/* encx265.c Copyright (c) 2003-2019 HandBrake Team This file is part of the HandBrake source code Homepage: . It may be used under the terms of the GNU General Public License v2. For full terms see the file COPYING file or visit http://www.gnu.org/licenses/gpl-2.0.html */ #include "handbrake/project.h" #if HB_PROJECT_FEATURE_X265 #include "handbrake/handbrake.h" #include "handbrake/hb_dict.h" #include "handbrake/h265_common.h" #include "x265.h" int encx265Init (hb_work_object_t*, hb_job_t*); int encx265Work (hb_work_object_t*, hb_buffer_t**, hb_buffer_t**); void encx265Close(hb_work_object_t*); hb_work_object_t hb_encx265 = { WORK_ENCX265, "H.265/HEVC encoder (libx265)", encx265Init, encx265Work, encx265Close, }; #define FRAME_INFO_MAX2 (8) // 2^8 = 256; 90000/256 = 352 frames/sec #define FRAME_INFO_MIN2 (17) // 2^17 = 128K; 90000/131072 = 1.4 frames/sec #define FRAME_INFO_SIZE (1 << (FRAME_INFO_MIN2 - FRAME_INFO_MAX2 + 1)) #define FRAME_INFO_MASK (FRAME_INFO_SIZE - 1) static const char * const hb_x265_encopt_synonyms[][2] = { { "me", "motion", }, { NULL, NULL, }, }; struct hb_work_private_s { hb_job_t * job; x265_encoder * x265; x265_param * param; int64_t last_stop; uint32_t frames_in; hb_chapter_queue_t * chapter_queue; struct { int64_t duration; } frame_info[FRAME_INFO_SIZE]; char * csvfn; // Multiple bit-depth const x265_api * api; }; static int param_parse(hb_work_private_t *pv, x265_param *param, const char *key, const char *value) { int ret = pv->api->param_parse(param, key, value); // let x265 sanity check the options for us switch (ret) { case X265_PARAM_BAD_NAME: hb_log("encx265: unknown option '%s'", key); break; case X265_PARAM_BAD_VALUE: hb_log("encx265: bad argument '%s=%s'", key, value ? value : "(null)"); break; default: break; } return ret; } int apply_h265_level(hb_work_private_t *pv, x265_param *param, const char *h265_level) { if (h265_level == NULL || !strcasecmp(h265_level, hb_h265_level_names[0])) { return 0; } // Verify that level is valid int i; for (i = 1; hb_h265_level_values[i]; i++) { if (!strcmp(hb_h265_level_names[i], h265_level) || !strcmp(hb_h265_level_names2[i], h265_level)) { return param_parse(pv, param, "level-idc", hb_h265_level_names2[i]); } } // error (invalid or unsupported level), abort hb_error("apply_h265_level: invalid level %s", h265_level); return X265_PARAM_BAD_VALUE; } /*********************************************************************** * hb_work_encx265_init *********************************************************************** * **********************************************************************/ int encx265Init(hb_work_object_t *w, hb_job_t *job) { hb_work_private_t *pv = calloc(1, sizeof(hb_work_private_t)); int ret, depth; x265_nal *nal; uint32_t nnal; const char * const *profile_names; pv->job = job; pv->last_stop = AV_NOPTS_VALUE; pv->chapter_queue = hb_chapter_queue_init(); w->private_data = pv; depth = hb_video_encoder_get_depth(job->vcodec); profile_names = hb_video_encoder_get_profiles(job->vcodec); pv->api = x265_api_query(depth, X265_BUILD, NULL); if (pv->api == NULL) { hb_error("encx265: x265_api_query failed, bit depth %d.", depth); goto fail; } x265_param *param = pv->param = pv->api->param_alloc(); if (pv->api->param_default_preset(param, job->encoder_preset, job->encoder_tune) < 0) { hb_error("encx265: x265_param_default_preset failed. Preset (%s) Tune (%s)", job->encoder_preset, job->encoder_tune); goto fail; } /* If the PSNR or SSIM tunes are in use, enable the relevant metric */ param->bEnablePsnr = param->bEnableSsim = 0; if (job->encoder_tune != NULL && *job->encoder_tune) { char *tmp = strdup(job->encoder_tune); char *tok = strtok(tmp, ",./-+"); do { if (!strncasecmp(tok, "psnr", 4)) { param->bEnablePsnr = 1; break; } if (!strncasecmp(tok, "ssim", 4)) { param->bEnableSsim = 1; break; } } while ((tok = strtok(NULL, ",./-+")) != NULL); free(tmp); } /* * Some HandBrake-specific defaults; users can override them * using the encoder_options string. */ param->fpsNum = job->orig_vrate.num; param->fpsDenom = job->orig_vrate.den; param->keyframeMin = (double)job->orig_vrate.num / job->orig_vrate.den + 0.5; param->keyframeMax = param->keyframeMin * 10; /* * Video Signal Type (color description only). * * Use x265_param_parse (let x265 determine which bEnable * flags, if any, should be set in the x265_param struct). */ char colorprim[11], transfer[11], colormatrix[11]; snprintf(colorprim, sizeof(colorprim), "%d", hb_output_color_prim(job)); snprintf(transfer, sizeof(transfer), "%d", hb_output_color_transfer(job)); snprintf(colormatrix, sizeof(colormatrix), "%d", hb_output_color_matrix(job)); if (param_parse(pv, param, "colorprim", colorprim) || param_parse(pv, param, "transfer", transfer) || param_parse(pv, param, "colormatrix", colormatrix)) { goto fail; } /* iterate through x265_opts and parse the options */ hb_dict_t *x265_opts; x265_opts = hb_encopts_to_dict(job->encoder_options, job->vcodec); hb_dict_iter_t iter; for (iter = hb_dict_iter_init(x265_opts); iter != HB_DICT_ITER_DONE; iter = hb_dict_iter_next(x265_opts, iter)) { const char *key = hb_dict_iter_key(iter); hb_value_t *value = hb_dict_iter_value(iter); char *str = hb_value_get_string_xform(value); // here's where the strings are passed to libx265 for parsing // unknown options or bad values are non-fatal, see encx264.c param_parse(pv, param, key, str); free(str); } hb_dict_free(&x265_opts); /* * Reload colorimetry settings in case custom * values were set in the encoder_options string. */ job->color_prim_override = param->vui.colorPrimaries; job->color_transfer_override = param->vui.transferCharacteristics; job->color_matrix_override = param->vui.matrixCoeffs; /* * Settings which can't be overridden in the encodeer_options string * (muxer-specific settings, resolution, ratecontrol, etc.). */ param->bRepeatHeaders = job->inline_parameter_sets; param->sourceWidth = job->width; param->sourceHeight = job->height; /* * Let x265 determnine whether to use an aspect ratio * index vs. the extended SAR index + SAR width/height. */ char sar[22]; snprintf(sar, sizeof(sar), "%d:%d", job->par.num, job->par.den); if (param_parse(pv, param, "sar", sar)) { goto fail; } if (job->vquality > HB_INVALID_VIDEO_QUALITY) { param->rc.rateControlMode = X265_RC_CRF; param->rc.rfConstant = job->vquality; } else { param->rc.rateControlMode = X265_RC_ABR; param->rc.bitrate = job->vbitrate; if (job->pass_id == HB_PASS_ENCODE_1ST || job->pass_id == HB_PASS_ENCODE_2ND) { char * stats_file; char pass[2]; snprintf(pass, sizeof(pass), "%d", job->pass_id); stats_file = hb_get_temporary_filename("x265.log"); if (param_parse(pv, param, "stats", stats_file) || param_parse(pv, param, "pass", pass)) { free(stats_file); goto fail; } free(stats_file); if (job->pass_id == HB_PASS_ENCODE_1ST) { char slowfirstpass[2]; snprintf(slowfirstpass, sizeof(slowfirstpass), "%d", !job->fastfirstpass); if (param_parse(pv, param, "slow-firstpass", slowfirstpass)) { goto fail; } } } } /* statsfile (but not 2-pass) */ if (param->logLevel >= X265_LOG_DEBUG) { if (param->csvfn == NULL) { pv->csvfn = hb_get_temporary_filename("x265.csv"); param->csvfn = strdup(pv->csvfn); } else { pv->csvfn = strdup(param->csvfn); } } /* Apply profile and level settings last. */ if (job->encoder_profile != NULL && strcasecmp(job->encoder_profile, profile_names[0]) != 0 && pv->api->param_apply_profile(param, job->encoder_profile) < 0) { goto fail; } if (apply_h265_level(pv, param, job->encoder_level) < 0) { goto fail; } /* we should now know whether B-frames are enabled */ job->areBframes = (param->bframes > 0) + (param->bframes > 0 && param->bBPyramid > 0); /* Reset global variables before opening a new encoder */ pv->api->cleanup(); pv->x265 = pv->api->encoder_open(param); if (pv->x265 == NULL) { hb_error("encx265: x265_encoder_open failed."); goto fail; } /* * x265's output (headers and bitstream) are in Annex B format. * * Write the header as is, and let the muxer reformat * the extradata and output bitstream properly for us. */ ret = pv->api->encoder_headers(pv->x265, &nal, &nnal); if (ret < 0) { hb_error("encx265: x265_encoder_headers failed (%d)", ret); goto fail; } if (ret > sizeof(w->config->h265.headers)) { hb_error("encx265: bitstream headers too large (%d)", ret); goto fail; } memcpy(w->config->h265.headers, nal->payload, ret); w->config->h265.headers_length = ret; return 0; fail: w->private_data = NULL; free(pv); return 1; } void encx265Close(hb_work_object_t *w) { hb_work_private_t *pv = w->private_data; if (pv == NULL) { return; } hb_chapter_queue_close(&pv->chapter_queue); pv->api->param_free(pv->param); pv->api->encoder_close(pv->x265); free(pv->csvfn); free(pv); w->private_data = NULL; } /* * see comments in definition of 'frame_info' in pv struct for description * of what these routines are doing. */ static void save_frame_info(hb_work_private_t *pv, hb_buffer_t *in) { int i = (in->s.start >> FRAME_INFO_MAX2) & FRAME_INFO_MASK; pv->frame_info[i].duration = in->s.stop - in->s.start; } static int64_t get_frame_duration(hb_work_private_t * pv, int64_t pts) { int i = (pts >> FRAME_INFO_MAX2) & FRAME_INFO_MASK; return pv->frame_info[i].duration; } static hb_buffer_t* nal_encode(hb_work_object_t *w, x265_picture *pic_out, x265_nal *nal, uint32_t nnal) { hb_work_private_t *pv = w->private_data; hb_job_t *job = pv->job; hb_buffer_t *buf = NULL; int i; if (nnal <= 0) { return NULL; } buf = hb_video_buffer_init(job->width, job->height); if (buf == NULL) { return NULL; } buf->s.flags = 0; buf->size = 0; // copy the bitstream data for (i = 0; i < nnal; i++) { if (HB_HEVC_NALU_KEYFRAME(nal[i].type)) { buf->s.flags |= HB_FLAG_FRAMETYPE_REF; buf->s.flags |= HB_FLAG_FRAMETYPE_KEY; } memcpy(buf->data + buf->size, nal[i].payload, nal[i].sizeBytes); buf->size += nal[i].sizeBytes; } // use the pts to get the original frame's duration. buf->s.duration = get_frame_duration(pv, pic_out->pts); buf->s.stop = pic_out->pts + buf->s.duration; buf->s.start = pic_out->pts; buf->s.renderOffset = pic_out->dts; if (w->config->init_delay == 0 && pic_out->dts < 0) { w->config->init_delay -= pic_out->dts; } switch (pic_out->sliceType) { case X265_TYPE_IDR: buf->s.flags |= HB_FLAG_FRAMETYPE_REF; buf->s.flags |= HB_FLAG_FRAMETYPE_KEY; buf->s.frametype = HB_FRAME_IDR; break; case X265_TYPE_P: buf->s.flags |= HB_FLAG_FRAMETYPE_REF; buf->s.frametype = HB_FRAME_P; break; case X265_TYPE_B: buf->s.frametype = HB_FRAME_B; break; case X265_TYPE_BREF: buf->s.flags |= HB_FLAG_FRAMETYPE_REF; buf->s.frametype = HB_FRAME_BREF; break; case X265_TYPE_I: default: buf->s.flags |= HB_FLAG_FRAMETYPE_REF; buf->s.frametype = HB_FRAME_I; break; } if (buf->s.flags & HB_FLAG_FRAMETYPE_KEY) { hb_chapter_dequeue(pv->chapter_queue, buf); } // discard empty buffers (no video) if (buf->size <= 0) { hb_buffer_close(&buf); } return buf; } static hb_buffer_t* x265_encode(hb_work_object_t *w, hb_buffer_t *in) { hb_work_private_t *pv = w->private_data; hb_job_t *job = pv->job; x265_picture pic_in, pic_out; x265_nal *nal; uint32_t nnal; pv->api->picture_init(pv->param, &pic_in); pic_in.stride[0] = in->plane[0].stride; pic_in.stride[1] = in->plane[1].stride; pic_in.stride[2] = in->plane[2].stride; pic_in.planes[0] = in->plane[0].data; pic_in.planes[1] = in->plane[1].data; pic_in.planes[2] = in->plane[2].data; pic_in.poc = pv->frames_in++; pic_in.pts = in->s.start; pic_in.bitDepth = 8; if (in->s.new_chap && job->chapter_markers) { /* * Chapters have to start with an IDR frame so request that this * frame be coded as IDR. Since there may be up to 16 frames * currently buffered in the encoder, remember the timestamp so * when this frame finally pops out of the encoder we'll mark * its buffer as the start of a chapter. */ pic_in.sliceType = X265_TYPE_IDR; hb_chapter_enqueue(pv->chapter_queue, in); } else { pic_in.sliceType = X265_TYPE_AUTO; } if (pv->last_stop != AV_NOPTS_VALUE && pv->last_stop != in->s.start) { hb_log("encx265 input continuity err: last stop %"PRId64" start %"PRId64, pv->last_stop, in->s.start); } pv->last_stop = in->s.stop; save_frame_info(pv, in); if (pv->api->encoder_encode(pv->x265, &nal, &nnal, &pic_in, &pic_out) > 0) { return nal_encode(w, &pic_out, nal, nnal); } return NULL; } int encx265Work(hb_work_object_t *w, hb_buffer_t **buf_in, hb_buffer_t **buf_out) { hb_work_private_t *pv = w->private_data; hb_buffer_t *in = *buf_in; if (in->s.flags & HB_BUF_FLAG_EOF) { uint32_t nnal; x265_nal *nal; x265_picture pic_out; hb_buffer_list_t list; hb_buffer_list_clear(&list); // flush delayed frames while (pv->api->encoder_encode(pv->x265, &nal, &nnal, NULL, &pic_out) > 0) { hb_buffer_t *buf = nal_encode(w, &pic_out, nal, nnal); hb_buffer_list_append(&list, buf); } // add the EOF to the end of the chain hb_buffer_list_append(&list, in); *buf_out = hb_buffer_list_clear(&list); *buf_in = NULL; return HB_WORK_DONE; } *buf_out = x265_encode(w, in); return HB_WORK_OK; } const char* hb_x265_encopt_name(const char *name) { int i; for (i = 0; hb_x265_encopt_synonyms[i][0] != NULL; i++) if (!strcmp(name, hb_x265_encopt_synonyms[i][1])) return hb_x265_encopt_synonyms[i][0]; return name; } #endif