modules/audio_coding/audio_network_adaptor/config.proto - src/ - Git at Google

 syntax = "proto2";

 package webrtc.audio_network_adaptor.config;

 option optimize_for = LITE_RUNTIME;
 option java_package = "org.webrtc.AudioNetworkAdaptor";
 option java_outer_classname = "Config";
 option objc_class_prefix = "WANA";

 message FecController {
   message Threshold {
     // Threshold defines a curve in the bandwidth/packet-loss domain. The
     // curve is characterized by the two conjunction points: A and B.
     //
     // packet ^  |
     //  loss  | A|
     //        |   \        A: (low_bandwidth_bps, low_bandwidth_packet_loss)
     //        |    \       B: (high_bandwidth_bps, high_bandwidth_packet_loss)
     //        |    B\________
     //        |---------------> bandwidth
     optional int32 low_bandwidth_bps = 1;
     optional float low_bandwidth_packet_loss = 2;
     optional int32 high_bandwidth_bps = 3;
     optional float high_bandwidth_packet_loss = 4;
   }

   // `fec_enabling_threshold` defines a curve, above which FEC should be
   // enabled. `fec_disabling_threshold` defines a curve, under which FEC
   // should be disabled. See below
   //
   // packet-loss ^   |  |
   //             |   |  |   FEC
   //             |    \  \   ON
   //             | FEC \  \_______ fec_enabling_threshold
   //             | OFF  \_________ fec_disabling_threshold
   //             |-----------------> bandwidth
   optional Threshold fec_enabling_threshold = 1;
   optional Threshold fec_disabling_threshold = 2;

   // `time_constant_ms` is the time constant for an exponential filter, which
   // is used for smoothing the packet loss fraction.
   optional int32 time_constant_ms = 3;
 }

 message FecControllerRplrBased {
   message Threshold {
     // Threshold defines a curve in the bandwidth/recoverable-packet-loss
     // domain.
     // The curve is characterized by the two conjunction points: A and B.
     //
     // recoverable ^
     // packet      |  |
     //  loss       | A|
     //             |   \        A: (low_bandwidth_bps,
     //             |    \           low_bandwidth_recoverable_packet_loss)
     //             |     \       B: (high_bandwidth_bps,
     //             |      \          high_bandwidth_recoverable_packet_loss)
     //             |      B\________
     //             |---------------> bandwidth
     optional int32 low_bandwidth_bps = 1;
     optional float low_bandwidth_recoverable_packet_loss = 2;
     optional int32 high_bandwidth_bps = 3;
     optional float high_bandwidth_recoverable_packet_loss = 4;
   }

   // `fec_enabling_threshold` defines a curve, above which FEC should be
   // enabled. `fec_disabling_threshold` defines a curve, under which FEC
   // should be disabled. See below
   //
   // packet-loss ^   |  |
   //             |   |  |   FEC
   //             |    \  \   ON
   //             | FEC \  \_______ fec_enabling_threshold
   //             | OFF  \_________ fec_disabling_threshold
   //             |-----------------> bandwidth
   optional Threshold fec_enabling_threshold = 1;
   optional Threshold fec_disabling_threshold = 2;
 }

 message FrameLengthController {
   // Uplink packet loss fraction below which frame length can increase.
   optional float fl_increasing_packet_loss_fraction = 1;

   // Uplink packet loss fraction above which frame length should decrease.
   optional float fl_decreasing_packet_loss_fraction = 2;

   // Uplink bandwidth below which frame length can switch from 20ms to 60ms.
   optional int32 fl_20ms_to_60ms_bandwidth_bps = 3;

   // Uplink bandwidth above which frame length should switch from 60ms to 20ms.
   optional int32 fl_60ms_to_20ms_bandwidth_bps = 4;

   // Uplink bandwidth below which frame length can switch from 60ms to 120ms.
   optional int32 fl_60ms_to_120ms_bandwidth_bps = 5;

   // Uplink bandwidth above which frame length should switch from 120ms to 60ms.
   optional int32 fl_120ms_to_60ms_bandwidth_bps = 6;

   // Offset to apply to the per-packet overhead when increasing frame length.
   optional int32 fl_increase_overhead_offset = 7;

   // Offset to apply to the per-packet overhead when decreasing frame length.
   optional int32 fl_decrease_overhead_offset = 8;

   // Uplink bandwidth below which frame length can switch from 20ms to 40ms. In
   // current implementation, defining this will invalidate
   // fl_20ms_to_60ms_bandwidth_bps.
   optional int32 fl_20ms_to_40ms_bandwidth_bps = 9;

   // Uplink bandwidth above which frame length should switch from 40ms to 20ms.
   optional int32 fl_40ms_to_20ms_bandwidth_bps = 10;

   // Uplink bandwidth below which frame length can switch from 40ms to 60ms.
   optional int32 fl_40ms_to_60ms_bandwidth_bps = 11;

   // Uplink bandwidth above which frame length should switch from 60ms to 40ms.
   // In current implementation, defining this will invalidate
   // fl_60ms_to_20ms_bandwidth_bps.
   optional int32 fl_60ms_to_40ms_bandwidth_bps = 12;
 }

 message FrameLengthControllerV2 {
   // FrameLengthControllerV2 chooses the frame length by taking the target
   // bitrate and subtracting the overhead bitrate to obtain the remaining
   // bitrate for the payload. The chosen frame length is the shortest possible
   // where the payload bitrate is more than `min_payload_bitrate_bps`.
   optional int32 min_payload_bitrate_bps = 1;

   // If true, uses the stable target bitrate to decide the frame length. This
   // will result in less frame length toggling but spending more time at longer
   // frame lengths compared to using the normal target bitrate.
   optional bool use_slow_adaptation = 2;
 }

 message ChannelController {
   // Uplink bandwidth above which the number of encoded channels should switch
   // from 1 to 2.
   optional int32 channel_1_to_2_bandwidth_bps = 1;

   // Uplink bandwidth below which the number of encoded channels should switch
   // from 2 to 1.
   optional int32 channel_2_to_1_bandwidth_bps = 2;
 }

 message DtxController {
   // Uplink bandwidth below which DTX should be switched on.
   optional int32 dtx_enabling_bandwidth_bps = 1;

   // Uplink bandwidth above which DTX should be switched off.
   optional int32 dtx_disabling_bandwidth_bps = 2;
 }

 message BitrateController {
   // Offset to apply to per-packet overhead when the frame length is increased.
   optional int32 fl_increase_overhead_offset = 1;
   // Offset to apply to per-packet overhead when the frame length is decreased.
   optional int32 fl_decrease_overhead_offset = 2;
 }

 message Controller {
   message ScoringPoint {
     // `ScoringPoint` is a subspace of network condition. It is used for
     // comparing the significance of controllers.
     optional int32 uplink_bandwidth_bps = 1;
     optional float uplink_packet_loss_fraction = 2;
   }

   // The distance from `scoring_point` to a given network condition defines
   // the significance of this controller with respect that network condition.
   // Shorter distance means higher significance. The significances of
   // controllers determine their order in the processing pipeline. Controllers
   // without `scoring_point` follow their default order in
   // `ControllerManager::controllers`.
   optional ScoringPoint scoring_point = 1;

   oneof controller {
     FecController fec_controller = 21;
     FrameLengthController frame_length_controller = 22;
     ChannelController channel_controller = 23;
     DtxController dtx_controller = 24;
     BitrateController bitrate_controller = 25;
     FecControllerRplrBased fec_controller_rplr_based = 26;
     FrameLengthControllerV2 frame_length_controller_v2 = 27;
   }
 }

 message ControllerManager {
   repeated Controller controllers = 1;

   // Least time since last reordering for a new reordering to be made.
   optional int32 min_reordering_time_ms = 2;

   // Least squared distance from last scoring point for a new reordering to be
   // made.
   optional float min_reordering_squared_distance = 3;
 }
	syntax = "proto2";

	package webrtc.audio_network_adaptor.config;

	option optimize_for = LITE_RUNTIME;
	option java_package = "org.webrtc.AudioNetworkAdaptor";
	option java_outer_classname = "Config";
	option objc_class_prefix = "WANA";

	message FecController {
	message Threshold {
	// Threshold defines a curve in the bandwidth/packet-loss domain. The
	// curve is characterized by the two conjunction points: A and B.
	//
	// packet ^ \|
	// loss \| A\|
	// \| \ A: (low_bandwidth_bps, low_bandwidth_packet_loss)
	// \| \ B: (high_bandwidth_bps, high_bandwidth_packet_loss)
	// \| B\________
	// \|---------------> bandwidth
	optional int32 low_bandwidth_bps = 1;
	optional float low_bandwidth_packet_loss = 2;
	optional int32 high_bandwidth_bps = 3;
	optional float high_bandwidth_packet_loss = 4;
	}

	// `fec_enabling_threshold` defines a curve, above which FEC should be
	// enabled. `fec_disabling_threshold` defines a curve, under which FEC
	// should be disabled. See below
	//
	// packet-loss ^ \| \|
	// \| \| \| FEC
	// \| \ \ ON
	// \| FEC \ \_______ fec_enabling_threshold
	// \| OFF \_________ fec_disabling_threshold
	// \|-----------------> bandwidth
	optional Threshold fec_enabling_threshold = 1;
	optional Threshold fec_disabling_threshold = 2;

	// `time_constant_ms` is the time constant for an exponential filter, which
	// is used for smoothing the packet loss fraction.
	optional int32 time_constant_ms = 3;
	}

	message FecControllerRplrBased {
	message Threshold {
	// Threshold defines a curve in the bandwidth/recoverable-packet-loss
	// domain.
	// The curve is characterized by the two conjunction points: A and B.
	//
	// recoverable ^
	// packet \| \|
	// loss \| A\|
	// \| \ A: (low_bandwidth_bps,
	// \| \ low_bandwidth_recoverable_packet_loss)
	// \| \ B: (high_bandwidth_bps,
	// \| \ high_bandwidth_recoverable_packet_loss)
	// \| B\________
	// \|---------------> bandwidth
	optional int32 low_bandwidth_bps = 1;
	optional float low_bandwidth_recoverable_packet_loss = 2;
	optional int32 high_bandwidth_bps = 3;
	optional float high_bandwidth_recoverable_packet_loss = 4;
	}

	// `fec_enabling_threshold` defines a curve, above which FEC should be
	// enabled. `fec_disabling_threshold` defines a curve, under which FEC
	// should be disabled. See below
	//
	// packet-loss ^ \| \|
	// \| \| \| FEC
	// \| \ \ ON
	// \| FEC \ \_______ fec_enabling_threshold
	// \| OFF \_________ fec_disabling_threshold
	// \|-----------------> bandwidth
	optional Threshold fec_enabling_threshold = 1;
	optional Threshold fec_disabling_threshold = 2;
	}

	message FrameLengthController {
	// Uplink packet loss fraction below which frame length can increase.
	optional float fl_increasing_packet_loss_fraction = 1;

	// Uplink packet loss fraction above which frame length should decrease.
	optional float fl_decreasing_packet_loss_fraction = 2;

	// Uplink bandwidth below which frame length can switch from 20ms to 60ms.
	optional int32 fl_20ms_to_60ms_bandwidth_bps = 3;

	// Uplink bandwidth above which frame length should switch from 60ms to 20ms.
	optional int32 fl_60ms_to_20ms_bandwidth_bps = 4;

	// Uplink bandwidth below which frame length can switch from 60ms to 120ms.
	optional int32 fl_60ms_to_120ms_bandwidth_bps = 5;

	// Uplink bandwidth above which frame length should switch from 120ms to 60ms.
	optional int32 fl_120ms_to_60ms_bandwidth_bps = 6;

	// Offset to apply to the per-packet overhead when increasing frame length.
	optional int32 fl_increase_overhead_offset = 7;

	// Offset to apply to the per-packet overhead when decreasing frame length.
	optional int32 fl_decrease_overhead_offset = 8;

	// Uplink bandwidth below which frame length can switch from 20ms to 40ms. In
	// current implementation, defining this will invalidate
	// fl_20ms_to_60ms_bandwidth_bps.
	optional int32 fl_20ms_to_40ms_bandwidth_bps = 9;

	// Uplink bandwidth above which frame length should switch from 40ms to 20ms.
	optional int32 fl_40ms_to_20ms_bandwidth_bps = 10;

	// Uplink bandwidth below which frame length can switch from 40ms to 60ms.
	optional int32 fl_40ms_to_60ms_bandwidth_bps = 11;

	// Uplink bandwidth above which frame length should switch from 60ms to 40ms.
	// In current implementation, defining this will invalidate
	// fl_60ms_to_20ms_bandwidth_bps.
	optional int32 fl_60ms_to_40ms_bandwidth_bps = 12;
	}

	message FrameLengthControllerV2 {
	// FrameLengthControllerV2 chooses the frame length by taking the target
	// bitrate and subtracting the overhead bitrate to obtain the remaining
	// bitrate for the payload. The chosen frame length is the shortest possible
	// where the payload bitrate is more than `min_payload_bitrate_bps`.
	optional int32 min_payload_bitrate_bps = 1;

	// If true, uses the stable target bitrate to decide the frame length. This
	// will result in less frame length toggling but spending more time at longer
	// frame lengths compared to using the normal target bitrate.
	optional bool use_slow_adaptation = 2;
	}

	message ChannelController {
	// Uplink bandwidth above which the number of encoded channels should switch
	// from 1 to 2.
	optional int32 channel_1_to_2_bandwidth_bps = 1;

	// Uplink bandwidth below which the number of encoded channels should switch
	// from 2 to 1.
	optional int32 channel_2_to_1_bandwidth_bps = 2;
	}

	message DtxController {
	// Uplink bandwidth below which DTX should be switched on.
	optional int32 dtx_enabling_bandwidth_bps = 1;

	// Uplink bandwidth above which DTX should be switched off.
	optional int32 dtx_disabling_bandwidth_bps = 2;
	}

	message BitrateController {
	// Offset to apply to per-packet overhead when the frame length is increased.
	optional int32 fl_increase_overhead_offset = 1;
	// Offset to apply to per-packet overhead when the frame length is decreased.
	optional int32 fl_decrease_overhead_offset = 2;
	}

	message Controller {
	message ScoringPoint {
	// `ScoringPoint` is a subspace of network condition. It is used for
	// comparing the significance of controllers.
	optional int32 uplink_bandwidth_bps = 1;
	optional float uplink_packet_loss_fraction = 2;
	}

	// The distance from `scoring_point` to a given network condition defines
	// the significance of this controller with respect that network condition.
	// Shorter distance means higher significance. The significances of
	// controllers determine their order in the processing pipeline. Controllers
	// without `scoring_point` follow their default order in
	// `ControllerManager::controllers`.
	optional ScoringPoint scoring_point = 1;

	oneof controller {
	FecController fec_controller = 21;
	FrameLengthController frame_length_controller = 22;
	ChannelController channel_controller = 23;
	DtxController dtx_controller = 24;
	BitrateController bitrate_controller = 25;
	FecControllerRplrBased fec_controller_rplr_based = 26;
	FrameLengthControllerV2 frame_length_controller_v2 = 27;
	}
	}

	message ControllerManager {
	repeated Controller controllers = 1;

	// Least time since last reordering for a new reordering to be made.
	optional int32 min_reordering_time_ms = 2;

	// Least squared distance from last scoring point for a new reordering to be
	// made.
	optional float min_reordering_squared_distance = 3;
	}