ref: f75ed687deda27988f9a566c35efdc074ecf84ed
dir: /src/ft2_trim.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 <stdio.h>
#include <math.h>
#include "ft2_header.h"
#include "ft2_sample_ed.h"
#include "ft2_gui.h"
#include "scopes/ft2_scopes.h"
#include "ft2_pattern_ed.h"
#include "ft2_replayer.h"
#include "ft2_audio.h"
#include "ft2_mouse.h"
#include "ft2_structs.h"
// this is truly a mess, but it works...
static char byteFormatBuffer[64], tmpInstrName[1 + MAX_INST][22 + 1], tmpInstName[MAX_INST][22 + 1];
static bool removePatt, removeInst, removeSamp, removeChans, removeSmpDataAfterLoop, convSmpsTo8Bit;
static uint8_t instrUsed[MAX_INST], instrOrder[MAX_INST], pattUsed[MAX_PATTERNS], pattOrder[MAX_PATTERNS];
static int16_t oldPattLens[MAX_PATTERNS], tmpPattLens[MAX_PATTERNS];
static int64_t xmSize64 = -1, xmAfterTrimSize64 = -1, spaceSaved64 = -1;
static note_t *oldPatts[MAX_PATTERNS], *tmpPatt[MAX_PATTERNS];
static instr_t *tmpInstr[1 + MAX_INST], *tmpInst[MAX_INST]; // tmpInstr[x] = copy of instr[x] for "after trim" size calculation
static SDL_Thread *trimThread;
void pbTrimCalc(void);
static void freeTmpInstruments(void)
{
for (int32_t i = 0; i <= MAX_INST; i++)
{
if (tmpInstr[i] != NULL)
{
// don't free samples, as the pointers are shared with main instruments...
free(tmpInstr[i]);
tmpInstr[i] = NULL;
}
}
}
static bool setTmpInstruments(void)
{
freeTmpInstruments();
for (int32_t i = 0; i <= MAX_INST; i++)
{
if (instr[i] != NULL)
{
tmpInstr[i] = (instr_t *)malloc(sizeof (instr_t));
if (tmpInstr[i] == NULL)
{
freeTmpInstruments();
return false;
}
*tmpInstr[i] = *instr[i];
}
}
return true;
}
static void remapInstrInSong(uint8_t src, uint8_t dst, int32_t ap)
{
for (int32_t i = 0; i < ap; i++)
{
note_t *pattPtr = pattern[i];
if (pattPtr == NULL)
continue;
const int32_t readLen = patternNumRows[i] * MAX_CHANNELS;
note_t *p = pattPtr;
for (int32_t j = 0; j < readLen; j++, p++)
{
if (p->instr == src)
p->instr = dst;
}
}
}
static int16_t getUsedTempSamples(uint16_t insNum)
{
if (tmpInstr[insNum] == NULL)
return 0;
instr_t *ins = tmpInstr[insNum];
int16_t i = 16 - 1;
while (i >= 0 && ins->smp[i].dataPtr == NULL && ins->smp[i].name[0] == '\0')
i--;
/* Yes, 'i' can be -1 here, and will be set to at least 0
** because of ins->ta values. Possibly an FT2 bug...
**/
for (int16_t j = 0; j < 96; j++)
{
if (ins->note2SampleLUT[j] > i)
i = ins->note2SampleLUT[j];
}
return i+1;
}
static int64_t getTempInsAndSmpSize(void)
{
int16_t j;
int16_t ai = MAX_INST;
while (ai > 0 && getUsedTempSamples(ai) == 0 && tmpInstrName[ai][0] == '\0')
ai--;
int64_t currSize64 = 0;
// count instrument and sample data size in song
for (int16_t i = 1; i <= ai; i++)
{
if (tmpInstr[i] == NULL)
j = 0;
else
j = i;
const int16_t a = getUsedTempSamples(i);
if (a > 0)
currSize64 += INSTR_HEADER_SIZE + (a * sizeof (xmSmpHdr_t));
else
currSize64 += 22+11;
instr_t *ins = tmpInstr[j];
for (int16_t k = 0; k < a; k++)
{
sample_t *s = &ins->smp[k];
if (s->dataPtr != NULL && s->length > 0)
{
if (s->flags & SAMPLE_16BIT)
currSize64 += s->length << 1;
else
currSize64 += s->length;
}
}
}
return currSize64;
}
static void wipeInstrUnused(bool testWipeSize, int16_t *ai, int32_t ap, int32_t antChn)
{
int16_t numRows;
int32_t i, j, k;
note_t *p;
int32_t numInsts = *ai;
// calculate what instruments are used
memset(instrUsed, 0, numInsts);
for (i = 0; i < ap; i++)
{
if (testWipeSize)
{
p = tmpPatt[i];
numRows = tmpPattLens[i];
}
else
{
p = pattern[i];
numRows = patternNumRows[i];
}
if (p == NULL)
continue;
for (j = 0; j < numRows; j++)
{
for (k = 0; k < antChn; k++)
{
uint8_t ins = p[(j * MAX_CHANNELS) + k].instr;
if (ins > 0 && ins <= MAX_INST)
instrUsed[ins-1] = true;
}
}
}
int16_t instToDel = 0;
uint8_t newInst = 0;
int16_t newNumInsts = 0;
memset(instrOrder, 0, numInsts);
for (i = 0; i < numInsts; i++)
{
if (instrUsed[i])
{
newNumInsts++;
instrOrder[i] = newInst++;
}
else
{
instToDel++;
}
}
if (instToDel == 0)
return;
if (testWipeSize)
{
for (i = 0; i < numInsts; i++)
{
if (!instrUsed[i] && tmpInstr[1+i] != NULL)
{
free(tmpInstr[1+i]);
tmpInstr[1+i] = NULL;
}
}
// relocate instruments
memcpy(tmpInstName, &tmpInstrName[1], MAX_INST * sizeof (song.instrName[0]));
memcpy(tmpInst, &tmpInstr[1], MAX_INST * sizeof (instr[0]));
memset(&tmpInstr[1], 0, numInsts * sizeof (tmpInstr[0]));
memset(&tmpInstrName[1], 0, numInsts * sizeof (tmpInstrName[0]));
for (i = 0; i < numInsts; i++)
{
if (instrUsed[i])
{
newInst = instrOrder[i];
memcpy(&tmpInstr[1+newInst], &tmpInst[i], sizeof (tmpInst[0]));
strcpy(tmpInstrName[1+newInst], tmpInstName[i]);
}
}
*ai = newNumInsts;
return;
}
// clear unused instruments
for (i = 0; i < numInsts; i++)
{
if (!instrUsed[i])
freeInstr(1 + i);
}
// relocate instruments
memcpy(tmpInstName, &song.instrName[1], MAX_INST * sizeof (song.instrName[0]));
memcpy(tmpInst, &instr[1], MAX_INST * sizeof (instr[0]));
memset(&instr[1], 0, numInsts * sizeof (instr[0]));
memset(song.instrName[1], 0, numInsts * sizeof (song.instrName[0])); // XXX: Is this safe?
for (i = 0; i < numInsts; i++)
{
if (instrUsed[i])
{
newInst = instrOrder[i];
remapInstrInSong(1 + (uint8_t)i, 1 + newInst, ap);
memcpy(&instr[1+newInst], &tmpInst[i], sizeof (instr[0]));
strcpy(song.instrName[1+newInst], tmpInstName[i]);
}
}
*ai = newNumInsts;
setTmpInstruments();
}
static void wipePattsUnused(bool testWipeSize, int16_t *ap)
{
uint8_t newPatt;
int16_t i, *pLens;
note_t **p;
int16_t usedPatts = *ap;
memset(pattUsed, 0, usedPatts);
int16_t newUsedPatts = 0;
for (i = 0; i < song.songLength; i++)
{
newPatt = song.orders[i];
if (newPatt < usedPatts && !pattUsed[newPatt])
{
pattUsed[newPatt] = true;
newUsedPatts++;
}
}
if (newUsedPatts == 0 || newUsedPatts == usedPatts)
return; // nothing to do!
newPatt = 0;
memset(pattOrder, 0, usedPatts);
for (i = 0; i < usedPatts; i++)
{
if (pattUsed[i])
pattOrder[i] = newPatt++;
}
if (testWipeSize)
{
p = tmpPatt;
pLens = tmpPattLens;
}
else
{
p = pattern;
pLens = patternNumRows;
}
memcpy(oldPatts, p, usedPatts * sizeof (note_t *));
memcpy(oldPattLens, pLens, usedPatts * sizeof (int16_t));
memset(p, 0, usedPatts * sizeof (note_t *));
memset(pLens, 0, usedPatts * sizeof (int16_t));
// relocate patterns
for (i = 0; i < usedPatts; i++)
{
p[i] = NULL;
if (!pattUsed[i])
{
if (!testWipeSize && oldPatts[i] != NULL)
{
free(oldPatts[i]);
oldPatts[i] = NULL;
}
}
else
{
newPatt = pattOrder[i];
p[newPatt] = oldPatts[i];
pLens[newPatt] = oldPattLens[i];
}
}
if (!testWipeSize)
{
for (i = 0; i < MAX_PATTERNS; i++)
{
if (pattern[i] == NULL)
patternNumRows[i] = 64;
}
// reorder order list (and clear unused entries)
for (i = 0; i < 256; i++)
{
if (i < song.songLength)
song.orders[i] = pattOrder[song.orders[i]];
else
song.orders[i] = 0;
}
}
*ap = newUsedPatts;
}
static void wipeSamplesUnused(bool testWipeSize, int16_t ai)
{
uint8_t smpUsed[16], smpOrder[16];
int16_t j, k, l;
instr_t *ins;
sample_t tempSamples[16];
for (int16_t i = 1; i <= ai; i++)
{
if (!testWipeSize)
{
if (instr[i] == NULL)
l = 0;
else
l = i;
ins = instr[l];
l = getUsedSamples(i);
}
else
{
if (tmpInstr[i] == NULL)
l = 0;
else
l = i;
ins = tmpInstr[l];
l = getUsedTempSamples(i);
}
memset(smpUsed, 0, l);
if (l > 0)
{
sample_t *s = ins->smp;
for (j = 0; j < l; j++, s++)
{
// check if sample is referenced in instrument
for (k = 0; k < 96; k++)
{
if (ins->note2SampleLUT[k] == j)
{
smpUsed[j] = true;
break; // sample is used
}
}
if (k == 96)
{
// sample is unused
if (s->dataPtr != NULL && !testWipeSize)
freeSmpData(s);
memset(s, 0, sizeof (sample_t));
}
}
// create re-order list
uint8_t newSamp = 0;
memset(smpOrder, 0, l);
for (j = 0; j < l; j++)
{
if (smpUsed[j])
smpOrder[j] = newSamp++;
}
// re-order samples
memcpy(tempSamples, ins->smp, l * sizeof (sample_t));
memset(ins->smp, 0, l * sizeof (sample_t));
for (j = 0; j < l; j++)
{
if (smpUsed[j])
ins->smp[smpOrder[j]] = tempSamples[j];
}
// re-order note->sample list
for (j = 0; j < 96; j++)
{
newSamp = ins->note2SampleLUT[j];
if (smpUsed[newSamp])
ins->note2SampleLUT[j] = smpOrder[newSamp];
else
ins->note2SampleLUT[j] = 0;
}
}
}
}
static void wipeSmpDataAfterLoop(bool testWipeSize, int16_t ai)
{
int16_t l;
instr_t *ins;
for (int16_t i = 1; i <= ai; i++)
{
if (!testWipeSize)
{
if (instr[i] == NULL)
l = 0;
else
l = i;
ins = instr[l];
l = getUsedSamples(i);
}
else
{
if (tmpInstr[i] == NULL)
l = 0;
else
l = i;
ins = tmpInstr[l];
l = getUsedTempSamples(i);
}
sample_t *s = ins->smp;
for (int16_t j = 0; j < l; j++, s++)
{
if (s->dataPtr != NULL && GET_LOOPTYPE(s->flags) != LOOP_OFF && s->length > 0 && s->length > s->loopStart+s->loopLength)
{
if (!testWipeSize)
unfixSample(s);
s->length = s->loopStart + s->loopLength;
if (!testWipeSize)
{
if (s->length <= 0)
{
s->length = 0;
freeSmpData(s);
}
else
{
reallocateSmpData(s, s->length, !!(s->flags & SAMPLE_16BIT));
}
}
if (!testWipeSize)
fixSample(s);
}
}
}
}
static void convertSamplesTo8bit(bool testWipeSize, int16_t ai)
{
int16_t k;
instr_t *ins;
for (int16_t i = 1; i <= ai; i++)
{
if (!testWipeSize)
{
if (instr[i] == NULL)
k = 0;
else
k = i;
ins = instr[k];
k = getUsedSamples(i);
}
else
{
if (tmpInstr[i] == NULL)
k = 0;
else
k = i;
ins = tmpInstr[k];
k = getUsedTempSamples(i);
}
sample_t *s = ins->smp;
for (int16_t j = 0; j < k; j++, s++)
{
if (s->dataPtr != NULL && s->length > 0 && (s->flags & SAMPLE_16BIT))
{
if (testWipeSize)
{
s->flags &= ~SAMPLE_16BIT;
}
else
{
unfixSample(s);
const int16_t *src16 = (const int16_t *)s->dataPtr;
int8_t *dst8 = s->dataPtr;
for (int32_t a = 0; a < s->length; a++)
dst8[a] = src16[a] >> 8;
s->flags &= ~SAMPLE_16BIT;
reallocateSmpData(s, s->length, true);
fixSample(s);
}
}
}
}
}
static uint16_t getPackedPattSize(note_t *p, int32_t numRows, int32_t antChn)
{
uint8_t bytes[sizeof (note_t)];
uint16_t totalPackLen = 0;
uint8_t *pattPtr = (uint8_t *)p;
uint8_t *writePtr = pattPtr;
for (int32_t row = 0; row < numRows; row++)
{
for (int32_t chn = 0; chn < antChn; chn++)
{
bytes[0] = *pattPtr++;
bytes[1] = *pattPtr++;
bytes[2] = *pattPtr++;
bytes[3] = *pattPtr++;
bytes[4] = *pattPtr++;
uint8_t *firstBytePtr = writePtr++;
uint8_t packBits = 0;
if (bytes[0] > 0) { packBits |= 1; writePtr++; } // note
if (bytes[1] > 0) { packBits |= 2; writePtr++; } // instrument
if (bytes[2] > 0) { packBits |= 4; writePtr++; } // volume column
if (bytes[3] > 0) { packBits |= 8; writePtr++; } // effect
if (packBits == 15) // first four bits set?
{
// no packing needed, write pattern data as is
totalPackLen += 5;
writePtr += 5;
continue;
}
if (bytes[4] > 0) writePtr++; // effect parameter
totalPackLen += (uint16_t)(writePtr - firstBytePtr); // bytes writen
}
// skip unused channels
pattPtr += sizeof (note_t) * (MAX_CHANNELS - antChn);
}
return totalPackLen;
}
static bool tmpPatternEmpty(uint16_t pattNum, int32_t numChannels)
{
if (tmpPatt[pattNum] == NULL)
return true;
uint8_t *scanPtr = (uint8_t *)tmpPatt[pattNum];
int32_t scanLen = numChannels * sizeof (note_t);
int32_t numRows = tmpPattLens[pattNum];
for (int32_t i = 0; i < numRows; i++, scanPtr += TRACK_WIDTH)
{
for (int32_t j = 0; j < scanLen; j++)
{
if (scanPtr[j] != 0)
return false;
}
}
return true;
}
static int64_t calculateXMSize(void)
{
// count header size in song
int64_t currSize64 = sizeof (xmHdr_t);
// count number of patterns that would be saved
int16_t ap = MAX_PATTERNS;
do
{
if (patternEmpty(ap - 1))
ap--;
else
break;
}
while (ap > 0);
// count number of instruments
int16_t ai = 128;
while (ai > 0 && getUsedSamples(ai) == 0 && song.instrName[ai][0] == '\0')
ai--;
// count packed pattern data size in song
for (int16_t i = 0; i < ap; i++)
{
currSize64 += sizeof (xmPatHdr_t);
if (!patternEmpty(i))
currSize64 += getPackedPattSize(pattern[i], patternNumRows[i], song.numChannels);
}
// count instrument and sample data size in song
for (int16_t i = 1; i <= ai; i++)
{
int16_t j;
if (instr[i] == NULL)
j = 0;
else
j = i;
const int16_t a = getUsedSamples(i);
if (a > 0)
currSize64 += INSTR_HEADER_SIZE + (a * sizeof (xmSmpHdr_t));
else
currSize64 += 22+11;
instr_t *ins = instr[j];
for (int16_t k = 0; k < a; k++)
{
sample_t* s = &ins->smp[k];
if (s->dataPtr != NULL && s->length > 0)
{
if (s->flags & SAMPLE_16BIT)
currSize64 += s->length << 1;
else
currSize64 += s->length;
}
}
}
return currSize64;
}
static int64_t calculateTrimSize(void)
{
int16_t i, j, k;
int32_t numChannels = song.numChannels;
int32_t pattDataLen = 0;
int32_t newPattDataLen = 0;
int64_t bytes64 = 0;
int64_t oldInstrSize64 = 0;
// copy over temp data
memcpy(tmpPatt, pattern, sizeof (tmpPatt));
memcpy(tmpPattLens, patternNumRows, sizeof (tmpPattLens));
memcpy(tmpInstrName, song.instrName, sizeof (tmpInstrName));
if (!setTmpInstruments())
{
okBox(0, "System message", "Not enough memory!");
return 0;
}
// get current size of all instruments and their samples
if (removeInst || removeSamp || removeSmpDataAfterLoop || convSmpsTo8Bit)
oldInstrSize64 = getTempInsAndSmpSize();
// count number of patterns that would be saved
int16_t ap = MAX_PATTERNS;
do
{
if (tmpPatternEmpty(ap - 1, numChannels))
ap--;
else
break;
}
while (ap > 0);
// count number of instruments that would be saved
int16_t ai = MAX_INST;
while (ai > 0 && getUsedTempSamples(ai) == 0 && tmpInstrName[ai][0] == '\0')
ai--;
// calculate "remove unused samples" size
if (removeSamp) wipeSamplesUnused(true, ai);
// calculate "remove sample data after loop" size
if (removeSmpDataAfterLoop) wipeSmpDataAfterLoop(true, ai);
// calculate "convert samples to 8-bit" size
if (convSmpsTo8Bit) convertSamplesTo8bit(true, ai);
// get old pattern data length
if (removeChans || removePatt)
{
for (i = 0; i < ap; i++)
{
pattDataLen += sizeof (xmPatHdr_t);
if (!tmpPatternEmpty(i, numChannels))
pattDataLen += getPackedPattSize(tmpPatt[i], tmpPattLens[i], numChannels);
}
}
// calculate "remove unused channels" size
if (removeChans)
{
// get real number of channels
int16_t highestChan = -1;
for (i = 0; i < ap; i++)
{
note_t *pattPtr = tmpPatt[i];
if (pattPtr == NULL)
continue;
const int16_t numRows = tmpPattLens[i];
for (j = 0; j < numRows; j++)
{
for (k = 0; k < numChannels; k++)
{
note_t *p = &pattPtr[(j * MAX_CHANNELS) + k];
if (p->note > 0 || p->instr > 0 || p->vol > 0 || p->efx > 0 || p->efxData > 0)
{
if (k > highestChan)
highestChan = k;
}
}
}
}
// set new number of channels (and make it an even number)
if (highestChan >= 0)
{
highestChan++;
if (highestChan & 1)
highestChan++;
numChannels = (uint8_t)(CLAMP(highestChan, 2, numChannels));
}
}
// calculate "remove unused patterns" size
if (removePatt) wipePattsUnused(true, &ap);
// calculate new pattern data size
if (removeChans || removePatt)
{
for (i = 0; i < ap; i++)
{
newPattDataLen += sizeof (xmPatHdr_t);
if (!tmpPatternEmpty(i, numChannels))
newPattDataLen += getPackedPattSize(tmpPatt[i], tmpPattLens[i], numChannels);
}
assert(pattDataLen >= newPattDataLen);
if (pattDataLen > newPattDataLen)
bytes64 += (pattDataLen - newPattDataLen);
}
// calculate "remove unused instruments" size
if (removeInst) wipeInstrUnused(true, &ai, ap, numChannels);
// calculate new instruments and samples size
if (removeInst || removeSamp || removeSmpDataAfterLoop || convSmpsTo8Bit)
{
int64_t newInstrSize64 = getTempInsAndSmpSize();
assert(oldInstrSize64 >= newInstrSize64);
if (oldInstrSize64 > newInstrSize64)
bytes64 += (oldInstrSize64 - newInstrSize64);
}
freeTmpInstruments();
return bytes64;
}
static int32_t SDLCALL trimThreadFunc(void *ptr)
{
int16_t i, j, k;
if (!setTmpInstruments())
{
okBoxThreadSafe(0, "System message", "Not enough memory!");
return true;
}
// audio callback is not running now, so we're safe
// count number of patterns
int16_t ap = MAX_PATTERNS;
do
{
if (patternEmpty(ap - 1))
ap--;
else
break;
}
while (ap > 0);
// count number of instruments
int16_t ai = MAX_INST;
while (ai > 0 && getUsedSamples(ai) == 0 && song.instrName[ai][0] == '\0')
ai--;
// remove unused samples
if (removeSamp)
wipeSamplesUnused(false, ai);
// remove sample data after loop
if (removeSmpDataAfterLoop)
wipeSmpDataAfterLoop(false, ai);
// convert samples to 8-bit
if (convSmpsTo8Bit)
convertSamplesTo8bit(false, ai);
// removed unused channels
if (removeChans)
{
// count used channels
int16_t highestChan = -1;
for (i = 0; i < ap; i++)
{
note_t *pattPtr = pattern[i];
if (pattPtr == NULL)
continue;
const int16_t numRows = patternNumRows[i];
for (j = 0; j < numRows; j++)
{
for (k = 0; k < song.numChannels; k++)
{
note_t *p = &pattPtr[(j * MAX_CHANNELS) + k];
if (p->note > 0 || p->vol > 0 || p->instr > 0 || p->efx > 0 || p->efxData > 0)
{
if (k > highestChan)
highestChan = k;
}
}
}
}
// set new 'channels used' number
if (highestChan >= 0)
{
highestChan++;
if (highestChan & 1)
highestChan++;
song.numChannels = (uint8_t)(CLAMP(highestChan, 2, song.numChannels));
}
// clear potentially unused channel data
if (song.numChannels < MAX_CHANNELS)
{
for (i = 0; i < MAX_PATTERNS; i++)
{
note_t *p = pattern[i];
if (p == NULL)
continue;
const int16_t numRows = patternNumRows[i];
for (j = 0; j < numRows; j++)
memset(&p[(j * MAX_CHANNELS) + song.numChannels], 0, sizeof (note_t) * (MAX_CHANNELS - song.numChannels));
}
}
}
// clear unused patterns
if (removePatt)
wipePattsUnused(false, &ap);
// remove unused instruments
if (removeInst)
wipeInstrUnused(false, &ai, ap, song.numChannels);
freeTmpInstruments();
editor.trimThreadWasDone = true;
return true;
(void)ptr;
}
void trimThreadDone(void)
{
if (removePatt)
setPos(song.songPos, song.row, false);
if (removeInst)
{
editor.currVolEnvPoint = 0;
editor.currPanEnvPoint = 0;
}
updateTextBoxPointers();
hideTopScreen();
showTopScreen(true);
showBottomScreen();
if (removeChans)
{
if (ui.patternEditorShown)
{
if (ui.channelOffset > song.numChannels-ui.numChannelsShown)
setScrollBarPos(SB_CHAN_SCROLL, song.numChannels - ui.numChannelsShown, true);
}
if (cursor.ch >= ui.channelOffset+ui.numChannelsShown)
cursor.ch = ui.channelOffset+ui.numChannelsShown - 1;
}
checkMarkLimits();
if (removeSamp || convSmpsTo8Bit)
updateSampleEditorSample();
pbTrimCalc();
setSongModifiedFlag();
resumeAudio();
setMouseBusy(false);
}
static char *formatBytes(uint64_t bytes, bool roundUp)
{
double dBytes;
if (bytes == 0)
{
strcpy(byteFormatBuffer, "0");
return byteFormatBuffer;
}
bytes %= 1000ULL*1024*1024*999; // wrap around gigabytes in case of overflow
if (bytes >= 1024ULL*1024*1024*9)
{
// gigabytes
dBytes = bytes / (1024.0*1024.0*1024.0);
if (dBytes < 100)
sprintf(byteFormatBuffer, "%.1fGB", dBytes);
else
sprintf(byteFormatBuffer, "%dGB", roundUp ? (int32_t)ceil(dBytes) : (int32_t)dBytes);
}
else if (bytes >= 1024*1024*9)
{
// megabytes
dBytes = bytes / (1024.0*1024.0);
if (dBytes < 100)
sprintf(byteFormatBuffer, "%.1fMB", dBytes);
else
sprintf(byteFormatBuffer, "%dMB", roundUp ? (int32_t)ceil(dBytes) : (int32_t)dBytes);
}
else if (bytes >= 1024*9)
{
// kilobytes
dBytes = bytes / 1024.0;
if (dBytes < 100)
sprintf(byteFormatBuffer, "%.1fkB", dBytes);
else
sprintf(byteFormatBuffer, "%dkB", roundUp ? (int32_t)ceil(dBytes) : (int32_t)dBytes);
}
else
{
// bytes
sprintf(byteFormatBuffer, "%d", (int32_t)bytes);
}
return byteFormatBuffer;
}
void drawTrimScreen(void)
{
char sizeBuf[16];
drawFramework(0, 92, 136, 81, FRAMEWORK_TYPE1);
drawFramework(136, 92, 155, 81, FRAMEWORK_TYPE1);
textOutShadow(4, 95, PAL_FORGRND, PAL_DSKTOP2, "What to remove:");
textOutShadow(19, 109, PAL_FORGRND, PAL_DSKTOP2, "Unused patterns");
textOutShadow(19, 122, PAL_FORGRND, PAL_DSKTOP2, "Unused instruments");
textOutShadow(19, 135, PAL_FORGRND, PAL_DSKTOP2, "Unused samples");
textOutShadow(19, 148, PAL_FORGRND, PAL_DSKTOP2, "Unused channels");
textOutShadow(19, 161, PAL_FORGRND, PAL_DSKTOP2, "Smp. dat. after loop");
textOutShadow(155, 96, PAL_FORGRND, PAL_DSKTOP2, "Conv. samples to 8-bit");
textOutShadow(140, 111, PAL_FORGRND, PAL_DSKTOP2, ".xm size before");
textOutShadow(140, 124, PAL_FORGRND, PAL_DSKTOP2, ".xm size after");
textOutShadow(140, 137, PAL_FORGRND, PAL_DSKTOP2, "Bytes to save");
if (xmSize64 > -1)
{
sprintf(sizeBuf, "%s", formatBytes(xmSize64, true));
textOut(287 - textWidth(sizeBuf), 111, PAL_FORGRND, sizeBuf);
}
else
{
textOut(287 - textWidth("Unknown"), 111, PAL_FORGRND, "Unknown");
}
if (xmAfterTrimSize64 > -1)
{
sprintf(sizeBuf, "%s", formatBytes(xmAfterTrimSize64, true));
textOut(287 - textWidth(sizeBuf), 124, PAL_FORGRND, sizeBuf);
}
else
{
textOut(287 - textWidth("Unknown"), 124, PAL_FORGRND, "Unknown");
}
if (spaceSaved64 > -1)
{
sprintf(sizeBuf, "%s", formatBytes(spaceSaved64, false));
textOut(287 - textWidth(sizeBuf), 137, PAL_FORGRND, sizeBuf);
}
else
{
textOut(287 - textWidth("Unknown"), 137, PAL_FORGRND, "Unknown");
}
showCheckBox(CB_TRIM_PATT);
showCheckBox(CB_TRIM_INST);
showCheckBox(CB_TRIM_SAMP);
showCheckBox(CB_TRIM_CHAN);
showCheckBox(CB_TRIM_SMPD);
showCheckBox(CB_TRIM_CONV);
showPushButton(PB_TRIM_CALC);
showPushButton(PB_TRIM_TRIM);
}
void hideTrimScreen(void)
{
hideCheckBox(CB_TRIM_PATT);
hideCheckBox(CB_TRIM_INST);
hideCheckBox(CB_TRIM_SAMP);
hideCheckBox(CB_TRIM_CHAN);
hideCheckBox(CB_TRIM_SMPD);
hideCheckBox(CB_TRIM_CONV);
hidePushButton(PB_TRIM_CALC);
hidePushButton(PB_TRIM_TRIM);
ui.trimScreenShown = false;
ui.scopesShown = true;
drawScopeFramework();
}
void showTrimScreen(void)
{
if (ui.extended)
exitPatternEditorExtended();
hideTopScreen();
showTopScreen(false);
ui.trimScreenShown = true;
ui.scopesShown = false;
drawTrimScreen();
}
void toggleTrimScreen(void)
{
if (ui.trimScreenShown)
hideTrimScreen();
else
showTrimScreen();
}
void setInitialTrimFlags(void)
{
removePatt = true;
removeInst = true;
removeSamp = true;
removeChans = true;
removeSmpDataAfterLoop = true;
convSmpsTo8Bit = false;
checkBoxes[CB_TRIM_PATT].checked = true;
checkBoxes[CB_TRIM_INST].checked = true;
checkBoxes[CB_TRIM_SAMP].checked = true;
checkBoxes[CB_TRIM_CHAN].checked = true;
checkBoxes[CB_TRIM_SMPD].checked = true;
checkBoxes[CB_TRIM_CONV].checked = false;
}
void cbTrimUnusedPatt(void)
{
removePatt ^= 1;
}
void cbTrimUnusedInst(void)
{
removeInst ^= 1;
}
void cbTrimUnusedSamp(void)
{
removeSamp ^= 1;
}
void cbTrimUnusedChans(void)
{
removeChans ^= 1;
}
void cbTrimUnusedSmpData(void)
{
removeSmpDataAfterLoop ^= 1;
}
void cbTrimSmpsTo8Bit(void)
{
convSmpsTo8Bit ^= 1;
}
void pbTrimCalc(void)
{
xmSize64 = calculateXMSize();
spaceSaved64 = calculateTrimSize();
xmAfterTrimSize64 = xmSize64 - spaceSaved64;
if (xmAfterTrimSize64 < 0)
xmAfterTrimSize64 = 0;
if (ui.trimScreenShown)
drawTrimScreen();
}
void pbTrimDoTrim(void)
{
if (!removePatt && !removeInst && !removeSamp && !removeChans && !removeSmpDataAfterLoop && !convSmpsTo8Bit)
return; // nothing to trim...
if (okBox(2, "System request", "Are you sure you want to trim the song? Making a backup of the song first is recommended.") != 1)
return;
mouseAnimOn();
pauseAudio();
trimThread = SDL_CreateThread(trimThreadFunc, NULL, NULL);
if (trimThread == NULL)
{
resumeAudio();
mouseAnimOff();
return;
}
SDL_DetachThread(trimThread);
}
void resetTrimSizes(void)
{
xmSize64 = -1;
xmAfterTrimSize64 = -1;
spaceSaved64 = -1;
if (ui.trimScreenShown)
drawTrimScreen();
}