enable frame parallel decodability features "
"(0: false (default), 1: true)");
#if CONFIG_DELTA_Q
static const arg_def_t aq_mode = ARG_DEF(
NULL, "aq-mode", 1,
"Adaptive quantization mode (0: off (default), 1: variance 2: complexity, "
"3: cyclic refresh, 4: delta quant)");
#else
static const arg_def_t aq_mode = ARG_DEF(
NULL, "aq-mode", 1,
"Adaptive quantization mode (0: off (default), 1: variance 2: complexity, "
"3: cyclic refresh)");
#endif
static const arg_def_t frame_periodic_boost =
ARG_DEF(NULL, "frame-boost", 1,
"Enable frame periodic boost (0: off (default), 1: on)");
static const arg_def_t gf_cbr_boost_pct = ARG_DEF(
NULL, "gf-cbr-boost", 1, "Boost for Golden Frame in CBR mode (pct)");
static const arg_def_t max_inter_rate_pct =
ARG_DEF(NULL, "max-inter-rate", 1, "Max P-frame bitrate (pct)");
static const arg_def_t min_gf_interval = ARG_DEF(
NULL, "min-gf-interval", 1,
"min gf/arf frame interval (default 0, indicating in-built behavior)");
static const arg_def_t max_gf_interval = ARG_DEF(
NULL, "max-gf-interval", 1,
"max gf/arf frame interval (default 0, indicating in-built behavior)");
static const struct arg_enum_list color_space_enum[] = {
{ "unknown", AOM_CS_UNKNOWN },
{ "bt601", AOM_CS_BT_601 },
{ "bt709", AOM_CS_BT_709 },
{ "smpte170", AOM_CS_SMPTE_170 },
{ "smpte240", AOM_CS_SMPTE_240 },
{ "bt2020", AOM_CS_BT_2020 },
{ "reserved", AOM_CS_RESERVED },
{ "sRGB", AOM_CS_SRGB },
{ NULL, 0 }
};
static const arg_def_t input_color_space =
ARG_DEF_ENUM(NULL, "color-space", 1, "The color space of input content:",
color_space_enum);
static const struct arg_enum_list tune_content_enum[] = {
{ "default", AOM_CONTENT_DEFAULT },
{ "screen", AOM_CONTENT_SCREEN },
{ NULL, 0 }
};
static const arg_def_t tune_content = ARG_DEF_ENUM(
NULL, "tune-content", 1, "Tune content type", tune_content_enum);
#endif
#if CONFIG_AV1_ENCODER
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
#if CONFIG_EXT_PARTITION
static const struct arg_enum_list superblock_size_enum[] = {
{ "dynamic", AOM_SUPERBLOCK_SIZE_DYNAMIC },
{ "64", AOM_SUPERBLOCK_SIZE_64X64 },
{ "128", AOM_SUPERBLOCK_SIZE_128X128 },
{ NULL, 0 }
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
};
static const arg_def_t superblock_size = ARG_DEF_ENUM(
NULL, "sb-size", 1, "Superblock size to use", superblock_size_enum);
#endif // CONFIG_EXT_PARTITION
static const arg_def_t *av1_args[] = { &cpu_used_av1,
&auto_altref,
&sharpness,
&static_thresh,
&tile_cols,
&tile_rows,
#if CONFIG_DEPENDENT_HORZTILES
&tile_dependent_rows,
#endif
#if CONFIG_LOOPFILTERING_ACROSS_TILES
&tile_loopfilter,
#endif // CONFIG_LOOPFILTERING_ACROSS_TILES
&arnr_maxframes,
&arnr_strength,
&tune_ssim,
&cq_level,
&max_intra_rate_pct,
&max_inter_rate_pct,
&gf_cbr_boost_pct,
&lossless,
#if CONFIG_AOM_QM
&enable_qm,
&qm_min,
&qm_max,
#endif
&frame_parallel_decoding,
&aq_mode,
&frame_periodic_boost,
&noise_sens,
&tune_content,
&input_color_space,
&min_gf_interval,
&max_gf_interval,
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
#if CONFIG_EXT_PARTITION
&superblock_size,
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
#endif // CONFIG_EXT_PARTITION
#if CONFIG_TILE_GROUPS
&num_tg,
&mtu_size,
#endif
#if CONFIG_TEMPMV_SIGNALING
&disable_tempmv,
#endif
#if CONFIG_AOM_HIGHBITDEPTH
&bitdeptharg,
&inbitdeptharg,
#endif // CONFIG_AOM_HIGHBITDEPTH
NULL };
static const int av1_arg_ctrl_map[] = { AOME_SET_CPUUSED,
AOME_SET_ENABLEAUTOALTREF,
AOME_SET_SHARPNESS,
AOME_SET_STATIC_THRESHOLD,
AV1E_SET_TILE_COLUMNS,
AV1E_SET_TILE_ROWS,
#if CONFIG_DEPENDENT_HORZTILES
AV1E_SET_TILE_DEPENDENT_ROWS,
#endif
#if CONFIG_LOOPFILTERING_ACROSS_TILES
AV1E_SET_TILE_LOOPFILTER,
#endif // CONFIG_LOOPFILTERING_ACROSS_TILES
AOME_SET_ARNR_MAXFRAMES,
AOME_SET_ARNR_STRENGTH,
AOME_SET_TUNING,
AOME_SET_CQ_LEVEL,
AOME_SET_MAX_INTRA_BITRATE_PCT,
AV1E_SET_MAX_INTER_BITRATE_PCT,
AV1E_SET_GF_CBR_BOOST_PCT,
AV1E_SET_LOSSLESS,
#if CONFIG_AOM_QM
AV1E_SET_ENABLE_QM,
AV1E_SET_QM_MIN,
AV1E_SET_QM_MAX,
#endif
AV1E_SET_FRAME_PARALLEL_DECODING,
AV1E_SET_AQ_MODE,
AV1E_SET_FRAME_PERIODIC_BOOST,
AV1E_SET_NOISE_SENSITIVITY,
AV1E_SET_TUNE_CONTENT,
AV1E_SET_COLOR_SPACE,
AV1E_SET_MIN_GF_INTERVAL,
AV1E_SET_MAX_GF_INTERVAL,
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
#if CONFIG_EXT_PARTITION
AV1E_SET_SUPERBLOCK_SIZE,
Make superblock size variable at the frame level. The uncompressed frame header contains a bit to signal whether the frame is encoded using 64x64 or 128x128 superblocks. This can vary between any 2 frames. vpxenc gained the --sb-size={64,128,dynamic} option, which allows the configuration of the superblock size used (default is dynamic). 64/128 will force the encoder to always use the specified superblock size. Dynamic would enable the encoder to choose the sb size for each frame, but this is not implemented yet (dynamic does the same as 128 for now). Constraints on tile sizes depend on the superblock size, the following is a summary of the current bitstream syntax and semantics: If both --enable-ext-tile is OFF and --enable-ext-partition is OFF: The tile coding in this case is the same as VP9. In particular, tiles have a minimum width of 256 pixels and a maximum width of 4096 pixels. The tile width must be multiples of 64 pixels (except for the rightmost tile column). There can be a maximum of 64 tile columns and 4 tile rows. If --enable-ext-tile is OFF and --enable-ext-partition is ON: Same constraints as above, except that tile width must be multiples of 128 pixels (except for the rightmost tile column). There is no change in the bitstream syntax used for coding the tile configuration if --enable-ext-tile is OFF. If --enable-ext-tile is ON and --enable-ext-partition is ON: This is the new large scale tile coding configuration. The minimum/maximum tile width and height are 64/4096 pixels. Tile width and height must be multiples of 64 pixels. The uncompressed header contains two 6 bit fields that hold the tile width/heigh in units of 64 pixels. The maximum number of tile rows/columns is only limited by the maximum frame size of 65536x65536 pixels that can be coded in the bitstream. This yields a maximum of 1024x1024 tile rows and columns (of 64x64 tiles in a 65536x65536 frame). If both --enable-ext-tile is ON and --enable-ext-partition is ON: Same applies as above, except that in the bitstream the 2 fields containing the tile width/height are in units of the superblock size, and the superblock size itself is also coded in the bitstream. If the uncompressed header signals the use of 64x64 superblocks, then the tile width/height fields are 6 bits wide and are in units of 64 pixels. If the uncompressed header signals the use of 128x128 superblocks, then the tile width/height fields are 5 bits wide and are in units of 128 pixels. The above is a summary of the bitstream. The user interface to vpxenc (and the equivalent encoder API) behaves a follows: If --enable-ext-tile is OFF: No change in the user interface. --tile-columns and --tile-rows specify the base 2 logarithm of the desired number of tile columns and tile rows. The actual number of tile rows and tile columns, and the particular tile width and tile height are computed by the codec ensuring all of the above constraints are respected. If --enable-ext-tile is ON, but --enable-ext-partition is OFF: No change in the user interface. --tile-columns and --tile-rows specify the WIDTH and HEIGHT of the tiles in unit of 64 pixels. The valid values are in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64. If both --enable-ext-tile is ON and --enable-ext-partition is ON: If --sb-size=64 (default): The user interface is the same as in the previous point. --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 64 pixels, in the range [1, 64] (which corresponds to [64, 4096] pixels in increments of 64). If --sb-size=128 or --sb-size=dynamic: --tile-columns and --tile-rows specify tile WIDTH and HEIGHT, in units of 128 pixels in the range [1, 32] (which corresponds to [128, 4096] pixels in increments of 128). Change-Id: Idc9beee1ad12ff1634e83671985d14c680f9179a
2016-03-24 16:56:05 +03:00
#endif // CONFIG_EXT_PARTITION
#if CONFIG_TILE_GROUPS
AV1E_SET_NUM_TG,
AV1E_SET_MTU,
#endif
#if CONFIG_TEMPMV_SIGNALING
AV1E_SET_DISABLE_TEMPMV,
#endif
0 };
#endif
2010-05-18 19:58:33 +04:00
static const arg_def_t *no_args[] = { NULL };
void usage_exit(void) {
int i;
const int num_encoder = get_aom_encoder_count();
fprintf(stderr, "Usage: %s <options> -o dst_filename src_filename \n",
exec_name);
fprintf(stderr, "\nOptions:\n");
arg_show_usage(stderr, main_args);
fprintf(stderr, "\nEncoder Global Options:\n");
arg_show_usage(stderr, global_args);
fprintf(stderr, "\nRate Control Options:\n");
arg_show_usage(stderr, rc_args);
fprintf(stderr, "\nTwopass Rate Control Options:\n");
arg_show_usage(stderr, rc_twopass_args);
fprintf(stderr, "\nKeyframe Placement Options:\n");
arg_show_usage(stderr, kf_args);
#if CONFIG_AV1_ENCODER
fprintf(stderr, "\nAV1 Specific Options:\n");
arg_show_usage(stderr, av1_args);
2010-05-18 19:58:33 +04:00
#endif
fprintf(stderr,
"\nStream timebase (--timebase):\n"
" The desired precision of timestamps in the output, expressed\n"
" in fractional seconds. Default is 1/1000.\n");
fprintf(stderr, "\nIncluded encoders:\n\n");
for (i = 0; i < num_encoder; ++i) {
const AvxInterface *const encoder = get_aom_encoder_by_index(i);
const char *defstr = (i == (num_encoder - 1)) ? "(default)" : "";
fprintf(stderr, " %-6s - %s %s\n", encoder->name,
aom_codec_iface_name(encoder->codec_interface()), defstr);
}
fprintf(stderr, "\n ");
fprintf(stderr, "Use --codec to switch to a non-default encoder.\n\n");
exit(EXIT_FAILURE);
2010-05-18 19:58:33 +04:00
}
#define mmin(a, b) ((a) < (b) ? (a) : (b))
#if CONFIG_AOM_HIGHBITDEPTH
static void find_mismatch_high(const aom_image_t *const img1,
const aom_image_t *const img2, int yloc[4],
int uloc[4], int vloc[4]) {
uint16_t *plane1, *plane2;
uint32_t stride1, stride2;
const uint32_t bsize = 64;
const uint32_t bsizey = bsize >> img1->y_chroma_shift;
const uint32_t bsizex = bsize >> img1->x_chroma_shift;
const uint32_t c_w =
(img1->d_w + img1->x_chroma_shift) >> img1->x_chroma_shift;
const uint32_t c_h =
(img1->d_h + img1->y_chroma_shift) >> img1->y_chroma_shift;
int match = 1;
uint32_t i, j;
yloc[0] = yloc[1] = yloc[2] = yloc[3] = -1;
plane1 = (uint16_t *)img1->planes[AOM_PLANE_Y];
plane2 = (uint16_t *)img2->planes[AOM_PLANE_Y];
stride1 = img1->stride[AOM_PLANE_Y] / 2;
stride2 = img2->stride[AOM_PLANE_Y] / 2;
for (i = 0, match = 1; match && i < img1->d_h; i += bsize) {
for (j = 0; match && j < img1->d_w; j += bsize) {
int k, l;
const int si = mmin(i + bsize, img1->d_h) - i;
const int sj = mmin(j + bsize, img1->d_w) - j;
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(plane1 + (i + k) * stride1 + j + l) !=
*(plane2 + (i + k) * stride2 + j + l)) {
yloc[0] = i + k;
yloc[1] = j + l;
yloc[2] = *(plane1 + (i + k) * stride1 + j + l);
yloc[3] = *(plane2 + (i + k) * stride2 + j + l);
match = 0;
break;
}
}
}
}
}
uloc[0] = uloc[1] = uloc[2] = uloc[3] = -1;
plane1 = (uint16_t *)img1->planes[AOM_PLANE_U];
plane2 = (uint16_t *)img2->planes[AOM_PLANE_U];
stride1 = img1->stride[AOM_PLANE_U] / 2;
stride2 = img2->stride[AOM_PLANE_U] / 2;
for (i = 0, match = 1; match && i < c_h; i += bsizey) {
for (j = 0; match && j < c_w; j += bsizex) {
int k, l;
const int si = mmin(i + bsizey, c_h - i);
const int sj = mmin(j + bsizex, c_w - j);
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(plane1 + (i + k) * stride1 + j + l) !=
*(plane2 + (i + k) * stride2 + j + l)) {
uloc[0] = i + k;
uloc[1] = j + l;
uloc[2] = *(plane1 + (i + k) * stride1 + j + l);
uloc[3] = *(plane2 + (i + k) * stride2 + j + l);
match = 0;
break;
}
}
}
}
}
vloc[0] = vloc[1] = vloc[2] = vloc[3] = -1;
plane1 = (uint16_t *)img1->planes[AOM_PLANE_V];
plane2 = (uint16_t *)img2->planes[AOM_PLANE_V];
stride1 = img1->stride[AOM_PLANE_V] / 2;
stride2 = img2->stride[AOM_PLANE_V] / 2;
for (i = 0, match = 1; match && i < c_h; i += bsizey) {
for (j = 0; match && j < c_w; j += bsizex) {
int k, l;
const int si = mmin(i + bsizey, c_h - i);
const int sj = mmin(j + bsizex, c_w - j);
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(plane1 + (i + k) * stride1 + j + l) !=
*(plane2 + (i + k) * stride2 + j + l)) {
vloc[0] = i + k;
vloc[1] = j + l;
vloc[2] = *(plane1 + (i + k) * stride1 + j + l);
vloc[3] = *(plane2 + (i + k) * stride2 + j + l);
match = 0;
break;
}
}
}
}
}
}
#endif
static void find_mismatch(const aom_image_t *const img1,
const aom_image_t *const img2, int yloc[4],
int uloc[4], int vloc[4]) {
const uint32_t bsize = 64;
const uint32_t bsizey = bsize >> img1->y_chroma_shift;
const uint32_t bsizex = bsize >> img1->x_chroma_shift;
const uint32_t c_w =
(img1->d_w + img1->x_chroma_shift) >> img1->x_chroma_shift;
const uint32_t c_h =
(img1->d_h + img1->y_chroma_shift) >> img1->y_chroma_shift;
int match = 1;
uint32_t i, j;
yloc[0] = yloc[1] = yloc[2] = yloc[3] = -1;
for (i = 0, match = 1; match && i < img1->d_h; i += bsize) {
for (j = 0; match && j < img1->d_w; j += bsize) {
int k, l;
const int si = mmin(i + bsize, img1->d_h) - i;
const int sj = mmin(j + bsize, img1->d_w) - j;
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(img1->planes[AOM_PLANE_Y] +
(i + k) * img1->stride[AOM_PLANE_Y] + j + l) !=
*(img2->planes[AOM_PLANE_Y] +
(i + k) * img2->stride[AOM_PLANE_Y] + j + l)) {
yloc[0] = i + k;
yloc[1] = j + l;
yloc[2] = *(img1->planes[AOM_PLANE_Y] +
(i + k) * img1->stride[AOM_PLANE_Y] + j + l);
yloc[3] = *(img2->planes[AOM_PLANE_Y] +
(i + k) * img2->stride[AOM_PLANE_Y] + j + l);
match = 0;
break;
}
}
}
}
}
uloc[0] = uloc[1] = uloc[2] = uloc[3] = -1;
for (i = 0, match = 1; match && i < c_h; i += bsizey) {
for (j = 0; match && j < c_w; j += bsizex) {
int k, l;
const int si = mmin(i + bsizey, c_h - i);
const int sj = mmin(j + bsizex, c_w - j);
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(img1->planes[AOM_PLANE_U] +
(i + k) * img1->stride[AOM_PLANE_U] + j + l) !=
*(img2->planes[AOM_PLANE_U] +
(i + k) * img2->stride[AOM_PLANE_U] + j + l)) {
uloc[0] = i + k;
uloc[1] = j + l;
uloc[2] = *(img1->planes[AOM_PLANE_U] +
(i + k) * img1->stride[AOM_PLANE_U] + j + l);
uloc[3] = *(img2->planes[AOM_PLANE_U] +
(i + k) * img2->stride[AOM_PLANE_U] + j + l);
match = 0;
break;
}
}
}
}
}
vloc[0] = vloc[1] = vloc[2] = vloc[3] = -1;
for (i = 0, match = 1; match && i < c_h; i += bsizey) {
for (j = 0; match && j < c_w; j += bsizex) {
int k, l;
const int si = mmin(i + bsizey, c_h - i);
const int sj = mmin(j + bsizex, c_w - j);
for (k = 0; match && k < si; ++k) {
for (l = 0; match && l < sj; ++l) {
if (*(img1->planes[AOM_PLANE_V] +
(i + k) * img1->stride[AOM_PLANE_V] + j + l) !=
*(img2->planes[AOM_PLANE_V] +
(i + k) * img2->stride[AOM_PLANE_V] + j + l)) {
vloc[0] = i + k;
vloc[1] = j + l;
vloc[2] = *(img1->planes[AOM_PLANE_V] +
(i + k) * img1->stride[AOM_PLANE_V] + j + l);
vloc[3] = *(img2->planes[AOM_PLANE_V] +
(i + k) * img2->stride[AOM_PLANE_V] + j + l);
match = 0;
break;
}
}
}
}
}
}
static int compare_img(const aom_image_t *const img1,
const aom_image_t *const img2) {
uint32_t l_w = img1->d_w;
uint32_t c_w = (img1->d_w + img1->x_chroma_shift) >> img1->x_chroma_shift;
const uint32_t c_h =
(img1->d_h + img1->y_chroma_shift) >> img1->y_chroma_shift;
uint32_t i;
int match = 1;
match &= (img1->fmt == img2->fmt);
match &= (img1->d_w == img2->d_w);
match &= (img1->d_h == img2->d_h);
#if CONFIG_AOM_HIGHBITDEPTH
if (img1->fmt & AOM_IMG_FMT_HIGHBITDEPTH) {
l_w *= 2;
c_w *= 2;
}
#endif
for (i = 0; i < img1->d_h; ++i)
match &= (memcmp(img1->planes[AOM_PLANE_Y] + i * img1->stride[AOM_PLANE_Y],
img2->planes[AOM_PLANE_Y] + i * img2->stride[AOM_PLANE_Y],
l_w) == 0);
for (i = 0; i < c_h; ++i)
match &= (memcmp(img1->planes[AOM_PLANE_U] + i * img1->stride[AOM_PLANE_U],
img2->planes[AOM_PLANE_U] + i * img2->stride[AOM_PLANE_U],
c_w) == 0);
for (i = 0; i < c_h; ++i)
match &= (memcmp(img1->planes[AOM_PLANE_V] + i * img1->stride[AOM_PLANE_V],
img2->planes[AOM_PLANE_V] + i * img2->stride[AOM_PLANE_V],
c_w) == 0);
return match;
}
#define NELEMENTS(x) (sizeof(x) / sizeof(x[0]))
#if CONFIG_AV1_ENCODER
#define ARG_CTRL_CNT_MAX NELEMENTS(av1_arg_ctrl_map)
#endif
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#if !CONFIG_WEBM_IO
typedef int stereo_format_t;
struct WebmOutputContext {
int debug;
};
#endif
/* Per-stream configuration */
struct stream_config {
struct aom_codec_enc_cfg cfg;
const char *out_fn;
const char *stats_fn;
#if CONFIG_FP_MB_STATS
const char *fpmb_stats_fn;
#endif
stereo_format_t stereo_fmt;
int arg_ctrls[ARG_CTRL_CNT_MAX][2];
int arg_ctrl_cnt;
int write_webm;
#if CONFIG_AOM_HIGHBITDEPTH
// whether to use 16bit internal buffers
int use_16bit_internal;
#endif
};
struct stream_state {
int index;
struct stream_state *next;
struct stream_config config;
FILE *file;
struct rate_hist *rate_hist;
struct WebmOutputContext webm_ctx;
uint64_t psnr_sse_total;
uint64_t psnr_samples_total;
double psnr_totals[4];
int psnr_count;
int counts[64];
aom_codec_ctx_t encoder;
unsigned int frames_out;
uint64_t cx_time;
size_t nbytes;
stats_io_t stats;
#if CONFIG_FP_MB_STATS
stats_io_t fpmb_stats;
#endif
struct aom_image *img;
aom_codec_ctx_t decoder;
int mismatch_seen;
};
static void validate_positive_rational(const char *msg,
struct aom_rational *rat) {
if (rat->den < 0) {
rat->num *= -1;
rat->den *= -1;
}
if (rat->num < 0) die("Error: %s must be positive\n", msg);
if (!rat->den) die("Error: %s has zero denominator\n", msg);
}
static void parse_global_config(struct AvxEncoderConfig *global, char **argv) {
char **argi, **argj;
struct arg arg;
const int num_encoder = get_aom_encoder_count();
if (num_encoder < 1) die("Error: no valid encoder available\n");
/* Initialize default parameters */
memset(global, 0, sizeof(*global));
global->codec = get_aom_encoder_by_index(num_encoder - 1);
global->passes = 0;
global->color_type = I420;
/* Assign default deadline to good quality */
global->deadline = AOM_DL_GOOD_QUALITY;
for (argi = argj = argv; (*argj = *argi); argi += arg.argv_step) {
arg.argv_step = 1;
if (arg_match(&arg, &codecarg, argi)) {
global->codec = get_aom_encoder_by_name(arg.val);
if (!global->codec)
die("Error: Unrecognized argument (%s) to --codec\n", arg.val);
} else if (arg_match(&arg, &passes, argi)) {
global->passes = arg_parse_uint(&arg);
if (global->passes < 1 || global->passes > 2)
die("Error: Invalid number of passes (%d)\n", global->passes);
} else if (arg_match(&arg, &pass_arg, argi)) {
global->pass = arg_parse_uint(&arg);
if (global->pass < 1 || global->pass > 2)
die("Error: Invalid pass selected (%d)\n", global->pass);
} else if (arg_match(&arg, &usage, argi))
global->usage = arg_parse_uint(&arg);
else if (arg_match(&arg, &deadline, argi))
global->deadline = arg_parse_uint(&arg);
else if (arg_match(&arg, &good_dl, argi))
global->deadline = AOM_DL_GOOD_QUALITY;
else if (arg_match(&arg, &rt_dl, argi))
global->deadline = AOM_DL_REALTIME;
else if (arg_match(&arg, &use_yv12, argi))
global->color_type = YV12;
else if (arg_match(&arg, &use_i420, argi))
global->color_type = I420;
else if (arg_match(&arg, &use_i422, argi))
global->color_type = I422;
else if (arg_match(&arg, &use_i444, argi))
global->color_type = I444;
else if (arg_match(&arg, &use_i440, argi))
global->color_type = I440;
else if (arg_match(&arg, &quietarg, argi))
global->quiet = 1;
else if (arg_match(&arg, &verbosearg, argi))
global->verbose = 1;
else if (arg_match(&arg, &limit, argi))
global->limit = arg_parse_uint(&arg);
else if (arg_match(&arg, &skip, argi))
global->skip_frames = arg_parse_uint(&arg);
else if (arg_match(&arg, &psnrarg, argi))
global->show_psnr = 1;
else if (arg_match(&arg, &recontest, argi))
global->test_decode = arg_parse_enum_or_int(&arg);
else if (arg_match(&arg, &framerate, argi)) {
global->framerate = arg_parse_rational(&arg);
validate_positive_rational(arg.name, &global->framerate);
global->have_framerate = 1;
} else if (arg_match(&arg, &out_part, argi))
global->out_part = 1;
else if (arg_match(&arg, &debugmode, argi))
global->debug = 1;
else if (arg_match(&arg, &q_hist_n, argi))
global->show_q_hist_buckets = arg_parse_uint(&arg);
else if (arg_match(&arg, &rate_hist_n, argi))
global->show_rate_hist_buckets = arg_parse_uint(&arg);
else if (arg_match(&arg, &disable_warnings, argi))
global->disable_warnings = 1;
else if (arg_match(&arg, &disable_warning_prompt, argi))
global->disable_warning_prompt = 1;
else
argj++;
}
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if (global->pass) {
/* DWIM: Assume the user meant passes=2 if pass=2 is specified */
if (global->pass > global->passes) {
warn("Assuming --pass=%d implies --passes=%d\n", global->pass,
global->pass);
global->passes = global->pass;
}
}
/* Validate global config */
if (global->passes == 0) {
#if CONFIG_AV1_ENCODER
// Make default AV1 passes = 2 until there is a better quality 1-pass
// encoder
if (global->codec != NULL && global->codec->name != NULL)
global->passes = (strcmp(global->codec->name, "av1") == 0 &&
global->deadline != AOM_DL_REALTIME)
? 2
: 1;
#else
global->passes = 1;
#endif
}
if (global->deadline == AOM_DL_REALTIME && global->passes > 1) {
warn("Enforcing one-pass encoding in realtime mode\n");
global->passes = 1;
}
}
static void open_input_file(struct AvxInputContext *input) {
/* Parse certain options from the input file, if possible */
input->file = strcmp(input->filename, "-") ? fopen(input->filename, "rb")
: set_binary_mode(stdin);
if (!input->file) fatal("Failed to open input file");
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if (!fseeko(input->file, 0, SEEK_END)) {
/* Input file is seekable. Figure out how long it is, so we can get
* progress info.
*/
input->length = ftello(input->file);
rewind(input->file);
}
/* Default to 1:1 pixel aspect ratio. */
input->pixel_aspect_ratio.numerator = 1;
input->pixel_aspect_ratio.denominator = 1;
/* For RAW input sources, these bytes will applied on the first frame
* in read_frame().
*/
input->detect.buf_read = fread(input->detect.buf, 1, 4, input->file);
input->detect.position = 0;
if (input->detect.buf_read == 4 && file_is_y4m(input->detect.buf)) {
if (y4m_input_open(&input->y4m, input->file, input->detect.buf, 4,
input->only_i420) >= 0) {
input->file_type = FILE_TYPE_Y4M;
input->width = input->y4m.pic_w;
input->height = input->y4m.pic_h;
input->pixel_aspect_ratio.numerator = input->y4m.par_n;
input->pixel_aspect_ratio.denominator = input->y4m.par_d;
input->framerate.numerator = input->y4m.fps_n;
input->framerate.denominator = input->y4m.fps_d;
input->fmt = input->y4m.aom_fmt;
input->bit_depth = input->y4m.bit_depth;
} else
fatal("Unsupported Y4M stream.");
} else if (input->detect.buf_read == 4 && fourcc_is_ivf(input->detect.buf)) {
fatal("IVF is not supported as input.");
} else {
input->file_type = FILE_TYPE_RAW;
}
}
static void close_input_file(struct AvxInputContext *input) {
fclose(input->file);
if (input->file_type == FILE_TYPE_Y4M) y4m_input_close(&input->y4m);
}
static struct stream_state *new_stream(struct AvxEncoderConfig *global,
struct stream_state *prev) {
struct stream_state *stream;
stream = calloc(1, sizeof(*stream));
if (stream == NULL) {
fatal("Failed to allocate new stream.");
}
if (prev) {
memcpy(stream, prev, sizeof(*stream));
stream->index++;
prev->next = stream;
} else {
aom_codec_err_t res;
/* Populate encoder configuration */
res = aom_codec_enc_config_default(global->codec->codec_interface(),
&stream->config.cfg, global->usage);
if (res) fatal("Failed to get config: %s\n", aom_codec_err_to_string(res));
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/* Change the default timebase to a high enough value so that the
* encoder will always create strictly increasing timestamps.
*/
stream->config.cfg.g_timebase.den = 1000;
/* Never use the library's default resolution, require it be parsed
* from the file or set on the command line.
*/
stream->config.cfg.g_w = 0;
stream->config.cfg.g_h = 0;
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/* Initialize remaining stream parameters */
stream->config.write_webm = 1;
#if CONFIG_WEBM_IO
stream->config.stereo_fmt = STEREO_FORMAT_MONO;
stream->webm_ctx.last_pts_ns = -1;
stream->webm_ctx.writer = NULL;
stream->webm_ctx.segment = NULL;
#endif
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/* Allows removal of the application version from the EBML tags */
stream->webm_ctx.debug = global->debug;
/* Default lag_in_frames is 0 in realtime mode */
if (global->deadline == AOM_DL_REALTIME)
stream->config.cfg.g_lag_in_frames = 0;
}
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/* Output files must be specified for each stream */
stream->config.out_fn = NULL;
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stream->next = NULL;
return stream;
}
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static int parse_stream_params(struct AvxEncoderConfig *global,
struct stream_state *stream, char **argv) {
char **argi, **argj;
struct arg arg;
static const arg_def_t **ctrl_args = no_args;
static const int *ctrl_args_map = NULL;
struct stream_config *config = &stream->config;
int eos_mark_found = 0;
#if CONFIG_AOM_HIGHBITDEPTH
int test_16bit_internal = 0;
#endif
// Handle codec specific options
if (0) {
#if CONFIG_AV1_ENCODER
} else if (strcmp(global->codec->name, "av1") == 0) {
// TODO(jingning): Reuse AV1 specific encoder configuration parameters.
// Consider to expand this set for AV1 encoder control.
ctrl_args = av1_args;
ctrl_args_map = av1_arg_ctrl_map;
#endif
}
for (argi = argj = argv; (*argj = *argi); argi += arg.argv_step) {
arg.argv_step = 1;
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/* Once we've found an end-of-stream marker (--) we want to continue
* shifting arguments but not consuming them.
*/
if (eos_mark_found) {
argj++;
continue;
} else if (!strcmp(*argj, "--")) {
eos_mark_found = 1;
continue;
}
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if (arg_match(&arg, &outputfile, argi)) {
config->out_fn = arg.val;
} else if (arg_match(&arg, &fpf_name, argi)) {
config->stats_fn = arg.val;
#if CONFIG_FP_MB_STATS
} else if (arg_match(&arg, &fpmbf_name, argi)) {
config->fpmb_stats_fn = arg.val;
#endif
} else if (arg_match(&arg, &use_webm, argi)) {
#if CONFIG_WEBM_IO
config->write_webm = 1;
#else
die("Error: --webm specified but webm is disabled.");
#endif
} else if (arg_match(&arg, &use_ivf, argi)) {
config->write_webm = 0;
} else if (arg_match(&arg, &threads, argi)) {
config->cfg.g_threads = arg_parse_uint(&arg);
} else if (arg_match(&arg, &profile, argi)) {
config->cfg.g_profile = arg_parse_uint(&arg);
} else if (arg_match(&arg, &width, argi)) {
config->cfg.g_w = arg_parse_uint(&arg);
} else if (arg_match(&arg, &height, argi)) {
config->cfg.g_h = arg_parse_uint(&arg);
#if CONFIG_AOM_HIGHBITDEPTH
} else if (arg_match(&arg, &bitdeptharg, argi)) {
config->cfg.g_bit_depth = arg_parse_enum_or_int(&arg);
} else if (arg_match(&arg, &inbitdeptharg, argi)) {
config->cfg.g_input_bit_depth = arg_parse_uint(&arg);
#endif
#if CONFIG_WEBM_IO
} else if (arg_match(&arg, &stereo_mode, argi)) {
config->stereo_fmt = arg_parse_enum_or_int(&arg);
#endif
} else if (arg_match(&arg, &timebase, argi)) {
config->cfg.g_timebase = arg_parse_rational(&arg);
validate_positive_rational(arg.name, &config->cfg.g_timebase);
} else if (arg_match(&arg, &error_resilient, argi)) {
config->cfg.g_error_resilient = arg_parse_uint(&arg);
} else if (arg_match(&arg, &lag_in_frames, argi)) {
config->cfg.g_lag_in_frames = arg_parse_uint(&arg);
if (global->deadline == AOM_DL_REALTIME &&
config->cfg.g_lag_in_frames != 0) {
warn("non-zero %s option ignored in realtime mode.\n", arg.name);
config->cfg.g_lag_in_frames = 0;
}
} else if (arg_match(&arg, &dropframe_thresh, argi)) {
config->cfg.rc_dropframe_thresh = arg_parse_uint(&arg);
} else if (arg_match(&arg, &resize_allowed, argi)) {
config->cfg.rc_resize_allowed = arg_parse_uint(&arg);
} else if (arg_match(&arg, &resize_width, argi)) {
config->cfg.rc_scaled_width = arg_parse_uint(&arg);
} else if (arg_match(&arg, &resize_height, argi)) {
config->cfg.rc_scaled_height = arg_parse_uint(&arg);
} else if (arg_match(&arg, &resize_up_thresh, argi)) {
config->cfg.rc_resize_up_thresh = arg_parse_uint(&arg);
} else if (arg_match(&arg, &resize_down_thresh, argi)) {
config->cfg.rc_resize_down_thresh = arg_parse_uint(&arg);
} else if (arg_match(&arg, &end_usage, argi)) {
config->cfg.rc_end_usage = arg_parse_enum_or_int(&arg);
} else if (arg_match(&arg, &target_bitrate, argi)) {
config->cfg.rc_target_bitrate = arg_parse_uint(&arg);
} else if (arg_match(&arg, &min_quantizer, argi)) {
config->cfg.rc_min_quantizer = arg_parse_uint(&arg);
} else if (arg_match(&arg, &max_quantizer, argi)) {
config->cfg.rc_max_quantizer = arg_parse_uint(&arg);
} else if (arg_match(&arg, &undershoot_pct, argi)) {
config->cfg.rc_undershoot_pct = arg_parse_uint(&arg);
} else if (arg_match(&arg, &overshoot_pct, argi)) {
config->cfg.rc_overshoot_pct = arg_parse_uint(&arg);
} else if (arg_match(&arg, &buf_sz, argi)) {
config->cfg.rc_buf_sz = arg_parse_uint(&arg);
} else if (arg_match(&arg, &buf_initial_sz, argi)) {
config->cfg.rc_buf_initial_sz = arg_parse_uint(&arg);
} else if (arg_match(&arg, &buf_optimal_sz, argi)) {
config->cfg.rc_buf_optimal_sz = arg_parse_uint(&arg);
} else if (arg_match(&arg, &bias_pct, argi)) {
config->cfg.rc_2pass_vbr_bias_pct = arg_parse_uint(&arg);
if (global->passes < 2)
warn("option %s ignored in one-pass mode.\n", arg.name);
} else if (arg_match(&arg, &minsection_pct, argi)) {
config->cfg.rc_2pass_vbr_minsection_pct = arg_parse_uint(&arg);
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if (global->passes < 2)
warn("option %s ignored in one-pass mode.\n", arg.name);
} else if (arg_match(&arg, &maxsection_pct, argi)) {
config->cfg.rc_2pass_vbr_maxsection_pct = arg_parse_uint(&arg);
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if (global->passes < 2)
warn("option %s ignored in one-pass mode.\n", arg.name);
} else if (arg_match(&arg, &kf_min_dist, argi)) {
config->cfg.kf_min_dist = arg_parse_uint(&arg);
} else if (arg_match(&arg, &kf_max_dist, argi)) {
config->cfg.kf_max_dist = arg_parse_uint(&arg);
} else if (arg_match(&arg, &kf_disabled, argi)) {
config->cfg.kf_mode = AOM_KF_DISABLED;
#if CONFIG_AOM_HIGHBITDEPTH
} else if (arg_match(&arg, &test16bitinternalarg, argi)) {
if (strcmp(global->codec->name, "av1") == 0 ||
strcmp(global->codec->name, "av1") == 0) {
test_16bit_internal = 1;
}
#endif
} else {
int i, match = 0;
for (i = 0; ctrl_args[i]; i++) {
if (arg_match(&arg, ctrl_args[i], argi)) {
int j;
match = 1;
/* Point either to the next free element or the first
* instance of this control.
*/
for (j = 0; j < config->arg_ctrl_cnt; j++)
if (ctrl_args_map != NULL &&
config->arg_ctrls[j][0] == ctrl_args_map[i])
break;
/* Update/insert */
assert(j < (int)ARG_CTRL_CNT_MAX);
if (ctrl_args_map != NULL && j < (int)ARG_CTRL_CNT_MAX) {
config->arg_ctrls[j][0] = ctrl_args_map[i];
config->arg_ctrls[j][1] = arg_parse_enum_or_int(&arg);
if (j == config->arg_ctrl_cnt) config->arg_ctrl_cnt++;
}
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}
}
if (!match) argj++;
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}
}
#if CONFIG_AOM_HIGHBITDEPTH
if (strcmp(global->codec->name, "av1") == 0 ||
strcmp(global->codec->name, "av1") == 0) {
config->use_16bit_internal =
test_16bit_internal | (config->cfg.g_profile > 1);
}
#endif
return eos_mark_found;
}
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#define FOREACH_STREAM(func) \
do { \
struct stream_state *stream; \
for (stream = streams; stream; stream = stream->next) { \
func; \
} \
} while (0)
static void validate_stream_config(const struct stream_state *stream,
const struct AvxEncoderConfig *global) {
const struct stream_state *streami;
(void)global;
if (!stream->config.cfg.g_w || !stream->config.cfg.g_h)
fatal(
"Stream %d: Specify stream dimensions with --width (-w) "
" and --height (-h)",
stream->index);
// Check that the codec bit depth is greater than the input bit depth.
if (stream->config.cfg.g_input_bit_depth >
(unsigned int)stream->config.cfg.g_bit_depth) {
fatal("Stream %d: codec bit depth (%d) less than input bit depth (%d)",
stream->index, (int)stream->config.cfg.g_bit_depth,
stream->config.cfg.g_input_bit_depth);
}
for (streami = stream; streami; streami = streami->next) {
/* All streams require output files */
if (!streami->config.out_fn)
fatal("Stream %d: Output file is required (specify with -o)",
streami->index);
/* Check for two streams outputting to the same file */
if (streami != stream) {
const char *a = stream->config.out_fn;
const char *b = streami->config.out_fn;
if (!strcmp(a, b) && strcmp(a, "/dev/null") && strcmp(a, ":nul"))
fatal("Stream %d: duplicate output file (from stream %d)",
streami->index, stream->index);
}
/* Check for two streams sharing a stats file. */
if (streami != stream) {
const char *a = stream->config.stats_fn;
const char *b = streami->config.stats_fn;
if (a && b && !strcmp(a, b))
fatal("Stream %d: duplicate stats file (from stream %d)",
streami->index, stream->index);
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}
#if CONFIG_FP_MB_STATS
/* Check for two streams sharing a mb stats file. */
if (streami != stream) {
const char *a = stream->config.fpmb_stats_fn;
const char *b = streami->config.fpmb_stats_fn;
if (a && b && !strcmp(a, b))
fatal("Stream %d: duplicate mb stats file (from stream %d)",
streami->index, stream->index);
}
#endif
}
}
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static void set_stream_dimensions(struct stream_state *stream, unsigned int w,
unsigned int h) {
if (!stream->config.cfg.g_w) {
if (!stream->config.cfg.g_h)
stream->config.cfg.g_w = w;
else
stream->config.cfg.g_w = w * stream->config.cfg.g_h / h;
}
if (!stream->config.cfg.g_h) {
stream->config.cfg.g_h = h * stream->config.cfg.g_w / w;
}
}
static const char *file_type_to_string(enum VideoFileType t) {
switch (t) {
case FILE_TYPE_RAW: return "RAW";
case FILE_TYPE_Y4M: return "Y4M";
default: return "Other";
}
}
static const char *image_format_to_string(aom_img_fmt_t f) {
switch (f) {
case AOM_IMG_FMT_I420: return "I420";
case AOM_IMG_FMT_I422: return "I422";
case AOM_IMG_FMT_I444: return "I444";
case AOM_IMG_FMT_I440: return "I440";
case AOM_IMG_FMT_YV12: return "YV12";
case AOM_IMG_FMT_I42016: return "I42016";
case AOM_IMG_FMT_I42216: return "I42216";
case AOM_IMG_FMT_I44416: return "I44416";
case AOM_IMG_FMT_I44016: return "I44016";
default: return "Other";
}
}
static void show_stream_config(struct stream_state *stream,
struct AvxEncoderConfig *global,
struct AvxInputContext *input) {
#define SHOW(field) \
fprintf(stderr, " %-28s = %d\n", #field, stream->config.cfg.field)
if (stream->index == 0) {
fprintf(stderr, "Codec: %s\n",
aom_codec_iface_name(global->codec->codec_interface()));
fprintf(stderr, "Source file: %s File Type: %s Format: %s\n",
input->filename, file_type_to_string(input->file_type),
image_format_to_string(input->fmt));
}
if (stream->next || stream->index)
fprintf(stderr, "\nStream Index: %d\n", stream->index);
fprintf(stderr, "Destination file: %s\n", stream->config.out_fn);
fprintf(stderr, "Encoder parameters:\n");
SHOW(g_usage);
SHOW(g_threads);
SHOW(g_profile);
SHOW(g_w);
SHOW(g_h);
SHOW(g_bit_depth);
SHOW(g_input_bit_depth);
SHOW(g_timebase.num);
SHOW(g_timebase.den);
SHOW(g_error_resilient);
SHOW(g_pass);
SHOW(g_lag_in_frames);
SHOW(rc_dropframe_thresh);
SHOW(rc_resize_allowed);
SHOW(rc_scaled_width);
SHOW(rc_scaled_height);
SHOW(rc_resize_up_thresh);
SHOW(rc_resize_down_thresh);
SHOW(rc_end_usage);
SHOW(rc_target_bitrate);
SHOW(rc_min_quantizer);
SHOW(rc_max_quantizer);
SHOW(rc_undershoot_pct);
SHOW(rc_overshoot_pct);
SHOW(rc_buf_sz);
SHOW(rc_buf_initial_sz);
SHOW(rc_buf_optimal_sz);
SHOW(rc_2pass_vbr_bias_pct);
SHOW(rc_2pass_vbr_minsection_pct);
SHOW(rc_2pass_vbr_maxsection_pct);
SHOW(kf_mode);
SHOW(kf_min_dist);
SHOW(kf_max_dist);
}
static void open_output_file(struct stream_state *stream,
struct AvxEncoderConfig *global,
const struct AvxRational *pixel_aspect_ratio) {
const char *fn = stream->config.out_fn;
const struct aom_codec_enc_cfg *const cfg = &stream->config.cfg;
if (cfg->g_pass == AOM_RC_FIRST_PASS) return;
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stream->file = strcmp(fn, "-") ? fopen(fn, "wb") : set_binary_mode(stdout);
if (!stream->file) fatal("Failed to open output file");
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if (stream->config.write_webm && fseek(stream->file, 0, SEEK_CUR))
fatal("WebM output to pipes not supported.");
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#if CONFIG_WEBM_IO
if (stream->config.write_webm) {
stream->webm_ctx.stream = stream->file;
write_webm_file_header(&stream->webm_ctx, cfg, stream->config.stereo_fmt,
global->codec->fourcc, pixel_aspect_ratio);
}
#else
(void)pixel_aspect_ratio;
#endif
if (!stream->config.write_webm) {
ivf_write_file_header(stream->file, cfg, global->codec->fourcc, 0);
}
}
static void close_output_file(struct stream_state *stream,
unsigned int fourcc) {
const struct aom_codec_enc_cfg *const cfg = &stream->config.cfg;
if (cfg->g_pass == AOM_RC_FIRST_PASS) return;
#if CONFIG_WEBM_IO
if (stream->config.write_webm) {
write_webm_file_footer(&stream->webm_ctx);
}
#endif
if (!stream->config.write_webm) {
if (!fseek(stream->file, 0, SEEK_SET))
ivf_write_file_header(stream->file, &stream->config.cfg, fourcc,
stream->frames_out);
}
fclose(stream->file);
}
static void setup_pass(struct stream_state *stream,
struct AvxEncoderConfig *global, int pass) {
if (stream->config.stats_fn) {
if (!stats_open_file(&stream->stats, stream->config.stats_fn, pass))
fatal("Failed to open statistics store");
} else {
if (!stats_open_mem(&stream->stats, pass))
fatal("Failed to open statistics store");
}
#if CONFIG_FP_MB_STATS
if (stream->config.fpmb_stats_fn) {
if (!stats_open_file(&stream->fpmb_stats, stream->config.fpmb_stats_fn,
pass))
fatal("Failed to open mb statistics store");
} else {
if (!stats_open_mem(&stream->fpmb_stats, pass))
fatal("Failed to open mb statistics store");
}
#endif
stream->config.cfg.g_pass = global->passes == 2
? pass ? AOM_RC_LAST_PASS : AOM_RC_FIRST_PASS
: AOM_RC_ONE_PASS;
if (pass) {
stream->config.cfg.rc_twopass_stats_in = stats_get(&stream->stats);
#if CONFIG_FP_MB_STATS
stream->config.cfg.rc_firstpass_mb_stats_in =
stats_get(&stream->fpmb_stats);
#endif
}
stream->cx_time = 0;
stream->nbytes = 0;
stream->frames_out = 0;
}
static void initialize_encoder(struct stream_state *stream,
struct AvxEncoderConfig *global) {
int i;
int flags = 0;
flags |= global->show_psnr ? AOM_CODEC_USE_PSNR : 0;
flags |= global->out_part ? AOM_CODEC_USE_OUTPUT_PARTITION : 0;
#if CONFIG_AOM_HIGHBITDEPTH
flags |= stream->config.use_16bit_internal ? AOM_CODEC_USE_HIGHBITDEPTH : 0;
#endif
/* Construct Encoder Context */
aom_codec_enc_init(&stream->encoder, global->codec->codec_interface(),
&stream->config.cfg, flags);
ctx_exit_on_error(&stream->encoder, "Failed to initialize encoder");
/* Note that we bypass the aom_codec_control wrapper macro because
* we're being clever to store the control IDs in an array. Real
* applications will want to make use of the enumerations directly
*/
for (i = 0; i < stream->config.arg_ctrl_cnt; i++) {
int ctrl = stream->config.arg_ctrls[i][0];
int value = stream->config.arg_ctrls[i][1];
if (aom_codec_control_(&stream->encoder, ctrl, value))
fprintf(stderr, "Error: Tried to set control %d = %d\n", ctrl, value);
ctx_exit_on_error(&stream->encoder, "Failed to control codec");
}
#if CONFIG_DECODERS
if (global->test_decode != TEST_DECODE_OFF) {
const AvxInterface *decoder = get_aom_decoder_by_name(global->codec->name);
aom_codec_dec_cfg_t cfg = { 0, 0, 0 };
aom_codec_dec_init(&stream->decoder, decoder->codec_interface(), &cfg, 0);
#if CONFIG_AV1_DECODER && CONFIG_EXT_TILE
if (strcmp(global->codec->name, "av1") == 0) {
aom_codec_control(&stream->decoder, AV1_SET_DECODE_TILE_ROW, -1);
ctx_exit_on_error(&stream->decoder, "Failed to set decode_tile_row");
aom_codec_control(&stream->decoder, AV1_SET_DECODE_TILE_COL, -1);
ctx_exit_on_error(&stream->decoder, "Failed to set decode_tile_col");
}
#endif
}
#endif
}
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static void encode_frame(struct stream_state *stream,
struct AvxEncoderConfig *global, struct aom_image *img,
unsigned int frames_in) {
aom_codec_pts_t frame_start, next_frame_start;
struct aom_codec_enc_cfg *cfg = &stream->config.cfg;
struct aom_usec_timer timer;
frame_start =
(cfg->g_timebase.den * (int64_t)(frames_in - 1) * global->framerate.den) /
cfg->g_timebase.num / global->framerate.num;
next_frame_start =
(cfg->g_timebase.den * (int64_t)(frames_in)*global->framerate.den) /
cfg->g_timebase.num / global->framerate.num;
/* Scale if necessary */
#if CONFIG_AOM_HIGHBITDEPTH
if (img) {
if ((img->fmt & AOM_IMG_FMT_HIGHBITDEPTH) &&
(img->d_w != cfg->g_w || img->d_h != cfg->g_h)) {
if (img->fmt != AOM_IMG_FMT_I42016) {
fprintf(stderr, "%s can only scale 4:2:0 inputs\n", exec_name);
exit(EXIT_FAILURE);
}
#if CONFIG_LIBYUV
if (!stream->img) {
stream->img =
aom_img_alloc(NULL, AOM_IMG_FMT_I42016, cfg->g_w, cfg->g_h, 16);
}
I420Scale_16(
(uint16 *)img->planes[AOM_PLANE_Y], img->stride[AOM_PLANE_Y] / 2,
(uint16 *)img->planes[AOM_PLANE_U], img->stride[AOM_PLANE_U] / 2,
(uint16 *)img->planes[AOM_PLANE_V], img->stride[AOM_PLANE_V] / 2,
img->d_w, img->d_h, (uint16 *)stream->img->planes[AOM_PLANE_Y],
stream->img->stride[AOM_PLANE_Y] / 2,
(uint16 *)stream->img->planes[AOM_PLANE_U],
stream->img->stride[AOM_PLANE_U] / 2,
(uint16 *)stream->img->planes[AOM_PLANE_V],
stream->img->stride[AOM_PLANE_V] / 2, stream->img->d_w,
stream->img->d_h, kFilterBox);
img = stream->img;
#else
stream->encoder.err = 1;
ctx_exit_on_error(&stream->encoder,
"Stream %d: Failed to encode frame.\n"
"Scaling disabled in this configuration. \n"
"To enable, configure with --enable-libyuv\n",
stream->index);
#endif
}
}
#endif
if (img && (img->d_w != cfg->g_w || img->d_h != cfg->g_h)) {
if (img->fmt != AOM_IMG_FMT_I420 && img->fmt != AOM_IMG_FMT_YV12) {
fprintf(stderr, "%s can only scale 4:2:0 8bpp inputs\n", exec_name);
exit(EXIT_FAILURE);
}
#if CONFIG_LIBYUV
if (!stream->img)
stream->img =
aom_img_alloc(NULL, AOM_IMG_FMT_I420, cfg->g_w, cfg->g_h, 16);
I420Scale(
img->planes[AOM_PLANE_Y], img->stride[AOM_PLANE_Y],
img->planes[AOM_PLANE_U], img->stride[AOM_PLANE_U],
img->planes[AOM_PLANE_V], img->stride[AOM_PLANE_V], img->d_w, img->d_h,
stream->img->planes[AOM_PLANE_Y], stream->img->stride[AOM_PLANE_Y],
stream->img->planes[AOM_PLANE_U], stream->img->stride[AOM_PLANE_U],
stream->img->planes[AOM_PLANE_V], stream->img->stride[AOM_PLANE_V],
stream->img->d_w, stream->img->d_h, kFilterBox);
img = stream->img;
#else
stream->encoder.err = 1;
ctx_exit_on_error(&stream->encoder,
"Stream %d: Failed to encode frame.\n"
"Scaling disabled in this configuration. \n"
"To enable, configure with --enable-libyuv\n",
stream->index);
#endif
}
aom_usec_timer_start(&timer);
aom_codec_encode(&stream->encoder, img, frame_start,
(unsigned long)(next_frame_start - frame_start), 0,
global->deadline);
aom_usec_timer_mark(&timer);
stream->cx_time += aom_usec_timer_elapsed(&timer);
ctx_exit_on_error(&stream->encoder, "Stream %d: Failed to encode frame",
stream->index);
}
static void update_quantizer_histogram(struct stream_state *stream) {
if (stream->config.cfg.g_pass != AOM_RC_FIRST_PASS) {
int q;
aom_codec_control(&stream->encoder, AOME_GET_LAST_QUANTIZER_64, &q);
ctx_exit_on_error(&stream->encoder, "Failed to read quantizer");
stream->counts[q]++;
}
}
static void get_cx_data(struct stream_state *stream,
struct AvxEncoderConfig *global, int *got_data) {
const aom_codec_cx_pkt_t *pkt;
const struct aom_codec_enc_cfg *cfg = &stream->config.cfg;
aom_codec_iter_t iter = NULL;
*got_data = 0;
while ((pkt = aom_codec_get_cx_data(&stream->encoder, &iter))) {
static size_t fsize = 0;
static FileOffset ivf_header_pos = 0;
switch (pkt->kind) {
case AOM_CODEC_CX_FRAME_PKT:
if (!(pkt->data.frame.flags & AOM_FRAME_IS_FRAGMENT)) {
stream->frames_out++;
}
if (!global->quiet)
fprintf(stderr, " %6luF", (unsigned long)pkt->data.frame.sz);
update_rate_histogram(stream->rate_hist, cfg, pkt);
#if CONFIG_WEBM_IO
if (stream->config.write_webm) {
write_webm_block(&stream->webm_ctx, cfg, pkt);
}
#endif
if (!stream->config.write_webm) {
if (pkt->data.frame.partition_id <= 0) {
ivf_header_pos = ftello(stream->file);
fsize = pkt->data.frame.sz;
ivf_write_frame_header(stream->file, pkt->data.frame.pts, fsize);
} else {
fsize += pkt->data.frame.sz;
if (!(pkt->data.frame.flags & AOM_FRAME_IS_FRAGMENT)) {
const FileOffset currpos = ftello(stream->file);
fseeko(stream->file, ivf_header_pos, SEEK_SET);
ivf_write_frame_size(stream->file, fsize);
fseeko(stream->file, currpos, SEEK_SET);
}
}
(void)fwrite(pkt->data.frame.buf, 1, pkt->data.frame.sz,
stream->file);
}
stream->nbytes += pkt->data.raw.sz;
*got_data = 1;
#if CONFIG_DECODERS
if (global->test_decode != TEST_DECODE_OFF && !stream->mismatch_seen) {
aom_codec_decode(&stream->decoder, pkt->data.frame.buf,
(unsigned int)pkt->data.frame.sz, NULL, 0);
if (stream->decoder.err) {
warn_or_exit_on_error(&stream->decoder,
global->test_decode == TEST_DECODE_FATAL,
"Failed to decode frame %d in stream %d",
stream->frames_out + 1, stream->index);
stream->mismatch_seen = stream->frames_out + 1;
}
}
#endif
break;
case AOM_CODEC_STATS_PKT:
stream->frames_out++;
stats_write(&stream->stats, pkt->data.twopass_stats.buf,
pkt->data.twopass_stats.sz);
stream->nbytes += pkt->data.raw.sz;
break;
#if CONFIG_FP_MB_STATS
case AOM_CODEC_FPMB_STATS_PKT:
stats_write(&stream->fpmb_stats, pkt->data.firstpass_mb_stats.buf,
pkt->data.firstpass_mb_stats.sz);
stream->nbytes += pkt->data.raw.sz;
break;
#endif
case AOM_CODEC_PSNR_PKT:
if (global->show_psnr) {
int i;
stream->psnr_sse_total += pkt->data.psnr.sse[0];
stream->psnr_samples_total += pkt->data.psnr.samples[0];
for (i = 0; i < 4; i++) {
if (!global->quiet)
fprintf(stderr, "%.3f ", pkt->data.psnr.psnr[i]);
stream->psnr_totals[i] += pkt->data.psnr.psnr[i];
}
stream->psnr_count++;
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}
break;
default: break;
}
}
}
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static void show_psnr(struct stream_state *stream, double peak) {
int i;
double ovpsnr;
if (!stream->psnr_count) return;
fprintf(stderr, "Stream %d PSNR (Overall/Avg/Y/U/V)", stream->index);
ovpsnr = sse_to_psnr((double)stream->psnr_samples_total, peak,
(double)stream->psnr_sse_total);
fprintf(stderr, " %.3f", ovpsnr);
for (i = 0; i < 4; i++) {
fprintf(stderr, " %.3f", stream->psnr_totals[i] / stream->psnr_count);
}
fprintf(stderr, "\n");
}
static float usec_to_fps(uint64_t usec, unsigned int frames) {
return (float)(usec > 0 ? frames * 1000000.0 / (float)usec : 0);
}
static void test_decode(struct stream_state *stream,
enum TestDecodeFatality fatal,
const AvxInterface *codec) {
aom_image_t enc_img, dec_img;
if (stream->mismatch_seen) return;
/* Get the internal reference frame */
if (strcmp(codec->name, "vp8") == 0) {
struct aom_ref_frame ref_enc, ref_dec;
const unsigned int frame_width = (stream->config.cfg.g_w + 15) & ~15;
const unsigned int frame_height = (stream->config.cfg.g_h + 15) & ~15;
aom_img_alloc(&ref_enc.img, AOM_IMG_FMT_I420, frame_width, frame_height, 1);
enc_img = ref_enc.img;
aom_img_alloc(&ref_dec.img, AOM_IMG_FMT_I420, frame_width, frame_height, 1);
dec_img = ref_dec.img;
ref_enc.frame_type = AOM_LAST_FRAME;
ref_dec.frame_type = AOM_LAST_FRAME;
aom_codec_control(&stream->encoder, AOM_COPY_REFERENCE, &ref_enc);
aom_codec_control(&stream->decoder, AOM_COPY_REFERENCE, &ref_dec);
} else {
aom_codec_control(&stream->encoder, AV1_GET_NEW_FRAME_IMAGE, &enc_img);
aom_codec_control(&stream->decoder, AV1_GET_NEW_FRAME_IMAGE, &dec_img);
#if CONFIG_AOM_HIGHBITDEPTH
if ((enc_img.fmt & AOM_IMG_FMT_HIGHBITDEPTH) !=
(dec_img.fmt & AOM_IMG_FMT_HIGHBITDEPTH)) {
if (enc_img.fmt & AOM_IMG_FMT_HIGHBITDEPTH) {
aom_image_t enc_hbd_img;
aom_img_alloc(&enc_hbd_img, enc_img.fmt - AOM_IMG_FMT_HIGHBITDEPTH,
enc_img.d_w, enc_img.d_h, 16);
aom_img_truncate_16_to_8(&enc_hbd_img, &enc_img);
enc_img = enc_hbd_img;
}
if (dec_img.fmt & AOM_IMG_FMT_HIGHBITDEPTH) {
aom_image_t dec_hbd_img;
aom_img_alloc(&dec_hbd_img, dec_img.fmt - AOM_IMG_FMT_HIGHBITDEPTH,
dec_img.d_w, dec_img.d_h, 16);
aom_img_truncate_16_to_8(&dec_hbd_img, &dec_img);
dec_img = dec_hbd_img;
}
}
#endif
}
ctx_exit_on_error(&stream->encoder, "Failed to get encoder reference frame");
ctx_exit_on_error(&stream->decoder, "Failed to get decoder reference frame");
if (!compare_img(&enc_img, &dec_img)) {
int y[4], u[4], v[4];
#if CONFIG_AOM_HIGHBITDEPTH
if (enc_img.fmt & AOM_IMG_FMT_HIGHBITDEPTH) {
find_mismatch_high(&enc_img, &dec_img, y, u, v);
} else {
find_mismatch(&enc_img, &dec_img, y, u, v);
}
#else
find_mismatch(&enc_img, &dec_img, y, u, v);
#endif
stream->decoder.err = 1;
warn_or_exit_on_error(&stream->decoder, fatal == TEST_DECODE_FATAL,
"Stream %d: Encode/decode mismatch on frame %d at"
" Y[%d, %d] {%d/%d},"
" U[%d, %d] {%d/%d},"
" V[%d, %d] {%d/%d}",
stream->index, stream->frames_out, y[0], y[1], y[2],
y[3], u[0], u[1], u[2], u[3], v[0], v[1], v[2], v[3]);
stream->mismatch_seen = stream->frames_out;
}
aom_img_free(&enc_img);
aom_img_free(&dec_img);
}
static void print_time(const char *label, int64_t etl) {
int64_t hours;
int64_t mins;
int64_t secs;
if (etl >= 0) {
hours = etl / 3600;
etl -= hours * 3600;
mins = etl / 60;
etl -= mins * 60;
secs = etl;
fprintf(stderr, "[%3s %2" PRId64 ":%02" PRId64 ":%02" PRId64 "] ", label,
hours, mins, secs);
} else {
fprintf(stderr, "[%3s unknown] ", label);
}
}
int main(int argc, const char **argv_) {
int pass;
aom_image_t raw;
#if CONFIG_AOM_HIGHBITDEPTH
aom_image_t raw_shift;
int allocated_raw_shift = 0;
int use_16bit_internal = 0;
int input_shift = 0;
#endif
int frame_avail, got_data;
struct AvxInputContext input;
struct AvxEncoderConfig global;
struct stream_state *streams = NULL;
char **argv, **argi;
uint64_t cx_time = 0;
int stream_cnt = 0;
int res = 0;
int profile_updated = 0;
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memset(&input, 0, sizeof(input));
exec_name = argv_[0];
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if (argc < 3) usage_exit();
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/* Setup default input stream settings */
input.framerate.numerator = 30;
input.framerate.denominator = 1;
input.only_i420 = 1;
input.bit_depth = 0;
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/* First parse the global configuration values, because we want to apply
* other parameters on top of the default configuration provided by the
* codec.
*/
argv = argv_dup(argc - 1, argv_ + 1);
parse_global_config(&global, argv);
switch (global.color_type) {
case I420: input.fmt = AOM_IMG_FMT_I420; break;
case I422: input.fmt = AOM_IMG_FMT_I422; break;
case I444: input.fmt = AOM_IMG_FMT_I444; break;
case I440: input.fmt = AOM_IMG_FMT_I440; break;
case YV12: input.fmt = AOM_IMG_FMT_YV12; break;
}
{
/* Now parse each stream's parameters. Using a local scope here
* due to the use of 'stream' as loop variable in FOREACH_STREAM
* loops
*/
struct stream_state *stream = NULL;
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do {
stream = new_stream(&global, stream);
stream_cnt++;
if (!streams) streams = stream;
} while (parse_stream_params(&global, stream, argv));
}
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/* Check for unrecognized options */
for (argi = argv; *argi; argi++)
if (argi[0][0] == '-' && argi[0][1])
die("Error: Unrecognized option %s\n", *argi);
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FOREACH_STREAM(check_encoder_config(global.disable_warning_prompt, &global,
&stream->config.cfg););
/* Handle non-option arguments */
input.filename = argv[0];
if (!input.filename) usage_exit();
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/* Decide if other chroma subsamplings than 4:2:0 are supported */
if (global.codec->fourcc == AV1_FOURCC) input.only_i420 = 0;
for (pass = global.pass ? global.pass - 1 : 0; pass < global.passes; pass++) {
int frames_in = 0, seen_frames = 0;
int64_t estimated_time_left = -1;
int64_t average_rate = -1;
int64_t lagged_count = 0;
open_input_file(&input);
/* If the input file doesn't specify its w/h (raw files), try to get
* the data from the first stream's configuration.
*/
if (!input.width || !input.height) {
FOREACH_STREAM({
if (stream->config.cfg.g_w && stream->config.cfg.g_h) {
input.width = stream->config.cfg.g_w;
input.height = stream->config.cfg.g_h;
break;
}
});
}
/* Update stream configurations from the input file's parameters */
if (!input.width || !input.height)
fatal(
"Specify stream dimensions with --width (-w) "
" and --height (-h)");
/* If input file does not specify bit-depth but input-bit-depth parameter
* exists, assume that to be the input bit-depth. However, if the
* input-bit-depth paramter does not exist, assume the input bit-depth
* to be the same as the codec bit-depth.
*/
if (!input.bit_depth) {
FOREACH_STREAM({
if (stream->config.cfg.g_input_bit_depth)
input.bit_depth = stream->config.cfg.g_input_bit_depth;
else
input.bit_depth = stream->config.cfg.g_input_bit_depth =
(int)stream->config.cfg.g_bit_depth;
});
if (input.bit_depth > 8) input.fmt |= AOM_IMG_FMT_HIGHBITDEPTH;
} else {
FOREACH_STREAM(
{ stream->config.cfg.g_input_bit_depth = input.bit_depth; });
}
#if CONFIG_AOM_HIGHBITDEPTH
FOREACH_STREAM({
if (input.fmt != AOM_IMG_FMT_I420 && input.fmt != AOM_IMG_FMT_I42016) {
/* Automatically upgrade if input is non-4:2:0 but a 4:2:0 profile
was selected. */
switch (stream->config.cfg.g_profile) {
case 0:
stream->config.cfg.g_profile = 1;
profile_updated = 1;
break;
case 2:
stream->config.cfg.g_profile = 3;
profile_updated = 1;
break;
default: break;
}
}
/* Automatically set the codec bit depth to match the input bit depth.
* Upgrade the profile if required. */
if (stream->config.cfg.g_input_bit_depth >
(unsigned int)stream->config.cfg.g_bit_depth) {
stream->config.cfg.g_bit_depth = stream->config.cfg.g_input_bit_depth;
}
if (stream->config.cfg.g_bit_depth > 8) {
switch (stream->config.cfg.g_profile) {
case 0:
stream->config.cfg.g_profile = 2;
profile_updated = 1;
break;
case 1:
stream->config.cfg.g_profile = 3;
profile_updated = 1;
break;
default: break;
}
}
if (stream->config.cfg.g_profile > 1) {
stream->config.use_16bit_internal = 1;
}
if (profile_updated && !global.quiet) {
fprintf(stderr,
"Warning: automatically upgrading to profile %d to "
"match input format.\n",
stream->config.cfg.g_profile);
}
});
#else
FOREACH_STREAM({
if (input.fmt != AOM_IMG_FMT_I420 && input.fmt != AOM_IMG_FMT_I42016) {
/* Automatically upgrade if input is non-4:2:0 but a 4:2:0 profile
was selected. */
switch (stream->config.cfg.g_profile) {
case 0:
stream->config.cfg.g_profile = 1;
profile_updated = 1;
break;
case 2:
stream->config.cfg.g_profile = 3;
profile_updated = 1;
break;
default: break;
}
}
if (profile_updated && !global.quiet) {
fprintf(stderr,
"Warning: automatically upgrading to profile %d to "
"match input format.\n",
stream->config.cfg.g_profile);
}
});
#endif
FOREACH_STREAM(set_stream_dimensions(stream, input.width, input.height));
FOREACH_STREAM(validate_stream_config(stream, &global));
/* Ensure that --passes and --pass are consistent. If --pass is set and
* --passes=2, ensure --fpf was set.
*/
if (global.pass && global.passes == 2)
FOREACH_STREAM({
if (!stream->config.stats_fn)
die("Stream %d: Must specify --fpf when --pass=%d"
" and --passes=2\n",
stream->index, global.pass);
});
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#if !CONFIG_WEBM_IO
FOREACH_STREAM({
if (stream->config.write_webm) {
stream->config.write_webm = 0;
warn(
"aomenc was compiled without WebM container support."
"Producing IVF output");
}
});
#endif
/* Use the frame rate from the file only if none was specified
* on the command-line.
*/
if (!global.have_framerate) {
global.framerate.num = input.framerate.numerator;
global.framerate.den = input.framerate.denominator;
FOREACH_STREAM(stream->config.cfg.g_timebase.den = global.framerate.num;
stream->config.cfg.g_timebase.num = global.framerate.den);
}
/* Show configuration */
if (global.verbose && pass == 0)
FOREACH_STREAM(show_stream_config(stream, &global, &input));
if (pass == (global.pass ? global.pass - 1 : 0)) {
if (input.file_type == FILE_TYPE_Y4M)
/*The Y4M reader does its own allocation.
Just initialize this here to avoid problems if we never read any
frames.*/
memset(&raw, 0, sizeof(raw));
else
aom_img_alloc(&raw, input.fmt, input.width, input.height, 32);
FOREACH_STREAM(stream->rate_hist = init_rate_histogram(
&stream->config.cfg, &global.framerate));
}
FOREACH_STREAM(setup_pass(stream, &global, pass));
FOREACH_STREAM(
open_output_file(stream, &global, &input.pixel_aspect_ratio));
FOREACH_STREAM(initialize_encoder(stream, &global));
#if CONFIG_AOM_HIGHBITDEPTH
if (strcmp(global.codec->name, "av1") == 0 ||
strcmp(global.codec->name, "av1") == 0) {
// Check to see if at least one stream uses 16 bit internal.
// Currently assume that the bit_depths for all streams using
// highbitdepth are the same.
FOREACH_STREAM({
if (stream->config.use_16bit_internal) {
use_16bit_internal = 1;
}
if (stream->config.cfg.g_profile == 0) {
input_shift = 0;
} else {
input_shift = (int)stream->config.cfg.g_bit_depth -
stream->config.cfg.g_input_bit_depth;
}
});
}
#endif
frame_avail = 1;
got_data = 0;
while (frame_avail || got_data) {
struct aom_usec_timer timer;
if (!global.limit || frames_in < global.limit) {
frame_avail = read_frame(&input, &raw);
if (frame_avail) frames_in++;
seen_frames =
frames_in > global.skip_frames ? frames_in - global.skip_frames : 0;
if (!global.quiet) {
float fps = usec_to_fps(cx_time, seen_frames);
fprintf(stderr, "\rPass %d/%d ", pass + 1, global.passes);
if (stream_cnt == 1)
fprintf(stderr, "frame %4d/%-4d %7" PRId64 "B ", frames_in,
streams->frames_out, (int64_t)streams->nbytes);
else
fprintf(stderr, "frame %4d ", frames_in);
fprintf(stderr, "%7" PRId64 " %s %.2f %s ",
cx_time > 9999999 ? cx_time / 1000 : cx_time,
cx_time > 9999999 ? "ms" : "us", fps >= 1.0 ? fps : fps * 60,
fps >= 1.0 ? "fps" : "fpm");
print_time("ETA", estimated_time_left);
}
} else {
frame_avail = 0;
}
if (frames_in > global.skip_frames) {
#if CONFIG_AOM_HIGHBITDEPTH
aom_image_t *frame_to_encode;
if (input_shift || (use_16bit_internal && input.bit_depth == 8)) {
assert(use_16bit_internal);
// Input bit depth and stream bit depth do not match, so up
// shift frame to stream bit depth
if (!allocated_raw_shift) {
aom_img_alloc(&raw_shift, raw.fmt | AOM_IMG_FMT_HIGHBITDEPTH,
input.width, input.height, 32);
allocated_raw_shift = 1;
}
aom_img_upshift(&raw_shift, &raw, input_shift);
frame_to_encode = &raw_shift;
} else {
frame_to_encode = &raw;
}
aom_usec_timer_start(&timer);
if (use_16bit_internal) {
assert(frame_to_encode->fmt & AOM_IMG_FMT_HIGHBITDEPTH);
FOREACH_STREAM({
if (stream->config.use_16bit_internal)
encode_frame(stream, &global,
frame_avail ? frame_to_encode : NULL, frames_in);
else
assert(0);
});
} else {
assert((frame_to_encode->fmt & AOM_IMG_FMT_HIGHBITDEPTH) == 0);
FOREACH_STREAM(encode_frame(stream, &global,
frame_avail ? frame_to_encode : NULL,
frames_in));
}
#else
aom_usec_timer_start(&timer);
FOREACH_STREAM(encode_frame(stream, &global, frame_avail ? &raw : NULL,
frames_in));
#endif
aom_usec_timer_mark(&timer);
cx_time += aom_usec_timer_elapsed(&timer);
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FOREACH_STREAM(update_quantizer_histogram(stream));
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got_data = 0;
FOREACH_STREAM(get_cx_data(stream, &global, &got_data));
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if (!got_data && input.length && streams != NULL &&
!streams->frames_out) {
lagged_count = global.limit ? seen_frames : ftello(input.file);
} else if (input.length) {
int64_t remaining;
int64_t rate;
if (global.limit) {
const int64_t frame_in_lagged = (seen_frames - lagged_count) * 1000;
rate = cx_time ? frame_in_lagged * (int64_t)1000000 / cx_time : 0;
remaining = 1000 * (global.limit - global.skip_frames -
seen_frames + lagged_count);
} else {
const int64_t input_pos = ftello(input.file);
const int64_t input_pos_lagged = input_pos - lagged_count;
const int64_t input_limit = input.length;
rate = cx_time ? input_pos_lagged * (int64_t)1000000 / cx_time : 0;
remaining = input_limit - input_pos + lagged_count;
}
average_rate =
(average_rate <= 0) ? rate : (average_rate * 7 + rate) / 8;
estimated_time_left = average_rate ? remaining / average_rate : -1;
}
if (got_data && global.test_decode != TEST_DECODE_OFF)
FOREACH_STREAM(test_decode(stream, global.test_decode, global.codec));
}
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fflush(stdout);
if (!global.quiet) fprintf(stderr, "\033[K");
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}
if (stream_cnt > 1) fprintf(stderr, "\n");
if (!global.quiet) {
FOREACH_STREAM(fprintf(
stderr, "\rPass %d/%d frame %4d/%-4d %7" PRId64 "B %7" PRId64
"b/f %7" PRId64 "b/s"
" %7" PRId64 " %s (%.2f fps)\033[K\n",
pass + 1, global.passes, frames_in, stream->frames_out,
(int64_t)stream->nbytes,
seen_frames ? (int64_t)(stream->nbytes * 8 / seen_frames) : 0,
seen_frames
? (int64_t)stream->nbytes * 8 * (int64_t)global.framerate.num /
global.framerate.den / seen_frames
: 0,
stream->cx_time > 9999999 ? stream->cx_time / 1000 : stream->cx_time,
stream->cx_time > 9999999 ? "ms" : "us",
usec_to_fps(stream->cx_time, seen_frames)));
}
if (global.show_psnr) {
if (global.codec->fourcc == AV1_FOURCC) {
FOREACH_STREAM(
show_psnr(stream, (1 << stream->config.cfg.g_input_bit_depth) - 1));
} else {
FOREACH_STREAM(show_psnr(stream, 255.0));
}
}
FOREACH_STREAM(aom_codec_destroy(&stream->encoder));
if (global.test_decode != TEST_DECODE_OFF) {
FOREACH_STREAM(aom_codec_destroy(&stream->decoder));
}
close_input_file(&input);
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if (global.test_decode == TEST_DECODE_FATAL) {
FOREACH_STREAM(res |= stream->mismatch_seen);
}
FOREACH_STREAM(close_output_file(stream, global.codec->fourcc));
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FOREACH_STREAM(stats_close(&stream->stats, global.passes - 1));
#if CONFIG_FP_MB_STATS
FOREACH_STREAM(stats_close(&stream->fpmb_stats, global.passes - 1));
#endif
if (global.pass) break;
}
if (global.show_q_hist_buckets)
FOREACH_STREAM(
show_q_histogram(stream->counts, global.show_q_hist_buckets));
if (global.show_rate_hist_buckets)
FOREACH_STREAM(show_rate_histogram(stream->rate_hist, &stream->config.cfg,
global.show_rate_hist_buckets));
FOREACH_STREAM(destroy_rate_histogram(stream->rate_hist));
#if CONFIG_INTERNAL_STATS
/* TODO(jkoleszar): This doesn't belong in this executable. Do it for now,
* to match some existing utilities.
*/
if (!(global.pass == 1 && global.passes == 2))
FOREACH_STREAM({
FILE *f = fopen("opsnr.stt", "a");
if (stream->mismatch_seen) {
fprintf(f, "First mismatch occurred in frame %d\n",
stream->mismatch_seen);
} else {
fprintf(f, "No mismatch detected in recon buffers\n");
}
fclose(f);
});
#endif
#if CONFIG_AOM_HIGHBITDEPTH
if (allocated_raw_shift) aom_img_free(&raw_shift);
#endif
aom_img_free(&raw);
free(argv);
free(streams);
return res ? EXIT_FAILURE : EXIT_SUCCESS;
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}