# # Copyright (c) 2024-2026, Daily # # SPDX-License-Identifier: BSD 2-Clause License # import os import aiohttp from dotenv import load_dotenv from loguru import logger from pipecat.frames.frames import LLMRunFrame from pipecat.pipeline.pipeline import Pipeline from pipecat.pipeline.runner import PipelineRunner from pipecat.pipeline.task import PipelineParams, PipelineTask from pipecat.processors.aggregators.llm_context import LLMContext from pipecat.processors.aggregators.llm_response_universal import ( LLMContextAggregatorPair, LLMUserAggregatorParams, ) from pipecat.runner.types import RunnerArguments from pipecat.runner.utils import create_transport from pipecat.services.openai.llm import OpenAILLMService from pipecat.services.speechmatics.stt import SpeechmaticsSTTService from pipecat.services.speechmatics.tts import SpeechmaticsTTSService from pipecat.transcriptions.language import Language from pipecat.transports.base_transport import BaseTransport, TransportParams from pipecat.transports.daily.transport import DailyParams from pipecat.transports.websocket.fastapi import FastAPIWebsocketParams from pipecat.turns.user_turn_strategies import ExternalUserTurnStrategies load_dotenv(override=True) # We use lambdas to defer transport parameter creation until the transport # type is selected at runtime. transport_params = { "daily": lambda: DailyParams( audio_in_enabled=True, audio_out_enabled=True, ), "twilio": lambda: FastAPIWebsocketParams( audio_in_enabled=True, audio_out_enabled=True, ), "webrtc": lambda: TransportParams( audio_in_enabled=True, audio_out_enabled=True, ), } async def run_bot(transport: BaseTransport, runner_args: RunnerArguments): """Speechmatics STT and TTS Service Example This example demonstrates using Speechmatics Speech-to-Text and Text-to-Speech services with speaker diarization and intelligent speaker management. Key features: 1. Speaker Diarization (STT) - Automatically identifies and distinguishes between different speakers - First speaker is identified as 'S1', others get subsequent IDs - Uses `enable_diarization` parameter to manage speaker detection 2. Smart Speaker Control (STT) - `focus_speakers` parameter lets you target specific speakers (e.g. ["S1"]) - Other speakers will be wrapped in PASSIVE tags - Only processes speech from focused speakers - Words from all speakers are wrapped with XML tags for clear speaker identification - Other speakers' speech only sent when focused speaker is active 3. Voice Activity Detection (STT) - Built-in VAD using `enable_vad` parameter - Remove `vad_analyzer` from `transport` config to use module's VAD - Emits speaker started/stopped events 4. Text-to-Speech (TTS) - Low latency streaming audio synthesis - Multiple voice options available including `sarah`, `theo`, `megan` and `jack` 5. Configuration Options - `operating_point` parameter defaults to `ENHANCED` for optimal accuracy - Configurable `end_of_utterance_silence_trigger` (default 0.5s) - Customizable speaker formatting - Additional diarization settings available For detailed information: - STT: https://docs.speechmatics.com/rt-api-ref - TTS: https://docs.speechmatics.com/text-to-speech/quickstart """ logger.info(f"Starting bot") async with aiohttp.ClientSession() as session: stt = SpeechmaticsSTTService( api_key=os.environ["SPEECHMATICS_API_KEY"], settings=SpeechmaticsSTTService.Settings( language=Language.EN, turn_detection_mode=SpeechmaticsSTTService.TurnDetectionMode.ADAPTIVE, # focus_speakers=["S1"], speaker_active_format="<{speaker_id}>{text}", speaker_passive_format="<{speaker_id}>{text}", ), ) tts = SpeechmaticsTTSService( api_key=os.environ["SPEECHMATICS_API_KEY"], settings=SpeechmaticsTTSService.Settings( voice="sarah", ), aiohttp_session=session, ) llm = OpenAILLMService( api_key=os.environ["OPENAI_API_KEY"], settings=OpenAILLMService.Settings( temperature=0.75, system_instruction="You are a helpful British assistant called Sarah in a voice conversation. Your responses will be spoken aloud, so avoid emojis, bullet points, or other formatting that can't be spoken. Always include punctuation in your responses. Give very short replies - do not give longer replies unless strictly necessary. Respond to what the user said in a concise, funny, creative and helpful way. Use `` tags to identify different speakers - do not use tags in your replies. Do not respond to speakers within `` tags unless explicitly asked to.", ), ) context = LLMContext() user_aggregator, assistant_aggregator = LLMContextAggregatorPair( context, user_params=LLMUserAggregatorParams(user_turn_strategies=ExternalUserTurnStrategies()), ) pipeline = Pipeline( [ transport.input(), # Transport user input stt, user_aggregator, # User responses llm, # LLM tts, # TTS transport.output(), # Transport bot output assistant_aggregator, # Assistant spoken responses ] ) task = PipelineTask( pipeline, params=PipelineParams( enable_metrics=True, enable_usage_metrics=True, ), idle_timeout_secs=runner_args.pipeline_idle_timeout_secs, ) @transport.event_handler("on_client_connected") async def on_client_connected(transport, client): logger.info(f"Client connected") # Kick off the conversation. context.add_message({"role": "developer", "content": "Say a short hello to the user."}) await task.queue_frames([LLMRunFrame()]) @transport.event_handler("on_client_disconnected") async def on_client_disconnected(transport, client): logger.info(f"Client disconnected") await task.cancel() runner = PipelineRunner(handle_sigint=runner_args.handle_sigint) await runner.run(task) async def bot(runner_args: RunnerArguments): """Main bot entry point compatible with Pipecat Cloud.""" transport = await create_transport(runner_args, transport_params) await run_bot(transport, runner_args) if __name__ == "__main__": from pipecat.runner.run import main main()