#include #include "libmmbackend.h" #include #include "winmidi.h" #define BACKEND_NAME "winmidi" static struct { uint8_t list_devices; uint8_t detect; int socket_pair[2]; CRITICAL_SECTION push_events; volatile size_t events_alloc; volatile size_t events_active; volatile winmidi_event* event; } backend_config = { .list_devices = 0, .socket_pair = {-1, -1} }; //TODO receive feedback socket until EAGAIN MM_PLUGIN_API int init(){ backend winmidi = { .name = BACKEND_NAME, .conf = winmidi_configure, .create = winmidi_instance, .conf_instance = winmidi_configure_instance, .channel = winmidi_channel, .handle = winmidi_set, .process = winmidi_handle, .start = winmidi_start, .shutdown = winmidi_shutdown }; if(sizeof(winmidi_channel_ident) != sizeof(uint64_t)){ fprintf(stderr, "winmidi channel identification union out of bounds\n"); return 1; } //register backend if(mm_backend_register(winmidi)){ fprintf(stderr, "Failed to register winmidi backend\n"); return 1; } //initialize critical section InitializeCriticalSectionAndSpinCount(&backend_config.push_events, 4000); return 0; } static int winmidi_configure(char* option, char* value){ if(!strcmp(option, "list")){ backend_config.list_devices = 0; if(!strcmp(value, "on")){ backend_config.list_devices = 1; } return 0; } else if(!strcmp(option, "detect")){ backend_config.detect = 0; if(!strcmp(value, "on")){ backend_config.detect = 1; } return 0; } fprintf(stderr, "Unknown winmidi backend option %s\n", option); return 1; } static int winmidi_configure_instance(instance* inst, char* option, char* value){ winmidi_instance_data* data = (winmidi_instance_data*) inst->impl; if(!strcmp(option, "read")){ if(data->read){ fprintf(stderr, "winmidi instance %s already connected to an input device\n", inst->name); return 1; } data->read = strdup(value); return 0; } if(!strcmp(option, "write")){ if(data->write){ fprintf(stderr, "winmidi instance %s already connected to an output device\n", inst->name); return 1; } data->write = strdup(value); return 0; } fprintf(stderr, "Unknown winmidi instance option %s\n", option); return 1; } static instance* winmidi_instance(){ instance* i = mm_instance(); if(!i){ return NULL; } i->impl = calloc(1, sizeof(winmidi_instance_data)); if(!i->impl){ fprintf(stderr, "Failed to allocate memory\n"); return NULL; } return i; } static channel* winmidi_channel(instance* inst, char* spec, uint8_t flags){ char* next_token = NULL; winmidi_channel_ident ident = { .label = 0 }; if(!strncmp(spec, "ch", 2)){ next_token = spec + 2; if(!strncmp(spec, "channel", 7)){ next_token = spec + 7; } } if(!next_token){ fprintf(stderr, "Invalid winmidi channel specification %s\n", spec); return NULL; } ident.fields.channel = strtoul(next_token, &next_token, 10); if(ident.fields.channel > 15){ fprintf(stderr, "MIDI channel out of range in winmidi channel spec %s\n", spec); return NULL; } if(*next_token != '.'){ fprintf(stderr, "winmidi channel specification %s does not conform to channel.\n", spec); return NULL; } next_token++; if(!strncmp(next_token, "cc", 2)){ ident.fields.type = cc; next_token += 2; } else if(!strncmp(next_token, "note", 4)){ ident.fields.type = note; next_token += 4; } else if(!strncmp(next_token, "pressure", 8)){ ident.fields.type = pressure; next_token += 8; } else if(!strncmp(next_token, "pitch", 5)){ ident.fields.type = pitchbend; } else if(!strncmp(next_token, "aftertouch", 10)){ ident.fields.type = aftertouch; } else{ fprintf(stderr, "Unknown winmidi channel control type in %s\n", spec); return NULL; } ident.fields.control = strtoul(next_token, NULL, 10); if(ident.label){ return mm_channel(inst, ident.label, 1); } return NULL; } static int winmidi_set(instance* inst, size_t num, channel** c, channel_value* v){ winmidi_instance_data* data = (winmidi_instance_data*) inst->impl; winmidi_channel_ident ident = { .label = 0 }; union { struct { uint8_t status; uint8_t data1; uint8_t data2; uint8_t unused; } components; DWORD dword; } output = { .dword = 0 }; size_t u; //early exit if(!num){ return 0; } if(!data->device_out){ fprintf(stderr, "winmidi instance %s has no output device\n", inst->name); return 0; } for(u = 0; u < num; u++){ ident.label = c[u]->ident; //build output message output.components.status = ident.fields.type | ident.fields.channel; output.components.data1 = ident.fields.control; output.components.data2 = v[u].normalised * 127.0; if(ident.fields.type == pitchbend){ output.components.data1 = ((int)(v[u].normalised * 16384.0)) & 0x7F; output.components.data2 = (((int)(v[u].normalised * 16384.0)) >> 7) & 0x7F; } else if(ident.fields.type == aftertouch){ output.components.data1 = v[u].normalised * 127.0; output.components.data2 = 0; } midiOutShortMsg(data->device_out, output.dword); } return 0; } static char* winmidi_type_name(uint8_t typecode){ switch(typecode){ case note: return "note"; case cc: return "cc"; case pressure: return "pressure"; case aftertouch: return "aftertouch"; case pitchbend: return "pitch"; } return "unknown"; } static int winmidi_handle(size_t num, managed_fd* fds){ size_t u; ssize_t bytes = 0; char recv_buf[1024]; channel* chan = NULL; if(!num){ return 0; } //flush the feedback socket for(u = 0; u < num; u++){ bytes += recv(fds[u].fd, recv_buf, sizeof(recv_buf), 0); } //push queued events EnterCriticalSection(&backend_config.push_events); for(u = 0; u < backend_config.events_active; u++){ if(backend_config.detect){ //pretty-print channel-wide events if(backend_config.event[u].channel.fields.type == pitchbend || backend_config.event[u].channel.fields.type == aftertouch){ fprintf(stderr, "Incoming MIDI data on channel %s.ch%d.%s, value %f\n", backend_config.event[u].inst->name, backend_config.event[u].channel.fields.channel, winmidi_type_name(backend_config.event[u].channel.fields.type), backend_config.event[u].value); } else{ fprintf(stderr, "Incoming MIDI data on channel %s.ch%d.%s%d, value %f\n", backend_config.event[u].inst->name, backend_config.event[u].channel.fields.channel, winmidi_type_name(backend_config.event[u].channel.fields.type), backend_config.event[u].channel.fields.control, backend_config.event[u].value); } } chan = mm_channel(backend_config.event[u].inst, backend_config.event[u].channel.label, 0); if(chan){ mm_channel_event(chan, backend_config.event[u].value); } } DBGPF("winmidi flushed %" PRIsize_t " wakeups, handled %" PRIsize_t " events\n", bytes, backend_config.events_active); backend_config.events_active = 0; LeaveCriticalSection(&backend_config.push_events); return 0; } static void CALLBACK winmidi_input_callback(HMIDIIN device, unsigned message, DWORD_PTR inst, DWORD param1, DWORD param2){ winmidi_channel_ident ident = { .label = 0 }; channel_value val; union { struct { uint8_t status; uint8_t data1; uint8_t data2; uint8_t unused; } components; DWORD dword; } input = { .dword = 0 }; //callbacks may run on different threads, so we queue all events and alert the main thread via the feedback socket DBGPF("winmidi input callback on thread %ld\n", GetCurrentThreadId()); switch(message){ case MIM_MOREDATA: //processing too slow, do not immediately alert the main loop case MIM_DATA: //param1 has the message input.dword = param1; ident.fields.channel = input.components.status & 0x0F; ident.fields.type = input.components.status & 0xF0; ident.fields.control = input.components.data1; val.normalised = (double) input.components.data2 / 127.0; if(ident.fields.type == 0x80){ ident.fields.type = note; val.normalised = 0; } else if(ident.fields.type == pitchbend){ ident.fields.control = 0; val.normalised = (double)((input.components.data2 << 7) | input.components.data1) / 16384.0; } else if(ident.fields.type == aftertouch){ ident.fields.control = 0; val.normalised = (double) input.components.data1 / 127.0; } break; case MIM_LONGDATA: //sysex message, ignore return; case MIM_ERROR: //error in input stream fprintf(stderr, "winmidi warning: error in input stream\n"); return; case MIM_OPEN: case MIM_CLOSE: //device opened/closed return; } DBGPF("winmidi incoming message type %d channel %d control %d value %f\n", ident.fields.type, ident.fields.channel, ident.fields.control, val.normalised); EnterCriticalSection(&backend_config.push_events); if(backend_config.events_alloc <= backend_config.events_active){ backend_config.event = realloc((void*) backend_config.event, (backend_config.events_alloc + 1) * sizeof(winmidi_event)); if(!backend_config.event){ fprintf(stderr, "Failed to allocate memory\n"); backend_config.events_alloc = 0; backend_config.events_active = 0; LeaveCriticalSection(&backend_config.push_events); return; } backend_config.events_alloc++; } backend_config.event[backend_config.events_active].inst = (instance*) inst; backend_config.event[backend_config.events_active].channel.label = ident.label; backend_config.event[backend_config.events_active].value = val; backend_config.events_active++; LeaveCriticalSection(&backend_config.push_events); if(message != MIM_MOREDATA){ //alert the main loop send(backend_config.socket_pair[1], "w", 1, 0); } } static void CALLBACK winmidi_output_callback(HMIDIOUT device, unsigned message, DWORD_PTR inst, DWORD param1, DWORD param2){ DBGPF("winmidi output callback on thread %ld\n", GetCurrentThreadId()); } static int winmidi_match_input(char* prefix){ MIDIINCAPS input_caps; unsigned inputs = midiInGetNumDevs(); char* next_token = NULL; size_t n; if(!prefix){ fprintf(stderr, "winmidi detected %u input devices\n", inputs); } else{ n = strtoul(prefix, &next_token, 10); if(!(*next_token) && n < inputs){ midiInGetDevCaps(n, &input_caps, sizeof(MIDIINCAPS)); fprintf(stderr, "winmidi selected input device %s for ID %d\n", input_caps.szPname, n); return n; } } //find prefix match for input device for(n = 0; n < inputs; n++){ midiInGetDevCaps(n, &input_caps, sizeof(MIDIINCAPS)); if(!prefix){ printf("\tID %d: %s\n", n, input_caps.szPname); } else if(!strncmp(input_caps.szPname, prefix, strlen(prefix))){ fprintf(stderr, "winmidi selected input device %s (ID %" PRIsize_t ") for name %s\n", input_caps.szPname, n, prefix); return n; } } return -1; } static int winmidi_match_output(char* prefix){ MIDIOUTCAPS output_caps; unsigned outputs = midiOutGetNumDevs(); char* next_token = NULL; size_t n; if(!prefix){ fprintf(stderr, "winmidi detected %u output devices\n", outputs); } else{ n = strtoul(prefix, &next_token, 10); if(!(*next_token) && n < outputs){ midiOutGetDevCaps(n, &output_caps, sizeof(MIDIOUTCAPS)); fprintf(stderr, "winmidi selected output device %s for ID %d\n", output_caps.szPname, n); return n; } } //find prefix match for output device for(n = 0; n < outputs; n++){ midiOutGetDevCaps(n, &output_caps, sizeof(MIDIOUTCAPS)); if(!prefix){ printf("\tID %d: %s\n", n, output_caps.szPname); } else if(!strncmp(output_caps.szPname, prefix, strlen(prefix))){ fprintf(stderr, "winmidi selected output device %s (ID %" PRIsize_t " for name %s\n", output_caps.szPname, n, prefix); return n; } } return -1; } static int winmidi_start(size_t n, instance** inst){ size_t p; int device, rv = -1; winmidi_instance_data* data = NULL; struct sockaddr_storage sockadd = { 0 }; //this really should be a size_t but getsockname specifies int* for some reason int sockadd_len = sizeof(sockadd); char* error = NULL; DBGPF("winmidi main thread ID is %ld\n", GetCurrentThreadId()); //output device list if requested if(backend_config.list_devices){ winmidi_match_input(NULL); winmidi_match_output(NULL); } //open the feedback sockets //for some reason the feedback connection fails to work on 'real' windows with ipv6 backend_config.socket_pair[0] = mmbackend_socket("127.0.0.1", "0", SOCK_DGRAM, 1, 0); if(backend_config.socket_pair[0] < 0){ fprintf(stderr, "winmidi failed to open feedback socket\n"); return 1; } if(getsockname(backend_config.socket_pair[0], (struct sockaddr*) &sockadd, &sockadd_len)){ FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, WSAGetLastError(), MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), (LPTSTR) &error, 0, NULL); fprintf(stderr, "winmidi failed to query feedback socket information: %s\n", error); LocalFree(error); return 1; } //getsockname on 'real' windows may not set the address - works on wine, though switch(sockadd.ss_family){ case AF_INET: case AF_INET6: ((struct sockaddr_in*) &sockadd)->sin_family = AF_INET; ((struct sockaddr_in*) &sockadd)->sin_addr.s_addr = htobe32(INADDR_LOOPBACK); break; //for some absurd reason 'real' windows announces the socket as AF_INET6 but rejects any connection unless its AF_INET // case AF_INET6: // ((struct sockaddr_in6*) &sockadd)->sin6_addr = in6addr_any; // break; default: fprintf(stderr, "winmidi invalid feedback socket family\n"); return 1; } DBGPF("winmidi feedback socket family %d port %d\n", sockadd.ss_family, be16toh(((struct sockaddr_in*)&sockadd)->sin_port)); backend_config.socket_pair[1] = socket(sockadd.ss_family, SOCK_DGRAM, IPPROTO_UDP); if(backend_config.socket_pair[1] < 0 || connect(backend_config.socket_pair[1], (struct sockaddr*) &sockadd, sockadd_len)){ FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, WSAGetLastError(), MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), (LPTSTR) &error, 0, NULL); fprintf(stderr, "winmidi failed to connect to feedback socket: %s\n", error); LocalFree(error); return 1; } //set up instances and start input for(p = 0; p < n; p++){ data = (winmidi_instance_data*) inst[p]->impl; inst[p]->ident = p; //connect input device if requested if(data->read){ device = winmidi_match_input(data->read); if(device < 0){ fprintf(stderr, "Failed to match input device %s for instance %s\n", data->read, inst[p]->name); goto bail; } if(midiInOpen(&(data->device_in), device, (DWORD_PTR) winmidi_input_callback, (DWORD_PTR) inst[p], CALLBACK_FUNCTION | MIDI_IO_STATUS) != MMSYSERR_NOERROR){ fprintf(stderr, "Failed to open input device for instance %s\n", inst[p]->name); goto bail; } //start midi input callbacks midiInStart(data->device_in); } //connect output device if requested if(data->write){ device = winmidi_match_output(data->write); if(device < 0){ fprintf(stderr, "Failed to match output device %s for instance %s\n", data->read, inst[p]->name); goto bail; } if(midiOutOpen(&(data->device_out), device, (DWORD_PTR) winmidi_output_callback, (DWORD_PTR) inst[p], CALLBACK_FUNCTION) != MMSYSERR_NOERROR){ fprintf(stderr, "Failed to open output device for instance %s\n", inst[p]->name); goto bail; } } } //register the feedback socket to the core fprintf(stderr, "winmidi backend registering 1 descriptor to core\n"); if(mm_manage_fd(backend_config.socket_pair[0], BACKEND_NAME, 1, NULL)){ goto bail; } rv = 0; bail: return rv; } static int winmidi_shutdown(size_t n, instance** inst){ size_t u; winmidi_instance_data* data = NULL; for(u = 0; u < n; u++){ data = (winmidi_instance_data*) inst[u]->impl; free(data->read); data->read = NULL; free(data->write); data->write = NULL; if(data->device_in){ midiInStop(data->device_in); midiInClose(data->device_in); data->device_in = NULL; } if(data->device_out){ midiOutReset(data->device_out); midiOutClose(data->device_out); data->device_out = NULL; } } closesocket(backend_config.socket_pair[0]); closesocket(backend_config.socket_pair[1]); EnterCriticalSection(&backend_config.push_events); free((void*) backend_config.event); backend_config.event = NULL; backend_config.events_alloc = 0; backend_config.events_active = 0; LeaveCriticalSection(&backend_config.push_events); DeleteCriticalSection(&backend_config.push_events); fprintf(stderr, "winmidi backend shut down\n"); return 0; }