/* GStreamer * Copyright (C) 2021 Sebastian Dröge * * 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 Street, Suite 500, * Boston, MA 02110-1335, USA. */ /** * SECTION:element-ajasrc * * Source element for [AJA](https://www.aja.com) capture cards. * * ## Example usage * * Capture 1080p30 audio/video and display it locally * * ```sh * gst-launch-1.0 ajasrc video-format=1080p-3000 ! ajasrcdemux name=d \ * d.video ! queue max-size-bytes=0 max-size-buffers=0 max-size-time=1000000000 ! videoconvert ! autovideosink \ * d.audio ! queue max-size-bytes=0 max-size-buffers=0 max-size-time=1000000000 ! audioconvert ! audioresample ! autoaudiosink * ``` * * Capture 1080p30 audio/video and directly output it again on the same card * * ```sh * gst-launch-1.0 ajasrc video-format=1080p-3000 channel=1 input-source=sdi-1 audio-system=2 ! ajasrcdemux name=d \ * d.video ! queue max-size-bytes=0 max-size-buffers=0 max-size-time=1000000000 ! c.video \ * d.audio ! queue max-size-bytes=0 max-size-buffers=0 max-size-time=1000000000 ! c.audio \ * ajasinkcombiner name=c ! ajasink channel=0 reference-source=input-1 * ``` * * Since: 1.24 * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include "gstajacommon.h" #include "gstajasrc.h" GST_DEBUG_CATEGORY_STATIC(gst_aja_src_debug); #define GST_CAT_DEFAULT gst_aja_src_debug #define DEFAULT_DEVICE_IDENTIFIER ("0") #define DEFAULT_CHANNEL (::NTV2_CHANNEL1) #define DEFAULT_VIDEO_FORMAT (GST_AJA_VIDEO_FORMAT_AUTO) #define DEFAULT_AUDIO_SYSTEM (GST_AJA_AUDIO_SYSTEM_AUTO) #define DEFAULT_INPUT_SOURCE (GST_AJA_INPUT_SOURCE_AUTO) #define DEFAULT_SDI_MODE (GST_AJA_SDI_MODE_SINGLE_LINK) #define DEFAULT_AUDIO_SOURCE (GST_AJA_AUDIO_SOURCE_EMBEDDED) #define DEFAULT_EMBEDDED_AUDIO_INPUT (GST_AJA_EMBEDDED_AUDIO_INPUT_AUTO) #define DEFAULT_TIMECODE_INDEX (GST_AJA_TIMECODE_INDEX_VITC) #define DEFAULT_RP188 (TRUE) #define DEFAULT_REFERENCE_SOURCE (GST_AJA_REFERENCE_SOURCE_FREERUN) #define DEFAULT_CLOSED_CAPTION_CAPTURE_MODE \ (GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_AND_CEA608) #define DEFAULT_QUEUE_SIZE (16) #define DEFAULT_START_FRAME (8) #define DEFAULT_END_FRAME (8) #define DEFAULT_CAPTURE_CPU_CORE (G_MAXUINT) #define DEFAULT_ATTACH_ANCILLARY_META (FALSE) enum { PROP_0, PROP_DEVICE_IDENTIFIER, PROP_CHANNEL, PROP_VIDEO_FORMAT, PROP_AUDIO_SYSTEM, PROP_INPUT_SOURCE, PROP_SDI_MODE, PROP_AUDIO_SOURCE, PROP_EMBEDDED_AUDIO_INPUT, PROP_TIMECODE_INDEX, PROP_RP188, PROP_REFERENCE_SOURCE, PROP_CLOSED_CAPTION_CAPTURE_MODE, PROP_START_FRAME, PROP_END_FRAME, PROP_QUEUE_SIZE, PROP_CAPTURE_CPU_CORE, PROP_SIGNAL, PROP_ATTACH_ANCILLARY_META, }; // Make these plain C structs for usage in GstQueueArray G_BEGIN_DECLS typedef enum { QUEUE_ITEM_TYPE_DUMMY, QUEUE_ITEM_TYPE_FRAME, QUEUE_ITEM_TYPE_SIGNAL_CHANGE, QUEUE_ITEM_TYPE_ERROR, QUEUE_ITEM_TYPE_FRAMES_DROPPED, } QueueItemType; typedef struct { QueueItemType type; union { // For DUMMY struct { gchar dummy; } dummy; // For FRAME struct { GstClockTime capture_time; GstBuffer *video_buffer; GstBuffer *audio_buffer; GstBuffer *anc_buffer, *anc_buffer2; NTV2_RP188 tc; NTV2VideoFormat detected_format; guint32 vpid; } frame; // For SIGNAL_CHANGE struct { gboolean have_signal; NTV2VideoFormat detected_format; guint32 vpid; } signal_change; // For ERROR struct { GstMessage *msg; } error; // For FRAMES_DROPPED struct { gboolean driver_side; GstClockTime timestamp_start, timestamp_end; } frames_dropped; }; } QueueItem; G_END_DECLS static void queue_item_clear(QueueItem *item) { switch (item->type) { case QUEUE_ITEM_TYPE_DUMMY: break; case QUEUE_ITEM_TYPE_FRAME: gst_clear_buffer(&item->frame.video_buffer); gst_clear_buffer(&item->frame.audio_buffer); gst_clear_buffer(&item->frame.anc_buffer); gst_clear_buffer(&item->frame.anc_buffer2); item->frame.tc.~NTV2_RP188(); break; case QUEUE_ITEM_TYPE_SIGNAL_CHANGE: break; case QUEUE_ITEM_TYPE_ERROR: gst_clear_message(&item->error.msg); break; case QUEUE_ITEM_TYPE_FRAMES_DROPPED: break; } item->type = QUEUE_ITEM_TYPE_DUMMY; } static void gst_aja_src_set_property(GObject *object, guint property_id, const GValue *value, GParamSpec *pspec); static void gst_aja_src_get_property(GObject *object, guint property_id, GValue *value, GParamSpec *pspec); static void gst_aja_src_constructed(GObject *object); static void gst_aja_src_finalize(GObject *object); static GstCaps *gst_aja_src_get_caps(GstBaseSrc *bsrc, GstCaps *filter); static gboolean gst_aja_src_query(GstBaseSrc *bsrc, GstQuery *query); static gboolean gst_aja_src_unlock(GstBaseSrc *bsrc); static gboolean gst_aja_src_unlock_stop(GstBaseSrc *bsrc); static GstFlowReturn gst_aja_src_create(GstPushSrc *psrc, GstBuffer **buffer); static gboolean gst_aja_src_open(GstAjaSrc *src); static gboolean gst_aja_src_close(GstAjaSrc *src); static gboolean gst_aja_src_stop(GstAjaSrc *src); static GstStateChangeReturn gst_aja_src_change_state(GstElement *element, GstStateChange transition); static GstClock *gst_aja_src_provide_clock(GstElement *element); static void capture_thread_func(AJAThread *thread, void *data); #define parent_class gst_aja_src_parent_class G_DEFINE_TYPE(GstAjaSrc, gst_aja_src, GST_TYPE_PUSH_SRC); static void gst_aja_src_class_init(GstAjaSrcClass *klass) { GObjectClass *gobject_class = G_OBJECT_CLASS(klass); GstElementClass *element_class = GST_ELEMENT_CLASS(klass); GstBaseSrcClass *basesrc_class = GST_BASE_SRC_CLASS(klass); GstPushSrcClass *pushsrc_class = GST_PUSH_SRC_CLASS(klass); GstCaps *templ_caps; gobject_class->set_property = gst_aja_src_set_property; gobject_class->get_property = gst_aja_src_get_property; gobject_class->constructed = gst_aja_src_constructed; gobject_class->finalize = gst_aja_src_finalize; g_object_class_install_property( gobject_class, PROP_DEVICE_IDENTIFIER, g_param_spec_string( "device-identifier", "Device identifier", "Input device instance to use", DEFAULT_DEVICE_IDENTIFIER, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_CHANNEL, g_param_spec_uint( "channel", "Channel", "Channel to use", 0, NTV2_MAX_NUM_CHANNELS - 1, DEFAULT_CHANNEL, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_VIDEO_FORMAT, g_param_spec_enum( "video-format", "Video Format", "Video format to use", GST_TYPE_AJA_VIDEO_FORMAT, DEFAULT_VIDEO_FORMAT, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_QUEUE_SIZE, g_param_spec_uint( "queue-size", "Queue Size", "Size of internal queue in number of video frames. " "Half of this is allocated as device buffers and equal to the " "latency.", 1, G_MAXINT, DEFAULT_QUEUE_SIZE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS))); g_object_class_install_property( gobject_class, PROP_START_FRAME, g_param_spec_uint( "start-frame", "Start Frame", "Start frame buffer to be used for capturing (automatically assign " "that many frames if same number as end-frame).", 0, G_MAXINT, DEFAULT_START_FRAME, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS))); g_object_class_install_property( gobject_class, PROP_END_FRAME, g_param_spec_uint( "end-frame", "End Frame", "End frame buffer to be used for capturing (automatically assign " "that many frames if same number as start-frame).", 0, G_MAXINT, DEFAULT_END_FRAME, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS))); g_object_class_install_property( gobject_class, PROP_AUDIO_SYSTEM, g_param_spec_enum( "audio-system", "Audio System", "Audio system to use", GST_TYPE_AJA_AUDIO_SYSTEM, DEFAULT_AUDIO_SYSTEM, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_INPUT_SOURCE, g_param_spec_enum( "input-source", "Input Source", "Input source to use", GST_TYPE_AJA_INPUT_SOURCE, DEFAULT_INPUT_SOURCE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_SDI_MODE, g_param_spec_enum( "sdi-input-mode", "SDI Input Mode", "SDI input mode to use", GST_TYPE_AJA_SDI_MODE, DEFAULT_SDI_MODE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_AUDIO_SOURCE, g_param_spec_enum( "audio-source", "Audio Source", "Audio source to use", GST_TYPE_AJA_AUDIO_SOURCE, DEFAULT_AUDIO_SOURCE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_EMBEDDED_AUDIO_INPUT, g_param_spec_enum( "embedded-audio-input", "Embedded Audio Input", "Embedded Audio Input to use", GST_TYPE_AJA_EMBEDDED_AUDIO_INPUT, DEFAULT_EMBEDDED_AUDIO_INPUT, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_TIMECODE_INDEX, g_param_spec_enum( "timecode-index", "Timecode Index", "Timecode index to use", GST_TYPE_AJA_TIMECODE_INDEX, DEFAULT_TIMECODE_INDEX, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_RP188, g_param_spec_boolean( "rp188", "RP188", "Enable RP188 timecode retrieval", DEFAULT_RP188, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_REFERENCE_SOURCE, g_param_spec_enum( "reference-source", "Reference Source", "Reference source to use", GST_TYPE_AJA_REFERENCE_SOURCE, DEFAULT_REFERENCE_SOURCE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_CLOSED_CAPTION_CAPTURE_MODE, g_param_spec_enum( "closed-caption-capture-mode", "Closed Caption Capture Mode", "Closed Caption Capture Mode", GST_TYPE_AJA_CLOSED_CAPTION_CAPTURE_MODE, DEFAULT_CLOSED_CAPTION_CAPTURE_MODE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_CAPTURE_CPU_CORE, g_param_spec_uint( "capture-cpu-core", "Capture CPU Core", "Sets the affinity of the capture thread to this CPU core " "(-1=disabled)", 0, G_MAXUINT, DEFAULT_CAPTURE_CPU_CORE, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); g_object_class_install_property( gobject_class, PROP_SIGNAL, g_param_spec_boolean( "signal", "Input signal available", "True if there is a valid input signal available", FALSE, (GParamFlags)(G_PARAM_READABLE | G_PARAM_STATIC_STRINGS))); /** * GstAjaSrc:attach-ancillary-meta: * * If set to %TRUE attach any ancillary data as #GstAncillaryMeta on buffers * * Since: 1.24 */ g_object_class_install_property( gobject_class, PROP_ATTACH_ANCILLARY_META, g_param_spec_boolean( "attach-ancillary-meta", "Attach Ancillary Meta", "Attach ancillary meta to video frames", DEFAULT_ATTACH_ANCILLARY_META, (GParamFlags)(G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS | G_PARAM_CONSTRUCT))); element_class->change_state = GST_DEBUG_FUNCPTR(gst_aja_src_change_state); element_class->provide_clock = GST_DEBUG_FUNCPTR(gst_aja_src_provide_clock); basesrc_class->get_caps = GST_DEBUG_FUNCPTR(gst_aja_src_get_caps); basesrc_class->negotiate = NULL; basesrc_class->query = GST_DEBUG_FUNCPTR(gst_aja_src_query); basesrc_class->unlock = GST_DEBUG_FUNCPTR(gst_aja_src_unlock); basesrc_class->unlock_stop = GST_DEBUG_FUNCPTR(gst_aja_src_unlock_stop); pushsrc_class->create = GST_DEBUG_FUNCPTR(gst_aja_src_create); templ_caps = gst_ntv2_supported_caps(DEVICE_ID_INVALID); gst_element_class_add_pad_template( element_class, gst_pad_template_new("src", GST_PAD_SRC, GST_PAD_ALWAYS, templ_caps)); gst_caps_unref(templ_caps); gst_element_class_set_static_metadata( element_class, "AJA audio/video src", "Audio/Video/Source", "Captures audio/video frames with AJA devices", "Sebastian Dröge "); GST_DEBUG_CATEGORY_INIT(gst_aja_src_debug, "ajasrc", 0, "AJA src"); } static void gst_aja_src_init(GstAjaSrc *self) { GST_OBJECT_FLAG_SET( self, GST_ELEMENT_FLAG_PROVIDE_CLOCK | GST_ELEMENT_FLAG_REQUIRE_CLOCK); g_mutex_init(&self->queue_lock); g_cond_init(&self->queue_cond); self->device_identifier = g_strdup(DEFAULT_DEVICE_IDENTIFIER); self->channel = DEFAULT_CHANNEL; self->queue_size = DEFAULT_QUEUE_SIZE; self->start_frame = DEFAULT_START_FRAME; self->end_frame = DEFAULT_END_FRAME; self->video_format_setting = DEFAULT_VIDEO_FORMAT; self->audio_system_setting = DEFAULT_AUDIO_SYSTEM; self->input_source = DEFAULT_INPUT_SOURCE; self->audio_source = DEFAULT_AUDIO_SOURCE; self->embedded_audio_input = DEFAULT_EMBEDDED_AUDIO_INPUT; self->timecode_index = DEFAULT_TIMECODE_INDEX; self->reference_source = DEFAULT_REFERENCE_SOURCE; self->closed_caption_capture_mode = DEFAULT_CLOSED_CAPTION_CAPTURE_MODE; self->capture_cpu_core = DEFAULT_CAPTURE_CPU_CORE; self->attach_ancillary_meta = DEFAULT_ATTACH_ANCILLARY_META; self->queue = gst_queue_array_new_for_struct(sizeof(QueueItem), self->queue_size); gst_base_src_set_live(GST_BASE_SRC_CAST(self), TRUE); gst_base_src_set_format(GST_BASE_SRC_CAST(self), GST_FORMAT_TIME); self->video_format = NTV2_FORMAT_UNKNOWN; } void gst_aja_src_set_property(GObject *object, guint property_id, const GValue *value, GParamSpec *pspec) { GstAjaSrc *self = GST_AJA_SRC(object); switch (property_id) { case PROP_DEVICE_IDENTIFIER: g_free(self->device_identifier); self->device_identifier = g_value_dup_string(value); break; case PROP_CHANNEL: self->channel = (NTV2Channel)g_value_get_uint(value); break; case PROP_QUEUE_SIZE: self->queue_size = g_value_get_uint(value); break; case PROP_START_FRAME: self->start_frame = g_value_get_uint(value); break; case PROP_END_FRAME: self->end_frame = g_value_get_uint(value); break; case PROP_VIDEO_FORMAT: self->video_format_setting = (GstAjaVideoFormat)g_value_get_enum(value); break; case PROP_AUDIO_SYSTEM: self->audio_system_setting = (GstAjaAudioSystem)g_value_get_enum(value); break; case PROP_INPUT_SOURCE: self->input_source = (GstAjaInputSource)g_value_get_enum(value); break; case PROP_SDI_MODE: self->sdi_mode = (GstAjaSdiMode)g_value_get_enum(value); break; case PROP_AUDIO_SOURCE: self->audio_source = (GstAjaAudioSource)g_value_get_enum(value); break; case PROP_EMBEDDED_AUDIO_INPUT: self->embedded_audio_input = (GstAjaEmbeddedAudioInput)g_value_get_enum(value); break; case PROP_TIMECODE_INDEX: self->timecode_index = (GstAjaTimecodeIndex)g_value_get_enum(value); break; case PROP_RP188: self->rp188 = g_value_get_boolean(value); break; case PROP_REFERENCE_SOURCE: self->reference_source = (GstAjaReferenceSource)g_value_get_enum(value); break; case PROP_CLOSED_CAPTION_CAPTURE_MODE: self->closed_caption_capture_mode = (GstAjaClosedCaptionCaptureMode)g_value_get_enum(value); break; case PROP_CAPTURE_CPU_CORE: self->capture_cpu_core = g_value_get_uint(value); break; case PROP_ATTACH_ANCILLARY_META: self->attach_ancillary_meta = g_value_get_boolean(value); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID(object, property_id, pspec); break; } } void gst_aja_src_get_property(GObject *object, guint property_id, GValue *value, GParamSpec *pspec) { GstAjaSrc *self = GST_AJA_SRC(object); switch (property_id) { case PROP_DEVICE_IDENTIFIER: g_value_set_string(value, self->device_identifier); break; case PROP_CHANNEL: g_value_set_uint(value, self->channel); break; case PROP_QUEUE_SIZE: g_value_set_uint(value, self->queue_size); break; case PROP_START_FRAME: g_value_set_uint(value, self->start_frame); break; case PROP_END_FRAME: g_value_set_uint(value, self->end_frame); break; case PROP_VIDEO_FORMAT: g_value_set_enum(value, self->video_format_setting); break; case PROP_AUDIO_SYSTEM: g_value_set_enum(value, self->audio_system_setting); break; case PROP_INPUT_SOURCE: g_value_set_enum(value, self->input_source); break; case PROP_SDI_MODE: g_value_set_enum(value, self->sdi_mode); break; case PROP_AUDIO_SOURCE: g_value_set_enum(value, self->audio_source); break; case PROP_EMBEDDED_AUDIO_INPUT: g_value_set_enum(value, self->embedded_audio_input); break; case PROP_TIMECODE_INDEX: g_value_set_enum(value, self->timecode_index); break; case PROP_RP188: g_value_set_boolean(value, self->rp188); break; case PROP_REFERENCE_SOURCE: g_value_set_enum(value, self->reference_source); break; case PROP_CLOSED_CAPTION_CAPTURE_MODE: g_value_set_enum(value, self->closed_caption_capture_mode); break; case PROP_CAPTURE_CPU_CORE: g_value_set_uint(value, self->capture_cpu_core); break; case PROP_SIGNAL: g_value_set_boolean(value, self->signal); break; case PROP_ATTACH_ANCILLARY_META: g_value_set_boolean(value, self->attach_ancillary_meta); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID(object, property_id, pspec); break; } } void gst_aja_src_constructed(GObject *object) { GstAjaSrc *self = GST_AJA_SRC(object); G_OBJECT_CLASS(parent_class)->constructed(object); gchar *aja_clock_name = g_strdup_printf("ajaclock-%s", GST_OBJECT_NAME(self)); self->clock = GST_CLOCK(g_object_new(GST_TYPE_SYSTEM_CLOCK, "name", aja_clock_name, "clock-type", GST_CLOCK_TYPE_MONOTONIC, NULL)); g_free(aja_clock_name); } void gst_aja_src_finalize(GObject *object) { GstAjaSrc *self = GST_AJA_SRC(object); g_assert(self->device == NULL); g_assert(gst_queue_array_get_length(self->queue) == 0); g_clear_pointer(&self->queue, gst_queue_array_free); gst_clear_object(&self->clock); g_mutex_clear(&self->queue_lock); g_cond_clear(&self->queue_cond); G_OBJECT_CLASS(parent_class)->finalize(object); } static gboolean gst_aja_src_open(GstAjaSrc *self) { GST_DEBUG_OBJECT(self, "Opening device"); g_assert(self->device == NULL); self->device = gst_aja_ntv2_device_obtain(self->device_identifier); if (!self->device) { GST_ERROR_OBJECT(self, "Failed to open device"); return FALSE; } if (!self->device->device->IsDeviceReady(false)) { g_clear_pointer(&self->device, gst_aja_ntv2_device_unref); return FALSE; } self->device->device->SetEveryFrameServices(::NTV2_OEM_TASKS); self->device_id = self->device->device->GetDeviceID(); std::string serial_number; if (!self->device->device->GetSerialNumberString(serial_number)) serial_number = "none"; GST_DEBUG_OBJECT(self, "Opened device with ID %d at index %d (%s, version %s, " "serial number %s, can do VANC %d)", self->device_id, self->device->device->GetIndexNumber(), self->device->device->GetDisplayName().c_str(), self->device->device->GetDeviceVersionString().c_str(), serial_number.c_str(), ::NTV2DeviceCanDoCustomAnc(self->device_id)); GST_DEBUG_OBJECT(self, "Using SDK version %d.%d.%d.%d (%s) and driver version %s", AJA_NTV2_SDK_VERSION_MAJOR, AJA_NTV2_SDK_VERSION_MINOR, AJA_NTV2_SDK_VERSION_POINT, AJA_NTV2_SDK_BUILD_NUMBER, AJA_NTV2_SDK_BUILD_DATETIME, self->device->device->GetDriverVersionString().c_str()); self->device->device->SetMultiFormatMode(true); self->allocator = gst_aja_allocator_new(self->device); GST_DEBUG_OBJECT(self, "Opened device"); return TRUE; } static gboolean gst_aja_src_close(GstAjaSrc *self) { gst_clear_object(&self->allocator); g_clear_pointer(&self->device, gst_aja_ntv2_device_unref); self->device_id = DEVICE_ID_INVALID; GST_DEBUG_OBJECT(self, "Closed device"); return TRUE; } // Must be called with GstAjaNtv2DeviceLocker static gboolean gst_aja_src_configure(GstAjaSrc *self) { GST_DEBUG_OBJECT(self, "Starting"); #define NEEDS_QUAD_MODE(self) \ (self->sdi_mode == GST_AJA_SDI_MODE_QUAD_LINK_SQD || \ self->sdi_mode == GST_AJA_SDI_MODE_QUAD_LINK_TSI || \ (self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && \ self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4)) self->quad_mode = NEEDS_QUAD_MODE(self); #undef NEEDS_QUAD_MODE if (self->quad_mode) { if (self->input_source != GST_AJA_INPUT_SOURCE_AUTO && !(self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4)) { GST_ERROR_OBJECT( self, "Quad modes require usage of the channel's default input source"); return FALSE; } if (self->channel != ::NTV2_CHANNEL1 && self->channel != ::NTV2_CHANNEL5) { GST_ERROR_OBJECT(self, "Quad modes require channels 1 or 5"); return FALSE; } } bool had_quad_enabled = false, had_quad_quad_enabled = false; // HDMI can also be internally quad mode but it runs on a single channel. if (!(self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4)) { if (self->channel < ::NTV2_CHANNEL5) { self->device->device->GetQuadFrameEnable(had_quad_enabled, ::NTV2_CHANNEL1); // 12G UHD is also internally considered quad modes but they run on a // single channel. if (had_quad_enabled && ::NTV2DeviceCanDo12gRouting(self->device_id)) { NTV2VideoFormat fmt = self->device->device->GetInputVideoFormat(::NTV2_INPUTSOURCE_SDI1); if (fmt >= NTV2_FORMAT_FIRST_UHD_TSI_DEF_FORMAT && fmt < NTV2_FORMAT_END_4K_TSI_DEF_FORMATS) had_quad_enabled = false; } self->device->device->GetQuadQuadFrameEnable(had_quad_quad_enabled, ::NTV2_CHANNEL1); } else { self->device->device->GetQuadFrameEnable(had_quad_enabled, ::NTV2_CHANNEL5); // 12G UHD is also internally considered quad modes but they run on a // single channel. if (had_quad_enabled && ::NTV2DeviceCanDo12gRouting(self->device_id)) { NTV2VideoFormat fmt = self->device->device->GetInputVideoFormat(::NTV2_INPUTSOURCE_SDI5); if (fmt >= NTV2_FORMAT_FIRST_UHD_TSI_DEF_FORMAT && fmt < NTV2_FORMAT_END_4K_TSI_DEF_FORMATS) had_quad_enabled = false; } self->device->device->GetQuadQuadFrameEnable(had_quad_quad_enabled, ::NTV2_CHANNEL5); } } // Stop any previously running quad mode, or other configurations on the // quad channels self->device->device->AutoCirculateStop(self->channel); if (self->quad_mode || had_quad_enabled || had_quad_enabled) { NTV2Channel quad_channel; if (self->channel < ::NTV2_CHANNEL5) quad_channel = ::NTV2_CHANNEL1; else quad_channel = ::NTV2_CHANNEL5; for (int i = 0; i < 4; i++) { self->device->device->AutoCirculateStop((NTV2Channel)(quad_channel + i)); } } if (self->buffer_pool) { gst_buffer_pool_set_active(self->buffer_pool, FALSE); gst_clear_object(&self->buffer_pool); } if (self->audio_buffer_pool) { gst_buffer_pool_set_active(self->audio_buffer_pool, FALSE); gst_clear_object(&self->audio_buffer_pool); } if (self->anc_buffer_pool) { gst_buffer_pool_set_active(self->anc_buffer_pool, FALSE); gst_clear_object(&self->anc_buffer_pool); } NTV2VANCMode vanc_mode; NTV2InputSource input_source; NTV2OutputCrosspointID input_source_id; switch (self->input_source) { case GST_AJA_INPUT_SOURCE_AUTO: input_source = ::NTV2ChannelToInputSource(self->channel); input_source_id = ::GetSDIInputOutputXptFromChannel(self->channel, false); vanc_mode = ::NTV2DeviceCanDoCustomAnc(self->device_id) ? ::NTV2_VANCMODE_OFF : ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_ANALOG1: input_source = ::NTV2_INPUTSOURCE_ANALOG1; input_source_id = ::NTV2_XptAnalogIn; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_HDMI1: input_source = ::NTV2_INPUTSOURCE_HDMI1; input_source_id = ::NTV2_XptHDMIIn1; vanc_mode = ::NTV2_VANCMODE_OFF; break; case GST_AJA_INPUT_SOURCE_HDMI2: input_source = ::NTV2_INPUTSOURCE_HDMI2; input_source_id = ::NTV2_XptHDMIIn2; vanc_mode = ::NTV2_VANCMODE_OFF; break; case GST_AJA_INPUT_SOURCE_HDMI3: input_source = ::NTV2_INPUTSOURCE_HDMI3; input_source_id = ::NTV2_XptHDMIIn3; vanc_mode = ::NTV2_VANCMODE_OFF; break; case GST_AJA_INPUT_SOURCE_HDMI4: input_source = ::NTV2_INPUTSOURCE_HDMI4; input_source_id = ::NTV2_XptHDMIIn4; vanc_mode = ::NTV2_VANCMODE_OFF; break; case GST_AJA_INPUT_SOURCE_SDI1: input_source = ::NTV2_INPUTSOURCE_SDI1; input_source_id = ::NTV2_XptSDIIn1; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI2: input_source = ::NTV2_INPUTSOURCE_SDI2; input_source_id = ::NTV2_XptSDIIn2; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI3: input_source = ::NTV2_INPUTSOURCE_SDI3; input_source_id = ::NTV2_XptSDIIn3; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI4: input_source = ::NTV2_INPUTSOURCE_SDI4; input_source_id = ::NTV2_XptSDIIn4; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI5: input_source = ::NTV2_INPUTSOURCE_SDI5; input_source_id = ::NTV2_XptSDIIn5; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI6: input_source = ::NTV2_INPUTSOURCE_SDI6; input_source_id = ::NTV2_XptSDIIn6; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI7: input_source = ::NTV2_INPUTSOURCE_SDI7; input_source_id = ::NTV2_XptSDIIn7; vanc_mode = ::NTV2_VANCMODE_TALL; break; case GST_AJA_INPUT_SOURCE_SDI8: input_source = ::NTV2_INPUTSOURCE_SDI8; input_source_id = ::NTV2_XptSDIIn8; vanc_mode = ::NTV2_VANCMODE_TALL; break; default: g_assert_not_reached(); break; } self->configured_input_source = input_source; self->vanc_mode = vanc_mode; if (!self->device->device->EnableChannel(self->channel)) { GST_ERROR_OBJECT(self, "Failed to enable channel"); return FALSE; } if (self->quad_mode) { for (int i = 1; i < 4; i++) { if (!self->device->device->EnableChannel( (NTV2Channel)(self->channel + i))) { GST_ERROR_OBJECT(self, "Failed to enable channel"); return FALSE; } } } self->device->device->EnableInputInterrupt(self->channel); self->device->device->SubscribeInputVerticalEvent(self->channel); if (self->video_format_setting == GST_AJA_VIDEO_FORMAT_AUTO) { self->device->device->WaitForInputVerticalInterrupt(self->channel, 10); self->video_format = self->device->device->GetInputVideoFormat( self->configured_input_source); if (self->video_format == NTV2_FORMAT_UNKNOWN) { GST_ERROR_OBJECT(self, "Input video format not detected"); return TRUE; } std::string configured_string = NTV2VideoFormatToString(self->video_format); GST_DEBUG_OBJECT(self, "Detected input video format %s (%d)", configured_string.c_str(), (int)self->video_format); } else { self->video_format = gst_ntv2_video_format_from_aja_format( self->video_format_setting, self->quad_mode); } if (self->video_format == NTV2_FORMAT_UNKNOWN) { GST_ERROR_OBJECT(self, "Unsupported mode"); return FALSE; } if (!::NTV2DeviceCanDoVideoFormat(self->device_id, self->video_format)) { GST_ERROR_OBJECT(self, "Device does not support mode %d", (int)self->video_format); return FALSE; } gst_video_info_from_ntv2_video_format(&self->configured_info, self->video_format); if (self->quad_mode) { if (self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4) { self->device->device->SetQuadQuadFrameEnable(false, self->channel); self->device->device->SetQuadQuadSquaresEnable(false, self->channel); self->device->device->Set4kSquaresEnable(true, self->channel); self->device->device->SetTsiFrameEnable(true, self->channel); } else { switch (self->sdi_mode) { case GST_AJA_SDI_MODE_SINGLE_LINK: g_assert_not_reached(); break; case GST_AJA_SDI_MODE_QUAD_LINK_SQD: if (self->configured_info.height > 2160) { self->device->device->Set4kSquaresEnable(false, self->channel); self->device->device->SetTsiFrameEnable(false, self->channel); self->device->device->SetQuadQuadFrameEnable(true, self->channel); self->device->device->SetQuadQuadSquaresEnable(true, self->channel); } else { self->device->device->SetQuadQuadFrameEnable(false, self->channel); self->device->device->SetQuadQuadSquaresEnable(false, self->channel); self->device->device->Set4kSquaresEnable(true, self->channel); self->device->device->SetTsiFrameEnable(false, self->channel); } break; case GST_AJA_SDI_MODE_QUAD_LINK_TSI: if (self->configured_info.height > 2160) { self->device->device->Set4kSquaresEnable(false, self->channel); self->device->device->SetTsiFrameEnable(false, self->channel); self->device->device->SetQuadQuadFrameEnable(true, self->channel); self->device->device->SetQuadQuadSquaresEnable(false, self->channel); } else { self->device->device->SetQuadQuadFrameEnable(false, self->channel); self->device->device->SetQuadQuadSquaresEnable(false, self->channel); self->device->device->Set4kSquaresEnable(false, self->channel); self->device->device->SetTsiFrameEnable(true, self->channel); } break; } } } else if (had_quad_enabled || had_quad_quad_enabled) { NTV2Channel quad_channel; if (self->channel < ::NTV2_CHANNEL5) quad_channel = ::NTV2_CHANNEL1; else quad_channel = ::NTV2_CHANNEL5; self->device->device->Set4kSquaresEnable(false, quad_channel); self->device->device->SetTsiFrameEnable(false, quad_channel); self->device->device->SetQuadQuadFrameEnable(false, quad_channel); self->device->device->SetQuadQuadSquaresEnable(false, quad_channel); } self->device->device->SetMode(self->channel, NTV2_MODE_CAPTURE, false); if (self->quad_mode) { for (int i = 1; i < 4; i++) self->device->device->SetMode((NTV2Channel)(self->channel + i), NTV2_MODE_CAPTURE, false); } std::string configured_string = NTV2VideoFormatToString(self->video_format); GST_DEBUG_OBJECT(self, "Configuring video format %s (%d) on channel %d", configured_string.c_str(), (int)self->video_format, (int)self->channel); if (!self->device->device->SetVideoFormat(self->video_format, false, false, self->channel)) { GST_DEBUG_OBJECT( self, "Failed configuring video format %s (%d) on channel %d", configured_string.c_str(), (int)self->video_format, (int)self->channel); return FALSE; } if (!::NTV2DeviceCanDoFrameBufferFormat(self->device_id, ::NTV2_FBF_10BIT_YCBCR)) { GST_ERROR_OBJECT(self, "Device does not support frame buffer format %d", (int)::NTV2_FBF_10BIT_YCBCR); return FALSE; } if (!self->device->device->SetFrameBufferFormat(self->channel, ::NTV2_FBF_10BIT_YCBCR)) { GST_ERROR_OBJECT(self, "Failed configuring frame buffer format %d", (int)::NTV2_FBF_10BIT_YCBCR); return FALSE; } // FIXME: Workaround for sometimes setting the video format not actually // changing the register values. Let's just try again. { NTV2VideoFormat fmt; self->device->device->GetVideoFormat(fmt, self->channel); if (fmt != self->video_format) { std::string actual_string = NTV2VideoFormatToString(fmt); GST_ERROR_OBJECT(self, "Configured video format %s (%d) on channel %d but %s " "(%d) is configured instead, trying again", configured_string.c_str(), (int)self->video_format, (int)self->channel, actual_string.c_str(), (int)fmt); self->video_format = ::NTV2_FORMAT_UNKNOWN; return TRUE; } } if (self->quad_mode) { for (int i = 1; i < 4; i++) self->device->device->SetFrameBufferFormat( (NTV2Channel)(self->channel + i), ::NTV2_FBF_10BIT_YCBCR); } self->device->device->DMABufferAutoLock(false, true, 0); if (::NTV2DeviceHasBiDirectionalSDI(self->device_id)) { self->device->device->SetSDITransmitEnable(self->channel, false); if (self->quad_mode) { for (int i = 1; i < 4; i++) self->device->device->SetSDITransmitEnable( (NTV2Channel)(self->channel + i), false); } } // Always use the framebuffer associated with the channel NTV2InputCrosspointID framebuffer_id = ::GetFrameBufferInputXptFromChannel(self->channel, false); const NTV2Standard standard( ::GetNTV2StandardFromVideoFormat(self->video_format)); self->device->device->SetStandard(standard, self->channel); if (self->quad_mode) { for (int i = 1; i < 4; i++) self->device->device->SetStandard(standard, (NTV2Channel)(self->channel + i)); } const NTV2FrameGeometry geometry = ::GetNTV2FrameGeometryFromVideoFormat(self->video_format); self->vanc_mode = ::HasVANCGeometries(geometry) ? vanc_mode : ::NTV2_VANCMODE_OFF; if (self->vanc_mode == ::NTV2_VANCMODE_OFF) { self->device->device->SetFrameGeometry(geometry, false, self->channel); if (self->quad_mode) { for (int i = 1; i < 4; i++) { self->device->device->SetFrameGeometry( geometry, false, (NTV2Channel)(self->channel + i)); } } } else { const NTV2FrameGeometry vanc_geometry = ::GetVANCFrameGeometry(geometry, self->vanc_mode); self->device->device->SetFrameGeometry(vanc_geometry, false, self->channel); if (self->quad_mode) { for (int i = 1; i < 4; i++) { self->device->device->SetFrameGeometry( vanc_geometry, false, (NTV2Channel)(self->channel + i)); } } } CNTV2SignalRouter router; // If any channels are currently running, initialize the router with the // existing routing setup. Otherwise overwrite the whole routing table. { bool have_channels_running = false; for (NTV2Channel c = ::NTV2_CHANNEL1; c < NTV2_MAX_NUM_CHANNELS; c = (NTV2Channel)(c + 1)) { AUTOCIRCULATE_STATUS ac_status; if (c == self->channel) continue; if (self->device->device->AutoCirculateGetStatus(c, ac_status) && !ac_status.IsStopped()) { have_channels_running = true; break; } } if (have_channels_running) self->device->device->GetRouting(router); } // Need to remove old routes for the output and framebuffer we're going to // use NTV2ActualConnections connections = router.GetConnections(); if (self->quad_mode) { if (self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4) { // Need to disconnect the 4 inputs corresponding to this channel from // their framebuffers/muxers, and muxers from their framebuffers for (auto iter = connections.begin(); iter != connections.end(); iter++) { if (iter->first == NTV2_XptFrameBuffer1Input || iter->first == NTV2_XptFrameBuffer1BInput || iter->first == NTV2_XptFrameBuffer2Input || iter->first == NTV2_XptFrameBuffer2BInput || iter->second == NTV2_Xpt425Mux1AYUV || iter->second == NTV2_Xpt425Mux1BYUV || iter->second == NTV2_Xpt425Mux2AYUV || iter->second == NTV2_Xpt425Mux2BYUV || iter->first == NTV2_Xpt425Mux1AInput || iter->first == NTV2_Xpt425Mux1BInput || iter->first == NTV2_Xpt425Mux2AInput || iter->first == NTV2_Xpt425Mux2BInput || iter->second == NTV2_XptHDMIIn1 || iter->second == NTV2_XptHDMIIn1Q2 || iter->second == NTV2_XptHDMIIn1Q3 || iter->second == NTV2_XptHDMIIn1Q4) router.RemoveConnection(iter->first, iter->second); } } else if (self->channel == NTV2_CHANNEL1) { for (auto iter = connections.begin(); iter != connections.end(); iter++) { if (iter->first == NTV2_XptFrameBuffer1Input || iter->first == NTV2_XptFrameBuffer1BInput || iter->first == NTV2_XptFrameBuffer1DS2Input || iter->first == NTV2_XptFrameBuffer2Input || iter->first == NTV2_XptFrameBuffer2BInput || iter->first == NTV2_XptFrameBuffer2DS2Input || iter->second == NTV2_Xpt425Mux1AYUV || iter->second == NTV2_Xpt425Mux1BYUV || iter->second == NTV2_Xpt425Mux2AYUV || iter->second == NTV2_Xpt425Mux2BYUV || iter->first == NTV2_Xpt425Mux1AInput || iter->first == NTV2_Xpt425Mux1BInput || iter->first == NTV2_Xpt425Mux2AInput || iter->first == NTV2_Xpt425Mux2BInput || iter->second == NTV2_XptSDIIn1 || iter->second == NTV2_XptSDIIn2 || iter->second == NTV2_XptSDIIn3 || iter->second == NTV2_XptSDIIn4 || iter->second == NTV2_XptSDIIn1DS2 || iter->second == NTV2_XptSDIIn2DS2 || iter->first == NTV2_XptFrameBuffer1Input || iter->first == NTV2_XptFrameBuffer2Input || iter->first == NTV2_XptFrameBuffer3Input || iter->first == NTV2_XptFrameBuffer4Input) router.RemoveConnection(iter->first, iter->second); } } else if (self->channel == NTV2_CHANNEL5) { for (auto iter = connections.begin(); iter != connections.end(); iter++) { if (iter->first == NTV2_XptFrameBuffer5Input || iter->first == NTV2_XptFrameBuffer5BInput || iter->first == NTV2_XptFrameBuffer5DS2Input || iter->first == NTV2_XptFrameBuffer6Input || iter->first == NTV2_XptFrameBuffer6BInput || iter->first == NTV2_XptFrameBuffer6DS2Input || iter->second == NTV2_Xpt425Mux3AYUV || iter->second == NTV2_Xpt425Mux3BYUV || iter->second == NTV2_Xpt425Mux4AYUV || iter->second == NTV2_Xpt425Mux4BYUV || iter->first == NTV2_Xpt425Mux3AInput || iter->first == NTV2_Xpt425Mux3BInput || iter->first == NTV2_Xpt425Mux4AInput || iter->first == NTV2_Xpt425Mux4BInput || iter->second == NTV2_XptSDIIn5 || iter->second == NTV2_XptSDIIn6 || iter->second == NTV2_XptSDIIn7 || iter->second == NTV2_XptSDIIn8 || iter->second == NTV2_XptSDIIn5DS2 || iter->second == NTV2_XptSDIIn6DS2 || iter->first == NTV2_XptFrameBuffer5Input || iter->first == NTV2_XptFrameBuffer6Input || iter->first == NTV2_XptFrameBuffer7Input || iter->first == NTV2_XptFrameBuffer8Input) router.RemoveConnection(iter->first, iter->second); } } else { g_assert_not_reached(); } } else { // This also removes all connections for any previous quad mode on the // corresponding channels. NTV2OutputCrosspointID quad_input_source_ids[10]; if (input_source_id == NTV2_XptSDIIn1 || input_source_id == NTV2_XptSDIIn2 || input_source_id == NTV2_XptSDIIn3 || input_source_id == NTV2_XptSDIIn4) { if (had_quad_enabled || had_quad_quad_enabled) { quad_input_source_ids[0] = NTV2_XptSDIIn1; quad_input_source_ids[1] = NTV2_XptSDIIn2; quad_input_source_ids[2] = NTV2_XptSDIIn3; quad_input_source_ids[3] = NTV2_XptSDIIn4; quad_input_source_ids[4] = NTV2_XptSDIIn1DS2; quad_input_source_ids[5] = NTV2_XptSDIIn2DS2; quad_input_source_ids[6] = NTV2_Xpt425Mux1AYUV; quad_input_source_ids[7] = NTV2_Xpt425Mux1BYUV; quad_input_source_ids[8] = NTV2_Xpt425Mux2AYUV; quad_input_source_ids[9] = NTV2_Xpt425Mux2BYUV; } } else if (input_source_id == NTV2_XptSDIIn5 || input_source_id == NTV2_XptSDIIn6 || input_source_id == NTV2_XptSDIIn7 || input_source_id == NTV2_XptSDIIn8) { if (had_quad_enabled || had_quad_quad_enabled) { quad_input_source_ids[0] = NTV2_XptSDIIn5; quad_input_source_ids[1] = NTV2_XptSDIIn6; quad_input_source_ids[2] = NTV2_XptSDIIn7; quad_input_source_ids[3] = NTV2_XptSDIIn8; quad_input_source_ids[4] = NTV2_XptSDIIn5DS2; quad_input_source_ids[5] = NTV2_XptSDIIn6DS2; quad_input_source_ids[6] = NTV2_Xpt425Mux3AYUV; quad_input_source_ids[7] = NTV2_Xpt425Mux3BYUV; quad_input_source_ids[8] = NTV2_Xpt425Mux4AYUV; quad_input_source_ids[9] = NTV2_Xpt425Mux4BYUV; } } else { g_assert_not_reached(); } for (auto iter = connections.begin(); iter != connections.end(); iter++) { if (had_quad_enabled || had_quad_quad_enabled) { for (auto quad_input_source_id : quad_input_source_ids) { if (iter->second == quad_input_source_id) router.RemoveConnection(iter->first, iter->second); } } else { if (iter->first == framebuffer_id || iter->second == input_source_id) router.RemoveConnection(iter->first, iter->second); } } } if (self->quad_mode) { if (self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4) { input_source_id = NTV2_Xpt425Mux1AYUV; } else if (self->sdi_mode == GST_AJA_SDI_MODE_QUAD_LINK_TSI && !NTV2_IS_QUAD_QUAD_HFR_VIDEO_FORMAT(self->video_format) && !NTV2_IS_QUAD_QUAD_FORMAT(self->video_format)) { if (self->channel == NTV2_CHANNEL1) input_source_id = NTV2_Xpt425Mux1AYUV; else if (self->channel == NTV2_CHANNEL5) input_source_id = NTV2_Xpt425Mux3AYUV; else g_assert_not_reached(); } } GST_DEBUG_OBJECT(self, "Creating connection %d - %d", framebuffer_id, input_source_id); router.AddConnection(framebuffer_id, input_source_id); if (self->quad_mode) { if (self->input_source >= GST_AJA_INPUT_SOURCE_HDMI1 && self->input_source <= GST_AJA_INPUT_SOURCE_HDMI4) { router.AddConnection(NTV2_XptFrameBuffer1BInput, NTV2_Xpt425Mux1BYUV); router.AddConnection(NTV2_XptFrameBuffer2Input, NTV2_Xpt425Mux2AYUV); router.AddConnection(NTV2_XptFrameBuffer2BInput, NTV2_Xpt425Mux2BYUV); router.AddConnection(NTV2_Xpt425Mux1AInput, NTV2_XptHDMIIn1); router.AddConnection(NTV2_Xpt425Mux1BInput, NTV2_XptHDMIIn1Q2); router.AddConnection(NTV2_Xpt425Mux2AInput, NTV2_XptHDMIIn1Q3); router.AddConnection(NTV2_Xpt425Mux2BInput, NTV2_XptHDMIIn1Q4); } else { if (self->sdi_mode == GST_AJA_SDI_MODE_QUAD_LINK_TSI) { if (NTV2_IS_QUAD_QUAD_HFR_VIDEO_FORMAT(self->video_format)) { if (self->channel == NTV2_CHANNEL1) { router.AddConnection(NTV2_XptFrameBuffer1DS2Input, NTV2_XptSDIIn2); router.AddConnection(NTV2_XptFrameBuffer2Input, NTV2_XptSDIIn3); router.AddConnection(NTV2_XptFrameBuffer2DS2Input, NTV2_XptSDIIn4); } else if (self->channel == NTV2_CHANNEL5) { router.AddConnection(NTV2_XptFrameBuffer5DS2Input, NTV2_XptSDIIn6); router.AddConnection(NTV2_XptFrameBuffer5Input, NTV2_XptSDIIn7); router.AddConnection(NTV2_XptFrameBuffer6DS2Input, NTV2_XptSDIIn8); } else { g_assert_not_reached(); } } else if (NTV2_IS_QUAD_QUAD_FORMAT(self->video_format)) { if (self->channel == NTV2_CHANNEL1) { router.AddConnection(NTV2_XptFrameBuffer1DS2Input, NTV2_XptSDIIn1DS2); router.AddConnection(NTV2_XptFrameBuffer2Input, NTV2_XptSDIIn2); router.AddConnection(NTV2_XptFrameBuffer2DS2Input, NTV2_XptSDIIn2DS2); } else if (self->channel == NTV2_CHANNEL5) { router.AddConnection(NTV2_XptFrameBuffer5DS2Input, NTV2_XptSDIIn5DS2); router.AddConnection(NTV2_XptFrameBuffer5Input, NTV2_XptSDIIn6); router.AddConnection(NTV2_XptFrameBuffer6DS2Input, NTV2_XptSDIIn6DS2); } else { g_assert_not_reached(); } // FIXME: Need special handling of NTV2_IS_4K_HFR_VIDEO_FORMAT for // TSI? } else { if (self->channel == NTV2_CHANNEL1) { router.AddConnection(NTV2_XptFrameBuffer1BInput, NTV2_Xpt425Mux1BYUV); router.AddConnection(NTV2_XptFrameBuffer2Input, NTV2_Xpt425Mux2AYUV); router.AddConnection(NTV2_XptFrameBuffer2BInput, NTV2_Xpt425Mux2BYUV); router.AddConnection(NTV2_Xpt425Mux1AInput, NTV2_XptSDIIn1); router.AddConnection(NTV2_Xpt425Mux1BInput, NTV2_XptSDIIn2); router.AddConnection(NTV2_Xpt425Mux2AInput, NTV2_XptSDIIn3); router.AddConnection(NTV2_Xpt425Mux2BInput, NTV2_XptSDIIn4); } else if (self->channel == NTV2_CHANNEL5) { router.AddConnection(NTV2_XptFrameBuffer5BInput, NTV2_Xpt425Mux3BYUV); router.AddConnection(NTV2_XptFrameBuffer6Input, NTV2_Xpt425Mux4AYUV); router.AddConnection(NTV2_XptFrameBuffer6BInput, NTV2_Xpt425Mux4BYUV); router.AddConnection(NTV2_Xpt425Mux3AInput, NTV2_XptSDIIn5); router.AddConnection(NTV2_Xpt425Mux3BInput, NTV2_XptSDIIn6); router.AddConnection(NTV2_Xpt425Mux4AInput, NTV2_XptSDIIn7); router.AddConnection(NTV2_Xpt425Mux4BInput, NTV2_XptSDIIn8); } else { g_assert_not_reached(); } } } else { if (self->channel == NTV2_CHANNEL1) { router.AddConnection(NTV2_XptFrameBuffer2Input, NTV2_XptSDIIn2); router.AddConnection(NTV2_XptFrameBuffer3Input, NTV2_XptSDIIn3); router.AddConnection(NTV2_XptFrameBuffer4Input, NTV2_XptSDIIn4); } else if (self->channel == NTV2_CHANNEL5) { router.AddConnection(NTV2_XptFrameBuffer6Input, NTV2_XptSDIIn6); router.AddConnection(NTV2_XptFrameBuffer7Input, NTV2_XptSDIIn7); router.AddConnection(NTV2_XptFrameBuffer8Input, NTV2_XptSDIIn8); } else { g_assert_not_reached(); } } } } { std::stringstream os; CNTV2SignalRouter oldRouter; self->device->device->GetRouting(oldRouter); oldRouter.Print(os); GST_DEBUG_OBJECT(self, "Previous routing:\n%s", os.str().c_str()); } self->device->device->ApplySignalRoute(router, true); { std::stringstream os; CNTV2SignalRouter currentRouter; self->device->device->GetRouting(currentRouter); currentRouter.Print(os); GST_DEBUG_OBJECT(self, "New routing:\n%s", os.str().c_str()); } switch (self->audio_system_setting) { case GST_AJA_AUDIO_SYSTEM_1: self->audio_system = ::NTV2_AUDIOSYSTEM_1; break; case GST_AJA_AUDIO_SYSTEM_2: self->audio_system = ::NTV2_AUDIOSYSTEM_2; break; case GST_AJA_AUDIO_SYSTEM_3: self->audio_system = ::NTV2_AUDIOSYSTEM_3; break; case GST_AJA_AUDIO_SYSTEM_4: self->audio_system = ::NTV2_AUDIOSYSTEM_4; break; case GST_AJA_AUDIO_SYSTEM_5: self->audio_system = ::NTV2_AUDIOSYSTEM_5; break; case GST_AJA_AUDIO_SYSTEM_6: self->audio_system = ::NTV2_AUDIOSYSTEM_6; break; case GST_AJA_AUDIO_SYSTEM_7: self->audio_system = ::NTV2_AUDIOSYSTEM_7; break; case GST_AJA_AUDIO_SYSTEM_8: self->audio_system = ::NTV2_AUDIOSYSTEM_8; break; case GST_AJA_AUDIO_SYSTEM_AUTO: self->audio_system = ::NTV2_AUDIOSYSTEM_1; if (::NTV2DeviceGetNumAudioSystems(self->device_id) > 1) self->audio_system = ::NTV2ChannelToAudioSystem(self->channel); if (!::NTV2DeviceCanDoFrameStore1Display(self->device_id)) self->audio_system = ::NTV2_AUDIOSYSTEM_1; break; default: g_assert_not_reached(); break; } GST_DEBUG_OBJECT(self, "Using audio system %d", self->audio_system); NTV2AudioSource audio_source; switch (self->audio_source) { case GST_AJA_AUDIO_SOURCE_EMBEDDED: audio_source = ::NTV2_AUDIO_EMBEDDED; break; case GST_AJA_AUDIO_SOURCE_AES: audio_source = ::NTV2_AUDIO_AES; break; case GST_AJA_AUDIO_SOURCE_ANALOG: audio_source = ::NTV2_AUDIO_ANALOG; break; case GST_AJA_AUDIO_SOURCE_HDMI: audio_source = ::NTV2_AUDIO_HDMI; break; case GST_AJA_AUDIO_SOURCE_MIC: audio_source = ::NTV2_AUDIO_MIC; break; default: g_assert_not_reached(); break; } NTV2EmbeddedAudioInput embedded_audio_input; switch (self->embedded_audio_input) { case GST_AJA_EMBEDDED_AUDIO_INPUT_AUTO: embedded_audio_input = ::NTV2InputSourceToEmbeddedAudioInput(input_source); break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO1: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_1; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO2: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_2; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO3: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_3; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO4: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_4; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO5: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_5; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO6: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_6; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO7: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_7; break; case GST_AJA_EMBEDDED_AUDIO_INPUT_VIDEO8: embedded_audio_input = ::NTV2_EMBEDDED_AUDIO_INPUT_VIDEO_8; break; default: g_assert_not_reached(); break; } self->device->device->SetAudioSystemInputSource( self->audio_system, audio_source, embedded_audio_input); self->configured_audio_channels = ::NTV2DeviceGetMaxAudioChannels(self->device_id); self->device->device->SetNumberAudioChannels(self->configured_audio_channels, self->audio_system); self->device->device->SetAudioRate(::NTV2_AUDIO_48K, self->audio_system); self->device->device->SetAudioBufferSize(::NTV2_AUDIO_BUFFER_BIG, self->audio_system); self->device->device->SetAudioLoopBack(::NTV2_AUDIO_LOOPBACK_OFF, self->audio_system); self->device->device->SetEmbeddedAudioClock( ::NTV2_EMBEDDED_AUDIO_CLOCK_VIDEO_INPUT, self->audio_system); NTV2ReferenceSource reference_source; switch (self->reference_source) { case GST_AJA_REFERENCE_SOURCE_AUTO: reference_source = ::NTV2InputSourceToReferenceSource(input_source); break; case GST_AJA_REFERENCE_SOURCE_EXTERNAL: reference_source = ::NTV2_REFERENCE_EXTERNAL; break; case GST_AJA_REFERENCE_SOURCE_FREERUN: reference_source = ::NTV2_REFERENCE_FREERUN; break; case GST_AJA_REFERENCE_SOURCE_INPUT_1: reference_source = ::NTV2_REFERENCE_INPUT1; break; case GST_AJA_REFERENCE_SOURCE_INPUT_2: reference_source = ::NTV2_REFERENCE_INPUT2; break; case GST_AJA_REFERENCE_SOURCE_INPUT_3: reference_source = ::NTV2_REFERENCE_INPUT3; break; case GST_AJA_REFERENCE_SOURCE_INPUT_4: reference_source = ::NTV2_REFERENCE_INPUT4; break; case GST_AJA_REFERENCE_SOURCE_INPUT_5: reference_source = ::NTV2_REFERENCE_INPUT5; break; case GST_AJA_REFERENCE_SOURCE_INPUT_6: reference_source = ::NTV2_REFERENCE_INPUT6; break; case GST_AJA_REFERENCE_SOURCE_INPUT_7: reference_source = ::NTV2_REFERENCE_INPUT7; break; case GST_AJA_REFERENCE_SOURCE_INPUT_8: reference_source = ::NTV2_REFERENCE_INPUT8; break; default: g_assert_not_reached(); break; } GST_DEBUG_OBJECT(self, "Configuring reference source %d", (int)reference_source); self->device->device->SetReference(reference_source); self->device->device->SetLTCInputEnable(true); self->device->device->SetRP188SourceFilter(self->channel, 0xff); guint video_buffer_size = ::GetVideoActiveSize( self->video_format, ::NTV2_FBF_10BIT_YCBCR, self->vanc_mode); self->buffer_pool = gst_buffer_pool_new(); GstStructure *config = gst_buffer_pool_get_config(self->buffer_pool); gst_buffer_pool_config_set_params(config, NULL, video_buffer_size, 2 * self->queue_size, 0); gst_buffer_pool_config_set_allocator(config, self->allocator, NULL); gst_buffer_pool_set_config(self->buffer_pool, config); gst_buffer_pool_set_active(self->buffer_pool, TRUE); guint audio_buffer_size = 401 * 1024; self->audio_buffer_pool = gst_buffer_pool_new(); config = gst_buffer_pool_get_config(self->audio_buffer_pool); gst_buffer_pool_config_set_params(config, NULL, audio_buffer_size, 2 * self->queue_size, 0); gst_buffer_pool_config_set_allocator(config, self->allocator, NULL); gst_buffer_pool_set_config(self->audio_buffer_pool, config); gst_buffer_pool_set_active(self->audio_buffer_pool, TRUE); guint anc_buffer_size = 8 * 1024; if (self->vanc_mode == ::NTV2_VANCMODE_OFF && ::NTV2DeviceCanDoCustomAnc(self->device_id)) { self->anc_buffer_pool = gst_buffer_pool_new(); config = gst_buffer_pool_get_config(self->anc_buffer_pool); gst_buffer_pool_config_set_params( config, NULL, anc_buffer_size, (self->configured_info.interlace_mode == GST_VIDEO_INTERLACE_MODE_PROGRESSIVE ? 1 : 2) * self->queue_size, 0); gst_buffer_pool_config_set_allocator(config, self->allocator, NULL); gst_buffer_pool_set_config(self->anc_buffer_pool, config); gst_buffer_pool_set_active(self->anc_buffer_pool, TRUE); } gst_element_post_message(GST_ELEMENT_CAST(self), gst_message_new_latency(GST_OBJECT_CAST(self))); return TRUE; } static gboolean gst_aja_src_start(GstAjaSrc *self) { GST_DEBUG_OBJECT(self, "Starting"); self->video_format = NTV2_FORMAT_UNKNOWN; self->signal = FALSE; self->capture_thread = new AJAThread(); self->capture_thread->Attach(capture_thread_func, self); self->capture_thread->SetPriority(AJA_ThreadPriority_High); self->capture_thread->Start(); g_mutex_lock(&self->queue_lock); self->shutdown = FALSE; self->playing = FALSE; self->flushing = FALSE; g_cond_signal(&self->queue_cond); g_mutex_unlock(&self->queue_lock); return TRUE; } static gboolean gst_aja_src_stop(GstAjaSrc *self) { QueueItem *item; GST_DEBUG_OBJECT(self, "Stopping"); g_mutex_lock(&self->queue_lock); self->shutdown = TRUE; self->flushing = TRUE; self->playing = FALSE; g_cond_signal(&self->queue_cond); g_mutex_unlock(&self->queue_lock); if (self->capture_thread) { self->capture_thread->Stop(); delete self->capture_thread; self->capture_thread = NULL; } GST_OBJECT_LOCK(self); memset(&self->current_info, 0, sizeof(self->current_info)); memset(&self->configured_info, 0, sizeof(self->configured_info)); self->configured_audio_channels = 0; GST_OBJECT_UNLOCK(self); while ((item = (QueueItem *)gst_queue_array_pop_head_struct(self->queue))) { queue_item_clear(item); } self->queue_num_frames = 0; if (self->buffer_pool) { gst_buffer_pool_set_active(self->buffer_pool, FALSE); gst_clear_object(&self->buffer_pool); } if (self->audio_buffer_pool) { gst_buffer_pool_set_active(self->audio_buffer_pool, FALSE); gst_clear_object(&self->audio_buffer_pool); } if (self->anc_buffer_pool) { gst_buffer_pool_set_active(self->anc_buffer_pool, FALSE); gst_clear_object(&self->anc_buffer_pool); } self->video_format = NTV2_FORMAT_UNKNOWN; if (self->signal) { self->signal = FALSE; g_object_notify(G_OBJECT(self), "signal"); } GST_DEBUG_OBJECT(self, "Stopped"); return TRUE; } static GstStateChangeReturn gst_aja_src_change_state( GstElement *element, GstStateChange transition) { GstAjaSrc *self = GST_AJA_SRC(element); GstStateChangeReturn ret; switch (transition) { case GST_STATE_CHANGE_NULL_TO_READY: if (!gst_aja_src_open(self)) return GST_STATE_CHANGE_FAILURE; break; case GST_STATE_CHANGE_READY_TO_PAUSED: if (!gst_aja_src_start(self)) return GST_STATE_CHANGE_FAILURE; break; case GST_STATE_CHANGE_PAUSED_TO_PLAYING: break; default: break; } ret = GST_ELEMENT_CLASS(parent_class)->change_state(element, transition); if (ret == GST_STATE_CHANGE_FAILURE) return ret; switch (transition) { case GST_STATE_CHANGE_PLAYING_TO_PAUSED: g_mutex_lock(&self->queue_lock); self->playing = FALSE; g_cond_signal(&self->queue_cond); g_mutex_unlock(&self->queue_lock); break; case GST_STATE_CHANGE_PAUSED_TO_PLAYING: g_mutex_lock(&self->queue_lock); self->playing = TRUE; g_cond_signal(&self->queue_cond); g_mutex_unlock(&self->queue_lock); break; case GST_STATE_CHANGE_PAUSED_TO_READY: if (!gst_aja_src_stop(self)) return GST_STATE_CHANGE_FAILURE; break; case GST_STATE_CHANGE_READY_TO_NULL: if (!gst_aja_src_close(self)) return GST_STATE_CHANGE_FAILURE; break; default: break; } return ret; } static GstClock *gst_aja_src_provide_clock(GstElement *element) { GstAjaSrc *self = GST_AJA_SRC(element); return GST_CLOCK(gst_object_ref(self->clock)); } static GstCaps *gst_aja_src_get_caps(GstBaseSrc *bsrc, GstCaps *filter) { GstAjaSrc *self = GST_AJA_SRC(bsrc); GstCaps *caps; if (self->device) { caps = gst_ntv2_supported_caps(self->device_id); } else { caps = gst_pad_get_pad_template_caps(GST_BASE_SRC_PAD(self)); } // Intersect with the configured video format if any to constrain the caps // further. if (self->video_format_setting != GST_AJA_VIDEO_FORMAT_AUTO) { GstCaps *configured_caps = gst_aja_video_format_to_caps(self->video_format_setting); if (configured_caps) { GstCaps *tmp; // Remove pixel-aspect-ratio from the configured caps to allow for both // widescreen and non-widescreen PAL/NTSC. It's added back by the // template caps above when intersecting. guint n = gst_caps_get_size(configured_caps); for (guint i = 0; i < n; i++) { GstStructure *s = gst_caps_get_structure(configured_caps, i); gst_structure_remove_fields(s, "pixel-aspect-ratio", NULL); } tmp = gst_caps_intersect(caps, configured_caps); gst_caps_unref(caps); gst_caps_unref(configured_caps); caps = tmp; } } if (filter) { GstCaps *tmp = gst_caps_intersect_full(filter, caps, GST_CAPS_INTERSECT_FIRST); gst_caps_unref(caps); caps = tmp; } return caps; } static gboolean gst_aja_src_query(GstBaseSrc *bsrc, GstQuery *query) { GstAjaSrc *self = GST_AJA_SRC(bsrc); gboolean ret = TRUE; switch (GST_QUERY_TYPE(query)) { case GST_QUERY_LATENCY: { if (self->current_info.finfo && self->current_info.finfo->format != GST_VIDEO_FORMAT_UNKNOWN) { GstClockTime min, max; min = gst_util_uint64_scale_ceil( GST_SECOND, 3 * self->current_info.fps_d, self->current_info.fps_n); max = self->queue_size * min; gst_query_set_latency(query, TRUE, min, max); ret = TRUE; } else { ret = FALSE; } return ret; } default: return GST_BASE_SRC_CLASS(parent_class)->query(bsrc, query); break; } } static gboolean gst_aja_src_unlock(GstBaseSrc *bsrc) { GstAjaSrc *self = GST_AJA_SRC(bsrc); g_mutex_lock(&self->queue_lock); self->flushing = TRUE; g_cond_signal(&self->queue_cond); g_mutex_unlock(&self->queue_lock); return TRUE; } static gboolean gst_aja_src_unlock_stop(GstBaseSrc *bsrc) { GstAjaSrc *self = GST_AJA_SRC(bsrc); g_mutex_lock(&self->queue_lock); self->flushing = FALSE; g_mutex_unlock(&self->queue_lock); return TRUE; } static GstFlowReturn gst_aja_src_create(GstPushSrc *psrc, GstBuffer **buffer) { GstAjaSrc *self = GST_AJA_SRC(psrc); GstFlowReturn flow_ret = GST_FLOW_OK; QueueItem item = { .type = QUEUE_ITEM_TYPE_DUMMY, }; next_item: item.type = QUEUE_ITEM_TYPE_DUMMY; g_mutex_lock(&self->queue_lock); while (gst_queue_array_is_empty(self->queue) && !self->flushing) { g_cond_wait(&self->queue_cond, &self->queue_lock); } if (self->flushing) { g_mutex_unlock(&self->queue_lock); GST_DEBUG_OBJECT(self, "Flushing"); return GST_FLOW_FLUSHING; } item = *(QueueItem *)gst_queue_array_pop_head_struct(self->queue); if (item.type == QUEUE_ITEM_TYPE_FRAME) { self->queue_num_frames -= 1; } g_mutex_unlock(&self->queue_lock); switch (item.type) { case QUEUE_ITEM_TYPE_DUMMY: queue_item_clear(&item); goto next_item; case QUEUE_ITEM_TYPE_SIGNAL_CHANGE: // These are already only produced when signal status is changing if (item.signal_change.have_signal) { GstAjaVideoFormat fmt = gst_aja_video_format_from_ntv2_format( item.signal_change.detected_format); gchar *format_str = g_enum_to_string(GST_TYPE_AJA_VIDEO_FORMAT, fmt); std::string format_string = NTV2VideoFormatToString(item.signal_change.detected_format); GST_ELEMENT_INFO_WITH_DETAILS( GST_ELEMENT(self), RESOURCE, READ, ("Signal recovered"), ("Input source detected"), ("detected-format", G_TYPE_STRING, format_string.c_str(), "gst-aja-format", G_TYPE_STRING, format_str, "vpid", G_TYPE_UINT, item.signal_change.vpid, NULL)); self->signal = TRUE; g_object_notify(G_OBJECT(self), "signal"); g_free(format_str); } else if (!item.signal_change.have_signal) { if (item.signal_change.detected_format != ::NTV2_FORMAT_UNKNOWN) { GstAjaVideoFormat fmt = gst_aja_video_format_from_ntv2_format( item.signal_change.detected_format); gchar *format_str = g_enum_to_string(GST_TYPE_AJA_VIDEO_FORMAT, fmt); std::string format_string = NTV2VideoFormatToString(item.signal_change.detected_format); GST_ELEMENT_WARNING_WITH_DETAILS( GST_ELEMENT(self), RESOURCE, READ, ("Signal lost"), ("Input source with different mode %s was detected", format_str), ("detected-format", G_TYPE_STRING, format_string.c_str(), "gst-aja-format", G_TYPE_STRING, format_str, "vpid", G_TYPE_UINT, item.signal_change.vpid, NULL)); g_free(format_str); } else { GST_ELEMENT_WARNING(GST_ELEMENT(self), RESOURCE, READ, ("Signal lost"), ("No input source was detected")); } self->signal = FALSE; g_object_notify(G_OBJECT(self), "signal"); } queue_item_clear(&item); goto next_item; case QUEUE_ITEM_TYPE_ERROR: GST_ERROR_OBJECT(self, "Stopping because of error on capture thread"); gst_element_post_message(GST_ELEMENT(self), (GstMessage *)g_steal_pointer(&item.error.msg)); queue_item_clear(&item); return GST_FLOW_ERROR; case QUEUE_ITEM_TYPE_FRAMES_DROPPED: GST_WARNING_OBJECT( self, "Dropped frames from %" GST_TIME_FORMAT " to %" GST_TIME_FORMAT, GST_TIME_ARGS(item.frames_dropped.timestamp_start), GST_TIME_ARGS(item.frames_dropped.timestamp_end)); gst_element_post_message( GST_ELEMENT(self), gst_message_new_qos(GST_OBJECT_CAST(self), TRUE, GST_CLOCK_TIME_NONE, GST_CLOCK_TIME_NONE, item.frames_dropped.timestamp_start, item.frames_dropped.timestamp_end - item.frames_dropped.timestamp_start)); queue_item_clear(&item); goto next_item; case QUEUE_ITEM_TYPE_FRAME: // fall through below break; } g_assert(item.type == QUEUE_ITEM_TYPE_FRAME); if (!self->signal) { self->signal = TRUE; g_object_notify(G_OBJECT(self), "signal"); } *buffer = (GstBuffer *)g_steal_pointer(&item.frame.video_buffer); gst_buffer_add_aja_audio_meta(*buffer, item.frame.audio_buffer); gst_clear_buffer(&item.frame.audio_buffer); if (item.frame.tc.IsValid()) { TimecodeFormat tc_format = ::kTCFormatUnknown; GstVideoTimeCodeFlags flags = GST_VIDEO_TIME_CODE_FLAGS_NONE; if (self->configured_info.fps_n == 24 && self->configured_info.fps_d == 1) { tc_format = kTCFormat24fps; } else if (self->configured_info.fps_n == 25 && self->configured_info.fps_d == 1) { tc_format = kTCFormat25fps; } else if (self->configured_info.fps_n == 30 && self->configured_info.fps_d == 1) { tc_format = kTCFormat30fps; } else if (self->configured_info.fps_n == 30000 && self->configured_info.fps_d == 1001) { tc_format = kTCFormat30fpsDF; flags = (GstVideoTimeCodeFlags)(flags | GST_VIDEO_TIME_CODE_FLAGS_DROP_FRAME); } else if (self->configured_info.fps_n == 48 && self->configured_info.fps_d == 1) { tc_format = kTCFormat48fps; } else if (self->configured_info.fps_n == 50 && self->configured_info.fps_d == 1) { tc_format = kTCFormat50fps; } else if (self->configured_info.fps_n == 60 && self->configured_info.fps_d == 1) { tc_format = kTCFormat60fps; } else if (self->configured_info.fps_n == 60000 && self->configured_info.fps_d == 1001) { tc_format = kTCFormat60fpsDF; flags = (GstVideoTimeCodeFlags)(flags | GST_VIDEO_TIME_CODE_FLAGS_DROP_FRAME); } if (self->configured_info.interlace_mode != GST_VIDEO_INTERLACE_MODE_PROGRESSIVE) flags = (GstVideoTimeCodeFlags)(flags | GST_VIDEO_TIME_CODE_FLAGS_INTERLACED); CRP188 rp188(item.frame.tc, tc_format); { std::stringstream os; os << rp188; GST_TRACE_OBJECT(self, "Adding timecode %s", os.str().c_str()); } guint hours, minutes, seconds, frames; rp188.GetRP188Hrs(hours); rp188.GetRP188Mins(minutes); rp188.GetRP188Secs(seconds); rp188.GetRP188Frms(frames); GstVideoTimeCode tc; gst_video_time_code_init(&tc, self->configured_info.fps_n, self->configured_info.fps_d, NULL, flags, hours, minutes, seconds, frames, 0); gst_buffer_add_video_time_code_meta(*buffer, &tc); } AJAAncillaryList anc_packets; if (item.frame.anc_buffer) { GstMapInfo map = GST_MAP_INFO_INIT; GstMapInfo map2 = GST_MAP_INFO_INIT; gst_buffer_map(item.frame.anc_buffer, &map, GST_MAP_READ); if (item.frame.anc_buffer2) gst_buffer_map(item.frame.anc_buffer2, &map2, GST_MAP_READ); NTV2_POINTER ptr1(map.data, map.size); NTV2_POINTER ptr2(map2.data, map2.size); AJAAncillaryList::SetFromDeviceAncBuffers(ptr1, ptr2, anc_packets); if (item.frame.anc_buffer2) gst_buffer_unmap(item.frame.anc_buffer2, &map2); gst_buffer_unmap(item.frame.anc_buffer, &map); } else if (self->vanc_mode != ::NTV2_VANCMODE_OFF) { GstMapInfo map; NTV2FormatDescriptor format_desc(self->video_format, ::NTV2_FBF_10BIT_YCBCR, self->vanc_mode); gst_buffer_map(*buffer, &map, GST_MAP_READ); NTV2_POINTER ptr(map.data, map.size); AJAAncillaryList::SetFromVANCData(ptr, format_desc, anc_packets); gst_buffer_unmap(*buffer, &map); guint offset = format_desc.RasterLineToByteOffset(format_desc.GetFirstActiveLine()); guint size = format_desc.GetVisibleRasterBytes(); gst_buffer_resize(*buffer, offset, size); } gst_clear_buffer(&item.frame.anc_buffer); gst_clear_buffer(&item.frame.anc_buffer2); // Not using CountAncillaryDataWithType(AJAAncillaryDataType_Cea708) etc // here because for SD it doesn't recognize the packets. It assumes they // would only be received on AJAAncillaryDataChannel_Y but for SD it is // actually AJAAncillaryDataChannel_Both. // // See AJA SDK support ticket #4844. guint32 n_vanc_packets = anc_packets.CountAncillaryData(); // Check if we have either CEA608 or CEA708 packets, or both. bool have_cea608 = false; bool have_cea708 = false; for (guint32 i = 0; i < n_vanc_packets; i++) { AJAAncillaryData *packet = anc_packets.GetAncillaryDataAtIndex(i); if (packet->GetDID() == AJAAncillaryData_Cea608_Vanc_DID && packet->GetSID() == AJAAncillaryData_Cea608_Vanc_SID && packet->GetPayloadData() && packet->GetPayloadByteCount() && AJA_SUCCESS(packet->ParsePayloadData())) { GST_TRACE_OBJECT( self, "Found CEA608 VANC of %" G_GSIZE_FORMAT " bytes at line %u", packet->GetPayloadByteCount(), packet->GetLocationLineNumber()); have_cea608 = true; } else if (packet->GetDID() == AJAAncillaryData_CEA708_DID && packet->GetSID() == AJAAncillaryData_CEA708_SID && packet->GetPayloadData() && packet->GetPayloadByteCount() && AJA_SUCCESS(packet->ParsePayloadData())) { GST_TRACE_OBJECT( self, "Found CEA708 CDP VANC of %" G_GSIZE_FORMAT " bytes at line %u", packet->GetPayloadByteCount(), packet->GetLocationLineNumber()); have_cea708 = true; } } // Decide based on the closed-caption-capture-mode property and closed // caption availability which ones to add as metadata to the output buffer. bool want_cea608 = have_cea608 && (self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_AND_CEA608 || self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA608_OR_CEA708 || self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA608_ONLY || (!have_cea708 && self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_OR_CEA608)); bool want_cea708 = have_cea708 && (self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_AND_CEA608 || self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_OR_CEA608 || self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA708_ONLY || (!have_cea608 && self->closed_caption_capture_mode == GST_AJA_CLOSED_CAPTION_CAPTURE_MODE_CEA608_OR_CEA708)); bool aspect_ratio_flag = false; bool have_afd_bar = false; for (guint32 i = 0; i < n_vanc_packets; i++) { AJAAncillaryData *packet = anc_packets.GetAncillaryDataAtIndex(i); if (want_cea608 && packet->GetDID() == AJAAncillaryData_Cea608_Vanc_DID && packet->GetSID() == AJAAncillaryData_Cea608_Vanc_SID && packet->GetPayloadData() && packet->GetPayloadByteCount() && AJA_SUCCESS(packet->ParsePayloadData())) { GST_TRACE_OBJECT( self, "Adding CEA608 VANC of %" G_GSIZE_FORMAT " bytes at line %u", packet->GetPayloadByteCount(), packet->GetLocationLineNumber()); gst_buffer_add_video_caption_meta( *buffer, GST_VIDEO_CAPTION_TYPE_CEA608_S334_1A, packet->GetPayloadData(), packet->GetPayloadByteCount()); } else if (want_cea708 && packet->GetDID() == AJAAncillaryData_CEA708_DID && packet->GetSID() == AJAAncillaryData_CEA708_SID && packet->GetPayloadData() && packet->GetPayloadByteCount() && AJA_SUCCESS(packet->ParsePayloadData())) { GST_TRACE_OBJECT( self, "Adding CEA708 CDP VANC of %" G_GSIZE_FORMAT " bytes at line %u", packet->GetPayloadByteCount(), packet->GetLocationLineNumber()); gst_buffer_add_video_caption_meta( *buffer, GST_VIDEO_CAPTION_TYPE_CEA708_CDP, packet->GetPayloadData(), packet->GetPayloadByteCount()); } else if (packet->GetDID() == 0x41 && packet->GetSID() == 0x05 && packet->GetPayloadData() && packet->GetPayloadByteCount() == 8) { const guint8 *data = packet->GetPayloadData(); have_afd_bar = true; aspect_ratio_flag = (data[0] >> 2) & 0x1; GstVideoAFDValue afd = (GstVideoAFDValue)((data[0] >> 3) & 0xf); gboolean is_letterbox = ((data[3] >> 4) & 0x3) == 0; guint16 bar1 = GST_READ_UINT16_BE(&data[4]); guint16 bar2 = GST_READ_UINT16_BE(&data[6]); GST_TRACE_OBJECT(self, "Found AFD/Bar VANC at line %u: AR %u, AFD %u, " "letterbox %u, bar1 %u, bar2 %u", packet->GetLocationLineNumber(), aspect_ratio_flag, afd, is_letterbox, bar1, bar2); const NTV2Standard standard( ::GetNTV2StandardFromVideoFormat(item.frame.detected_format)); const NTV2SmpteLineNumber smpte_line_num_info = ::GetSmpteLineNumber(standard); bool field2 = packet->GetLocationLineNumber() > smpte_line_num_info.GetLastLine( smpte_line_num_info.firstFieldTop ? NTV2_FIELD0 : NTV2_FIELD1); gst_buffer_add_video_afd_meta(*buffer, field2 ? 1 : 0, GST_VIDEO_AFD_SPEC_SMPTE_ST2016_1, afd); gst_buffer_add_video_bar_meta(*buffer, field2 ? 1 : 0, is_letterbox, bar1, bar2); } // Don't attach other ANC as ancillary meta if not requested to do so. if (!self->attach_ancillary_meta) continue; // Skip non-SMPTE 291M ancillary data if (packet->GetDataCoding() != AJAAncillaryDataCoding_Digital) continue; const guint8 *in_data = packet->GetPayloadData(); guint data_count = packet->GetDC(); guint16 line_number = packet->GetLocationLineNumber(); guint16 horiz_offset = packet->GetLocationHorizOffset(); if (!in_data || data_count == 0) { GST_TRACE_OBJECT(self, "ANC %s (%04x) at (%u,%u) has no payload data", packet->IDAsString().c_str(), packet->GetDIDSID(), line_number, horiz_offset); continue; } GST_TRACE_OBJECT(self, "Adding ANC meta for %s (%04x) at (%u,%u) of size %u", packet->IDAsString().c_str(), packet->GetDIDSID(), line_number, horiz_offset, data_count); GstAncillaryMeta *anc_meta = gst_buffer_add_ancillary_meta(*buffer); anc_meta->c_not_y_channel = packet->IsChromaChannel(); anc_meta->line = line_number; anc_meta->offset = horiz_offset; packet->GeneratePayloadData(); anc_meta->DID = AJAAncillaryData::AddEvenParity(packet->GetDID()); anc_meta->SDID_block_number = AJAAncillaryData::AddEvenParity(packet->GetSID()); anc_meta->data_count = AJAAncillaryData::AddEvenParity(data_count); guint16 *data = g_new(guint16, packet->GetDC()); for (guint i = 0; i < data_count; i++) { data[i] = AJAAncillaryData::AddEvenParity(in_data[i]); } anc_meta->data = data; anc_meta->checksum = packet->Calculate9BitChecksum(); } bool caps_changed = false; CNTV2VPID vpid(item.frame.vpid); if (vpid.IsValid()) { GstVideoInfo info; { std::stringstream os; vpid.Print(os); GST_TRACE_OBJECT(self, "Got valid VPID %s", os.str().c_str()); } if (gst_video_info_from_ntv2_video_format(&info, item.frame.detected_format)) { switch (vpid.GetTransferCharacteristics()) { default: case NTV2_VPID_TC_SDR_TV: if (info.height < 720) { info.colorimetry.transfer = GST_VIDEO_TRANSFER_BT601; } else { info.colorimetry.transfer = GST_VIDEO_TRANSFER_BT709; } break; case NTV2_VPID_TC_HLG: info.colorimetry.transfer = GST_VIDEO_TRANSFER_ARIB_STD_B67; break; case NTV2_VPID_TC_PQ: info.colorimetry.transfer = GST_VIDEO_TRANSFER_SMPTE2084; break; } switch (vpid.GetColorimetry()) { case NTV2_VPID_Color_Rec709: info.colorimetry.matrix = GST_VIDEO_COLOR_MATRIX_BT709; info.colorimetry.primaries = GST_VIDEO_COLOR_PRIMARIES_BT709; break; case NTV2_VPID_Color_UHDTV: info.colorimetry.matrix = GST_VIDEO_COLOR_MATRIX_BT2020; info.colorimetry.primaries = GST_VIDEO_COLOR_PRIMARIES_BT2020; break; default: // Default handling break; } switch (vpid.GetRGBRange()) { case NTV2_VPID_Range_Full: info.colorimetry.range = GST_VIDEO_COLOR_RANGE_0_255; break; case NTV2_VPID_Range_Narrow: info.colorimetry.range = GST_VIDEO_COLOR_RANGE_16_235; break; } if (!have_afd_bar && vpid.GetImageAspect16x9()) aspect_ratio_flag = true; // Widescreen PAL/NTSC if (aspect_ratio_flag && info.height == 486) { info.par_n = 40; info.par_d = 33; } else if (aspect_ratio_flag && info.height == 576) { info.par_n = 16; info.par_d = 11; } if (!gst_pad_has_current_caps(GST_BASE_SRC_PAD(self)) || !gst_video_info_is_equal(&info, &self->current_info)) { self->current_info = info; caps_changed = true; } } } else { GstVideoInfo info; if (gst_video_info_from_ntv2_video_format(&info, item.frame.detected_format)) { // Widescreen PAL/NTSC if (aspect_ratio_flag && info.height == 486) { info.par_n = 40; info.par_d = 33; } else if (aspect_ratio_flag && info.height == 576) { info.par_n = 16; info.par_d = 11; } if (!gst_pad_has_current_caps(GST_BASE_SRC_PAD(self)) || !gst_video_info_is_equal(&info, &self->current_info)) { self->current_info = info; caps_changed = true; } } else if (!gst_pad_has_current_caps(GST_BASE_SRC_PAD(self))) { self->current_info = self->configured_info; // Widescreen PAL/NTSC if (aspect_ratio_flag && self->current_info.height == 486) { self->current_info.par_n = 40; self->current_info.par_d = 33; } else if (aspect_ratio_flag && self->current_info.height == 576) { self->current_info.par_n = 16; self->current_info.par_d = 11; } caps_changed = true; } } if (caps_changed) { GstCaps *caps = gst_video_info_to_caps(&self->current_info); gst_caps_set_simple(caps, "audio-channels", G_TYPE_INT, self->configured_audio_channels, NULL); GST_DEBUG_OBJECT(self, "Configuring caps %" GST_PTR_FORMAT, caps); gst_base_src_set_caps(GST_BASE_SRC_CAST(self), caps); gst_caps_unref(caps); } if (self->configured_info.interlace_mode != GST_VIDEO_INTERLACE_MODE_PROGRESSIVE) { GST_BUFFER_FLAG_SET(*buffer, GST_VIDEO_BUFFER_FLAG_INTERLACED); switch (GST_VIDEO_INFO_FIELD_ORDER(&self->configured_info)) { case GST_VIDEO_FIELD_ORDER_TOP_FIELD_FIRST: GST_BUFFER_FLAG_SET(*buffer, GST_VIDEO_BUFFER_FLAG_TFF); default: break; } } queue_item_clear(&item); GST_TRACE_OBJECT(self, "Outputting buffer %" GST_PTR_FORMAT, *buffer); return flow_ret; } #define AJA_SRC_ERROR(el, domain, code, text, debug) \ G_STMT_START { \ gchar *__txt = _gst_element_error_printf text; \ gchar *__dbg = _gst_element_error_printf debug; \ GstMessage *__msg; \ GError *__err; \ gchar *__name, *__fmt_dbg; \ if (__txt) GST_WARNING_OBJECT(el, "error: %s", __txt); \ if (__dbg) GST_WARNING_OBJECT(el, "error: %s", __dbg); \ if (!__txt) \ __txt = gst_error_get_message(GST_##domain##_ERROR, \ GST_##domain##_ERROR_##code); \ __err = g_error_new_literal(GST_##domain##_ERROR, \ GST_##domain##_ERROR_##code, __txt); \ __name = gst_object_get_path_string(GST_OBJECT_CAST(el)); \ if (__dbg) \ __fmt_dbg = g_strdup_printf("%s(%d): %s (): %s:\n%s", __FILE__, \ __LINE__, GST_FUNCTION, __name, __dbg); \ else \ __fmt_dbg = g_strdup_printf("%s(%d): %s (): %s", __FILE__, __LINE__, \ GST_FUNCTION, __name); \ g_free(__name); \ g_free(__dbg); \ __msg = gst_message_new_error(GST_OBJECT(el), __err, __fmt_dbg); \ QueueItem item = {.type = QUEUE_ITEM_TYPE_ERROR, .error{.msg = __msg}}; \ gst_queue_array_push_tail_struct(el->queue, &item); \ g_cond_signal(&el->queue_cond); \ } \ G_STMT_END; static void capture_thread_func(AJAThread *thread, void *data) { GstAjaSrc *self = GST_AJA_SRC(data); GstClock *clock = NULL; GstClock *real_time_clock; AUTOCIRCULATE_TRANSFER transfer; guint64 frames_dropped_last = G_MAXUINT64; gboolean have_signal = TRUE, discont = TRUE; guint iterations_without_frame = 0; NTV2VideoFormat last_detected_video_format = ::NTV2_FORMAT_UNKNOWN; if (self->capture_cpu_core != G_MAXUINT) { cpu_set_t mask; pthread_t current_thread = pthread_self(); CPU_ZERO(&mask); CPU_SET(self->capture_cpu_core, &mask); if (pthread_setaffinity_np(current_thread, sizeof(mask), &mask) != 0) { GST_ERROR_OBJECT(self, "Failed to set affinity for current thread to core %u", self->capture_cpu_core); } } // We're getting a system clock for the real-time clock here because // g_get_real_time() is less accurate generally. real_time_clock = GST_CLOCK(g_object_new(GST_TYPE_SYSTEM_CLOCK, "clock-type", GST_CLOCK_TYPE_REALTIME, NULL)); bool clock_is_monotonic_system_clock = false; bool first_frame_after_start = true; GstClockTime first_frame_time = 0; guint64 first_frame_processed_plus_dropped_minus_buffered = 0; g_mutex_lock(&self->queue_lock); restart: GST_DEBUG_OBJECT(self, "Waiting for playing or shutdown"); while (!self->playing && !self->shutdown) g_cond_wait(&self->queue_cond, &self->queue_lock); if (self->shutdown) { GST_DEBUG_OBJECT(self, "Shutting down"); goto out; } GST_DEBUG_OBJECT(self, "Starting capture"); g_mutex_unlock(&self->queue_lock); gst_clear_object(&clock); clock = gst_element_get_clock(GST_ELEMENT_CAST(self)); clock_is_monotonic_system_clock = false; if (G_OBJECT_TYPE(clock) == GST_TYPE_SYSTEM_CLOCK) { GstClock *system_clock = gst_system_clock_obtain(); if (clock == system_clock) { GstClockType clock_type; g_object_get(clock, "clock-type", &clock_type, NULL); clock_is_monotonic_system_clock = clock_type == GST_CLOCK_TYPE_MONOTONIC; } gst_clear_object(&system_clock); } first_frame_after_start = true; first_frame_time = 0; frames_dropped_last = G_MAXUINT64; have_signal = TRUE; g_mutex_lock(&self->queue_lock); while (self->playing && !self->shutdown) { // If we don't have a video format configured, configure the device now // and potentially auto-detect the video format if (self->video_format == NTV2_FORMAT_UNKNOWN) { // Don't keep queue locked while configuring as this might take a while g_mutex_unlock(&self->queue_lock); // Make sure to globally lock here as the routing settings and others are // global shared state GstAjaNtv2DeviceLocker locker(self->device); if (!gst_aja_src_configure(self)) { g_mutex_lock(&self->queue_lock); AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to configure device")); goto out; } g_mutex_lock(&self->queue_lock); if (!self->playing || self->shutdown) goto restart; if (self->video_format == ::NTV2_FORMAT_UNKNOWN) { GST_DEBUG_OBJECT(self, "No signal, waiting"); frames_dropped_last = G_MAXUINT64; if (have_signal) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = FALSE, .detected_format = ::NTV2_FORMAT_UNKNOWN, .vpid = 0}}; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); have_signal = FALSE; discont = TRUE; } self->device->device->WaitForInputVerticalInterrupt(self->channel); continue; } guint16 start_frame = self->start_frame; guint16 end_frame = self->end_frame; // If both are set to the same value, try to find that many unallocated // frames and use those. if (start_frame == end_frame) { gint assigned_start_frame = gst_aja_ntv2_device_find_unallocated_frames( self->device, self->channel, self->start_frame); if (assigned_start_frame == -1) { AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to allocate %u frames", start_frame)); goto out; } start_frame = assigned_start_frame; end_frame = start_frame + self->start_frame - 1; } GST_DEBUG_OBJECT( self, "Configuring channel %u with start frame %u and end frame %u", self->channel, start_frame, end_frame); if (!self->device->device->AutoCirculateInitForInput( self->channel, 0, self->audio_system, (self->rp188 ? AUTOCIRCULATE_WITH_RP188 : 0) | (self->vanc_mode == ::NTV2_VANCMODE_OFF ? AUTOCIRCULATE_WITH_ANC : 0), 1, start_frame, end_frame)) { AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to initialize autocirculate")); goto out; } self->device->device->AutoCirculateStart(self->channel); first_frame_after_start = true; } // Check for valid signal first NTV2VideoFormat current_video_format = self->device->device->GetInputVideoFormat( self->configured_input_source); bool all_quads_equal = true; if (self->quad_mode) { for (int i = 1; i < 4; i++) { NTV2VideoFormat other_video_format = self->device->device->GetInputVideoFormat( (NTV2InputSource)(self->configured_input_source + i)); if (other_video_format != current_video_format) { std::string current_string = NTV2VideoFormatToString(current_video_format); std::string other_string = NTV2VideoFormatToString(other_video_format); GST_DEBUG_OBJECT( self, "Not all quadrants had the same format in " "quad-link-mode: %s (%d) on input 1 vs. %s (%d) on input %d", current_string.c_str(), current_video_format, other_string.c_str(), other_video_format, i + 1); all_quads_equal = false; break; } } } ULWord vpid_a = 0; ULWord vpid_b = 0; self->device->device->ReadSDIInVPID(self->channel, vpid_a, vpid_b); { std::string current_string = NTV2VideoFormatToString(current_video_format); GST_TRACE_OBJECT( self, "Detected input video format %s (%d) with VPID %08x / %08x", current_string.c_str(), (int)current_video_format, vpid_a, vpid_b); } NTV2VideoFormat effective_video_format = self->video_format; // Can't call this unconditionally as it also maps e.g. 3840x2160p to 1080p if (self->quad_mode) { effective_video_format = ::GetQuarterSizedVideoFormat(effective_video_format); } switch (self->video_format) { case NTV2_FORMAT_1080psf_2500_2: if (current_video_format == NTV2_FORMAT_1080i_5000) current_video_format = NTV2_FORMAT_1080psf_2500_2; break; case NTV2_FORMAT_1080psf_2997_2: if (current_video_format == NTV2_FORMAT_1080i_5994) current_video_format = NTV2_FORMAT_1080psf_2997_2; break; case NTV2_FORMAT_1080psf_3000_2: if (current_video_format == NTV2_FORMAT_1080i_6000) current_video_format = NTV2_FORMAT_1080psf_3000_2; break; default: break; } if (current_video_format == ::NTV2_FORMAT_UNKNOWN || !all_quads_equal) { if (self->video_format_setting == GST_AJA_VIDEO_FORMAT_AUTO) self->video_format = NTV2_FORMAT_UNKNOWN; GST_DEBUG_OBJECT(self, "No signal, waiting"); g_mutex_unlock(&self->queue_lock); frames_dropped_last = G_MAXUINT64; if (have_signal || current_video_format != last_detected_video_format) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = FALSE, .detected_format = ::NTV2_FORMAT_UNKNOWN, .vpid = 0}}; last_detected_video_format = ::NTV2_FORMAT_UNKNOWN; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); have_signal = FALSE; discont = TRUE; } self->device->device->WaitForInputVerticalInterrupt(self->channel); g_mutex_lock(&self->queue_lock); continue; } else if (current_video_format != effective_video_format && current_video_format != self->video_format) { // Try reconfiguring with the newly detected video format if (self->video_format_setting == GST_AJA_VIDEO_FORMAT_AUTO) { self->video_format = NTV2_FORMAT_UNKNOWN; continue; } std::string current_string = NTV2VideoFormatToString(current_video_format); std::string configured_string = NTV2VideoFormatToString(self->video_format); std::string effective_string = NTV2VideoFormatToString(effective_video_format); GST_DEBUG_OBJECT(self, "Different input format %s than configured %s " "(effective %s), waiting", current_string.c_str(), configured_string.c_str(), effective_string.c_str()); g_mutex_unlock(&self->queue_lock); frames_dropped_last = G_MAXUINT64; if (have_signal || current_video_format != last_detected_video_format) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = FALSE, .detected_format = current_video_format, .vpid = vpid_a}}; last_detected_video_format = current_video_format; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); have_signal = FALSE; discont = TRUE; } self->device->device->WaitForInputVerticalInterrupt(self->channel); g_mutex_lock(&self->queue_lock); continue; } else if (have_signal && current_video_format != last_detected_video_format) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = TRUE, .detected_format = current_video_format, .vpid = vpid_a}}; last_detected_video_format = current_video_format; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); } AUTOCIRCULATE_STATUS status; self->device->device->AutoCirculateGetStatus(self->channel, status); GST_TRACE_OBJECT( self, "State %d " "start frame %d " "end frame %d " "active frame %d " "start time %" GST_TIME_FORMAT " " "current time %" GST_TIME_FORMAT " " "frames processed %u " "frames dropped %u " "buffer level %u", status.acState, status.acStartFrame, status.acEndFrame, status.acActiveFrame, GST_TIME_ARGS(status.acRDTSCStartTime * 100), GST_TIME_ARGS(status.acRDTSCCurrentTime * 100), status.acFramesProcessed, status.acFramesDropped, status.acBufferLevel); if (status.IsRunning() && status.acBufferLevel > 1) { GstBuffer *video_buffer = NULL; GstBuffer *audio_buffer = NULL; GstBuffer *anc_buffer = NULL, *anc_buffer2 = NULL; GstMapInfo video_map = GST_MAP_INFO_INIT; GstMapInfo audio_map = GST_MAP_INFO_INIT; GstMapInfo anc_map = GST_MAP_INFO_INIT; GstMapInfo anc_map2 = GST_MAP_INFO_INIT; AUTOCIRCULATE_TRANSFER transfer; if (!have_signal) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = TRUE, .detected_format = current_video_format, .vpid = vpid_a}}; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); have_signal = TRUE; } iterations_without_frame = 0; if (gst_buffer_pool_acquire_buffer(self->buffer_pool, &video_buffer, NULL) != GST_FLOW_OK) { AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to acquire video buffer")); break; } if (gst_buffer_pool_acquire_buffer(self->audio_buffer_pool, &audio_buffer, NULL) != GST_FLOW_OK) { gst_buffer_unref(video_buffer); AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to acquire audio buffer")); break; } if (self->vanc_mode == ::NTV2_VANCMODE_OFF && ::NTV2DeviceCanDoCustomAnc(self->device_id)) { if (gst_buffer_pool_acquire_buffer(self->anc_buffer_pool, &anc_buffer, NULL) != GST_FLOW_OK) { gst_buffer_unref(audio_buffer); gst_buffer_unref(video_buffer); AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to acquire anc buffer")); break; } if (self->configured_info.interlace_mode != GST_VIDEO_INTERLACE_MODE_PROGRESSIVE) { if (gst_buffer_pool_acquire_buffer( self->anc_buffer_pool, &anc_buffer2, NULL) != GST_FLOW_OK) { gst_buffer_unref(anc_buffer); gst_buffer_unref(audio_buffer); gst_buffer_unref(video_buffer); AJA_SRC_ERROR(self, STREAM, FAILED, (NULL), ("Failed to acquire anc buffer")); break; } } } gst_buffer_map(video_buffer, &video_map, GST_MAP_READWRITE); gst_buffer_map(audio_buffer, &audio_map, GST_MAP_READWRITE); if (anc_buffer) gst_buffer_map(anc_buffer, &anc_map, GST_MAP_READWRITE); if (anc_buffer2) gst_buffer_map(anc_buffer2, &anc_map2, GST_MAP_READWRITE); transfer.acFrameBufferFormat = ::NTV2_FBF_10BIT_YCBCR; transfer.SetVideoBuffer((ULWord *)video_map.data, video_map.size); transfer.SetAudioBuffer((ULWord *)audio_map.data, audio_map.size); transfer.SetAncBuffers((ULWord *)anc_map.data, anc_map.size, (ULWord *)anc_map2.data, anc_map2.size); g_mutex_unlock(&self->queue_lock); bool transfered = true; if (!self->device->device->AutoCirculateTransfer(self->channel, transfer)) { GST_WARNING_OBJECT(self, "Failed to transfer frame"); transfered = false; } if (anc_buffer2) gst_buffer_unmap(anc_buffer2, &anc_map2); if (anc_buffer) gst_buffer_unmap(anc_buffer, &anc_map); gst_buffer_unmap(audio_buffer, &audio_map); gst_buffer_unmap(video_buffer, &video_map); g_mutex_lock(&self->queue_lock); if (!transfered) { gst_clear_buffer(&anc_buffer2); gst_clear_buffer(&anc_buffer); gst_clear_buffer(&audio_buffer); gst_clear_buffer(&video_buffer); continue; } const AUTOCIRCULATE_TRANSFER_STATUS &transfer_status = transfer.GetTransferStatus(); const FRAME_STAMP &frame_stamp = transfer_status.GetFrameStamp(); GST_TRACE_OBJECT(self, "State %d " "transfer frame %d " "current frame %u " "frame time %" GST_TIME_FORMAT " " "current frame time %" GST_TIME_FORMAT " " "current time %" GST_TIME_FORMAT " " "frames processed %u " "frames dropped %u " "buffer level %u", transfer_status.acState, transfer_status.acTransferFrame, frame_stamp.acCurrentFrame, GST_TIME_ARGS(frame_stamp.acFrameTime * 100), GST_TIME_ARGS(frame_stamp.acCurrentFrameTime * 100), GST_TIME_ARGS(frame_stamp.acCurrentTime * 100), transfer_status.acFramesProcessed, transfer_status.acFramesDropped, transfer_status.acBufferLevel); GstClockTime frame_time_real = frame_stamp.acFrameTime * 100; // Convert capture time from real-time clock to monotonic clock by // sampling both and working with the difference. The monotonic clock is // used for all further calculations because it is more reliable. GstClockTime now_real_sys = gst_clock_get_time(real_time_clock); GstClockTime now_monotonic_sys = gst_clock_get_internal_time(self->clock); GstClockTime now_gst = gst_clock_get_time(clock); GstClockTime frame_time_monotonic; if (now_real_sys > now_monotonic_sys) { GstClockTime diff = now_real_sys - now_monotonic_sys; if (frame_time_real > diff) frame_time_monotonic = frame_time_real - diff; else frame_time_monotonic = 0; } else { GstClockTime diff = now_monotonic_sys - now_real_sys; frame_time_monotonic = frame_time_real + diff; } GstClockTime frame_src_time; // Update clock mapping if (first_frame_after_start) { GstClockTime internal, external; guint64 num, denom; // FIXME: Workaround to get rid of all previous observations g_object_set(self->clock, "window-size", 32, NULL); // Use the monotonic frame time converted back to our clock as base. // In the beginning this would be equal to the monotonic clock, at // later times this is needed to avoid jumps (possibly backwards!) of // the clock time when the framerate changes. // // We manually adjust with the calibration here because otherwise the // clock will clamp it to the last returned clock time, which most // likely is in the future. gst_clock_get_calibration(self->clock, &internal, &external, &num, &denom); first_frame_time = frame_src_time = gst_clock_adjust_with_calibration( NULL, frame_time_monotonic, internal, external, num, denom); first_frame_processed_plus_dropped_minus_buffered = transfer_status.acFramesProcessed + transfer_status.acFramesDropped - transfer_status.acBufferLevel; } else { gdouble r_squared; frame_src_time = first_frame_time + gst_util_uint64_scale_ceil( transfer_status.acFramesProcessed + transfer_status.acFramesDropped - transfer_status.acBufferLevel - first_frame_processed_plus_dropped_minus_buffered, self->configured_info.fps_d * GST_SECOND, self->configured_info.fps_n); gst_clock_add_observation(self->clock, frame_time_monotonic, frame_src_time, &r_squared); } first_frame_after_start = false; GstClockTime capture_time; if (self->clock == clock) { // If the pipeline is using our clock then we can directly use the // frame counter based time as capture time. capture_time = frame_src_time; } else { GstClockTime internal, external; guint64 num, denom; // Otherwise convert the frame counter based time to the monotonic // clock via our clock, which should give a smoother time than just // the raw capture time. // // We manually adjust with the calibration here because otherwise the // clock will clamp it to the last returned clock time, which most // likely is in the future. gst_clock_get_calibration(self->clock, &internal, &external, &num, &denom); GstClockTime capture_time_monotonic = gst_clock_unadjust_with_calibration(NULL, frame_src_time, internal, external, num, denom); if (clock_is_monotonic_system_clock) { // If the pipeline is using the monotonic system clock then we can // just use this. GST_OBJECT_LOCK(clock); capture_time = capture_time_monotonic; GST_OBJECT_UNLOCK(clock); } else { // If the pipeline clock is neither the monotonic clock nor the system // clock we calculate the difference between the monotonic clock and // the pipeline clock and work with that. if (now_monotonic_sys > now_gst) { GstClockTime diff = now_monotonic_sys - now_gst; if (capture_time_monotonic > diff) capture_time = capture_time_monotonic - diff; else capture_time = 0; } else { GstClockTime diff = now_gst - now_monotonic_sys; capture_time = capture_time_monotonic + diff; } } } GstClockTime base_time = GST_ELEMENT_CAST(self)->base_time; GstClockTime pts = GST_CLOCK_TIME_NONE; if (capture_time != GST_CLOCK_TIME_NONE) { if (capture_time > base_time) pts = capture_time - base_time; else pts = 0; } GST_BUFFER_PTS(video_buffer) = pts; GST_BUFFER_DURATION(video_buffer) = gst_util_uint64_scale( GST_SECOND, self->configured_info.fps_d, self->configured_info.fps_n); GST_BUFFER_PTS(audio_buffer) = pts; GST_BUFFER_DURATION(audio_buffer) = gst_util_uint64_scale( GST_SECOND, self->configured_info.fps_d, self->configured_info.fps_n); if (frames_dropped_last == G_MAXUINT64) { frames_dropped_last = transfer_status.acFramesDropped; } else if (frames_dropped_last < transfer_status.acFramesDropped) { GST_WARNING_OBJECT( self, "Dropped %" G_GUINT64_FORMAT " frames", transfer_status.acFramesDropped - frames_dropped_last); GstClockTime timestamp = gst_util_uint64_scale( transfer_status.acFramesProcessed + frames_dropped_last, self->configured_info.fps_n, self->configured_info.fps_d * GST_SECOND); GstClockTime timestamp_end = gst_util_uint64_scale( transfer_status.acFramesProcessed + transfer_status.acFramesDropped, self->configured_info.fps_n, self->configured_info.fps_d * GST_SECOND); QueueItem item = {.type = QUEUE_ITEM_TYPE_FRAMES_DROPPED, .frames_dropped = {.driver_side = TRUE, .timestamp_start = timestamp, .timestamp_end = timestamp_end}}; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); frames_dropped_last = transfer_status.acFramesDropped; discont = TRUE; } gst_buffer_set_size(audio_buffer, transfer.GetCapturedAudioByteCount()); if (anc_buffer) gst_buffer_set_size(anc_buffer, transfer.GetCapturedAncByteCount(false)); if (anc_buffer2) gst_buffer_set_size(anc_buffer2, transfer.GetCapturedAncByteCount(true)); NTV2TCIndex tc_index; switch (self->timecode_index) { case GST_AJA_TIMECODE_INDEX_VITC: tc_index = ::NTV2InputSourceToTimecodeIndex( self->configured_input_source, true); break; case GST_AJA_TIMECODE_INDEX_ATC_LTC: tc_index = ::NTV2InputSourceToTimecodeIndex( self->configured_input_source, false); break; case GST_AJA_TIMECODE_INDEX_LTC1: tc_index = ::NTV2_TCINDEX_LTC1; break; case GST_AJA_TIMECODE_INDEX_LTC2: tc_index = ::NTV2_TCINDEX_LTC2; break; default: g_assert_not_reached(); break; } NTV2_RP188 time_code; frame_stamp.GetInputTimeCode(time_code, tc_index); while (self->queue_num_frames >= self->queue_size) { guint n = gst_queue_array_get_length(self->queue); for (guint i = 0; i < n; i++) { QueueItem *tmp = (QueueItem *)gst_queue_array_peek_nth_struct(self->queue, i); if (tmp->type == QUEUE_ITEM_TYPE_FRAME) { GST_WARNING_OBJECT(self, "Element queue overrun, dropping old frame"); QueueItem item = { .type = QUEUE_ITEM_TYPE_FRAMES_DROPPED, .frames_dropped = { .driver_side = FALSE, .timestamp_start = tmp->frame.capture_time, .timestamp_end = tmp->frame.capture_time + gst_util_uint64_scale(GST_SECOND, self->configured_info.fps_d, self->configured_info.fps_n)}}; queue_item_clear(tmp); gst_queue_array_drop_struct(self->queue, i, NULL); gst_queue_array_push_tail_struct(self->queue, &item); self->queue_num_frames -= 1; discont = TRUE; g_cond_signal(&self->queue_cond); break; } } } if (discont) { GST_BUFFER_FLAG_SET(video_buffer, GST_BUFFER_FLAG_DISCONT); GST_BUFFER_FLAG_SET(audio_buffer, GST_BUFFER_FLAG_DISCONT); discont = FALSE; } QueueItem item = { .type = QUEUE_ITEM_TYPE_FRAME, .frame = {.capture_time = capture_time, .video_buffer = video_buffer, .audio_buffer = audio_buffer, .anc_buffer = anc_buffer, .anc_buffer2 = anc_buffer2, .tc = time_code, .detected_format = (self->quad_mode ? ::GetQuadSizedVideoFormat(current_video_format) : current_video_format), .vpid = vpid_a}}; GST_TRACE_OBJECT(self, "Queuing frame %" GST_TIME_FORMAT, GST_TIME_ARGS(capture_time)); gst_queue_array_push_tail_struct(self->queue, &item); self->queue_num_frames += 1; GST_TRACE_OBJECT(self, "%u frames queued", self->queue_num_frames); g_cond_signal(&self->queue_cond); } else { g_mutex_unlock(&self->queue_lock); // If we don't have a frame for 32 iterations (512ms) then consider // this as signal loss too even if the driver still reports the // expected mode above if (have_signal && iterations_without_frame < 32) { iterations_without_frame++; } else { frames_dropped_last = G_MAXUINT64; if (have_signal || last_detected_video_format != current_video_format) { QueueItem item = { .type = QUEUE_ITEM_TYPE_SIGNAL_CHANGE, .signal_change = {.have_signal = TRUE, .detected_format = current_video_format, .vpid = vpid_a}}; last_detected_video_format = current_video_format; gst_queue_array_push_tail_struct(self->queue, &item); g_cond_signal(&self->queue_cond); have_signal = FALSE; discont = TRUE; } } self->device->device->WaitForInputVerticalInterrupt(self->channel); g_mutex_lock(&self->queue_lock); } } out: { // Make sure to globally lock here as the routing settings and others are // global shared state GstAjaNtv2DeviceLocker locker(self->device); self->device->device->AutoCirculateStop(self->channel); self->device->device->UnsubscribeInputVerticalEvent(self->channel); self->device->device->DisableInputInterrupt(self->channel); self->device->device->DisableChannel(self->channel); if (self->quad_mode) { for (int i = 1; i < 4; i++) { self->device->device->DisableChannel((NTV2Channel)(self->channel + i)); } } } if (!self->playing && !self->shutdown) goto restart; g_mutex_unlock(&self->queue_lock); gst_clear_object(&clock); gst_clear_object(&real_time_clock); GST_DEBUG_OBJECT(self, "Stopped"); }