/* Copyright (C) 2001 Paul Davis Copyright (C) 2004-2008 Grame. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or This program 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 (at your option) any later version. GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "JackSystemDeps.h" #include "JackAudioDriver.h" #include "JackTime.h" #include "JackError.h" #include "JackEngineControl.h" #include "JackPort.h" #include "JackGraphManager.h" #include "JackLockedEngine.h" #include "JackException.h" #include #include "JackServerGlobals.h" using namespace std; namespace Jack { JackAudioDriver::JackAudioDriver(const char* name, const char* alias, JackLockedEngine* engine, JackSynchro* table) : JackDriver(name, alias, engine, table) {} JackAudioDriver::~JackAudioDriver() {} int JackAudioDriver::SetBufferSize(jack_nframes_t buffer_size) { // Update engine and graph manager state fEngineControl->fBufferSize = buffer_size; fGraphManager->SetBufferSize(buffer_size); fEngineControl->UpdateTimeOut(); UpdateLatencies(); // Redirected on slaves drivers... return JackDriver::SetBufferSize(buffer_size); } int JackAudioDriver::SetSampleRate(jack_nframes_t sample_rate) { fEngineControl->fSampleRate = sample_rate; fEngineControl->UpdateTimeOut(); // Redirected on slaves drivers... return JackDriver::SetSampleRate(sample_rate); } int JackAudioDriver::Open(jack_nframes_t buffer_size, jack_nframes_t samplerate, bool capturing, bool playing, int inchannels, int outchannels, bool monitor, const char* capture_driver_name, const char* playback_driver_name, jack_nframes_t capture_latency, jack_nframes_t playback_latency) { fCaptureChannels = inchannels; fPlaybackChannels = outchannels; fWithMonitorPorts = monitor; memset(fCapturePortList, 0, sizeof(jack_port_id_t) * DRIVER_PORT_NUM); memset(fPlaybackPortList, 0, sizeof(jack_port_id_t) * DRIVER_PORT_NUM); memset(fMonitorPortList, 0, sizeof(jack_port_id_t) * DRIVER_PORT_NUM); return JackDriver::Open(buffer_size, samplerate, capturing, playing, inchannels, outchannels, monitor, capture_driver_name, playback_driver_name, capture_latency, playback_latency); } void JackAudioDriver::UpdateLatencies() { jack_latency_range_t input_range; jack_latency_range_t output_range; jack_latency_range_t monitor_range; for (int i = 0; i < fCaptureChannels; i++) { input_range.max = input_range.min = fEngineControl->fBufferSize + fCaptureLatency; fGraphManager->GetPort(fCapturePortList[i])->SetLatencyRange(JackCaptureLatency, &input_range); } for (int i = 0; i < fPlaybackChannels; i++) { output_range.max = output_range.min = fPlaybackLatency; if (fEngineControl->fSyncMode) { output_range.max = output_range.min += fEngineControl->fBufferSize; } else { output_range.max = output_range.min += fEngineControl->fBufferSize * 2; } fGraphManager->GetPort(fPlaybackPortList[i])->SetLatencyRange(JackPlaybackLatency, &output_range); if (fWithMonitorPorts) { monitor_range.min = monitor_range.max = fEngineControl->fBufferSize; fGraphManager->GetPort(fMonitorPortList[i])->SetLatencyRange(JackCaptureLatency, &monitor_range); } } } int JackAudioDriver::Attach() { JackPort* port; jack_port_id_t port_index; char name[REAL_JACK_PORT_NAME_SIZE+1]; char alias[REAL_JACK_PORT_NAME_SIZE+1]; int i; jack_log("JackAudioDriver::Attach fBufferSize = %ld fSampleRate = %ld", fEngineControl->fBufferSize, fEngineControl->fSampleRate); for (i = 0; i < fCaptureChannels; i++) { snprintf(alias, sizeof(alias), "%s:%s:out%d", fAliasName, fCaptureDriverName, i + 1); snprintf(name, sizeof(name), "%s:capture_%d", fClientControl.fName, i + 1); if (fEngine->PortRegister(fClientControl.fRefNum, name, JACK_DEFAULT_AUDIO_TYPE, CaptureDriverFlags, fEngineControl->fBufferSize, &port_index) < 0) { jack_error("driver: cannot register port for %s", name); return -1; } port = fGraphManager->GetPort(port_index); port->SetAlias(alias); fCapturePortList[i] = port_index; jack_log("JackAudioDriver::Attach fCapturePortList[i] port_index = %ld", port_index); } for (i = 0; i < fPlaybackChannels; i++) { snprintf(alias, sizeof(alias), "%s:%s:in%d", fAliasName, fPlaybackDriverName, i + 1); snprintf(name, sizeof(name), "%s:playback_%d", fClientControl.fName, i + 1); if (fEngine->PortRegister(fClientControl.fRefNum, name, JACK_DEFAULT_AUDIO_TYPE, PlaybackDriverFlags, fEngineControl->fBufferSize, &port_index) < 0) { jack_error("driver: cannot register port for %s", name); return -1; } port = fGraphManager->GetPort(port_index); port->SetAlias(alias); fPlaybackPortList[i] = port_index; jack_log("JackAudioDriver::Attach fPlaybackPortList[i] port_index = %ld", port_index); // Monitor ports if (fWithMonitorPorts) { jack_log("Create monitor port"); snprintf(name, sizeof(name), "%s:monitor_%u", fClientControl.fName, i + 1); if (fEngine->PortRegister(fClientControl.fRefNum, name, JACK_DEFAULT_AUDIO_TYPE, JackPortIsOutput, fEngineControl->fBufferSize, &port_index) < 0) { jack_error("Cannot register monitor port for %s", name); return -1; } else { fMonitorPortList[i] = port_index; } } } UpdateLatencies(); return 0; } int JackAudioDriver::Detach() { int i; jack_log("JackAudioDriver::Detach"); for (i = 0; i < fCaptureChannels; i++) { fEngine->PortUnRegister(fClientControl.fRefNum, fCapturePortList[i]); } for (i = 0; i < fPlaybackChannels; i++) { fEngine->PortUnRegister(fClientControl.fRefNum, fPlaybackPortList[i]); if (fWithMonitorPorts) { fEngine->PortUnRegister(fClientControl.fRefNum, fMonitorPortList[i]); } } return 0; } int JackAudioDriver::Write() { for (int i = 0; i < fPlaybackChannels; i++) { if (fGraphManager->GetConnectionsNum(fPlaybackPortList[i]) > 0) { jack_default_audio_sample_t* buffer = GetOutputBuffer(i); int size = sizeof(jack_default_audio_sample_t) * fEngineControl->fBufferSize; // Monitor ports if (fWithMonitorPorts && fGraphManager->GetConnectionsNum(fMonitorPortList[i]) > 0) { memcpy(GetMonitorBuffer(i), buffer, size); } } } return 0; } int JackAudioDriver::Process() { int err = (fEngineControl->fSyncMode) ? ProcessSync() : ProcessAsync(); if(err && JackServerGlobals::on_failure != NULL) { JackServerGlobals::on_failure(); } return err; } /* The driver "asynchronous" mode: output buffers computed at the *previous cycle* are used, the server does not synchronize to the end of client graph execution. */ int JackAudioDriver::ProcessAsync() { // Read input buffers for the current cycle if (Read() < 0) { jack_error("JackAudioDriver::ProcessAsync: read error, stopping..."); return -1; } // Write output buffers from the previous cycle if (Write() < 0) { jack_error("JackAudioDriver::ProcessAsync: write error, stopping..."); return -1; } // Process graph ProcessGraphAsync(); // Keep end cycle time JackDriver::CycleTakeEndTime(); return 0; } void JackAudioDriver::ProcessGraphAsync() { // Process graph if (fIsMaster) { ProcessGraphAsyncMaster(); } else { ProcessGraphAsyncSlave(); } } /* Used when the driver works in master mode. */ void JackAudioDriver::ProcessGraphAsyncMaster() { // fBeginDateUst is set in the "low level" layer, fEndDateUst is from previous cycle if (!fEngine->Process(fBeginDateUst, fEndDateUst)) { jack_error("JackAudioDriver::ProcessGraphAsyncMaster: Process error"); } if (ResumeRefNum() < 0) { jack_error("JackAudioDriver::ProcessGraphAsyncMaster: ResumeRefNum error"); } if (ProcessReadSlaves() < 0) { jack_error("JackAudioDriver::ProcessGraphAsyncMaster: ProcessReadSlaves error"); } if (ProcessWriteSlaves() < 0) { jack_error("JackAudioDriver::ProcessGraphAsyncMaster: ProcessWriteSlaves error"); } // Does not wait on graph execution end } /* Used when the driver works in slave mode. */ void JackAudioDriver::ProcessGraphAsyncSlave() { if (ResumeRefNum() < 0) { jack_error("JackAudioDriver::ProcessGraphAsyncSlave: ResumeRefNum error"); } } /* The driver "synchronous" mode: the server does synchronize to the end of client graph execution, if graph process succeed, output buffers computed at the *current cycle* are used. */ int JackAudioDriver::ProcessSync() { // Read input buffers for the current cycle if (Read() < 0) { jack_error("JackAudioDriver::ProcessSync: read error, stopping..."); return -1; } // Process graph ProcessGraphSync(); // Write output buffers from the current cycle if (Write() < 0) { jack_error("JackAudioDriver::ProcessSync: write error, stopping..."); return -1; } // Keep end cycle time JackDriver::CycleTakeEndTime(); return 0; } void JackAudioDriver::ProcessGraphSync() { // Process graph if (fIsMaster) { ProcessGraphSyncMaster(); } else { ProcessGraphSyncSlave(); } } /* Used when the driver works in master mode. */ void JackAudioDriver::ProcessGraphSyncMaster() { // fBeginDateUst is set in the "low level" layer, fEndDateUst is from previous cycle if (fEngine->Process(fBeginDateUst, fEndDateUst)) { if (ResumeRefNum() < 0) { jack_error("JackAudioDriver::ProcessGraphSyncMaster: ResumeRefNum error"); } if (ProcessReadSlaves() < 0) { jack_error("JackAudioDriver::ProcessGraphSync: ProcessReadSlaves error, engine may now behave abnormally!!"); } if (ProcessWriteSlaves() < 0) { jack_error("JackAudioDriver::ProcessGraphSync: ProcessWriteSlaves error, engine may now behave abnormally!!"); } // Waits for graph execution end if (SuspendRefNum() < 0) { jack_error("JackAudioDriver::ProcessGraphSync: SuspendRefNum error, engine may now behave abnormally!!"); } } else { // Graph not finished: do not activate it jack_error("JackAudioDriver::ProcessGraphSync: Process error"); } } /* Used when the driver works in slave mode. */ void JackAudioDriver::ProcessGraphSyncSlave() { if (ResumeRefNum() < 0) { jack_error("JackAudioDriver::ProcessGraphSyncSlave: ResumeRefNum error"); } } jack_default_audio_sample_t* JackAudioDriver::GetInputBuffer(int port_index) { return fCapturePortList[port_index] ? (jack_default_audio_sample_t*)fGraphManager->GetBuffer(fCapturePortList[port_index], fEngineControl->fBufferSize) : NULL; } jack_default_audio_sample_t* JackAudioDriver::GetOutputBuffer(int port_index) { return fPlaybackPortList[port_index] ? (jack_default_audio_sample_t*)fGraphManager->GetBuffer(fPlaybackPortList[port_index], fEngineControl->fBufferSize) : NULL; } jack_default_audio_sample_t* JackAudioDriver::GetMonitorBuffer(int port_index) { return fMonitorPortList[port_index] ? (jack_default_audio_sample_t*)fGraphManager->GetBuffer(fMonitorPortList[port_index], fEngineControl->fBufferSize) : NULL; } int JackAudioDriver::ClientNotify(int refnum, const char* name, int notify, int sync, const char* message, int value1, int value2) { switch (notify) { case kLatencyCallback: HandleLatencyCallback(value1); break; default: JackDriver::ClientNotify(refnum, name, notify, sync, message, value1, value2); break; } return 0; } void JackAudioDriver::HandleLatencyCallback(int status) { jack_latency_callback_mode_t mode = (status == 0) ? JackCaptureLatency : JackPlaybackLatency; for (int i = 0; i < fCaptureChannels; i++) { if (mode == JackPlaybackLatency) { fGraphManager->RecalculateLatency(fCapturePortList[i], mode); } } for (int i = 0; i < fPlaybackChannels; i++) { if (mode == JackCaptureLatency) { fGraphManager->RecalculateLatency(fPlaybackPortList[i], mode); } } } } // end of namespace