ref: 223e321731efcd8475e4ef6738bf050dcfef3fea
dir: /src/pt2_scopes.c/
// for finding memory leaks in debug mode with Visual Studio
#if defined _DEBUG && defined _MSC_VER
#include <crtdbg.h>
#endif
#include <stdint.h>
#include <stdbool.h>
#include <math.h> // modf()
#ifndef _WIN32
#include <unistd.h> // usleep()
#endif
#include "pt2_header.h"
#include "pt2_helpers.h"
#include "pt2_visuals.h"
#include "pt2_scopes.h"
#include "pt2_sampler.h"
#include "pt2_palette.h"
#include "pt2_tables.h"
// this uses code that is not entirely thread safe, but I have never had any issues so far...
static volatile bool scopesReading;
static uint32_t scopeTimeLen, scopeTimeLenFrac;
static uint64_t timeNext64, timeNext64Frac;
static SDL_Thread *scopeThread;
scopeChannel_t scope[4]; // global
scopeChannelExt_t scopeExt[4]; // global
extern bool forceMixerOff; // pt_audio.c
extern uint32_t *pixelBuffer; // pt_main.c
int32_t getSampleReadPos(uint8_t ch, uint8_t smpNum)
{
const int8_t *data;
int32_t pos;
scopeChannel_t *sc;
moduleSample_t *s;
sc = &scope[ch];
// cache some stuff
data = sc->data;
pos = sc->pos;
if (scopeExt[ch].active && pos >= 2)
{
s = &modEntry->samples[smpNum];
/* get real sampling position regardless of where the scope data points to
** sc->data changes during loop, offset and so on, so this has to be done
** (sadly, because it's really hackish) */
pos = (int32_t)(&data[pos] - &modEntry->sampleData[s->offset]);
if (pos >= s->length)
return -1;
return pos;
}
return -1;
}
void setScopeDelta(uint8_t ch, uint32_t delta)
{
scope[ch].delta = delta;
}
void updateScopes(void)
{
scopeChannel_t *sc, tmp;
scopeChannelExt_t *se, tmpExt;
if (editor.isWAVRendering)
return;
for (uint32_t i = 0; i < AMIGA_VOICES; i++)
{
sc = &scope[i];
se = &scopeExt[i];
// cache these
tmp = *sc;
tmpExt = *se;
if (!tmpExt.active)
continue; // scope is not active
tmp.posFrac += tmp.delta;
tmp.pos += tmp.posFrac >> 16;
tmp.posFrac &= 0xFFFF;
if (tmp.pos >= tmp.length)
{
// sample reached end, simulate Paula register update (sample swapping)
/* wrap pos around one time with current length, then set new length
** and wrap around it (handles one-shot loops and sample swapping) */
tmp.pos -= tmp.length;
tmp.length = tmpExt.newLength;
if (tmp.length > 0)
tmp.pos %= tmp.length;
tmp.data = tmpExt.newData;
tmp.loopFlag = tmpExt.newLoopFlag;
tmp.loopStart = tmpExt.newLoopStart;
se->didSwapData = true;
}
*sc = tmp; // update it
}
}
/* This routine gets the average sample peak through the running scope voices.
** This gives a much more smooth and stable result than getting the peak from
** the mixer, and we don't care about including filters/BLEP in the peak calculation. */
static void updateRealVuMeters(void)
{
bool didSwapData;
int16_t volume;
int32_t i, x, readPos, samplesToScan, smpDat, smpPeak;
scopeChannel_t tmpScope, *sc;
scopeChannelExt_t *se;
// sink VU-meters first
for (i = 0; i < AMIGA_VOICES; i++)
{
editor.realVuMeterVolumes[i] -= 3;
if (editor.realVuMeterVolumes[i] < 0)
editor.realVuMeterVolumes[i] = 0;
}
// get peak sample data from running scope voices
for (i = 0; i < AMIGA_VOICES; i++)
{
sc = &scope[i];
se = &scopeExt[i];
// cache these two
tmpScope = *sc;
didSwapData = se->didSwapData;
samplesToScan = tmpScope.delta >> 16;
if (samplesToScan <= 0)
continue;
if (samplesToScan > 512) // don't waste cycles on reading a ton of samples
samplesToScan = 512;
volume = modEntry->channels[i].n_volume;
if (se->active && tmpScope.data != NULL && volume != 0 && tmpScope.length > 0)
{
smpPeak = 0;
readPos = tmpScope.pos;
if (tmpScope.loopFlag)
{
for (x = 0; x < samplesToScan; x += 2) // loop enabled
{
if (didSwapData)
{
if (readPos >= tmpScope.length)
readPos %= tmpScope.length; // s.data = loopStartPtr, wrap readPos to 0
}
else if (readPos >= tmpScope.length)
{
readPos = tmpScope.loopStart; // s.data = sampleStartPtr, wrap readPos to loop start
}
smpDat = tmpScope.data[readPos] * volume;
smpDat = ABS(smpDat);
if (smpDat > smpPeak)
smpPeak = smpDat;
readPos += 2;
}
}
else
{
for (x = 0; x < samplesToScan; x += 2) // no loop
{
if (readPos >= tmpScope.length)
break;
smpDat = tmpScope.data[readPos] * volume;
smpDat = ABS(smpDat);
if (smpDat > smpPeak)
smpPeak = smpDat;
readPos += 2;
}
}
smpPeak = ((smpPeak * 48) + (1 << 12)) >> 13;
if (smpPeak > editor.realVuMeterVolumes[i])
editor.realVuMeterVolumes[i] = smpPeak;
}
}
}
void drawScopes(void)
{
bool didSwapData;
int16_t scopeData, volume;
int32_t i, x, y, readPos;
uint32_t *dstPtr, *scopePtr, scopePixel;
scopeChannel_t tmpScope, *sc;
scopeChannelExt_t *se;
scopesReading = true;
if (editor.ui.visualizerMode == VISUAL_QUADRASCOPE)
{
// --- QUADRASCOPE ---
scopePtr = &pixelBuffer[(71 * SCREEN_W) + 128];
for (i = 0; i < AMIGA_VOICES; i++)
{
sc = &scope[i];
se = &scopeExt[i];
// cache these two
tmpScope = *sc;
didSwapData = se->didSwapData;
volume = -modEntry->channels[i].n_volume; // 0..64 -> -64..0
// render scope
if (se->active && tmpScope.data != NULL && volume != 0 && tmpScope.length > 0)
{
// scope is active
se->emptyScopeDrawn = false;
// draw scope background
dstPtr = &pixelBuffer[(55 * SCREEN_W) + (128 + (i * (SCOPE_WIDTH + 8)))];
scopePixel = palette[PAL_BACKGRD]; // this palette can change
for (y = 0; y < SCOPE_HEIGHT; y++)
{
for (x = 0; x < SCOPE_WIDTH; x++)
dstPtr[x] = scopePixel;
dstPtr += SCREEN_W;
}
// render scope data
scopePixel = palette[PAL_QADSCP];
readPos = tmpScope.pos;
if (tmpScope.loopFlag)
{
// loop enabled
for (x = 0; x < SCOPE_WIDTH; x++)
{
if (didSwapData)
{
if (readPos >= tmpScope.length)
readPos %= tmpScope.length; // s.data = loopStartPtr, wrap readPos to 0
}
else if (readPos >= tmpScope.length)
{
readPos = tmpScope.loopStart; // s.data = sampleStartPtr, wrap readPos to loop start
}
scopeData = (tmpScope.data[readPos++] * volume) >> 9; // (-128..127)*(-64..0) / 2^9 = -15..16
scopePtr[(scopeData * SCREEN_W) + x] = scopePixel;
}
}
else
{
// no loop
for (x = 0; x < SCOPE_WIDTH; x++)
{
if (readPos >= tmpScope.length)
{
scopePtr[x] = scopePixel; // end of data, draw center pixel
}
else
{
scopeData = (tmpScope.data[readPos++] * volume) >> 9; // (-128..127)*(-64..0) / 2^9 = -15..16
scopePtr[(scopeData * SCREEN_W) + x] = scopePixel;
}
}
}
}
else
{
// scope is inactive, draw empty scope once until it gets active again
if (!se->emptyScopeDrawn)
{
// draw scope background
dstPtr = &pixelBuffer[(55 * SCREEN_W) + (128 + (i * (SCOPE_WIDTH + 8)))];
scopePixel = palette[PAL_BACKGRD];
for (y = 0; y < SCOPE_HEIGHT; y++)
{
for (x = 0; x < SCOPE_WIDTH; x++)
dstPtr[x] = scopePixel;
dstPtr += SCREEN_W;
}
// draw line
scopePixel = palette[PAL_QADSCP];
for (x = 0; x < SCOPE_WIDTH; x++)
scopePtr[x] = scopePixel;
se->emptyScopeDrawn = true;
}
}
scopePtr += SCOPE_WIDTH+8;
}
}
scopesReading = false;
}
static int32_t SDLCALL scopeThreadFunc(void *ptr)
{
int32_t time32;
uint32_t diff32;
uint64_t time64;
(void)ptr;
// this is needed for scope stability (confirmed)
SDL_SetThreadPriority(SDL_THREAD_PRIORITY_HIGH);
// set next frame time
timeNext64 = SDL_GetPerformanceCounter() + scopeTimeLen;
timeNext64Frac = scopeTimeLenFrac;
while (editor.programRunning)
{
if (ptConfig.realVuMeters)
updateRealVuMeters();
updateScopes();
time64 = SDL_GetPerformanceCounter();
if (time64 < timeNext64)
{
assert(timeNext64-time64 <= 0xFFFFFFFFULL);
diff32 = (uint32_t)(timeNext64 - time64);
// convert to microseconds and round to integer
time32 = (uint32_t)((diff32 * editor.dPerfFreqMulMicro) + 0.5);
// delay until we have reached next tick
if (time32 > 0)
usleep(time32);
}
// update next tick time
timeNext64 += scopeTimeLen;
timeNext64Frac += scopeTimeLenFrac;
if (timeNext64Frac >= (1ULL << 32))
{
timeNext64Frac &= 0xFFFFFFFF;
timeNext64++;
}
}
return true;
}
bool initScopes(void)
{
double dInt, dFrac;
// calculate scope time for performance counters and split into int/frac
dFrac = modf(editor.dPerfFreq / SCOPE_HZ, &dInt);
// integer part
scopeTimeLen = (uint32_t)dInt;
// fractional part scaled to 0..2^32-1
dFrac *= UINT32_MAX + 1.0;
if (dFrac > (double)UINT32_MAX)
dFrac = (double)UINT32_MAX;
scopeTimeLenFrac = (uint32_t)round(dFrac);
scopeThread = SDL_CreateThread(scopeThreadFunc, NULL, NULL);
if (scopeThread == NULL)
{
showErrorMsgBox("Couldn't create scope thread!");
return false;
}
SDL_DetachThread(scopeThread);
return true;
}
void waitOnScopes(void)
{
while (scopesReading);
}
void clearScopes(void)
{
waitOnScopes();
memset(scope, 0, sizeof (scope));
memset(scopeExt, 0, sizeof (scopeExt));
for (uint8_t i = 0; i < AMIGA_VOICES; i++)
scope[i].length = scopeExt[i].newLength = 2;
}