/* GStreamer NVENC plugin * Copyright (C) 2015 Centricular Ltd * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, * Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "gstnvbaseenc.h" #include #include #define GST_CAT_DEFAULT gst_nvenc_debug #if HAVE_NVENC_GST_GL #include #include #include #include #include #endif /* TODO: * - reset last_flow on FLUSH_STOP (seeking) */ /* This currently supports both 5.x and 6.x versions of the NvEncodeAPI.h * header which are mostly API compatible. */ #define N_BUFFERS_PER_FRAME 1 #define SUPPORTED_GL_APIS GST_GL_API_OPENGL3 /* magic pointer value we can put in the async queue to signal shut down */ #define SHUTDOWN_COOKIE ((gpointer)GINT_TO_POINTER (1)) #define parent_class gst_nv_base_enc_parent_class G_DEFINE_ABSTRACT_TYPE (GstNvBaseEnc, gst_nv_base_enc, GST_TYPE_VIDEO_ENCODER); #define GST_TYPE_NV_PRESET (gst_nv_preset_get_type()) static GType gst_nv_preset_get_type (void) { static GType nv_preset_type = 0; static const GEnumValue presets[] = { {GST_NV_PRESET_DEFAULT, "Default", "default"}, {GST_NV_PRESET_HP, "High Performance", "hp"}, {GST_NV_PRESET_HQ, "High Quality", "hq"}, /* {GST_NV_PRESET_BD, "BD", "bd"}, */ {GST_NV_PRESET_LOW_LATENCY_DEFAULT, "Low Latency", "low-latency"}, {GST_NV_PRESET_LOW_LATENCY_HQ, "Low Latency, High Quality", "low-latency-hq"}, {GST_NV_PRESET_LOW_LATENCY_HP, "Low Latency, High Performance", "low-latency-hp"}, {GST_NV_PRESET_LOSSLESS_DEFAULT, "Lossless", "lossless"}, {GST_NV_PRESET_LOSSLESS_HP, "Lossless, High Performance", "lossless-hp"}, {0, NULL, NULL}, }; if (!nv_preset_type) { nv_preset_type = g_enum_register_static ("GstNvPreset", presets); } return nv_preset_type; } static GUID _nv_preset_to_guid (GstNvPreset preset) { GUID null = { 0, }; switch (preset) { #define CASE(gst,nv) case G_PASTE(GST_NV_PRESET_,gst): return G_PASTE(G_PASTE(NV_ENC_PRESET_,nv),_GUID) CASE (DEFAULT, DEFAULT); CASE (HP, HP); CASE (HQ, HQ); /* CASE (BD, BD);*/ CASE (LOW_LATENCY_DEFAULT, LOW_LATENCY_DEFAULT); CASE (LOW_LATENCY_HQ, LOW_LATENCY_HQ); CASE (LOW_LATENCY_HP, LOW_LATENCY_HQ); CASE (LOSSLESS_DEFAULT, LOSSLESS_DEFAULT); CASE (LOSSLESS_HP, LOSSLESS_HP); #undef CASE default: return null; } } #define GST_TYPE_NV_RC_MODE (gst_nv_rc_mode_get_type()) static GType gst_nv_rc_mode_get_type (void) { static GType nv_rc_mode_type = 0; static const GEnumValue modes[] = { {GST_NV_RC_MODE_DEFAULT, "Default (from NVENC preset)", "default"}, {GST_NV_RC_MODE_CONSTQP, "Constant Quantization", "constqp"}, {GST_NV_RC_MODE_CBR, "Constant Bit Rate", "cbr"}, {GST_NV_RC_MODE_VBR, "Variable Bit Rate", "vbr"}, {GST_NV_RC_MODE_VBR_MINQP, "Variable Bit Rate (with minimum quantization parameter)", "vbr-minqp"}, {0, NULL, NULL}, }; if (!nv_rc_mode_type) { nv_rc_mode_type = g_enum_register_static ("GstNvRCMode", modes); } return nv_rc_mode_type; } static NV_ENC_PARAMS_RC_MODE _rc_mode_to_nv (GstNvRCMode mode) { switch (mode) { case GST_NV_RC_MODE_DEFAULT: return -1; #define CASE(gst,nv) case G_PASTE(GST_NV_RC_MODE_,gst): return G_PASTE(NV_ENC_PARAMS_RC_,nv) CASE (CONSTQP, CONSTQP); CASE (CBR, CBR); CASE (VBR, VBR); CASE (VBR_MINQP, VBR_MINQP); #undef CASE default: return -1; } } enum { PROP_0, PROP_DEVICE_ID, PROP_PRESET, PROP_BITRATE, PROP_RC_MODE, PROP_QP_MIN, PROP_QP_MAX, PROP_QP_CONST, PROP_GOP_SIZE, }; #define DEFAULT_PRESET GST_NV_PRESET_DEFAULT #define DEFAULT_BITRATE 0 #define DEFAULT_RC_MODE GST_NV_RC_MODE_DEFAULT #define DEFAULT_QP_MIN -1 #define DEFAULT_QP_MAX -1 #define DEFAULT_QP_CONST -1 #define DEFAULT_GOP_SIZE 75 /* This lock is needed to prevent the situation where multiple encoders are * initialised at the same time which appears to cause excessive CPU usage over * some period of time. */ G_LOCK_DEFINE_STATIC (initialization_lock); #if HAVE_NVENC_GST_GL struct gl_input_resource { GstGLMemory *gl_mem[GST_VIDEO_MAX_PLANES]; CUgraphicsResource cuda_texture; CUdeviceptr cuda_plane_pointers[GST_VIDEO_MAX_PLANES]; gpointer cuda_pointer; gsize cuda_stride; gsize cuda_num_bytes; NV_ENC_REGISTER_RESOURCE nv_resource; NV_ENC_MAP_INPUT_RESOURCE nv_mapped_resource; /* whether nv_mapped_resource was mapped via NvEncMapInputResource() * and therefore should unmap via NvEncUnmapInputResource or not */ gboolean mapped; }; #endif struct frame_state { gint n_buffers; gpointer in_bufs[N_BUFFERS_PER_FRAME]; gpointer out_bufs[N_BUFFERS_PER_FRAME]; }; static gboolean gst_nv_base_enc_open (GstVideoEncoder * enc); static gboolean gst_nv_base_enc_close (GstVideoEncoder * enc); static gboolean gst_nv_base_enc_start (GstVideoEncoder * enc); static gboolean gst_nv_base_enc_stop (GstVideoEncoder * enc); static void gst_nv_base_enc_set_context (GstElement * element, GstContext * context); static gboolean gst_nv_base_enc_sink_query (GstVideoEncoder * enc, GstQuery * query); static gboolean gst_nv_base_enc_set_format (GstVideoEncoder * enc, GstVideoCodecState * state); static GstFlowReturn gst_nv_base_enc_handle_frame (GstVideoEncoder * enc, GstVideoCodecFrame * frame); static void gst_nv_base_enc_free_buffers (GstNvBaseEnc * nvenc); static GstFlowReturn gst_nv_base_enc_finish (GstVideoEncoder * enc); static void gst_nv_base_enc_set_property (GObject * object, guint prop_id, const GValue * value, GParamSpec * pspec); static void gst_nv_base_enc_get_property (GObject * object, guint prop_id, GValue * value, GParamSpec * pspec); static void gst_nv_base_enc_finalize (GObject * obj); static GstCaps *gst_nv_base_enc_getcaps (GstVideoEncoder * enc, GstCaps * filter); static gboolean gst_nv_base_enc_stop_bitstream_thread (GstNvBaseEnc * nvenc, gboolean force); static void gst_nv_base_enc_class_init (GstNvBaseEncClass * klass) { GObjectClass *gobject_class = G_OBJECT_CLASS (klass); GstElementClass *element_class = GST_ELEMENT_CLASS (klass); GstVideoEncoderClass *videoenc_class = GST_VIDEO_ENCODER_CLASS (klass); gobject_class->set_property = gst_nv_base_enc_set_property; gobject_class->get_property = gst_nv_base_enc_get_property; gobject_class->finalize = gst_nv_base_enc_finalize; element_class->set_context = GST_DEBUG_FUNCPTR (gst_nv_base_enc_set_context); videoenc_class->open = GST_DEBUG_FUNCPTR (gst_nv_base_enc_open); videoenc_class->close = GST_DEBUG_FUNCPTR (gst_nv_base_enc_close); videoenc_class->start = GST_DEBUG_FUNCPTR (gst_nv_base_enc_start); videoenc_class->stop = GST_DEBUG_FUNCPTR (gst_nv_base_enc_stop); videoenc_class->set_format = GST_DEBUG_FUNCPTR (gst_nv_base_enc_set_format); videoenc_class->getcaps = GST_DEBUG_FUNCPTR (gst_nv_base_enc_getcaps); videoenc_class->handle_frame = GST_DEBUG_FUNCPTR (gst_nv_base_enc_handle_frame); videoenc_class->finish = GST_DEBUG_FUNCPTR (gst_nv_base_enc_finish); videoenc_class->sink_query = GST_DEBUG_FUNCPTR (gst_nv_base_enc_sink_query); g_object_class_install_property (gobject_class, PROP_DEVICE_ID, g_param_spec_uint ("cuda-device-id", "Cuda Device ID", "Set the GPU device to use for operations", 0, G_MAXUINT, 0, G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_PRESET, g_param_spec_enum ("preset", "Encoding Preset", "Encoding Preset", GST_TYPE_NV_PRESET, DEFAULT_PRESET, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_RC_MODE, g_param_spec_enum ("rc-mode", "RC Mode", "Rate Control Mode", GST_TYPE_NV_RC_MODE, DEFAULT_RC_MODE, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_QP_MIN, g_param_spec_int ("qp-min", "Minimum Quantizer", "Minimum quantizer (-1 = from NVENC preset)", -1, 51, DEFAULT_QP_MIN, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_QP_MAX, g_param_spec_int ("qp-max", "Maximum Quantizer", "Maximum quantizer (-1 = from NVENC preset)", -1, 51, DEFAULT_QP_MAX, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_QP_CONST, g_param_spec_int ("qp-const", "Constant Quantizer", "Constant quantizer (-1 = from NVENC preset)", -1, 51, DEFAULT_QP_CONST, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_GOP_SIZE, g_param_spec_int ("gop-size", "GOP size", "Number of frames between intra frames (-1 = infinite)", -1, G_MAXINT, DEFAULT_GOP_SIZE, (GParamFlags) (G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS))); g_object_class_install_property (gobject_class, PROP_BITRATE, g_param_spec_uint ("bitrate", "Bitrate", "Bitrate in kbit/sec (0 = from NVENC preset)", 0, 2000 * 1024, DEFAULT_BITRATE, G_PARAM_READWRITE | GST_PARAM_MUTABLE_PLAYING | G_PARAM_STATIC_STRINGS)); } static gboolean _get_supported_input_formats (GstNvBaseEnc * nvenc) { GstNvBaseEncClass *nvenc_class = GST_NV_BASE_ENC_GET_CLASS (nvenc); guint64 format_mask = 0; uint32_t i, num = 0; NV_ENC_BUFFER_FORMAT formats[64]; GValue val = G_VALUE_INIT; if (nvenc->input_formats) return TRUE; NvEncGetInputFormats (nvenc->encoder, nvenc_class->codec_id, formats, G_N_ELEMENTS (formats), &num); for (i = 0; i < num; ++i) { GST_INFO_OBJECT (nvenc, "input format: 0x%08x", formats[i]); /* Apparently we can just ignore the tiled formats and can feed * it the respective untiled planar format instead ?! */ switch (formats[i]) { case NV_ENC_BUFFER_FORMAT_NV12_PL: #if defined (NV_ENC_BUFFER_FORMAT_NV12_TILED16x16) case NV_ENC_BUFFER_FORMAT_NV12_TILED16x16: #endif #if defined (NV_ENC_BUFFER_FORMAT_NV12_TILED64x16) case NV_ENC_BUFFER_FORMAT_NV12_TILED64x16: #endif format_mask |= (1 << GST_VIDEO_FORMAT_NV12); break; case NV_ENC_BUFFER_FORMAT_YV12_PL: #if defined(NV_ENC_BUFFER_FORMAT_YV12_TILED16x16) case NV_ENC_BUFFER_FORMAT_YV12_TILED16x16: #endif #if defined (NV_ENC_BUFFER_FORMAT_YV12_TILED64x16) case NV_ENC_BUFFER_FORMAT_YV12_TILED64x16: #endif format_mask |= (1 << GST_VIDEO_FORMAT_YV12); break; case NV_ENC_BUFFER_FORMAT_IYUV_PL: #if defined (NV_ENC_BUFFER_FORMAT_IYUV_TILED16x16) case NV_ENC_BUFFER_FORMAT_IYUV_TILED16x16: #endif #if defined (NV_ENC_BUFFER_FORMAT_IYUV_TILED64x16) case NV_ENC_BUFFER_FORMAT_IYUV_TILED64x16: #endif format_mask |= (1 << GST_VIDEO_FORMAT_I420); break; case NV_ENC_BUFFER_FORMAT_YUV444_PL: #if defined (NV_ENC_BUFFER_FORMAT_YUV444_TILED16x16) case NV_ENC_BUFFER_FORMAT_YUV444_TILED16x16: #endif #if defined (NV_ENC_BUFFER_FORMAT_YUV444_TILED64x16) case NV_ENC_BUFFER_FORMAT_YUV444_TILED64x16: #endif { NV_ENC_CAPS_PARAM caps_param = { 0, }; int yuv444_supported = 0; caps_param.version = NV_ENC_CAPS_PARAM_VER; caps_param.capsToQuery = NV_ENC_CAPS_SUPPORT_YUV444_ENCODE; if (NvEncGetEncodeCaps (nvenc->encoder, nvenc_class->codec_id, &caps_param, &yuv444_supported) != NV_ENC_SUCCESS) yuv444_supported = 0; if (yuv444_supported) format_mask |= (1 << GST_VIDEO_FORMAT_Y444); break; } default: GST_FIXME ("unmapped input format: 0x%08x", formats[i]); break; } } if (format_mask == 0) return FALSE; GST_OBJECT_LOCK (nvenc); nvenc->input_formats = g_new0 (GValue, 1); /* process a second time so we can add formats in the order we want */ g_value_init (nvenc->input_formats, GST_TYPE_LIST); g_value_init (&val, G_TYPE_STRING); if ((format_mask & (1 << GST_VIDEO_FORMAT_NV12))) { g_value_set_static_string (&val, "NV12"); gst_value_list_append_value (nvenc->input_formats, &val); } if ((format_mask & (1 << GST_VIDEO_FORMAT_YV12))) { g_value_set_static_string (&val, "YV12"); gst_value_list_append_value (nvenc->input_formats, &val); } if ((format_mask & (1 << GST_VIDEO_FORMAT_I420))) { g_value_set_static_string (&val, "I420"); gst_value_list_append_value (nvenc->input_formats, &val); } if ((format_mask & (1 << GST_VIDEO_FORMAT_Y444))) { g_value_set_static_string (&val, "Y444"); gst_value_list_append_value (nvenc->input_formats, &val); } g_value_unset (&val); GST_OBJECT_UNLOCK (nvenc); return TRUE; } static gboolean gst_nv_base_enc_open (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); nvenc->cuda_ctx = gst_nvenc_create_cuda_context (nvenc->cuda_device_id); if (nvenc->cuda_ctx == NULL) { GST_ELEMENT_ERROR (enc, LIBRARY, INIT, (NULL), ("Failed to create CUDA context, perhaps CUDA is not supported.")); return FALSE; } { NV_ENC_OPEN_ENCODE_SESSION_EX_PARAMS params = { 0, }; NVENCSTATUS nv_ret; params.version = NV_ENC_OPEN_ENCODE_SESSION_EX_PARAMS_VER; params.apiVersion = NVENCAPI_VERSION; params.device = nvenc->cuda_ctx; params.deviceType = NV_ENC_DEVICE_TYPE_CUDA; nv_ret = NvEncOpenEncodeSessionEx (¶ms, &nvenc->encoder); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR ("Failed to create NVENC encoder session, ret=%d", nv_ret); if (gst_nvenc_destroy_cuda_context (nvenc->cuda_ctx)) nvenc->cuda_ctx = NULL; return FALSE; } GST_INFO ("created NVENC encoder %p", nvenc->encoder); } /* query supported input formats */ if (!_get_supported_input_formats (nvenc)) { GST_WARNING_OBJECT (nvenc, "No supported input formats"); gst_nv_base_enc_close (enc); return FALSE; } return TRUE; } static void gst_nv_base_enc_set_context (GstElement * element, GstContext * context) { #if HAVE_NVENC_GST_GL GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (element); gst_gl_handle_set_context (element, context, (GstGLDisplay **) & nvenc->display, (GstGLContext **) & nvenc->other_context); if (nvenc->display) gst_gl_display_filter_gl_api (GST_GL_DISPLAY (nvenc->display), SUPPORTED_GL_APIS); #endif GST_ELEMENT_CLASS (parent_class)->set_context (element, context); } static gboolean gst_nv_base_enc_sink_query (GstVideoEncoder * enc, GstQuery * query) { #if HAVE_NVENC_GST_GL GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); #endif switch (GST_QUERY_TYPE (query)) { #if HAVE_NVENC_GST_GL case GST_QUERY_CONTEXT:{ gboolean ret; ret = gst_gl_handle_context_query ((GstElement *) nvenc, query, nvenc->display, NULL, nvenc->other_context); if (nvenc->display) gst_gl_display_filter_gl_api (GST_GL_DISPLAY (nvenc->display), SUPPORTED_GL_APIS); if (ret) return ret; break; } #endif default: break; } return GST_VIDEO_ENCODER_CLASS (parent_class)->sink_query (enc, query); } static gboolean gst_nv_base_enc_start (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); nvenc->bitstream_pool = g_async_queue_new (); nvenc->bitstream_queue = g_async_queue_new (); nvenc->in_bufs_pool = g_async_queue_new (); nvenc->last_flow = GST_FLOW_OK; #if HAVE_NVENC_GST_GL { gst_gl_ensure_element_data (GST_ELEMENT (nvenc), (GstGLDisplay **) & nvenc->display, (GstGLContext **) & nvenc->other_context); if (nvenc->display) gst_gl_display_filter_gl_api (GST_GL_DISPLAY (nvenc->display), SUPPORTED_GL_APIS); } #endif return TRUE; } static gboolean gst_nv_base_enc_stop (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); gst_nv_base_enc_stop_bitstream_thread (nvenc, TRUE); gst_nv_base_enc_free_buffers (nvenc); if (nvenc->input_state) { gst_video_codec_state_unref (nvenc->input_state); nvenc->input_state = NULL; } if (nvenc->bitstream_pool) { g_async_queue_unref (nvenc->bitstream_pool); nvenc->bitstream_pool = NULL; } if (nvenc->bitstream_queue) { g_async_queue_unref (nvenc->bitstream_queue); nvenc->bitstream_queue = NULL; } if (nvenc->in_bufs_pool) { g_async_queue_unref (nvenc->in_bufs_pool); nvenc->in_bufs_pool = NULL; } if (nvenc->display) { gst_object_unref (nvenc->display); nvenc->display = NULL; } if (nvenc->other_context) { gst_object_unref (nvenc->other_context); nvenc->other_context = NULL; } return TRUE; } static GValue * _get_interlace_modes (GstNvBaseEnc * nvenc) { GstNvBaseEncClass *nvenc_class = GST_NV_BASE_ENC_GET_CLASS (nvenc); NV_ENC_CAPS_PARAM caps_param = { 0, }; GValue *list = g_new0 (GValue, 1); GValue val = G_VALUE_INIT; g_value_init (list, GST_TYPE_LIST); g_value_init (&val, G_TYPE_STRING); g_value_set_static_string (&val, "progressive"); gst_value_list_append_value (list, &val); caps_param.version = NV_ENC_CAPS_PARAM_VER; caps_param.capsToQuery = NV_ENC_CAPS_SUPPORT_FIELD_ENCODING; if (NvEncGetEncodeCaps (nvenc->encoder, nvenc_class->codec_id, &caps_param, &nvenc->interlace_modes) != NV_ENC_SUCCESS) nvenc->interlace_modes = 0; if (nvenc->interlace_modes >= 1) { g_value_set_static_string (&val, "interleaved"); gst_value_list_append_value (list, &val); g_value_set_static_string (&val, "mixed"); gst_value_list_append_and_take_value (list, &val); } /* TODO: figure out what nvenc frame based interlacing means in gst terms */ return list; } static GstCaps * gst_nv_base_enc_getcaps (GstVideoEncoder * enc, GstCaps * filter) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); GstCaps *supported_incaps = NULL; GstCaps *template_caps, *caps; GST_OBJECT_LOCK (nvenc); if (nvenc->input_formats != NULL) { GValue *val; template_caps = gst_pad_get_pad_template_caps (enc->sinkpad); supported_incaps = gst_caps_copy (template_caps); gst_caps_set_value (supported_incaps, "format", nvenc->input_formats); val = _get_interlace_modes (nvenc); gst_caps_set_value (supported_incaps, "interlace-mode", val); g_value_unset (val); g_free (val); GST_LOG_OBJECT (enc, "codec input caps %" GST_PTR_FORMAT, supported_incaps); GST_LOG_OBJECT (enc, " template caps %" GST_PTR_FORMAT, template_caps); caps = gst_caps_intersect (template_caps, supported_incaps); gst_caps_unref (template_caps); gst_caps_unref (supported_incaps); supported_incaps = caps; GST_LOG_OBJECT (enc, " supported caps %" GST_PTR_FORMAT, supported_incaps); } GST_OBJECT_UNLOCK (nvenc); caps = gst_video_encoder_proxy_getcaps (enc, supported_incaps, filter); if (supported_incaps) gst_caps_unref (supported_incaps); GST_DEBUG_OBJECT (nvenc, " returning caps %" GST_PTR_FORMAT, caps); return caps; } static gboolean gst_nv_base_enc_close (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); if (nvenc->encoder) { if (NvEncDestroyEncoder (nvenc->encoder) != NV_ENC_SUCCESS) return FALSE; nvenc->encoder = NULL; } if (nvenc->cuda_ctx) { if (!gst_nvenc_destroy_cuda_context (nvenc->cuda_ctx)) return FALSE; nvenc->cuda_ctx = NULL; } GST_OBJECT_LOCK (nvenc); if (nvenc->input_formats) g_value_unset (nvenc->input_formats); g_free (nvenc->input_formats); nvenc->input_formats = NULL; GST_OBJECT_UNLOCK (nvenc); if (nvenc->input_state) { gst_video_codec_state_unref (nvenc->input_state); nvenc->input_state = NULL; } if (nvenc->bitstream_pool != NULL) { g_assert (g_async_queue_length (nvenc->bitstream_pool) == 0); g_async_queue_unref (nvenc->bitstream_pool); nvenc->bitstream_pool = NULL; } return TRUE; } static void gst_nv_base_enc_init (GstNvBaseEnc * nvenc) { GstVideoEncoder *encoder = GST_VIDEO_ENCODER (nvenc); nvenc->preset_enum = DEFAULT_PRESET; nvenc->selected_preset = _nv_preset_to_guid (nvenc->preset_enum); nvenc->rate_control_mode = DEFAULT_RC_MODE; nvenc->qp_min = DEFAULT_QP_MIN; nvenc->qp_max = DEFAULT_QP_MAX; nvenc->qp_const = DEFAULT_QP_CONST; nvenc->bitrate = DEFAULT_BITRATE; nvenc->gop_size = DEFAULT_GOP_SIZE; GST_VIDEO_ENCODER_STREAM_LOCK (encoder); GST_VIDEO_ENCODER_STREAM_UNLOCK (encoder); } static void gst_nv_base_enc_finalize (GObject * obj) { G_OBJECT_CLASS (gst_nv_base_enc_parent_class)->finalize (obj); } static GstVideoCodecFrame * _find_frame_with_output_buffer (GstNvBaseEnc * nvenc, NV_ENC_OUTPUT_PTR out_buf) { GList *l, *walk = gst_video_encoder_get_frames (GST_VIDEO_ENCODER (nvenc)); GstVideoCodecFrame *ret = NULL; gint i; for (l = walk; l; l = l->next) { GstVideoCodecFrame *frame = (GstVideoCodecFrame *) l->data; struct frame_state *state = frame->user_data; if (!state) continue; for (i = 0; i < N_BUFFERS_PER_FRAME; i++) { if (!state->out_bufs[i]) break; if (state->out_bufs[i] == out_buf) ret = frame; } } if (ret) gst_video_codec_frame_ref (ret); g_list_free_full (walk, (GDestroyNotify) gst_video_codec_frame_unref); return ret; } static gpointer gst_nv_base_enc_bitstream_thread (gpointer user_data) { GstVideoEncoder *enc = user_data; GstNvBaseEnc *nvenc = user_data; /* overview of operation: * 1. retreive the next buffer submitted to the bitstream pool * 2. wait for that buffer to be ready from nvenc (LockBitsream) * 3. retreive the GstVideoCodecFrame associated with that buffer * 4. for each buffer in the frame * 4.1 (step 2): wait for that buffer to be ready from nvenc (LockBitsream) * 4.2 create an output GstBuffer from the nvenc buffers * 4.3 unlock the nvenc bitstream buffers UnlockBitsream * 5. finish_frame() * 6. cleanup */ do { GstBuffer *buffers[N_BUFFERS_PER_FRAME]; struct frame_state *state = NULL; GstVideoCodecFrame *frame = NULL; NVENCSTATUS nv_ret; GstFlowReturn flow = GST_FLOW_OK; gint i; { NV_ENC_LOCK_BITSTREAM lock_bs = { 0, }; NV_ENC_OUTPUT_PTR out_buf; for (i = 0; i < N_BUFFERS_PER_FRAME; i++) { /* get and lock bitstream buffers */ GstVideoCodecFrame *tmp_frame; if (state && i >= state->n_buffers) break; GST_LOG_OBJECT (enc, "wait for bitstream buffer.."); /* assumes buffers are submitted in order */ out_buf = g_async_queue_pop (nvenc->bitstream_queue); if ((gpointer) out_buf == SHUTDOWN_COOKIE) break; GST_LOG_OBJECT (nvenc, "waiting for output buffer %p to be ready", out_buf); lock_bs.version = NV_ENC_LOCK_BITSTREAM_VER; lock_bs.outputBitstream = out_buf; lock_bs.doNotWait = 0; /* FIXME: this would need to be updated for other slice modes */ lock_bs.sliceOffsets = NULL; nv_ret = NvEncLockBitstream (nvenc->encoder, &lock_bs); if (nv_ret != NV_ENC_SUCCESS) { /* FIXME: what to do here? */ GST_ELEMENT_ERROR (nvenc, STREAM, ENCODE, (NULL), ("Failed to lock bitstream buffer %p, ret %d", lock_bs.outputBitstream, nv_ret)); out_buf = SHUTDOWN_COOKIE; break; } GST_LOG_OBJECT (nvenc, "picture type %d", lock_bs.pictureType); tmp_frame = _find_frame_with_output_buffer (nvenc, out_buf); g_assert (tmp_frame != NULL); if (frame) g_assert (frame == tmp_frame); frame = tmp_frame; state = frame->user_data; g_assert (state->out_bufs[i] == out_buf); /* copy into output buffer */ buffers[i] = gst_buffer_new_allocate (NULL, lock_bs.bitstreamSizeInBytes, NULL); gst_buffer_fill (buffers[i], 0, lock_bs.bitstreamBufferPtr, lock_bs.bitstreamSizeInBytes); if (lock_bs.pictureType == NV_ENC_PIC_TYPE_IDR) { GST_DEBUG_OBJECT (nvenc, "This is a keyframe"); GST_VIDEO_CODEC_FRAME_SET_SYNC_POINT (frame); } /* TODO: use lock_bs.outputTimeStamp and lock_bs.outputDuration */ /* TODO: check pts/dts is handled properly if there are B-frames */ nv_ret = NvEncUnlockBitstream (nvenc->encoder, state->out_bufs[i]); if (nv_ret != NV_ENC_SUCCESS) { /* FIXME: what to do here? */ GST_ELEMENT_ERROR (nvenc, STREAM, ENCODE, (NULL), ("Failed to unlock bitstream buffer %p, ret %d", lock_bs.outputBitstream, nv_ret)); state->out_bufs[i] = SHUTDOWN_COOKIE; break; } GST_LOG_OBJECT (nvenc, "returning bitstream buffer %p to pool", state->out_bufs[i]); g_async_queue_push (nvenc->bitstream_pool, state->out_bufs[i]); } if (out_buf == SHUTDOWN_COOKIE) break; } { GstBuffer *output_buffer = gst_buffer_new (); for (i = 0; i < state->n_buffers; i++) output_buffer = gst_buffer_append (output_buffer, buffers[i]); frame->output_buffer = output_buffer; } for (i = 0; i < state->n_buffers; i++) { void *in_buf = state->in_bufs[i]; g_assert (in_buf != NULL); #if HAVE_NVENC_GST_GL if (nvenc->gl_input) { struct gl_input_resource *in_gl_resource = in_buf; nv_ret = NvEncUnmapInputResource (nvenc->encoder, in_gl_resource->nv_mapped_resource.mappedResource); in_gl_resource->mapped = FALSE; if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to unmap input resource %p, ret %d", in_gl_resource, nv_ret); break; } memset (&in_gl_resource->nv_mapped_resource, 0, sizeof (in_gl_resource->nv_mapped_resource)); } #endif g_async_queue_push (nvenc->in_bufs_pool, in_buf); } flow = gst_video_encoder_finish_frame (enc, frame); frame = NULL; if (flow != GST_FLOW_OK) { GST_INFO_OBJECT (enc, "got flow %s", gst_flow_get_name (flow)); g_atomic_int_set (&nvenc->last_flow, flow); break; } } while (TRUE); GST_INFO_OBJECT (nvenc, "exiting thread"); return NULL; } static gboolean gst_nv_base_enc_start_bitstream_thread (GstNvBaseEnc * nvenc) { gchar *name = g_strdup_printf ("%s-read-bits", GST_OBJECT_NAME (nvenc)); g_assert (nvenc->bitstream_thread == NULL); g_assert (g_async_queue_length (nvenc->bitstream_queue) == 0); nvenc->bitstream_thread = g_thread_try_new (name, gst_nv_base_enc_bitstream_thread, nvenc, NULL); g_free (name); if (nvenc->bitstream_thread == NULL) return FALSE; GST_INFO_OBJECT (nvenc, "started thread to read bitstream"); return TRUE; } static gboolean gst_nv_base_enc_stop_bitstream_thread (GstNvBaseEnc * nvenc, gboolean force) { gpointer out_buf; if (nvenc->bitstream_thread == NULL) return TRUE; if (force) { g_async_queue_lock (nvenc->bitstream_queue); g_async_queue_lock (nvenc->bitstream_pool); while ((out_buf = g_async_queue_try_pop_unlocked (nvenc->bitstream_queue))) { GST_INFO_OBJECT (nvenc, "stole bitstream buffer %p from queue", out_buf); g_async_queue_push_unlocked (nvenc->bitstream_pool, out_buf); } g_async_queue_push_unlocked (nvenc->bitstream_queue, SHUTDOWN_COOKIE); g_async_queue_unlock (nvenc->bitstream_pool); g_async_queue_unlock (nvenc->bitstream_queue); } else { /* wait for encoder to drain the remaining buffers */ g_async_queue_push (nvenc->bitstream_queue, SHUTDOWN_COOKIE); } if (!force) { /* temporary unlock during finish, so other thread can find and push frame */ GST_VIDEO_ENCODER_STREAM_UNLOCK (nvenc); } g_thread_join (nvenc->bitstream_thread); if (!force) GST_VIDEO_ENCODER_STREAM_LOCK (nvenc); nvenc->bitstream_thread = NULL; return TRUE; } static void gst_nv_base_enc_reset_queues (GstNvBaseEnc * nvenc, gboolean refill) { gpointer ptr; gint i; GST_INFO_OBJECT (nvenc, "clearing queues"); while ((ptr = g_async_queue_try_pop (nvenc->bitstream_queue))) { /* do nothing */ } while ((ptr = g_async_queue_try_pop (nvenc->bitstream_pool))) { /* do nothing */ } while ((ptr = g_async_queue_try_pop (nvenc->in_bufs_pool))) { /* do nothing */ } if (refill) { GST_INFO_OBJECT (nvenc, "refilling buffer pools"); for (i = 0; i < nvenc->n_bufs; ++i) { g_async_queue_push (nvenc->bitstream_pool, nvenc->input_bufs[i]); g_async_queue_push (nvenc->in_bufs_pool, nvenc->output_bufs[i]); } } } static void gst_nv_base_enc_free_buffers (GstNvBaseEnc * nvenc) { NVENCSTATUS nv_ret; guint i; if (nvenc->encoder == NULL) return; gst_nv_base_enc_reset_queues (nvenc, FALSE); for (i = 0; i < nvenc->n_bufs; ++i) { NV_ENC_OUTPUT_PTR out_buf = nvenc->output_bufs[i]; #if HAVE_NVENC_GST_GL if (nvenc->gl_input) { struct gl_input_resource *in_gl_resource = nvenc->input_bufs[i]; cuCtxPushCurrent (nvenc->cuda_ctx); if (in_gl_resource->mapped) { GST_LOG_OBJECT (nvenc, "Unmap resource %p", in_gl_resource); nv_ret = NvEncUnmapInputResource (nvenc->encoder, in_gl_resource->nv_mapped_resource.mappedResource); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to unmap input resource %p, ret %d", in_gl_resource, nv_ret); } } nv_ret = NvEncUnregisterResource (nvenc->encoder, in_gl_resource->nv_resource.registeredResource); if (nv_ret != NV_ENC_SUCCESS) GST_ERROR_OBJECT (nvenc, "Failed to unregister resource %p, ret %d", in_gl_resource, nv_ret); g_free (in_gl_resource); cuCtxPopCurrent (NULL); } else #endif { NV_ENC_INPUT_PTR in_buf = (NV_ENC_INPUT_PTR) nvenc->input_bufs[i]; GST_DEBUG_OBJECT (nvenc, "Destroying input buffer %p", in_buf); nv_ret = NvEncDestroyInputBuffer (nvenc->encoder, in_buf); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to destroy input buffer %p, ret %d", in_buf, nv_ret); } } GST_DEBUG_OBJECT (nvenc, "Destroying output bitstream buffer %p", out_buf); nv_ret = NvEncDestroyBitstreamBuffer (nvenc->encoder, out_buf); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to destroy output buffer %p, ret %d", out_buf, nv_ret); } } nvenc->n_bufs = 0; g_free (nvenc->output_bufs); nvenc->output_bufs = NULL; g_free (nvenc->input_bufs); nvenc->input_bufs = NULL; } static inline guint _get_plane_width (GstVideoInfo * info, guint plane) { if (GST_VIDEO_INFO_IS_YUV (info)) /* For now component width and plane width are the same and the * plane-component mapping matches */ return GST_VIDEO_INFO_COMP_WIDTH (info, plane); else /* RGB, GRAY */ return GST_VIDEO_INFO_WIDTH (info); } static inline guint _get_plane_height (GstVideoInfo * info, guint plane) { if (GST_VIDEO_INFO_IS_YUV (info)) /* For now component width and plane width are the same and the * plane-component mapping matches */ return GST_VIDEO_INFO_COMP_HEIGHT (info, plane); else /* RGB, GRAY */ return GST_VIDEO_INFO_HEIGHT (info); } static inline gsize _get_frame_data_height (GstVideoInfo * info) { gsize ret = 0; gint i; for (i = 0; i < GST_VIDEO_INFO_N_PLANES (info); i++) { ret += _get_plane_height (info, i); } return ret; } void gst_nv_base_enc_set_max_encode_size (GstNvBaseEnc * nvenc, guint max_width, guint max_height) { nvenc->max_encode_width = max_width; nvenc->max_encode_height = max_height; } void gst_nv_base_enc_get_max_encode_size (GstNvBaseEnc * nvenc, guint * max_width, guint * max_height) { *max_width = nvenc->max_encode_width; *max_height = nvenc->max_encode_height; } static gboolean gst_nv_base_enc_set_format (GstVideoEncoder * enc, GstVideoCodecState * state) { GstNvBaseEncClass *nvenc_class = GST_NV_BASE_ENC_GET_CLASS (enc); GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); GstVideoInfo *info = &state->info; GstVideoCodecState *old_state = nvenc->input_state; NV_ENC_RECONFIGURE_PARAMS reconfigure_params = { 0, }; NV_ENC_INITIALIZE_PARAMS init_params = { 0, }; NV_ENC_INITIALIZE_PARAMS *params; NV_ENC_PRESET_CONFIG preset_config = { 0, }; NVENCSTATUS nv_ret; g_atomic_int_set (&nvenc->reconfig, FALSE); if (old_state) { reconfigure_params.version = NV_ENC_RECONFIGURE_PARAMS_VER; params = &reconfigure_params.reInitEncodeParams; } else { params = &init_params; } params->version = NV_ENC_INITIALIZE_PARAMS_VER; params->encodeGUID = nvenc_class->codec_id; params->encodeWidth = GST_VIDEO_INFO_WIDTH (info); params->encodeHeight = GST_VIDEO_INFO_HEIGHT (info); { guint32 n_presets; GUID *presets; guint32 i; nv_ret = NvEncGetEncodePresetCount (nvenc->encoder, params->encodeGUID, &n_presets); if (nv_ret != NV_ENC_SUCCESS) { GST_ELEMENT_ERROR (nvenc, LIBRARY, SETTINGS, (NULL), ("Failed to get encoder presets")); return FALSE; } presets = g_new0 (GUID, n_presets); nv_ret = NvEncGetEncodePresetGUIDs (nvenc->encoder, params->encodeGUID, presets, n_presets, &n_presets); if (nv_ret != NV_ENC_SUCCESS) { GST_ELEMENT_ERROR (nvenc, LIBRARY, SETTINGS, (NULL), ("Failed to get encoder presets")); g_free (presets); return FALSE; } for (i = 0; i < n_presets; i++) { if (gst_nvenc_cmp_guid (presets[i], nvenc->selected_preset)) break; } g_free (presets); if (i >= n_presets) { GST_ELEMENT_ERROR (nvenc, LIBRARY, SETTINGS, (NULL), ("Selected preset not supported")); return FALSE; } params->presetGUID = nvenc->selected_preset; } params->enablePTD = 1; if (!old_state) { /* this sets the required buffer size and the maximum allowed size on * subsequent reconfigures */ /* FIXME: propertise this */ params->maxEncodeWidth = GST_VIDEO_INFO_WIDTH (info); params->maxEncodeHeight = GST_VIDEO_INFO_HEIGHT (info); gst_nv_base_enc_set_max_encode_size (nvenc, params->maxEncodeWidth, params->maxEncodeHeight); } else { guint max_width, max_height; gst_nv_base_enc_get_max_encode_size (nvenc, &max_width, &max_height); if (GST_VIDEO_INFO_WIDTH (info) > max_width || GST_VIDEO_INFO_HEIGHT (info) > max_height) { GST_ELEMENT_ERROR (nvenc, STREAM, FORMAT, ("%s", "Requested stream " "size is larger than the maximum configured size"), (NULL)); return FALSE; } } preset_config.version = NV_ENC_PRESET_CONFIG_VER; preset_config.presetCfg.version = NV_ENC_CONFIG_VER; nv_ret = NvEncGetEncodePresetConfig (nvenc->encoder, params->encodeGUID, params->presetGUID, &preset_config); if (nv_ret != NV_ENC_SUCCESS) { GST_ELEMENT_ERROR (nvenc, LIBRARY, SETTINGS, (NULL), ("Failed to get encode preset configuration: %d", nv_ret)); return FALSE; } params->encodeConfig = &preset_config.presetCfg; if (GST_VIDEO_INFO_IS_INTERLACED (info)) { if (GST_VIDEO_INFO_INTERLACE_MODE (info) == GST_VIDEO_INTERLACE_MODE_INTERLEAVED || GST_VIDEO_INFO_INTERLACE_MODE (info) == GST_VIDEO_INTERLACE_MODE_MIXED) { preset_config.presetCfg.frameFieldMode = NV_ENC_PARAMS_FRAME_FIELD_MODE_FIELD; } } if (info->fps_d > 0 && info->fps_n > 0) { params->frameRateNum = info->fps_n; params->frameRateDen = info->fps_d; } else { GST_FIXME_OBJECT (nvenc, "variable framerate"); } if (nvenc->rate_control_mode != GST_NV_RC_MODE_DEFAULT) { params->encodeConfig->rcParams.rateControlMode = _rc_mode_to_nv (nvenc->rate_control_mode); if (nvenc->bitrate > 0) { /* FIXME: this produces larger bitrates?! */ params->encodeConfig->rcParams.averageBitRate = nvenc->bitrate * 1024; params->encodeConfig->rcParams.maxBitRate = nvenc->bitrate * 1024; } if (nvenc->qp_const > 0) { params->encodeConfig->rcParams.constQP.qpInterB = nvenc->qp_const; params->encodeConfig->rcParams.constQP.qpInterP = nvenc->qp_const; params->encodeConfig->rcParams.constQP.qpIntra = nvenc->qp_const; } if (nvenc->qp_min >= 0) { params->encodeConfig->rcParams.enableMinQP = 1; params->encodeConfig->rcParams.minQP.qpInterB = nvenc->qp_min; params->encodeConfig->rcParams.minQP.qpInterP = nvenc->qp_min; params->encodeConfig->rcParams.minQP.qpIntra = nvenc->qp_min; } if (nvenc->qp_max >= 0) { params->encodeConfig->rcParams.enableMaxQP = 1; params->encodeConfig->rcParams.maxQP.qpInterB = nvenc->qp_max; params->encodeConfig->rcParams.maxQP.qpInterP = nvenc->qp_max; params->encodeConfig->rcParams.maxQP.qpIntra = nvenc->qp_max; } } if (nvenc->gop_size < 0) { params->encodeConfig->gopLength = NVENC_INFINITE_GOPLENGTH; params->encodeConfig->frameIntervalP = 1; } else if (nvenc->gop_size > 0) { params->encodeConfig->gopLength = nvenc->gop_size; } g_assert (nvenc_class->set_encoder_config); if (!nvenc_class->set_encoder_config (nvenc, state, params->encodeConfig)) { GST_ERROR_OBJECT (enc, "Subclass failed to set encoder configuration"); return FALSE; } G_LOCK (initialization_lock); if (old_state) { nv_ret = NvEncReconfigureEncoder (nvenc->encoder, &reconfigure_params); } else { nv_ret = NvEncInitializeEncoder (nvenc->encoder, params); } G_UNLOCK (initialization_lock); if (nv_ret != NV_ENC_SUCCESS) { GST_ELEMENT_ERROR (nvenc, LIBRARY, SETTINGS, (NULL), ("Failed to %sinit encoder: %d", old_state ? "re" : "", nv_ret)); return FALSE; } GST_INFO_OBJECT (nvenc, "configured encoder"); if (!old_state) { nvenc->input_info = *info; nvenc->gl_input = FALSE; } if (nvenc->input_state) gst_video_codec_state_unref (nvenc->input_state); nvenc->input_state = gst_video_codec_state_ref (state); GST_INFO_OBJECT (nvenc, "configured encoder"); /* now allocate some buffers only on first configuration */ if (!old_state) { #if HAVE_NVENC_GST_GL GstCapsFeatures *features; #endif guint num_macroblocks, i; guint input_width, input_height; input_width = GST_VIDEO_INFO_WIDTH (info); input_height = GST_VIDEO_INFO_HEIGHT (info); num_macroblocks = (GST_ROUND_UP_16 (input_width) >> 4) * (GST_ROUND_UP_16 (input_height) >> 4); nvenc->n_bufs = (num_macroblocks >= 8160) ? 32 : 48; /* input buffers */ nvenc->input_bufs = g_new0 (gpointer, nvenc->n_bufs); #if HAVE_NVENC_GST_GL features = gst_caps_get_features (state->caps, 0); if (gst_caps_features_contains (features, GST_CAPS_FEATURE_MEMORY_GL_MEMORY)) { guint pixel_depth = 0; nvenc->gl_input = TRUE; for (i = 0; i < GST_VIDEO_INFO_N_COMPONENTS (info); i++) { pixel_depth += GST_VIDEO_INFO_COMP_DEPTH (info, i); } cuCtxPushCurrent (nvenc->cuda_ctx); for (i = 0; i < nvenc->n_bufs; ++i) { struct gl_input_resource *in_gl_resource = g_new0 (struct gl_input_resource, 1); CUresult cu_ret; memset (&in_gl_resource->nv_resource, 0, sizeof (in_gl_resource->nv_resource)); memset (&in_gl_resource->nv_mapped_resource, 0, sizeof (in_gl_resource->nv_mapped_resource)); /* scratch buffer for non-contigious planer into a contigious buffer */ cu_ret = cuMemAllocPitch ((CUdeviceptr *) & in_gl_resource->cuda_pointer, &in_gl_resource->cuda_stride, input_width, _get_frame_data_height (info), 16); if (cu_ret != CUDA_SUCCESS) { const gchar *err; cuGetErrorString (cu_ret, &err); GST_ERROR_OBJECT (nvenc, "failed to alocate cuda scratch buffer " "ret %d error :%s", cu_ret, err); g_assert_not_reached (); } in_gl_resource->nv_resource.version = NV_ENC_REGISTER_RESOURCE_VER; in_gl_resource->nv_resource.resourceType = NV_ENC_INPUT_RESOURCE_TYPE_CUDADEVICEPTR; in_gl_resource->nv_resource.width = input_width; in_gl_resource->nv_resource.height = input_height; in_gl_resource->nv_resource.pitch = in_gl_resource->cuda_stride; in_gl_resource->nv_resource.bufferFormat = gst_nvenc_get_nv_buffer_format (GST_VIDEO_INFO_FORMAT (info)); in_gl_resource->nv_resource.resourceToRegister = in_gl_resource->cuda_pointer; nv_ret = NvEncRegisterResource (nvenc->encoder, &in_gl_resource->nv_resource); if (nv_ret != NV_ENC_SUCCESS) GST_ERROR_OBJECT (nvenc, "Failed to register resource %p, ret %d", in_gl_resource, nv_ret); nvenc->input_bufs[i] = in_gl_resource; g_async_queue_push (nvenc->in_bufs_pool, nvenc->input_bufs[i]); } cuCtxPopCurrent (NULL); } else #endif { for (i = 0; i < nvenc->n_bufs; ++i) { NV_ENC_CREATE_INPUT_BUFFER cin_buf = { 0, }; cin_buf.version = NV_ENC_CREATE_INPUT_BUFFER_VER; cin_buf.width = GST_ROUND_UP_32 (input_width); cin_buf.height = GST_ROUND_UP_32 (input_height); cin_buf.memoryHeap = NV_ENC_MEMORY_HEAP_SYSMEM_CACHED; cin_buf.bufferFmt = gst_nvenc_get_nv_buffer_format (GST_VIDEO_INFO_FORMAT (info)); nv_ret = NvEncCreateInputBuffer (nvenc->encoder, &cin_buf); if (nv_ret != NV_ENC_SUCCESS) { GST_WARNING_OBJECT (enc, "Failed to allocate input buffer: %d", nv_ret); /* FIXME: clean up */ return FALSE; } nvenc->input_bufs[i] = cin_buf.inputBuffer; GST_INFO_OBJECT (nvenc, "allocated input buffer %2d: %p", i, nvenc->input_bufs[i]); g_async_queue_push (nvenc->in_bufs_pool, nvenc->input_bufs[i]); } } /* output buffers */ nvenc->output_bufs = g_new0 (NV_ENC_OUTPUT_PTR, nvenc->n_bufs); for (i = 0; i < nvenc->n_bufs; ++i) { NV_ENC_CREATE_BITSTREAM_BUFFER cout_buf = { 0, }; cout_buf.version = NV_ENC_CREATE_BITSTREAM_BUFFER_VER; /* 1 MB should be large enough to hold most output frames. * NVENC will automatically increase this if it's not enough. */ cout_buf.size = 1024 * 1024; cout_buf.memoryHeap = NV_ENC_MEMORY_HEAP_SYSMEM_CACHED; G_LOCK (initialization_lock); nv_ret = NvEncCreateBitstreamBuffer (nvenc->encoder, &cout_buf); G_UNLOCK (initialization_lock); if (nv_ret != NV_ENC_SUCCESS) { GST_WARNING_OBJECT (enc, "Failed to allocate input buffer: %d", nv_ret); /* FIXME: clean up */ return FALSE; } nvenc->output_bufs[i] = cout_buf.bitstreamBuffer; GST_INFO_OBJECT (nvenc, "allocated output buffer %2d: %p", i, nvenc->output_bufs[i]); g_async_queue_push (nvenc->bitstream_pool, nvenc->output_bufs[i]); } #if 0 /* Get SPS/PPS */ { NV_ENC_SEQUENCE_PARAM_PAYLOAD seq_param = { 0 }; uint32_t seq_size = 0; seq_param.version = NV_ENC_SEQUENCE_PARAM_PAYLOAD_VER; seq_param.spsppsBuffer = g_alloca (1024); seq_param.inBufferSize = 1024; seq_param.outSPSPPSPayloadSize = &seq_size; nv_ret = NvEncGetSequenceParams (nvenc->encoder, &seq_param); if (nv_ret != NV_ENC_SUCCESS) { GST_WARNING_OBJECT (enc, "Failed to retrieve SPS/PPS: %d", nv_ret); return FALSE; } /* FIXME: use SPS/PPS */ GST_MEMDUMP_OBJECT (enc, "SPS/PPS", seq_param.spsppsBuffer, seq_size); } #endif } g_assert (nvenc_class->set_src_caps); if (!nvenc_class->set_src_caps (nvenc, state)) { GST_ERROR_OBJECT (nvenc, "Subclass failed to set output caps"); /* FIXME: clean up */ return FALSE; } return TRUE; } static inline guint _plane_get_n_components (GstVideoInfo * info, guint plane) { switch (GST_VIDEO_INFO_FORMAT (info)) { case GST_VIDEO_FORMAT_RGBx: case GST_VIDEO_FORMAT_BGRx: case GST_VIDEO_FORMAT_xRGB: case GST_VIDEO_FORMAT_xBGR: case GST_VIDEO_FORMAT_RGBA: case GST_VIDEO_FORMAT_BGRA: case GST_VIDEO_FORMAT_ARGB: case GST_VIDEO_FORMAT_ABGR: case GST_VIDEO_FORMAT_AYUV: return 4; case GST_VIDEO_FORMAT_RGB: case GST_VIDEO_FORMAT_BGR: case GST_VIDEO_FORMAT_RGB16: case GST_VIDEO_FORMAT_BGR16: return 3; case GST_VIDEO_FORMAT_GRAY16_BE: case GST_VIDEO_FORMAT_GRAY16_LE: case GST_VIDEO_FORMAT_YUY2: case GST_VIDEO_FORMAT_UYVY: return 2; case GST_VIDEO_FORMAT_NV12: case GST_VIDEO_FORMAT_NV21: return plane == 0 ? 1 : 2; case GST_VIDEO_FORMAT_GRAY8: case GST_VIDEO_FORMAT_Y444: case GST_VIDEO_FORMAT_Y42B: case GST_VIDEO_FORMAT_Y41B: case GST_VIDEO_FORMAT_I420: case GST_VIDEO_FORMAT_YV12: return 1; default: g_assert_not_reached (); return 1; } } #if HAVE_NVENC_GST_GL struct map_gl_input { GstNvBaseEnc *nvenc; GstVideoCodecFrame *frame; GstVideoInfo *info; struct gl_input_resource *in_gl_resource; }; static void _map_gl_input_buffer (GstGLContext * context, struct map_gl_input *data) { cudaError_t cuda_ret; guint8 *data_pointer; guint i; CUDA_MEMCPY2D param; cuCtxPushCurrent (data->nvenc->cuda_ctx); data_pointer = data->in_gl_resource->cuda_pointer; for (i = 0; i < GST_VIDEO_INFO_N_PLANES (data->info); i++) { guint plane_n_components; GstGLBuffer *gl_buf_obj; GstGLMemoryPBO *gl_mem; guint src_stride, dest_stride; gl_mem = (GstGLMemoryPBO *) gst_buffer_peek_memory (data->frame->input_buffer, i); g_return_if_fail (gst_is_gl_memory_pbo ((GstMemory *) gl_mem)); data->in_gl_resource->gl_mem[i] = GST_GL_MEMORY_CAST (gl_mem); plane_n_components = _plane_get_n_components (data->info, i); gl_buf_obj = (GstGLBuffer *) gl_mem->pbo; g_return_if_fail (gl_buf_obj != NULL); /* get the texture into the PBO */ gst_gl_memory_pbo_upload_transfer (gl_mem); gst_gl_memory_pbo_download_transfer (gl_mem); GST_LOG_OBJECT (data->nvenc, "attempting to copy texture %u into cuda", gl_mem->mem.tex_id); cuda_ret = cuGraphicsGLRegisterBuffer (&data->in_gl_resource->cuda_texture, gl_buf_obj->id, cudaGraphicsRegisterFlagsReadOnly); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to register GL texture %u to cuda " "ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } cuda_ret = cuGraphicsMapResources (1, &data->in_gl_resource->cuda_texture, 0); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to map GL texture %u into cuda " "ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } cuda_ret = cuGraphicsResourceGetMappedPointer (&data->in_gl_resource-> cuda_plane_pointers[i], &data->in_gl_resource->cuda_num_bytes, data->in_gl_resource->cuda_texture); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to get mapped pointer of map GL " "texture %u in cuda ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } src_stride = GST_VIDEO_INFO_PLANE_STRIDE (data->info, i); dest_stride = data->in_gl_resource->cuda_stride; /* copy into scratch buffer */ param.srcXInBytes = 0; param.srcY = 0; param.srcMemoryType = CU_MEMORYTYPE_DEVICE; param.srcDevice = data->in_gl_resource->cuda_plane_pointers[i]; param.srcPitch = src_stride; param.dstXInBytes = 0; param.dstY = 0; param.dstMemoryType = CU_MEMORYTYPE_DEVICE; param.dstDevice = (CUdeviceptr) data_pointer; param.dstPitch = dest_stride; param.WidthInBytes = _get_plane_width (data->info, i) * plane_n_components; param.Height = _get_plane_height (data->info, i); cuda_ret = cuMemcpy2D (¶m); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to copy GL texture %u into cuda " "ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } cuda_ret = cuGraphicsUnmapResources (1, &data->in_gl_resource->cuda_texture, 0); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to unmap GL texture %u from cuda " "ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } cuda_ret = cuGraphicsUnregisterResource (data->in_gl_resource->cuda_texture); if (cuda_ret != cudaSuccess) { GST_ERROR_OBJECT (data->nvenc, "failed to unregister GL texture %u from " "cuda ret :%d", gl_mem->mem.tex_id, cuda_ret); g_assert_not_reached (); } data_pointer = data_pointer + data->in_gl_resource->cuda_stride * _get_plane_height (&data->nvenc->input_info, i); } cuCtxPopCurrent (NULL); } #endif static GstFlowReturn _acquire_input_buffer (GstNvBaseEnc * nvenc, gpointer * input) { g_assert (input); GST_LOG_OBJECT (nvenc, "acquiring input buffer.."); GST_VIDEO_ENCODER_STREAM_UNLOCK (nvenc); *input = g_async_queue_pop (nvenc->in_bufs_pool); GST_VIDEO_ENCODER_STREAM_LOCK (nvenc); return GST_FLOW_OK; } static GstFlowReturn _submit_input_buffer (GstNvBaseEnc * nvenc, GstVideoCodecFrame * frame, GstVideoFrame * vframe, void *inputBuffer, void *inputBufferPtr, NV_ENC_BUFFER_FORMAT bufferFormat, void *outputBufferPtr) { GstNvBaseEncClass *nvenc_class = GST_NV_BASE_ENC_GET_CLASS (nvenc); NV_ENC_PIC_PARAMS pic_params = { 0, }; NVENCSTATUS nv_ret; GST_LOG_OBJECT (nvenc, "%u: input buffer %p, output buffer %p, " "pts %" GST_TIME_FORMAT, frame->system_frame_number, inputBuffer, outputBufferPtr, GST_TIME_ARGS (frame->pts)); pic_params.version = NV_ENC_PIC_PARAMS_VER; pic_params.inputBuffer = inputBufferPtr; pic_params.bufferFmt = bufferFormat; pic_params.inputWidth = GST_VIDEO_FRAME_WIDTH (vframe); pic_params.inputHeight = GST_VIDEO_FRAME_HEIGHT (vframe); pic_params.outputBitstream = outputBufferPtr; pic_params.completionEvent = NULL; if (GST_VIDEO_FRAME_IS_INTERLACED (vframe)) { if (GST_VIDEO_FRAME_IS_TFF (vframe)) pic_params.pictureStruct = NV_ENC_PIC_STRUCT_FIELD_TOP_BOTTOM; else pic_params.pictureStruct = NV_ENC_PIC_STRUCT_FIELD_BOTTOM_TOP; } else { pic_params.pictureStruct = NV_ENC_PIC_STRUCT_FRAME; } pic_params.inputTimeStamp = frame->pts; pic_params.inputDuration = GST_CLOCK_TIME_IS_VALID (frame->duration) ? frame->duration : 0; pic_params.frameIdx = frame->system_frame_number; if (GST_VIDEO_CODEC_FRAME_IS_FORCE_KEYFRAME (frame)) pic_params.encodePicFlags = NV_ENC_PIC_FLAG_FORCEIDR; else pic_params.encodePicFlags = 0; if (nvenc_class->set_pic_params && !nvenc_class->set_pic_params (nvenc, frame, &pic_params)) { GST_ERROR_OBJECT (nvenc, "Subclass failed to submit buffer"); return GST_FLOW_ERROR; } nv_ret = NvEncEncodePicture (nvenc->encoder, &pic_params); if (nv_ret == NV_ENC_SUCCESS) { GST_LOG_OBJECT (nvenc, "Encoded picture"); } else if (nv_ret == NV_ENC_ERR_NEED_MORE_INPUT) { /* FIXME: we should probably queue pending output buffers here and only * submit them to the async queue once we got sucess back */ GST_DEBUG_OBJECT (nvenc, "Encoded picture (encoder needs more input)"); } else { GST_ERROR_OBJECT (nvenc, "Failed to encode picture: %d", nv_ret); GST_DEBUG_OBJECT (nvenc, "re-enqueueing input buffer %p", inputBuffer); g_async_queue_push (nvenc->in_bufs_pool, inputBuffer); GST_DEBUG_OBJECT (nvenc, "re-enqueueing output buffer %p", outputBufferPtr); g_async_queue_push (nvenc->bitstream_pool, outputBufferPtr); return GST_FLOW_ERROR; } g_async_queue_push (nvenc->bitstream_queue, outputBufferPtr); return GST_FLOW_OK; } static GstFlowReturn gst_nv_base_enc_handle_frame (GstVideoEncoder * enc, GstVideoCodecFrame * frame) { gpointer input_buffer = NULL; GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); NV_ENC_OUTPUT_PTR out_buf; NVENCSTATUS nv_ret; GstVideoFrame vframe; GstVideoInfo *info = &nvenc->input_state->info; GstFlowReturn flow = GST_FLOW_OK; GstMapFlags in_map_flags = GST_MAP_READ; struct frame_state *state = NULL; guint frame_n = 0; g_assert (nvenc->encoder != NULL); if (g_atomic_int_compare_and_exchange (&nvenc->reconfig, TRUE, FALSE)) { if (!gst_nv_base_enc_set_format (enc, nvenc->input_state)) return GST_FLOW_ERROR; } #if HAVE_NVENC_GST_GL if (nvenc->gl_input) in_map_flags |= GST_MAP_GL; #endif if (!gst_video_frame_map (&vframe, info, frame->input_buffer, in_map_flags)) return GST_FLOW_ERROR; /* make sure our thread that waits for output to be ready is started */ if (nvenc->bitstream_thread == NULL) { if (!gst_nv_base_enc_start_bitstream_thread (nvenc)) goto error; } flow = _acquire_input_buffer (nvenc, &input_buffer); if (flow != GST_FLOW_OK) goto out; if (input_buffer == NULL) goto error; state = frame->user_data; if (!state) state = g_new0 (struct frame_state, 1); state->n_buffers = 1; #if HAVE_NVENC_GST_GL if (nvenc->gl_input) { struct gl_input_resource *in_gl_resource = input_buffer; struct map_gl_input data; GST_LOG_OBJECT (enc, "got input buffer %p", in_gl_resource); in_gl_resource->gl_mem[0] = (GstGLMemory *) gst_buffer_peek_memory (frame->input_buffer, 0); g_assert (gst_is_gl_memory ((GstMemory *) in_gl_resource->gl_mem[0])); data.nvenc = nvenc; data.frame = frame; data.info = &vframe.info; data.in_gl_resource = in_gl_resource; gst_gl_context_thread_add (in_gl_resource->gl_mem[0]->mem.context, (GstGLContextThreadFunc) _map_gl_input_buffer, &data); in_gl_resource->nv_mapped_resource.version = NV_ENC_MAP_INPUT_RESOURCE_VER; in_gl_resource->nv_mapped_resource.registeredResource = in_gl_resource->nv_resource.registeredResource; nv_ret = NvEncMapInputResource (nvenc->encoder, &in_gl_resource->nv_mapped_resource); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to map input resource %p, ret %d", in_gl_resource, nv_ret); goto error; } in_gl_resource->mapped = TRUE; out_buf = g_async_queue_try_pop (nvenc->bitstream_pool); if (out_buf == NULL) { GST_DEBUG_OBJECT (nvenc, "wait for output buf to become available again"); out_buf = g_async_queue_pop (nvenc->bitstream_pool); } state->in_bufs[frame_n] = in_gl_resource; state->out_bufs[frame_n++] = out_buf; frame->user_data = state; frame->user_data_destroy_notify = (GDestroyNotify) g_free; flow = _submit_input_buffer (nvenc, frame, &vframe, in_gl_resource, in_gl_resource->nv_mapped_resource.mappedResource, in_gl_resource->nv_mapped_resource.mappedBufferFmt, out_buf); /* encoder will keep frame in list internally, we'll look it up again later * in the thread where we get the output buffers and finish it there */ gst_video_codec_frame_unref (frame); frame = NULL; } #endif if (!nvenc->gl_input) { NV_ENC_LOCK_INPUT_BUFFER in_buf_lock = { 0, }; NV_ENC_INPUT_PTR in_buf = input_buffer; guint8 *src, *dest; guint src_stride, dest_stride; guint height, width; guint y; GST_LOG_OBJECT (enc, "got input buffer %p", in_buf); in_buf_lock.version = NV_ENC_LOCK_INPUT_BUFFER_VER; in_buf_lock.inputBuffer = in_buf; nv_ret = NvEncLockInputBuffer (nvenc->encoder, &in_buf_lock); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to lock input buffer: %d", nv_ret); /* FIXME: post proper error message */ goto error; } GST_LOG_OBJECT (nvenc, "Locked input buffer %p", in_buf); width = GST_VIDEO_FRAME_WIDTH (&vframe); height = GST_VIDEO_FRAME_HEIGHT (&vframe); /* copy Y plane */ src = GST_VIDEO_FRAME_PLANE_DATA (&vframe, 0); src_stride = GST_VIDEO_FRAME_PLANE_STRIDE (&vframe, 0); dest = in_buf_lock.bufferDataPtr; dest_stride = in_buf_lock.pitch; for (y = 0; y < height; ++y) { memcpy (dest, src, width); dest += dest_stride; src += src_stride; } if (GST_VIDEO_FRAME_FORMAT (&vframe) == GST_VIDEO_FORMAT_NV12) { /* copy UV plane */ src = GST_VIDEO_FRAME_PLANE_DATA (&vframe, 1); src_stride = GST_VIDEO_FRAME_PLANE_STRIDE (&vframe, 1); dest = (guint8 *) in_buf_lock.bufferDataPtr + GST_ROUND_UP_32 (height) * in_buf_lock.pitch; dest_stride = in_buf_lock.pitch; for (y = 0; y < GST_ROUND_UP_2 (height) / 2; ++y) { memcpy (dest, src, width); dest += dest_stride; src += src_stride; } } else if (GST_VIDEO_FRAME_FORMAT (&vframe) == GST_VIDEO_FORMAT_I420) { guint8 *dest_u, *dest_v; dest_u = (guint8 *) in_buf_lock.bufferDataPtr + GST_ROUND_UP_32 (height) * in_buf_lock.pitch; dest_v = dest_u + ((GST_ROUND_UP_32 (height) / 2) * (in_buf_lock.pitch / 2)); dest_stride = in_buf_lock.pitch / 2; /* copy U plane */ src = GST_VIDEO_FRAME_PLANE_DATA (&vframe, 1); src_stride = GST_VIDEO_FRAME_PLANE_STRIDE (&vframe, 1); dest = dest_u; for (y = 0; y < GST_ROUND_UP_2 (height) / 2; ++y) { memcpy (dest, src, width / 2); dest += dest_stride; src += src_stride; } /* copy V plane */ src = GST_VIDEO_FRAME_PLANE_DATA (&vframe, 2); src_stride = GST_VIDEO_FRAME_PLANE_STRIDE (&vframe, 2); dest = dest_v; for (y = 0; y < GST_ROUND_UP_2 (height) / 2; ++y) { memcpy (dest, src, width / 2); dest += dest_stride; src += src_stride; } } else { // FIXME: this only works for NV12 and I420 g_assert_not_reached (); } nv_ret = NvEncUnlockInputBuffer (nvenc->encoder, in_buf); if (nv_ret != NV_ENC_SUCCESS) { GST_ERROR_OBJECT (nvenc, "Failed to unlock input buffer: %d", nv_ret); goto error; } out_buf = g_async_queue_try_pop (nvenc->bitstream_pool); if (out_buf == NULL) { GST_DEBUG_OBJECT (nvenc, "wait for output buf to become available again"); out_buf = g_async_queue_pop (nvenc->bitstream_pool); } state->in_bufs[frame_n] = in_buf; state->out_bufs[frame_n++] = out_buf; frame->user_data = state; frame->user_data_destroy_notify = (GDestroyNotify) g_free; flow = _submit_input_buffer (nvenc, frame, &vframe, in_buf, in_buf, gst_nvenc_get_nv_buffer_format (GST_VIDEO_INFO_FORMAT (info)), out_buf); /* encoder will keep frame in list internally, we'll look it up again later * in the thread where we get the output buffers and finish it there */ gst_video_codec_frame_unref (frame); frame = NULL; } if (flow != GST_FLOW_OK) goto out; flow = g_atomic_int_get (&nvenc->last_flow); out: gst_video_frame_unmap (&vframe); return flow; error: flow = GST_FLOW_ERROR; if (state) g_free (state); if (input_buffer) g_free (input_buffer); goto out; } static gboolean gst_nv_base_enc_drain_encoder (GstNvBaseEnc * nvenc) { NV_ENC_PIC_PARAMS pic_params = { 0, }; NVENCSTATUS nv_ret; GST_INFO_OBJECT (nvenc, "draining encoder"); if (nvenc->input_state == NULL) { GST_DEBUG_OBJECT (nvenc, "no input state, nothing to do"); return TRUE; } pic_params.version = NV_ENC_PIC_PARAMS_VER; pic_params.encodePicFlags = NV_ENC_PIC_FLAG_EOS; nv_ret = NvEncEncodePicture (nvenc->encoder, &pic_params); if (nv_ret != NV_ENC_SUCCESS) { GST_LOG_OBJECT (nvenc, "Failed to drain encoder, ret %d", nv_ret); return FALSE; } return TRUE; } static GstFlowReturn gst_nv_base_enc_finish (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); if (!gst_nv_base_enc_drain_encoder (nvenc)) return GST_FLOW_ERROR; gst_nv_base_enc_stop_bitstream_thread (nvenc, FALSE); return GST_FLOW_OK; } #if 0 static gboolean gst_nv_base_enc_flush (GstVideoEncoder * enc) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (enc); GST_INFO_OBJECT (nvenc, "done flushing encoder"); return TRUE; } #endif static void gst_nv_base_enc_schedule_reconfig (GstNvBaseEnc * nvenc) { g_atomic_int_set (&nvenc->reconfig, TRUE); } static void gst_nv_base_enc_set_property (GObject * object, guint prop_id, const GValue * value, GParamSpec * pspec) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (object); switch (prop_id) { case PROP_DEVICE_ID: nvenc->cuda_device_id = g_value_get_uint (value); break; case PROP_PRESET: nvenc->preset_enum = g_value_get_enum (value); nvenc->selected_preset = _nv_preset_to_guid (nvenc->preset_enum); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_RC_MODE: nvenc->rate_control_mode = g_value_get_enum (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_QP_MIN: nvenc->qp_min = g_value_get_int (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_QP_MAX: nvenc->qp_max = g_value_get_int (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_QP_CONST: nvenc->qp_const = g_value_get_int (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_BITRATE: nvenc->bitrate = g_value_get_uint (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; case PROP_GOP_SIZE: nvenc->gop_size = g_value_get_int (value); gst_nv_base_enc_schedule_reconfig (nvenc); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } } static void gst_nv_base_enc_get_property (GObject * object, guint prop_id, GValue * value, GParamSpec * pspec) { GstNvBaseEnc *nvenc = GST_NV_BASE_ENC (object); switch (prop_id) { case PROP_DEVICE_ID: g_value_set_uint (value, nvenc->cuda_device_id); break; case PROP_PRESET: g_value_set_enum (value, nvenc->preset_enum); break; case PROP_RC_MODE: g_value_set_enum (value, nvenc->rate_control_mode); break; case PROP_QP_MIN: g_value_set_int (value, nvenc->qp_min); break; case PROP_QP_MAX: g_value_set_int (value, nvenc->qp_max); break; case PROP_QP_CONST: g_value_set_int (value, nvenc->qp_const); break; case PROP_BITRATE: g_value_set_uint (value, nvenc->bitrate); break; case PROP_GOP_SIZE: g_value_set_int (value, nvenc->gop_size); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } }