mirror of
https://github.com/JorjBauer/aiie.git
synced 2024-12-29 12:30:54 +00:00
226 lines
6.2 KiB
C++
226 lines
6.2 KiB
C++
#include "sdl-speaker.h"
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#include <pthread.h>
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#include <unistd.h>
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extern "C"
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{
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#include <SDL.h>
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#include <SDL_thread.h>
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};
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#include "globals.h"
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#include "timeutil.h"
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// FIXME: 4096 is the right value here, I'm just debugging
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#define SDLSIZE (4096)
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// FIXME: Globals; ick.
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static volatile uint32_t bufIdx = 0;
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static uint8_t soundBuf[44100];
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static pthread_mutex_t togmutex = PTHREAD_MUTEX_INITIALIZER;
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static struct timespec sdlEmptyTime, sdlStartTime;
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extern struct timespec startTime; // defined in aiie (main)
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static void audioCallback(void *unused, Uint8 *stream, int len)
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{
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pthread_mutex_lock(&togmutex);
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if (g_biosInterrupt) {
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// While the BIOS is running, we don't put samples in the audio
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// queue.
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memset(stream, 0x80, len);
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pthread_mutex_unlock(&togmutex);
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return;
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}
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// calculate when the buffer will be empty again
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do_gettime(&sdlEmptyTime);
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timespec_add_us(&sdlEmptyTime, ((float)len * (float)1000000)/(float)44100, &sdlEmptyTime);
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sdlEmptyTime = tsSubtract(sdlEmptyTime, sdlStartTime);
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static uint8_t lastKnownSample = 0; // saved for when the apple is quiescent
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if (bufIdx >= len) {
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memcpy(stream, soundBuf, len);
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lastKnownSample = stream[len-1];
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if (bufIdx > len) {
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// move the remaining data down
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memcpy(soundBuf, &soundBuf[len], bufIdx - len + 1);
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bufIdx -= len;
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}
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} else {
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if (bufIdx) {
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// partial buffer exists
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memcpy(stream, soundBuf, bufIdx);
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// and it's a partial underrun
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memset(&stream[bufIdx], lastKnownSample, len-bufIdx);
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bufIdx = 0;
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} else {
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// Total audio underrun. This is normal if nothing is toggling the
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// speaker; we stay at the last known level.
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memset(stream, lastKnownSample, len);
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}
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}
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pthread_mutex_unlock(&togmutex);
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}
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void ResetDCFilter(); // FIXME: remove
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SDLSpeaker::SDLSpeaker()
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{
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toggleState = false;
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mixerValue = 0x80;
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pthread_mutex_init(&togmutex, NULL);
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_init_darwin_shim();
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ResetDCFilter();
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lastCycleCount = 0;
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lastSampleCount = 0;
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}
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SDLSpeaker::~SDLSpeaker()
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{
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}
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void SDLSpeaker::begin()
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{
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do_gettime(&sdlStartTime);
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do_gettime(&sdlEmptyTime);
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sdlEmptyTime = tsSubtract(sdlEmptyTime, sdlStartTime);
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SDL_AudioSpec audioDevice;
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SDL_AudioSpec audioActual;
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SDL_memset(&audioDevice, 0, sizeof(audioDevice));
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audioDevice.freq = 44100; // count of 8-bit samples
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audioDevice.format = AUDIO_U8;
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audioDevice.channels = 1;
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audioDevice.samples = SDLSIZE; // SDLSIZE 8-bit samples @ 44100Hz: 4096 is about 1/10th second out of sync
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audioDevice.callback = audioCallback;
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audioDevice.userdata = NULL;
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memset(&soundBuf[0], 0, SDLSIZE);
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bufIdx = SDLSIZE/2; // FIXME: why? Shouldn't this just be 0?
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SDL_OpenAudio(&audioDevice, &audioActual); // FIXME retval
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printf("Actual: freq %d channels %d samples %d\n",
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audioActual.freq, audioActual.channels, audioActual.samples);
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SDL_PauseAudio(0);
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}
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void SDLSpeaker::toggle(uint32_t c)
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{
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pthread_mutex_lock(&togmutex);
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/* Figuring out what to do:
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*
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* The wallclock time we started the app is in startTime.
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*
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* The wallclock time when the SDL audio buffer will be totally
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* drained is in sdlEmptyTime. When that time comes, we want to have
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* at least SDLSIZE samples in soundBuf[] - which is currently filled
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* to bufIdx samples.
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*
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* So given the cycle number at which this toggle happened (c), we
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* know we need to fill soundBuf[bufIdx..?] with either 0 or 127
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* (adjusted for volume). The end of that area that we need to fill is
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* based on what time cycle 'c' refers to,
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*
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* The wallclock time of cycle (c) is calculable from
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* timespec_add_cycles(&startTime, c, &outputTime);
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*
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* And the point at which the SDL buffer will be drained is the same
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* as the time at which soundBuf begins. So the difference between
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* the two tells us where the end point is.
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*
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* Then we need to fill soundBuf[bufIdx .. endPoint] with that 0 or 127,
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* and set bufIdx = endPoint.
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*
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* Bonus: if it looks like we're not filling enough buffer, then we
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* should tell the emulation layer above to run more cycles in bulk
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* to build up more speaker backlog.
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*/
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// calculate the timespec that refers to the cycle where this
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// speaker toggle happened
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struct timespec blipTime;
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timespec_add_cycles(&startTime, c, &blipTime);
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timespec_add_us(&blipTime, ((float)SDLSIZE * (float)1000000)/(float)44100, &blipTime); // it's delayed one SDL buffer naturally, and there's some drift between the start of the CPU and the start of the speaker. :/
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// determine how long there will be between the start of the buffer
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// and that cycle time. (tsSubtract bounds at 0 and is never
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// negative.)
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struct timespec timeOffset = tsSubtract(blipTime, sdlEmptyTime);
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// Turn that in to a sample index in the soundBuf[] buffer. There are 44100 of them per second,
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// so this is straightforward
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float newIdx = (float)timeOffset.tv_sec + ((float)timeOffset.tv_nsec / (float)NANOSECONDS_PER_SECOND);
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newIdx *= 44100.0;
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if (newIdx >= sizeof(soundBuf)) {
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// Buffer overrun
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printf("ERROR: buffer overrun, dropping data\n");
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newIdx = sizeof(soundBuf)-1;
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}
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// Flip the toggle state
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toggleState = !toggleState;
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// Fill from bufIdx .. newIdx and set bufIdx to newIdx when done
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if (newIdx > bufIdx) {
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long count = (long)newIdx - bufIdx;
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memset(&soundBuf[bufIdx], toggleState ? 127 : 0, count);
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bufIdx = newIdx;
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} else {
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// Why are we backtracking? This does happen, and it's a bug.
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if (newIdx >= 1) {
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bufIdx = newIdx-1;
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long count = (long)newIdx - bufIdx;
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memset(&soundBuf[bufIdx], toggleState ? 127 : 0, count);
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bufIdx = newIdx;
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} else {
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// ... and it's zero?
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}
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}
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pthread_mutex_unlock(&togmutex);
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}
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// FIXME: make methods
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uint16_t dcFilterState = 0;
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void ResetDCFilter()
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{
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dcFilterState = 32768 + 10000;
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}
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int16_t DCFilter(int16_t in)
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{
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if (dcFilterState == 0)
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return 0;
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if (dcFilterState >= 32768) {
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dcFilterState--;
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return in;
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}
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return ( (int32_t)in * (int32_t)dcFilterState-- ) / (int32_t)32768;
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}
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void SDLSpeaker::maintainSpeaker(uint32_t c, uint64_t microseconds)
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{
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}
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void SDLSpeaker::beginMixing()
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{
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}
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void SDLSpeaker::mixOutput(uint8_t v)
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{
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}
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