ref: dc624b813e7e8d6eb819efdad02087c4e01ffef1
dir: /src/ft2_sample_ed.c/
// for finding memory leaks in debug mode with Visual Studio #if defined _DEBUG && defined _MSC_VER #include <crtdbg.h> #endif #include <stdio.h> #include <stdint.h> #include <stdbool.h> #include <math.h> #ifndef _WIN32 #include <unistd.h> // chdir() in UNICHAR_CHDIR() #endif #if defined _WIN32 || defined __amd64__ || (defined __i386__ && defined __SSE2__) #include <emmintrin.h> #endif #include "ft2_header.h" #include "ft2_config.h" #include "ft2_audio.h" #include "ft2_pattern_ed.h" #include "ft2_gui.h" #include "ft2_scopes.h" #include "ft2_video.h" #include "ft2_inst_ed.h" #include "ft2_sample_ed.h" #include "ft2_sample_saver.h" #include "ft2_mouse.h" #include "ft2_diskop.h" #include "ft2_keyboard.h" #include "ft2_structs.h" #include "mixer/ft2_windowed_sinc.h" // SINC_TAPS, SINC_NEGATIVE_TAPS static const char sharpNote1Char[12] = { 'C', 'C', 'D', 'D', 'E', 'F', 'F', 'G', 'G', 'A', 'A', 'B' }; static const char sharpNote2Char[12] = { '-', '#', '-', '#', '-', '-', '#', '-', '#', '-', '#', '-' }; static const char flatNote1Char[12] = { 'C', 'D', 'D', 'E', 'E', 'F', 'G', 'G', 'A', 'A', 'B', 'B' }; static const char flatNote2Char[12] = { '-', 'b', '-', 'b', '-', '-', 'b', '-', 'b', '-', 'b', '-' }; static char smpEd_SysReqText[64]; static int8_t *smpCopyBuff; static bool updateLoopsOnMouseUp, writeSampleFlag; static int32_t smpEd_OldSmpPosLine = -1; static int32_t smpEd_ViewSize, smpEd_ScrPos, smpCopySize, smpCopyBits; static int32_t old_Rx1, old_Rx2, old_ViewSize, old_SmpScrPos; static int32_t lastMouseX, lastMouseY, lastDrawX, lastDrawY, mouseXOffs, curSmpRepS, curSmpRepL; static double dScrPosScaled, dPos2ScrMul, dScr2SmpPosMul; static SDL_Thread *thread; // globals int32_t smpEd_Rx1 = 0, smpEd_Rx2 = 0; sampleTyp *getCurSample(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL) return NULL; return &instr[editor.curInstr]->samp[editor.curSmp]; } // modifies samples before index 0, and after loop/end (for branchless mixer interpolation (kinda)) void fixSample(sampleTyp *s) { int32_t pos; bool backwards; assert(s != NULL); if (s->origPek == NULL || s->pek == NULL) { s->fixed = false; s->fixedPos = 0; return; // empty sample } const bool sample16Bit = (s->typ & 16) ? true : false; int16_t *ptr16 = (int16_t *)s->pek; uint8_t loopType = s->typ & 3; int32_t len = s->len; int32_t loopStart = s->repS; int32_t loopLen = s->repL; int32_t loopEnd = s->repS + s->repL; if (sample16Bit) { len >>= 1; loopStart >>= 1; loopLen >>= 1; loopEnd >>= 1; } if (len < 1) { s->fixed = false; s->fixedPos = 0; return; // empty sample } // treat loop as disabled if loopLen == 0 (FT2 does this) if (loopType != 0 && loopLen <= 0) { loopType = 0; loopStart = loopLen = loopEnd = 0; } /* All negative taps should be equal to the first sample point when at sampling ** position #0 (on sample trigger), until an eventual loop cycle, where we do ** a special left edge case with replaced tap data. ** The sample pointer is offset and has allocated data before it, so this is ** safe. */ if (sample16Bit) { for (int32_t i = 0; i < SINC_LEFT_TAPS; i++) ptr16[i-SINC_LEFT_TAPS] = ptr16[0]; } else { for (int32_t i = 0; i < SINC_LEFT_TAPS; i++) s->pek[i-SINC_LEFT_TAPS] = s->pek[0]; } // no loop if (loopType == 0) { if (sample16Bit) { for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) ptr16[len+i] = ptr16[len-1]; } else { for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) s->pek[len+i] = s->pek[len-1]; } s->fixedPos = 0; // this value is not used for non-looping samples, set to zero s->fixed = false; // no fixed samples inside actual sample data return; } if (s->fixed) return; // already fixed s->fixedPos = loopEnd; s->fixed = true; // special-case for loop-lengt of 1 if (loopLen == 1) { if (sample16Bit) { for (int32_t i = 0; i < SINC_TAPS+SINC_LEFT_TAPS; i++) s->leftEdgeTapSamples16[i] = ptr16[loopStart]; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = ptr16[loopEnd+i]; ptr16[loopEnd+i] = ptr16[loopStart]; } } else { for (int32_t i = 0; i < SINC_TAPS+SINC_LEFT_TAPS; i++) s->leftEdgeTapSamples8[i] = s->pek[loopStart]; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = s->pek[loopEnd+i]; s->pek[loopEnd+i] = s->pek[loopStart]; } } return; } if (loopType == 1) { // forward loop if (sample16Bit) { // left edge (we need SINC_LEFT_TAPS amount of extra unrolled samples) for (int32_t i = 0; i < SINC_TAPS+SINC_LEFT_TAPS; i++) { if (i < SINC_LEFT_TAPS) // negative taps { pos = loopEnd-i; if (pos <= loopStart) // XXX: Correct? pos += loopLen; } else // positive taps { pos = loopStart + ((i-SINC_LEFT_TAPS) % loopLen); } s->leftEdgeTapSamples16[i] = ptr16[pos]; } // right edge (change actual sample data since data after loop is never used) for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = ptr16[loopEnd+i]; ptr16[loopEnd+i] = ptr16[loopStart + (i % loopLen)]; } } else { // left edge (we need SINC_LEFT_TAPS amount of extra unrolled samples) for (int32_t i = 0; i < SINC_TAPS+SINC_LEFT_TAPS; i++) { if (i < SINC_LEFT_TAPS) // negative taps { pos = loopEnd-i; if (pos <= loopStart) // XXX: Correct? pos += loopLen; } else // positive taps { pos = loopStart + ((i-SINC_LEFT_TAPS) % loopLen); } s->leftEdgeTapSamples8[i] = s->pek[pos]; } // right edge (change actual sample data since data after loop is never used) for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = s->pek[loopEnd+i]; s->pek[loopEnd+i] = s->pek[loopStart + (i % loopLen)]; } } } else { // pingpong loop if (sample16Bit) { // left edge (we need SINC_LEFT_TAPS amount of extra unrolled samples) pos = loopStart; backwards = false; for (int32_t i = 0; i < SINC_LEFT_TAPS; i++) { if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } s->leftEdgeTapSamples16[3-i] = ptr16[pos]; } pos = loopStart; backwards = true; for (int32_t i = 3; i < SINC_TAPS+SINC_LEFT_TAPS; i++) { if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } s->leftEdgeTapSamples16[i] = ptr16[pos]; } // right edge (change actual sample data since data after loop is never used) pos = loopEnd-1; backwards = true; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = ptr16[loopEnd+i]; ptr16[loopEnd+i] = ptr16[pos]; if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } } } else { // left edge (we need SINC_LEFT_TAPS amount of extra unrolled samples) pos = loopStart; backwards = false; for (int32_t i = 0; i < SINC_LEFT_TAPS; i++) { if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } s->leftEdgeTapSamples8[3-i] = s->pek[pos]; } pos = loopStart; backwards = true; for (int32_t i = 3; i < SINC_TAPS+SINC_LEFT_TAPS; i++) { if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } s->leftEdgeTapSamples8[i] = s->pek[pos]; } // right edge (change actual sample data since data after loop is never used) pos = loopEnd-1; backwards = true; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) { s->fixedSmp[i] = s->pek[loopEnd+i]; s->pek[loopEnd+i] = s->pek[pos]; if (backwards) { if (--pos < loopStart) { pos = loopStart; backwards = false; } } else { if (++pos >= loopEnd) { pos = loopEnd-1; backwards = true; } } } } } } // restores interpolation tap samples after loop/end void restoreSample(sampleTyp *s) { assert(s != NULL); if (s->origPek == NULL || s->pek == NULL || !s->fixed) return; // empty sample or not fixed (f.ex. no loop) if (s->typ & 16) { // 16-bit sample int16_t *ptr16 = (int16_t *)s->pek + s->fixedPos; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) ptr16[i] = s->fixedSmp[i]; } else { // 8-bit sample int8_t *ptr8 = s->pek + s->fixedPos; for (int32_t i = 0; i < SINC_RIGHT_TAPS; i++) ptr8[i] = (int8_t)s->fixedSmp[i]; } s->fixed = false; } int16_t getSampleValue(int8_t *ptr, uint8_t typ, int32_t pos) { assert(pos >= 0); if (ptr == NULL) return 0; if (typ & 16) { assert(!(pos & 1)); return *(int16_t *)&ptr[pos]; } else { return ptr[pos]; } } void putSampleValue(int8_t *ptr, uint8_t typ, int32_t pos, int16_t val) { assert(pos >= 0); if (ptr == NULL) return; if (typ & 16) { assert(!(pos & 1)); *(int16_t *)&ptr[pos] = val; } else { ptr[pos] = (int8_t)val; } } void clearCopyBuffer(void) { if (smpCopyBuff != NULL) { free(smpCopyBuff); smpCopyBuff = NULL; } smpCopySize = 0; smpCopyBits = 8; } int32_t getSampleMiddleCRate(sampleTyp *s) { const int32_t realFineTune = (int32_t)s->fine >> 3; // the FT2 replayer is ASR'ing the finetune to the right by 3 const double dFTune = realFineTune / 16.0; // new range is -16..15 const double dFreq = 8363.0 * exp2((s->relTon + dFTune) / 12.0); return (int32_t)(dFreq + 0.5); // rounded } int32_t getSampleRangeStart(void) { return smpEd_Rx1; } int32_t getSampleRangeEnd(void) { return smpEd_Rx2; } int32_t getSampleRangeLength(void) { return smpEd_Rx2 - smpEd_Rx1; } // for smpPos2Scr() / scr2SmpPos() static void updateViewSize(void) { if (smpEd_ViewSize == 0) dPos2ScrMul = 1.0; else dPos2ScrMul = (double)SAMPLE_AREA_WIDTH / smpEd_ViewSize; dScr2SmpPosMul = smpEd_ViewSize * (1.0 / SAMPLE_AREA_WIDTH); } static void updateScrPos(void) { dScrPosScaled = trunc(smpEd_ScrPos * dPos2ScrMul); } // sample pos -> screen x pos (if outside of visible area, will return <0 or >=SCREEN_W) static int32_t smpPos2Scr(int32_t pos) { if (smpEd_ViewSize <= 0) return -1; sampleTyp *s = getCurSample(); if (s == NULL) return -1; if (pos > s->len) pos = s->len; double dPos = (pos * dPos2ScrMul) + 0.5; // rounding is needed here (+ 0.5) dPos -= dScrPosScaled; // this is important, or else the result can mess up in some cases dPos = CLAMP(dPos, INT32_MIN, INT32_MAX); pos = (int32_t)dPos; return pos; } // screen x pos -> sample pos static int32_t scr2SmpPos(int32_t x) { if (smpEd_ViewSize <= 0) return 0; sampleTyp *s = getCurSample(); if (s == NULL) return 0; if (x < 0) x = 0; double dPos = (dScrPosScaled + x) * dScr2SmpPosMul; x = (int32_t)dPos; if (x > s->len) x = s->len; if (s->typ & 16) x &= 0xFFFFFFFE; return x; } static void fixRepeatGadgets(void) { bool showLoopPins = true; sampleTyp *s = getCurSample(); if (s == NULL || s->len <= 0 || s->pek == NULL || (s->typ & 3) == 0 || !ui.sampleEditorShown) showLoopPins = false; if (ui.sampleEditorShown) { // draw Repeat/Replen. numbers hexOutBg(536, 375, PAL_FORGRND, PAL_DESKTOP, curSmpRepS, 8); hexOutBg(536, 387, PAL_FORGRND, PAL_DESKTOP, curSmpRepL, 8); } if (!showLoopPins) { hideSprite(SPRITE_LEFT_LOOP_PIN); hideSprite(SPRITE_RIGHT_LOOP_PIN); return; } // draw sample loop points int32_t repS = smpPos2Scr(curSmpRepS); int32_t repE = smpPos2Scr(curSmpRepS+curSmpRepL); // do -8 test because part of the loop sprite sticks out on the left/right if (repS >= -8 && repS <= SAMPLE_AREA_WIDTH+8) setSpritePos(SPRITE_LEFT_LOOP_PIN, (int16_t)(repS - 8), 174); else hideSprite(SPRITE_LEFT_LOOP_PIN); if (repE >= -8) { if (repE <= SAMPLE_AREA_WIDTH+8) setSpritePos(SPRITE_RIGHT_LOOP_PIN, (int16_t)(repE - 8), 174); else hideSprite(SPRITE_RIGHT_LOOP_PIN); } else { hideSprite(SPRITE_RIGHT_LOOP_PIN); } } static void fixSampleDrag(void) { sampleTyp *s = getCurSample(); if (s == NULL) { setScrollBarPageLength(SB_SAMP_SCROLL, 0); setScrollBarEnd(SB_SAMP_SCROLL, 0); setScrollBarPos(SB_SAMP_SCROLL, 0, false); return; } setScrollBarPageLength(SB_SAMP_SCROLL, smpEd_ViewSize); setScrollBarEnd(SB_SAMP_SCROLL, instr[editor.curInstr]->samp[editor.curSmp].len); setScrollBarPos(SB_SAMP_SCROLL, smpEd_ScrPos, false); } static bool getCopyBuffer(int32_t size) { if (smpCopyBuff != NULL) free(smpCopyBuff); if (size > MAX_SAMPLE_LEN) size = MAX_SAMPLE_LEN; smpCopyBuff = (int8_t *)malloc(size); if (smpCopyBuff == NULL) { smpCopySize = 0; return false; } smpCopySize = size; return true; } static int32_t SDLCALL copySampleThread(void *ptr) { bool error = false; int16_t destIns = editor.curInstr; int16_t destSmp = editor.curSmp; int16_t sourceIns = editor.srcInstr; int16_t sourceSmp = editor.srcSmp; pauseAudio(); if (instr[destIns] == NULL) error = !allocateInstr(destIns); if (!error) { freeSample(destIns, destSmp); sampleTyp *src = &instr[sourceIns]->samp[sourceSmp]; sampleTyp *dst = &instr[destIns]->samp[destSmp]; if (instr[sourceIns] != NULL && src->origPek != NULL) { int8_t *p = (int8_t *)malloc(src->len + LOOP_FIX_LEN); if (p != NULL) { memcpy(dst, src, sizeof (sampleTyp)); memcpy(p, src->origPek, src->len + LOOP_FIX_LEN); dst->origPek = p; dst->pek = dst->origPek + SMP_DAT_OFFSET; } else error = true; } } resumeAudio(); if (error) okBoxThreadSafe(0, "System message", "Not enough memory!"); editor.updateCurSmp = true; setSongModifiedFlag(); setMouseBusy(false); return true; (void)ptr; } void copySmp(void) // copy sample from srcInstr->srcSmp to curInstr->curSmp { if (editor.curInstr == 0 || (editor.curInstr == editor.srcInstr && editor.curSmp == editor.srcSmp)) return; mouseAnimOn(); thread = SDL_CreateThread(copySampleThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } void xchgSmp(void) // dstSmp <-> srcSmp { if (editor.curInstr == 0 || (editor.curInstr == editor.srcInstr && editor.curSmp == editor.srcSmp) || instr[editor.curInstr] == NULL) { return; } sampleTyp *src = &instr[editor.curInstr]->samp[editor.srcSmp]; sampleTyp *dst = &instr[editor.curInstr]->samp[editor.curSmp]; lockMixerCallback(); const sampleTyp dstTmp = *dst; *dst = *src; *src = dstTmp; unlockMixerCallback(); updateNewSample(); setSongModifiedFlag(); } static void writeRange(void) { // very first sample (rx1=0,rx2=0) is the "no range" special case if (!ui.sampleEditorShown || smpEd_ViewSize == 0 || (smpEd_Rx1 == 0 && smpEd_Rx2 == 0)) return; // test if range is outside of view (passed it by scrolling) int32_t start = smpPos2Scr(smpEd_Rx1); if (start >= SAMPLE_AREA_WIDTH) return; // test if range is outside of view (passed it by scrolling) int32_t end = smpPos2Scr(smpEd_Rx2); if (end < 0) return; start = CLAMP(start, 0, SAMPLE_AREA_WIDTH-1); end = CLAMP(end, 0, SAMPLE_AREA_WIDTH-1); int32_t rangeLen = (end + 1) - start; assert(start+rangeLen <= SCREEN_W); uint32_t *ptr32 = &video.frameBuffer[(174 * SCREEN_W) + start]; for (int32_t y = 0; y < SAMPLE_AREA_HEIGHT; y++) { for (int32_t x = 0; x < rangeLen; x++) ptr32[x] = video.palette[(ptr32[x] >> 24) ^ 2]; // ">> 24" to get palette, XOR 2 to switch between mark/normal palette ptr32 += SCREEN_W; } } static int8_t getScaledSample(sampleTyp *s, int32_t index) // for drawing sample waveform in zoomed-in mode { int8_t sample; int32_t tmp32; const int32_t loopEnd = s->repS + s->repL; if (s->pek == NULL || index < 0 || index >= s->len) return 0; if (s->typ & 16) { assert(!(index & 1)); index >>= 1; int16_t *ptr16 = (int16_t *)s->pek; // don't read fixed mixer interpolation samples, read the prestine ones instead if (index >= s->fixedPos && index < s->fixedPos+SINC_RIGHT_TAPS && s->len > loopEnd && s->fixed) tmp32 = s->fixedSmp[index-s->fixedPos]; else tmp32 = ptr16[index]; sample = (int8_t)((tmp32 * SAMPLE_AREA_HEIGHT) >> 16); } else { // don't read fixed mixer interpolation samples, read the prestine ones instead if (index >= s->fixedPos && index < s->fixedPos+SINC_RIGHT_TAPS && s->len > loopEnd && s->fixed) tmp32 = s->fixedSmp[index-s->fixedPos]; else tmp32 = s->pek[index]; sample = (int8_t)((tmp32 * SAMPLE_AREA_HEIGHT) >> 8); } return sample; } static void sampleLine(int16_t x1, int16_t x2, int16_t y1, int16_t y2) { int16_t d; const int16_t dx = x2 - x1; const int16_t ax = ABS(dx) * 2; const int16_t sx = SGN(dx); const int16_t dy = y2 - y1; const int16_t ay = ABS(dy) * 2; const int16_t sy = SGN(dy); int16_t x = x1; int16_t y = y1; const uint32_t pal1 = video.palette[PAL_DESKTOP]; const uint32_t pal2 = video.palette[PAL_FORGRND]; const uint32_t pixVal = video.palette[PAL_PATTEXT]; const int32_t pitch = sy * SCREEN_W; uint32_t *dst32 = &video.frameBuffer[(y * SCREEN_W) + x]; // draw line if (ax > ay) { d = ay - (ax >> 1); while (true) { // invert certain colors if (*dst32 != pal2) { if (*dst32 == pal1) *dst32 = pal2; else *dst32 = pixVal; } if (x == x2) break; if (d >= 0) { d -= ax; dst32 += pitch; } x += sx; d += ay; dst32 += sx; } } else { d = ax - (ay >> 1); while (true) { // invert certain colors if (*dst32 != pal2) { if (*dst32 == pal1) *dst32 = pal2; else *dst32 = pixVal; } if (y == y2) break; if (d >= 0) { d -= ay; dst32 += sx; } y += sy; d += ax; dst32 += pitch; } } } static void getMinMax16(const void *p, uint32_t scanLen, int16_t *min16, int16_t *max16) { #if defined _WIN32 || defined __amd64__ || (defined __i386__ && defined __SSE2__) if (cpu.hasSSE2) { /* Taken with permission from the OpenMPT project (and slightly modified). ** ** SSE2 implementation for min/max finder, packs 8*int16 in a 128-bit XMM register. ** scanLen = How many samples to process */ const int16_t *p16; uint32_t scanLen8; const __m128i *v; __m128i minVal, maxVal, minVal2, maxVal2, curVals; // Put minimum / maximum in 8 packed int16 values minVal = _mm_set1_epi16(32767); maxVal = _mm_set1_epi16(-32768); scanLen8 = scanLen / 8; if (scanLen8 > 0) { v = (__m128i *)p; p = (const __m128i *)p + scanLen8; while (scanLen8--) { curVals = _mm_loadu_si128(v++); minVal = _mm_min_epi16(minVal, curVals); maxVal = _mm_max_epi16(maxVal, curVals); } /* Now we have 8 minima and maxima each. ** Move the upper 4 values to the lower half and compute the minima/maxima of that. */ minVal2 = _mm_unpackhi_epi64(minVal, minVal); maxVal2 = _mm_unpackhi_epi64(maxVal, maxVal); minVal = _mm_min_epi16(minVal, minVal2); maxVal = _mm_max_epi16(maxVal, maxVal2); /* Now we have 4 minima and maxima each. ** Move the upper 2 values to the lower half and compute the minima/maxima of that. */ minVal2 = _mm_shuffle_epi32(minVal, _MM_SHUFFLE(1, 1, 1, 1)); maxVal2 = _mm_shuffle_epi32(maxVal, _MM_SHUFFLE(1, 1, 1, 1)); minVal = _mm_min_epi16(minVal, minVal2); maxVal = _mm_max_epi16(maxVal, maxVal2); // Compute the minima/maxima of the both remaining values minVal2 = _mm_shufflelo_epi16(minVal, _MM_SHUFFLE(1, 1, 1, 1)); maxVal2 = _mm_shufflelo_epi16(maxVal, _MM_SHUFFLE(1, 1, 1, 1)); minVal = _mm_min_epi16(minVal, minVal2); maxVal = _mm_max_epi16(maxVal, maxVal2); } p16 = (const int16_t *)p; while (scanLen-- & 7) { curVals = _mm_set1_epi16(*p16++); minVal = _mm_min_epi16(minVal, curVals); maxVal = _mm_max_epi16(maxVal, curVals); } *min16 = (int16_t)_mm_cvtsi128_si32(minVal); *max16 = (int16_t)_mm_cvtsi128_si32(maxVal); } else #endif { // non-SSE version (really slow for big samples while zoomed out) int16_t minVal = 32767; int16_t maxVal = -32768; const int16_t *ptr16 = (const int16_t *)p; for (uint32_t i = 0; i < scanLen; i++) { const int16_t smp16 = ptr16[i]; if (smp16 < minVal) minVal = smp16; if (smp16 > maxVal) maxVal = smp16; } *min16 = minVal; *max16 = maxVal; } } static void getMinMax8(const void *p, uint32_t scanLen, int8_t *min8, int8_t *max8) { #if defined _WIN32 || defined __amd64__ || (defined __i386__ && defined __SSE2__) if (cpu.hasSSE2) { /* Taken with permission from the OpenMPT project (and slightly modified). ** ** SSE2 implementation for min/max finder, packs 16*int8 in a 128-bit XMM register. ** scanLen = How many samples to process */ const int8_t *p8; uint32_t scanLen16; const __m128i *v; __m128i xorVal, minVal, maxVal, minVal2, maxVal2, curVals; // Put minimum / maximum in 8 packed int16 values (-1 and 0 because unsigned) minVal = _mm_set1_epi8(-1); maxVal = _mm_set1_epi8(0); // For signed <-> unsigned conversion (_mm_min_epi8/_mm_max_epi8 is SSE4) xorVal = _mm_set1_epi8(0x80); scanLen16 = scanLen / 16; if (scanLen16 > 0) { v = (__m128i *)p; p = (const __m128i *)p + scanLen16; while (scanLen16--) { curVals = _mm_loadu_si128(v++); curVals = _mm_xor_si128(curVals, xorVal); minVal = _mm_min_epu8(minVal, curVals); maxVal = _mm_max_epu8(maxVal, curVals); } /* Now we have 16 minima and maxima each. ** Move the upper 8 values to the lower half and compute the minima/maxima of that. */ minVal2 = _mm_unpackhi_epi64(minVal, minVal); maxVal2 = _mm_unpackhi_epi64(maxVal, maxVal); minVal = _mm_min_epu8(minVal, minVal2); maxVal = _mm_max_epu8(maxVal, maxVal2); /* Now we have 8 minima and maxima each. ** Move the upper 4 values to the lower half and compute the minima/maxima of that. */ minVal2 = _mm_shuffle_epi32(minVal, _MM_SHUFFLE(1, 1, 1, 1)); maxVal2 = _mm_shuffle_epi32(maxVal, _MM_SHUFFLE(1, 1, 1, 1)); minVal = _mm_min_epu8(minVal, minVal2); maxVal = _mm_max_epu8(maxVal, maxVal2); /* Now we have 4 minima and maxima each. ** Move the upper 2 values to the lower half and compute the minima/maxima of that. */ minVal2 = _mm_srai_epi32(minVal, 16); maxVal2 = _mm_srai_epi32(maxVal, 16); minVal = _mm_min_epu8(minVal, minVal2); maxVal = _mm_max_epu8(maxVal, maxVal2); // Compute the minima/maxima of the both remaining values minVal2 = _mm_srai_epi16(minVal, 8); maxVal2 = _mm_srai_epi16(maxVal, 8); minVal = _mm_min_epu8(minVal, minVal2); maxVal = _mm_max_epu8(maxVal, maxVal2); } p8 = (const int8_t *)p; while (scanLen-- & 15) { curVals = _mm_set1_epi8(*p8++ ^ 0x80); minVal = _mm_min_epu8(minVal, curVals); maxVal = _mm_max_epu8(maxVal, curVals); } *min8 = (int8_t)(_mm_cvtsi128_si32(minVal) ^ 0x80); *max8 = (int8_t)(_mm_cvtsi128_si32(maxVal) ^ 0x80); } else #endif { // non-SSE version (really slow for big samples while zoomed out) int8_t minVal = 127; int8_t maxVal = -128; const int8_t *ptr8 = (const int8_t *)p; for (uint32_t i = 0; i < scanLen; i++) { const int8_t smp8 = ptr8[i]; if (smp8 < minVal) minVal = smp8; if (smp8 > maxVal) maxVal = smp8; } *min8 = minVal; *max8 = maxVal; } } // for scanning sample data peak where loopEnd+SINC_RIGHT_TAPS is within scan range (fixed interpolation tap samples) static void getSpecialMinMax16(sampleTyp *s, int32_t index, int32_t scanEnd, int16_t *min16, int16_t *max16) { int16_t minVal2, maxVal2; const int16_t *ptr16 = (const int16_t *)s->pek; int16_t minVal = 32767; int16_t maxVal = -32768; // read samples before fixed samples (if needed) if (index < s->fixedPos) { getMinMax16(&ptr16[index], s->fixedPos-index, &minVal, &maxVal); index = s->fixedPos; } // read fixed samples (we are guaranteed to be within the fixed samples here) const int32_t tapIndex = index-s->fixedPos; const int32_t scanLength = SINC_RIGHT_TAPS-tapIndex; int32_t tmpScanEnd = index+scanLength; if (tmpScanEnd > scanEnd) tmpScanEnd = scanEnd; const int16_t *smpReadPtr = s->fixedSmp + tapIndex; for (; index < tmpScanEnd; index++) { const int16_t smp16 = *smpReadPtr++; if (smp16 < minVal) minVal = smp16; if (smp16 > maxVal) maxVal = smp16; } // read samples after fixed samples (if needed) if (index < scanEnd) { getMinMax16(&ptr16[index], scanEnd-index, &minVal2, &maxVal2); if (minVal2 < minVal) minVal = minVal2; if (maxVal2 > maxVal) maxVal = maxVal2; } *min16 = minVal; *max16 = maxVal; } // for scanning sample data peak where loopEnd+SINC_RIGHT_TAPS is within scan range (fixed interpolation tap samples) static void getSpecialMinMax8(sampleTyp *s, int32_t index, int32_t scanEnd, int8_t *min8, int8_t *max8) { int8_t minVal2, maxVal2; const int8_t *ptr8 = (const int8_t *)s->pek; int8_t minVal = 127; int8_t maxVal = -128; // read samples before fixed samples (if needed) if (index < s->fixedPos) { getMinMax8(&ptr8[index], s->fixedPos-index, &minVal, &maxVal); index = s->fixedPos; } // read fixed samples (we are guaranteed to be within the fixed samples here) const int32_t tapIndex = index-s->fixedPos; const int32_t scanLength = SINC_RIGHT_TAPS-tapIndex; int32_t tmpScanEnd = index+scanLength; if (tmpScanEnd > scanEnd) tmpScanEnd = scanEnd; const int16_t *smpReadPtr = (const int16_t *)s->fixedSmp + tapIndex; for (; index < tmpScanEnd; index++) { const int8_t smp8 = (int8_t)(*smpReadPtr++); if (smp8 < minVal) minVal = smp8; if (smp8 > maxVal) maxVal = smp8; } // read samples after fixed samples (if needed) if (index < scanEnd) { getMinMax8(&ptr8[index], scanEnd-index, &minVal2, &maxVal2); if (minVal2 < minVal) minVal = minVal2; if (maxVal2 > maxVal) maxVal = maxVal2; } *min8 = minVal; *max8 = maxVal; } static void getSampleDataPeak(sampleTyp *s, int32_t index, int32_t numSamples, int16_t *outMin, int16_t *outMax) { int8_t min8, max8; int16_t min16, max16; if (numSamples == 0 || s->pek == NULL || s->len <= 0) { *outMin = SAMPLE_AREA_Y_CENTER; *outMax = SAMPLE_AREA_Y_CENTER; return; } if (s->typ & 16) { assert(!(index & 1)); index >>= 1; numSamples >>= 1; } if (s->fixed && s->len > s->repL+s->repS) { const int32_t scanEnd = index + numSamples; /* If the scan area is including the fixed samples (for branchless mixer interpolation), ** do a special procedure to scan the original non-touched samples when needed. */ const bool insideRange = index >= s->fixedPos && index < s->fixedPos+SINC_RIGHT_TAPS; if (insideRange || (index < s->fixedPos && scanEnd >= s->fixedPos)) { if (s->typ & 16) { // 16-bit sample getSpecialMinMax16(s, index, scanEnd, &min16, &max16); *outMin = SAMPLE_AREA_Y_CENTER - ((min16 * SAMPLE_AREA_HEIGHT) >> 16); *outMax = SAMPLE_AREA_Y_CENTER - ((max16 * SAMPLE_AREA_HEIGHT) >> 16); } else { // 8-bit sample getSpecialMinMax8(s, index, scanEnd, &min8, &max8); *outMin = SAMPLE_AREA_Y_CENTER - ((min8 * SAMPLE_AREA_HEIGHT) >> 8); *outMax = SAMPLE_AREA_Y_CENTER - ((max8 * SAMPLE_AREA_HEIGHT) >> 8); } return; } } if (s->typ & 16) { // 16-bit sample const int16_t *smpPtr16 = (int16_t *)s->pek; getMinMax16(&smpPtr16[index], numSamples, &min16, &max16); *outMin = SAMPLE_AREA_Y_CENTER - ((min16 * SAMPLE_AREA_HEIGHT) >> 16); *outMax = SAMPLE_AREA_Y_CENTER - ((max16 * SAMPLE_AREA_HEIGHT) >> 16); } else { // 8-bit sample getMinMax8(&s->pek[index], numSamples, &min8, &max8); *outMin = SAMPLE_AREA_Y_CENTER - ((min8 * SAMPLE_AREA_HEIGHT) >> 8); *outMax = SAMPLE_AREA_Y_CENTER - ((max8 * SAMPLE_AREA_HEIGHT) >> 8); } } static void writeWaveform(void) { int16_t y1, y2, min, max; // clear sample data area memset(&video.frameBuffer[174 * SCREEN_W], 0, SAMPLE_AREA_WIDTH * SAMPLE_AREA_HEIGHT * sizeof (int32_t)); // draw center line hLine(0, SAMPLE_AREA_Y_CENTER, SAMPLE_AREA_WIDTH, PAL_DESKTOP); if (instr[editor.curInstr] == NULL || smpEd_ViewSize == 0) return; sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; if (s->pek == NULL || s->len == 0) return; y1 = SAMPLE_AREA_Y_CENTER - getScaledSample(s, scr2SmpPos(0)); uint32_t viewSizeSamples = smpEd_ViewSize; if (s->typ & 16) viewSizeSamples >>= 1; if (viewSizeSamples <= SAMPLE_AREA_WIDTH) { // 1:1 or zoomed in for (int16_t x = 1; x < SAMPLE_AREA_WIDTH; x++) { y2 = SAMPLE_AREA_Y_CENTER - getScaledSample(s, scr2SmpPos(x)); sampleLine(x - 1, x, y1, y2); y1 = y2; } } else { // zoomed out int16_t oldMin = y1; int16_t oldMax = y1; int32_t smpNumMin = (s->typ & 16) ? 2 : 1; for (int16_t x = 0; x < SAMPLE_AREA_WIDTH; x++) { int32_t smpIdx = scr2SmpPos(x); int32_t smpNum = scr2SmpPos(x+1) - smpIdx; // prevent look-up overflow (yes, this can happen near the end of the sample) if (smpIdx+smpNum > s->len) smpNum = s->len - smpNum; if (smpNum < smpNumMin) smpNum = smpNumMin; getSampleDataPeak(s, smpIdx, smpNum, &min, &max); if (x != 0) { if (min > oldMax) sampleLine(x - 1, x, oldMax, min); if (max < oldMin) sampleLine(x - 1, x, oldMin, max); } sampleLine(x, x, max, min); oldMin = min; oldMax = max; } } } void writeSample(bool forceSmpRedraw) { int32_t tmpRx1, tmpRx2; sampleTyp *s; // update sample loop points for visuals if (instr[editor.curInstr] == NULL) s = &instr[0]->samp[0]; else s = &instr[editor.curInstr]->samp[editor.curSmp]; curSmpRepS = s->repS; curSmpRepL = s->repL; // exchange range variables if x1 is after x2 if (smpEd_Rx1 > smpEd_Rx2) { tmpRx2 = smpEd_Rx2; smpEd_Rx2 = smpEd_Rx1; smpEd_Rx1 = tmpRx2; } // clamp range smpEd_Rx1 = CLAMP(smpEd_Rx1, 0, s->len); smpEd_Rx2 = CLAMP(smpEd_Rx2, 0, s->len); // sanitize sample scroll position if (smpEd_ScrPos+smpEd_ViewSize > s->len) { smpEd_ScrPos = s->len - smpEd_ViewSize; updateScrPos(); } if (smpEd_ScrPos < 0) { smpEd_ScrPos = 0; updateScrPos(); if (smpEd_ViewSize > s->len) { smpEd_ViewSize = s->len; updateViewSize(); } } // handle updating if (ui.sampleEditorShown) { // check if we need to redraw sample data if (forceSmpRedraw || (old_SmpScrPos != smpEd_ScrPos || old_ViewSize != smpEd_ViewSize)) { if (ui.sampleEditorShown) writeWaveform(); old_SmpScrPos = smpEd_ScrPos; old_ViewSize = smpEd_ViewSize; if (ui.sampleEditorShown) writeRange(); // range was overwritten, draw it again smpEd_OldSmpPosLine = -1; old_Rx1 = smpEd_Rx1; old_Rx2 = smpEd_Rx2; } // check if we need to write new range if (old_Rx1 != smpEd_Rx1 || old_Rx2 != smpEd_Rx2) { tmpRx1 = smpEd_Rx1; tmpRx2 = smpEd_Rx2; // remove old range smpEd_Rx1 = old_Rx1; smpEd_Rx2 = old_Rx2; if (ui.sampleEditorShown) writeRange(); // write new range smpEd_Rx1 = tmpRx1; smpEd_Rx2 = tmpRx2; if (ui.sampleEditorShown) writeRange(); old_Rx1 = smpEd_Rx1; old_Rx2 = smpEd_Rx2; } fixRepeatGadgets(); } if (ui.sampleEditorShown) fixSampleDrag(); updateSampleEditor(); } static void setSampleRange(int32_t start, int32_t end) { if (instr[editor.curInstr] == NULL) { smpEd_Rx1 = 0; smpEd_Rx2 = 0; return; } sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; if (start < 0) start = 0; if (end < 0) end = 0; smpEd_Rx1 = scr2SmpPos(start); smpEd_Rx2 = scr2SmpPos(end); // 2-byte align if sample is 16-bit if (s->typ & 16) { smpEd_Rx1 &= 0xFFFFFFFE; smpEd_Rx2 &= 0xFFFFFFFE; } } void updateSampleEditorSample(void) { smpEd_Rx1 = 0; smpEd_Rx2 = 0; smpEd_ScrPos = 0; updateScrPos(); if (instr[editor.curInstr] == NULL) smpEd_ViewSize = 0; else smpEd_ViewSize = instr[editor.curInstr]->samp[editor.curSmp].len; updateViewSize(); writeSample(true); } void updateSampleEditor(void) { char noteChar1, noteChar2; uint8_t typ; int32_t sampleLen; if (!ui.sampleEditorShown) return; if (instr[editor.curInstr] == NULL) { typ = 0; sampleLen = 0; } else { typ = instr[editor.curInstr]->samp[editor.curSmp].typ; sampleLen = instr[editor.curInstr]->samp[editor.curSmp].len; } // sample bit depth radio buttons uncheckRadioButtonGroup(RB_GROUP_SAMPLE_DEPTH); if (typ & 16) radioButtons[RB_SAMPLE_16BIT].state = RADIOBUTTON_CHECKED; else radioButtons[RB_SAMPLE_8BIT].state = RADIOBUTTON_CHECKED; showRadioButtonGroup(RB_GROUP_SAMPLE_DEPTH); // sample loop radio buttons uncheckRadioButtonGroup(RB_GROUP_SAMPLE_LOOP); if (typ & 3) { if (typ & 2) radioButtons[RB_SAMPLE_PINGPONG_LOOP].state = RADIOBUTTON_CHECKED; else radioButtons[RB_SAMPLE_FORWARD_LOOP].state = RADIOBUTTON_CHECKED; } else { radioButtons[RB_SAMPLE_NO_LOOP].state = RADIOBUTTON_CHECKED; } showRadioButtonGroup(RB_GROUP_SAMPLE_LOOP); // draw sample play note const uint8_t note = (editor.smpEd_NoteNr - 1) % 12; if (config.ptnAcc == 0) { noteChar1 = sharpNote1Char[note]; noteChar2 = sharpNote2Char[note]; } else { noteChar1 = flatNote1Char[note]; noteChar2 = flatNote2Char[note]; } char octaChar = '0' + ((editor.smpEd_NoteNr - 1) / 12); charOutBg(7, 369, PAL_FORGRND, PAL_BCKGRND, noteChar1); charOutBg(15, 369, PAL_FORGRND, PAL_BCKGRND, noteChar2); charOutBg(23, 369, PAL_FORGRND, PAL_BCKGRND, octaChar); // draw sample display/length hexOutBg(536, 350, PAL_FORGRND, PAL_DESKTOP, smpEd_ViewSize, 8); hexOutBg(536, 362, PAL_FORGRND, PAL_DESKTOP, sampleLen, 8); } void sampPlayNoteUp(void) { if (editor.smpEd_NoteNr < 96) { editor.smpEd_NoteNr++; updateSampleEditor(); } } void sampPlayNoteDown(void) { if (editor.smpEd_NoteNr > 1) { editor.smpEd_NoteNr--; updateSampleEditor(); } } void scrollSampleDataLeft(void) { int32_t scrollAmount, sampleLen; if (instr[editor.curInstr] == NULL) sampleLen = 0; else sampleLen = instr[editor.curInstr]->samp[editor.curSmp].len; if (smpEd_ViewSize == 0 || smpEd_ViewSize == sampleLen) return; if (mouse.rightButtonPressed) scrollAmount = smpEd_ViewSize / 14; // rounded from 16 (70Hz) else scrollAmount = smpEd_ViewSize / 27; // rounded from 32 (70Hz) if (scrollAmount < 1) scrollAmount = 1; smpEd_ScrPos -= scrollAmount; if (smpEd_ScrPos < 0) smpEd_ScrPos = 0; updateScrPos(); } void scrollSampleDataRight(void) { int32_t scrollAmount, sampleLen; if (instr[editor.curInstr] == NULL) sampleLen = 0; else sampleLen = instr[editor.curInstr]->samp[editor.curSmp].len; if (smpEd_ViewSize == 0 || smpEd_ViewSize == sampleLen) return; if (mouse.rightButtonPressed) scrollAmount = smpEd_ViewSize / 14; // was 16 (70Hz->60Hz) else scrollAmount = smpEd_ViewSize / 27; // was 32 (70Hz->60Hz) if (scrollAmount < 1) scrollAmount = 1; smpEd_ScrPos += scrollAmount; if (smpEd_ScrPos+smpEd_ViewSize > sampleLen) smpEd_ScrPos = sampleLen - smpEd_ViewSize; updateScrPos(); } void scrollSampleData(uint32_t pos) { int32_t sampleLen; if (instr[editor.curInstr] == NULL) sampleLen = 0; else sampleLen = instr[editor.curInstr]->samp[editor.curSmp].len; if (smpEd_ViewSize == 0 || smpEd_ViewSize == sampleLen) return; smpEd_ScrPos = (int32_t)pos; updateScrPos(); } void sampPlayWave(void) { playSample(cursor.ch, editor.curInstr, editor.curSmp, editor.smpEd_NoteNr, 0, 0); } void sampPlayDisplay(void) { playRange(cursor.ch, editor.curInstr, editor.curSmp, editor.smpEd_NoteNr, 0, 0, smpEd_ScrPos, smpEd_ViewSize); } void sampPlayRange(void) { playRange(cursor.ch, editor.curInstr, editor.curSmp, editor.smpEd_NoteNr, 0, 0, smpEd_Rx1, smpEd_Rx2 - smpEd_Rx1); } void showRange(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL) return; sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; if (s->pek == NULL) return; if (smpEd_Rx1 < smpEd_Rx2) { smpEd_ViewSize = smpEd_Rx2 - smpEd_Rx1; if (s->typ & 16) { if (smpEd_ViewSize < 4) smpEd_ViewSize = 4; } else if (smpEd_ViewSize < 2) { smpEd_ViewSize = 2; } updateViewSize(); smpEd_ScrPos = smpEd_Rx1; updateScrPos(); } else { okBox(0, "System message", "Cannot show empty range!"); } } void rangeAll(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } smpEd_Rx1 = smpEd_ScrPos; smpEd_Rx2 = smpEd_ScrPos + smpEd_ViewSize; } static void zoomSampleDataIn(int32_t step, int32_t x) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; int32_t minViewSize = (s->typ & 16) ? 4 : 2; if (old_ViewSize <= minViewSize) return; if (step < 1) step = 1; smpEd_ViewSize = old_ViewSize - (step * 2); if (smpEd_ViewSize < minViewSize) smpEd_ViewSize = minViewSize; updateViewSize(); int32_t tmp32 = (x - (SAMPLE_AREA_WIDTH / 2)) * step; tmp32 += SAMPLE_AREA_WIDTH/4; // rounding bias tmp32 /= SAMPLE_AREA_WIDTH/2; step += tmp32; int64_t newScrPos64 = old_SmpScrPos + step; if (newScrPos64+smpEd_ViewSize > s->len) newScrPos64 = s->len - smpEd_ViewSize; smpEd_ScrPos = newScrPos64 & 0xFFFFFFFF; updateScrPos(); } static void zoomSampleDataOut(int32_t step, int32_t x) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; if (old_ViewSize == s->len) return; if (step < 1) step = 1; int64_t newViewSize64 = (int64_t)old_ViewSize + (step * 2); if (newViewSize64 > s->len) { smpEd_ViewSize = s->len; smpEd_ScrPos = 0; } else { int32_t tmp32 = (x - (SAMPLE_AREA_WIDTH / 2)) * step; tmp32 += SAMPLE_AREA_WIDTH/4; // rounding bias tmp32 /= SAMPLE_AREA_WIDTH/2; step += tmp32; smpEd_ViewSize = newViewSize64 & 0xFFFFFFFF; smpEd_ScrPos = old_SmpScrPos - step; if (smpEd_ScrPos < 0) smpEd_ScrPos = 0; if ((smpEd_ScrPos + smpEd_ViewSize) > s->len) smpEd_ScrPos = s->len - smpEd_ViewSize; } updateViewSize(); updateScrPos(); } void mouseZoomSampleDataIn(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } zoomSampleDataIn((old_ViewSize+5) / 10, mouse.x); } void mouseZoomSampleDataOut(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } zoomSampleDataOut((old_ViewSize+5) / 10, mouse.x); } void zoomOut(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } sampleTyp *s = &instr[editor.curInstr]->samp[editor.curSmp]; if (old_ViewSize == s->len) return; int32_t tmp32 = old_ViewSize; tmp32++; // rounding bias tmp32 >>= 1; smpEd_ScrPos = old_SmpScrPos - tmp32; if (smpEd_ScrPos < 0) smpEd_ScrPos = 0; smpEd_ViewSize = old_ViewSize * 2; if (smpEd_ViewSize < old_ViewSize) { smpEd_ViewSize = s->len; smpEd_ScrPos = 0; } else if (smpEd_ViewSize+smpEd_ScrPos > s->len) { smpEd_ViewSize = s->len - smpEd_ScrPos; } updateViewSize(); updateScrPos(); } void showAll(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } smpEd_ScrPos = 0; updateScrPos(); smpEd_ViewSize = instr[editor.curInstr]->samp[editor.curSmp].len; updateViewSize(); } void saveRange(void) { if (editor.curInstr == 0 || instr[editor.curInstr] == NULL || instr[editor.curInstr]->samp[editor.curSmp].pek == NULL) { return; } if (smpEd_Rx1 >= smpEd_Rx2) { okBox(0, "System message", "No range specified!"); return; } smpEd_SysReqText[0] = '\0'; if (inputBox(1, "Enter filename:", smpEd_SysReqText, sizeof (smpEd_SysReqText) - 1) != 1) return; if (smpEd_SysReqText[0] == '\0') { okBox(0, "System message", "Filename can't be empty!"); return; } if (smpEd_SysReqText[0] == '.') { okBox(0, "System message", "The very first character in the filename can't be '.' (dot)!"); return; } if (strpbrk(smpEd_SysReqText, "\\/:*?\"<>|") != NULL) { okBox(0, "System message", "The filename can't contain the following characters: \\ / : * ? \" < > |"); return; } switch (editor.sampleSaveMode) { case SMP_SAVE_MODE_RAW: changeFilenameExt(smpEd_SysReqText, ".raw", sizeof (smpEd_SysReqText) - 1); break; case SMP_SAVE_MODE_IFF: changeFilenameExt(smpEd_SysReqText, ".iff", sizeof (smpEd_SysReqText) - 1); break; default: case SMP_SAVE_MODE_WAV: changeFilenameExt(smpEd_SysReqText, ".wav", sizeof (smpEd_SysReqText) - 1); break; } UNICHAR *filenameU = cp437ToUnichar(smpEd_SysReqText); if (filenameU == NULL) { okBox(0, "System message", "Error converting string locale!"); return; } saveSample(filenameU, SAVE_RANGE); free(filenameU); } static bool cutRange(bool cropMode, int32_t r1, int32_t r2) { sampleTyp *s = getCurSample(); if (s == NULL) return false; assert(!(s->typ & 16) || (!(r1 & 1) && !(r2 & 1) && !(s->len & 1))); if (!cropMode) { if (editor.curInstr == 0 || s->pek == NULL || s->len == 0) return false; pauseAudio(); restoreSample(s); if (config.smpCutToBuffer) { if (!getCopyBuffer(r2 - r1)) { fixSample(s); resumeAudio(); okBoxThreadSafe(0, "System message", "Not enough memory!"); return false; } memcpy(smpCopyBuff, &s->pek[r1], r2 - r1); smpCopyBits = (s->typ & 16) ? 16 : 8; } } memmove(&s->pek[r1], &s->pek[r2], s->len - r2); int32_t len = s->len - r2 + r1; if (len > 0) { int8_t *newPtr = (int8_t *)realloc(s->origPek, len + LOOP_FIX_LEN); if (newPtr == NULL) { freeSample(editor.curInstr, editor.curSmp); editor.updateCurSmp = true; if (!cropMode) resumeAudio(); okBoxThreadSafe(0, "System message", "Not enough memory!"); return false; } s->origPek = newPtr; s->pek = s->origPek + SMP_DAT_OFFSET; s->len = len; int32_t repE = s->repS + s->repL; if (s->repS > r1) { s->repS -= r2 - r1; if (s->repS < r1) s->repS = r1; } if (repE > r1) { repE -= r2 - r1; if (repE < r1) repE = r1; } s->repL = repE - s->repS; if (s->repL < 0) s->repL = 0; if (s->repS+s->repL > len) s->repL = len - s->repS; // 2-byte align loop points if sample is 16-bit if (s->typ & 16) { s->repL &= 0xFFFFFFFE; s->repS &= 0xFFFFFFFE; } if (s->repL == 0) { s->repS = 0; s->typ &= ~3; // disable loop } if (!cropMode) fixSample(s); } else { freeSample(editor.curInstr, editor.curSmp); editor.updateCurSmp = true; } if (!cropMode) { resumeAudio(); setSongModifiedFlag(); setMouseBusy(false); smpEd_Rx2 = r1; writeSampleFlag = true; } return true; } static int32_t SDLCALL sampCutThread(void *ptr) { if (!cutRange(false, smpEd_Rx1, smpEd_Rx2)) okBoxThreadSafe(0, "System message", "Not enough memory! (Disable \"cut to buffer\")"); else writeSampleFlag = true; return true; (void)ptr; } void sampCut(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0 || smpEd_Rx2 == 0 || smpEd_Rx2 < smpEd_Rx1) return; mouseAnimOn(); thread = SDL_CreateThread(sampCutThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static int32_t SDLCALL sampCopyThread(void *ptr) { sampleTyp *s = getCurSample(); assert(s != NULL && (!(s->typ & 16) || (!(smpEd_Rx1 & 1) && !(smpEd_Rx2 & 1)))); if (!getCopyBuffer(smpEd_Rx2 - smpEd_Rx1)) { okBoxThreadSafe(0, "System message", "Not enough memory!"); return true; } restoreSample(s); memcpy(smpCopyBuff, &s->pek[smpEd_Rx1], smpEd_Rx2 - smpEd_Rx1); fixSample(s); smpCopyBits = (s->typ & 16) ? 16 : 8; setMouseBusy(false); return true; (void)ptr; } void sampCopy(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->origPek == NULL || s->len <= 0 || smpEd_Rx2 == 0 || smpEd_Rx2 < smpEd_Rx1) return; mouseAnimOn(); thread = SDL_CreateThread(sampCopyThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static void pasteOverwrite(sampleTyp *s) { int8_t *p = (int8_t *)malloc(smpCopySize + LOOP_FIX_LEN); if (p == NULL) { okBoxThreadSafe(0, "System message", "Not enough memory!"); return; } pauseAudio(); if (s->origPek != NULL) free(s->origPek); memset(s, 0, sizeof (sampleTyp)); s->origPek = p; s->pek = p + SMP_DAT_OFFSET; memcpy(s->pek, smpCopyBuff, smpCopySize); s->len = smpCopySize; s->vol = 64; s->pan = 128; s->typ = (smpCopyBits == 16) ? 16 : 0; fixSample(s); resumeAudio(); editor.updateCurSmp = true; setSongModifiedFlag(); setMouseBusy(false); } static void pasteCopiedData(int8_t *pek, int32_t offset, int32_t length, bool smpIs16Bit) { if (smpIs16Bit) { // destination sample = 16-bit if (smpCopyBits == 16) { // src/dst = equal bits, copy directly memcpy(&pek[offset], smpCopyBuff, length); } else { // convert copy data to 16-bit then paste int16_t *ptr16 = (int16_t *)&pek[offset]; int32_t len32 = length >> 1; for (int32_t i = 0; i < len32; i++) ptr16[i] = smpCopyBuff[i] << 8; } } else { // destination sample = 8-bit if (smpCopyBits == 8) { // src/dst = equal bits, copy directly memcpy(&pek[offset], smpCopyBuff, length); } else { // convert copy data to 8-bit then paste int8_t *ptr8 = (int8_t *)&pek[offset]; int16_t *ptr16 = (int16_t *)smpCopyBuff; for (int32_t i = 0; i < length; i++) ptr8[i] = ptr16[i] >> 8; } } } static int32_t SDLCALL sampPasteThread(void *ptr) { if (instr[editor.curInstr] == NULL && !allocateInstr(editor.curInstr)) { okBoxThreadSafe(0, "System message", "Not enough memory!"); return true; } sampleTyp *s = getCurSample(); if (smpEd_Rx2 == 0 || s == NULL || s->pek == NULL) { pasteOverwrite(s); return true; } bool smpIs16Bit = (s->typ >> 4) & 1; assert(!smpIs16Bit || (!(smpEd_Rx1 & 1) && !(smpEd_Rx2 & 1) && !(s->len & 1))); if (s->len+smpCopySize > MAX_SAMPLE_LEN) { okBoxThreadSafe(0, "System message", "Not enough room in sample!"); return true; } int32_t realCopyLen = smpCopySize; if (smpIs16Bit) { // destination sample is 16-bit if (smpCopyBits == 8) // copy buffer is 8-bit, multiply length by 2 realCopyLen <<= 1; } else { // destination sample is 8-bit if (smpCopyBits == 16) // copy buffer is 16-bit, divide length by 2 realCopyLen >>= 1; } int32_t newLength = s->len + realCopyLen - (smpEd_Rx2 - smpEd_Rx1); if (newLength <= 0) return true; if (newLength > MAX_SAMPLE_LEN) { okBoxThreadSafe(0, "System message", "Not enough room in sample!"); return true; } int8_t *p = (int8_t *)malloc(newLength + LOOP_FIX_LEN); if (p == NULL) { okBoxThreadSafe(0, "System message", "Not enough memory!"); return true; } int8_t *newPek = p + SMP_DAT_OFFSET; pauseAudio(); restoreSample(s); // paste left part of original sample if (smpEd_Rx1 > 0) memcpy(newPek, s->pek, smpEd_Rx1); // paste copied data pasteCopiedData(newPek, smpEd_Rx1, realCopyLen, smpIs16Bit); // paste right part of original sample if (smpEd_Rx2 < s->len) memmove(&newPek[smpEd_Rx1+realCopyLen], &s->pek[smpEd_Rx2], s->len - smpEd_Rx2); free(s->origPek); // adjust loop points if necessary if (smpEd_Rx2-smpEd_Rx1 != realCopyLen) { int32_t loopAdjust = realCopyLen - (smpEd_Rx1 - smpEd_Rx2); if (s->repS > smpEd_Rx2) { s->repS += loopAdjust; s->repL -= loopAdjust; } if (s->repS+s->repL > smpEd_Rx2) s->repL += loopAdjust; if (s->repS > newLength) { s->repS = 0; s->repL = 0; } if (s->repS+s->repL > newLength) s->repL = newLength - s->repS; // align loop points if sample is 16-bit if (smpIs16Bit) { s->repL &= 0xFFFFFFFE; s->repS &= 0xFFFFFFFE; } } s->len = newLength; s->origPek = p; s->pek = s->origPek + SMP_DAT_OFFSET; fixSample(s); resumeAudio(); setSongModifiedFlag(); setMouseBusy(false); // set new range smpEd_Rx2 = smpEd_Rx1 + realCopyLen; // align sample marking points if sample is 16-bit if (smpIs16Bit) { smpEd_Rx1 &= 0xFFFFFFFE; smpEd_Rx2 &= 0xFFFFFFFE; } writeSampleFlag = true; return true; (void)ptr; } void sampPaste(void) { if (editor.curInstr == 0 || smpEd_Rx2 < smpEd_Rx1 || smpCopyBuff == NULL || smpCopySize == 0) return; if (smpEd_Rx2 == 0) // no sample data marked, overwrite sample with copy buffer { sampleTyp *s = getCurSample(); if (s != NULL && s->pek != NULL) { if (okBox(2, "System request", "The current sample is not empty. Do you really want to overwrite it?") != 1) return; } } mouseAnimOn(); thread = SDL_CreateThread(sampPasteThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static int32_t SDLCALL sampCropThread(void *ptr) { sampleTyp *s = getCurSample(); assert(!(s->typ & 16) || (!(smpEd_Rx1 & 1) && !(smpEd_Rx2 & 1) && !(s->len & 1))); int32_t r1 = smpEd_Rx1; int32_t r2 = smpEd_Rx2; pauseAudio(); restoreSample(s); if (!cutRange(true, 0, r1) || !cutRange(true, r2 - r1, s->len)) { fixSample(s); resumeAudio(); return true; } fixSample(s); resumeAudio(); r1 = 0; r2 = s->len; if (s->typ & 16) r2 &= 0xFFFFFFFE; setSongModifiedFlag(); setMouseBusy(false); smpEd_Rx1 = r1; smpEd_Rx2 = r2; writeSampleFlag = true; return true; (void)ptr; } void sampCrop(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0 || smpEd_Rx1 >= smpEd_Rx2) return; if (smpEd_Rx1 == 0 && smpEd_Rx2 >= s->len) return; // no need to crop (the whole sample is marked) mouseAnimOn(); thread = SDL_CreateThread(sampCropThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } void sampXFade(void) { int16_t c, d; int32_t tmp32, i, y1, y2, a, b, d1, d2, d3, dist; double dR, dS1, dS2, dS3, dS4; sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; assert(!(s->typ & 16) || (!(smpEd_Rx1 & 1) && !(smpEd_Rx2 & 1) && !(s->len & 1))); uint8_t t = s->typ; // check if the sample has the loop flag enabled if ((t & 3) == 0) { okBox(0, "System message", "X-Fade can only be used on a loop-enabled sample!"); return; } // check if we selected a range if (smpEd_Rx2 == 0) { okBox(0, "System message", "No range selected! Make a small range that includes loop start or loop end."); return; } // check if we selected a valid range length if (smpEd_Rx2-smpEd_Rx1 <= 2) { okBox(0, "System message", "Invalid range!"); return; } int32_t x1 = smpEd_Rx1; int32_t x2 = smpEd_Rx2; bool is16Bit = (t & 16) ? true : false; if ((t & 3) >= 2) { // pingpong loop y1 = s->repS; if (x1 <= y1) { // first loop point if (x2 <= y1 || x2 >= s->repS+s->repL) { okBox(0, "System message", "Invalid range!"); return; } d1 = y1 - x1; if (x2-y1 > d1) d1 = x2 - y1; d2 = y1 - x1; d3 = x2 - y1; if (d1 < 2 || d2 < 2 || d3 < 2) { okBox(0, "System message", "Invalid range!"); return; } if (y1-d1 < 0 || y1+d1 >= s->len) { okBox(0, "System message", "Not enough sample data outside loop!"); return; } if (is16Bit) { y1 >>= 1; d1 >>= 1; d2 >>= 1; d3 >>= 1; } pauseAudio(); restoreSample(s); i = 0; while (i < d1) { a = getSampleValue(s->pek, t, (y1 - i - 1) << is16Bit); b = getSampleValue(s->pek, t, (y1 + i) << is16Bit); dS1 = 1.0 - i / (double)d2; dS2 = 2.0 - dS1; dS3 = 1.0 - i / (double)d3; dS4 = 2.0 - dS3; tmp32 = (int32_t)round((a * dS2 + b * dS1) / (dS1 + dS2)); c = (int16_t)tmp32; tmp32 = (int32_t)round((b * dS4 + a * dS3) / (dS3 + dS4)); d = (int16_t)tmp32; if (i < d2) putSampleValue(s->pek, t, (y1 - i - 1) << is16Bit, c); if (i < d3) putSampleValue(s->pek, t, (y1 + i) << is16Bit, d); i++; } fixSample(s); resumeAudio(); } else { // last loop point y1 += s->repL; if (x1 >= y1 || x2 <= y1 || x2 >= s->len) { okBox(0, "System message", "Invalid range!"); return; } d1 = y1 - x1; if (x2-y1 > d1) d1 = x2 - y1; d2 = y1 - x1; d3 = x2 - y1; if (d1 < 2 || d2 < 2 || d3 < 2) { okBox(0, "System message", "Invalid range!"); return; } if (y1-d1 < 0 || y1+d1 >= s->len) { okBox(0, "System message", "Not enough sample data outside loop!"); return; } if (is16Bit) { y1 >>= 1; d1 >>= 1; d2 >>= 1; d3 >>= 1; } pauseAudio(); restoreSample(s); i = 0; while (i < d1) { a = getSampleValue(s->pek, t, (y1 - i - 1) << is16Bit); b = getSampleValue(s->pek, t, (y1 + i) << is16Bit); dS1 = 1.0 - i / (double)d2; dS2 = 2.0 - dS1; dS3 = 1.0 - i / (double)d3; dS4 = 2.0 - dS3; tmp32 = (int32_t)round((a * dS2 + b * dS1) / (dS1 + dS2)); c = (int16_t)tmp32; tmp32 = (int32_t)round((b * dS4 + a * dS3) / (dS3 + dS4)); d = (int16_t)tmp32; if (i < d2) putSampleValue(s->pek, t, (y1 - i - 1) << is16Bit, c); if (i < d3) putSampleValue(s->pek, t, (y1 + i) << is16Bit, d); i++; } fixSample(s); resumeAudio(); } } else { // standard loop if (x1 > s->repS) { x1 -= s->repL; x2 -= s->repL; } if (x1 < 0 || x2 <= x1 || x2 >= s->len) { okBox(0, "System message", "Invalid range!"); return; } i = (x2 - x1 + 1) >> 1; y1 = s->repS - i; y2 = s->repS + s->repL - i; if (t & 16) { y1 &= 0xFFFFFFFE; y2 &= 0xFFFFFFFE; } if (y1 < 0 || y2+(x2-x1) >= s->len) { okBox(0, "System message", "Not enough sample data outside loop!"); return; } d1 = x2 - x1; d2 = s->repS - y1; d3 = x2 - x1 - d2; if (y1+(x2-x1) <= s->repS || d1 == 0 || d3 == 0 || d1 > s->repL) { okBox(0, "System message", "Invalid range!"); return; } dR = (s->repS - i) / (double)(x2 - x1); dist = is16Bit ? 2 : 1; pauseAudio(); restoreSample(s); i = 0; while (i < x2-x1) { a = getSampleValue(s->pek, t, y1 + i); b = getSampleValue(s->pek, t, y2 + i); dS2 = i / (double)d1; dS1 = 1.0 - dS2; if (y1+i < s->repS) { dS3 = 1.0 - (1.0 - dR) * i / d2; dS4 = dR * i / d2; tmp32 = (int32_t)round((a * dS3 + b * dS4) / (dS3 + dS4)); c = (int16_t)tmp32; tmp32 = (int32_t)round((a * dS2 + b * dS1) / (dS1 + dS2)); d = (int16_t)tmp32; } else { dS3 = 1.0 - (1.0 - dR) * (d1 - i) / d3; dS4 = dR * (d1 - i) / d3; tmp32 = (int32_t)round((a * dS2 + b * dS1) / (dS1 + dS2)); c = (int16_t)tmp32; tmp32 = (int32_t)round((a * dS4 + b * dS3) / (dS3 + dS4)); d = (int16_t)tmp32; } putSampleValue(s->pek, t, y1 + i, c); putSampleValue(s->pek, t, y2 + i, d); i += dist; } fixSample(s); resumeAudio(); } writeSample(true); setSongModifiedFlag(); } void rbSampleNoLoop(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; lockMixerCallback(); restoreSample(s); s->typ &= ~3; fixSample(s); unlockMixerCallback(); updateSampleEditor(); writeSample(true); setSongModifiedFlag(); } void rbSampleForwardLoop(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; lockMixerCallback(); restoreSample(s); s->typ = (s->typ & ~3) | 1; if (s->repL+s->repS == 0) { s->repS = 0; s->repL = s->len; } fixSample(s); unlockMixerCallback(); updateSampleEditor(); writeSample(true); setSongModifiedFlag(); } void rbSamplePingpongLoop(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; lockMixerCallback(); restoreSample(s); s->typ = (s->typ & ~3) | 2; if (s->repL+s->repS == 0) { s->repS = 0; s->repL = s->len; } fixSample(s); unlockMixerCallback(); updateSampleEditor(); writeSample(true); setSongModifiedFlag(); } static int32_t SDLCALL convSmp8Bit(void *ptr) { sampleTyp *s = getCurSample(); pauseAudio(); restoreSample(s); const int16_t *src16 = (const int16_t *)s->pek; int32_t newLen = s->len >> 1; for (int32_t i = 0; i < newLen; i++) s->pek[i] = src16[i] >> 8; assert(s->origPek != NULL); int8_t *newPtr = (int8_t *)realloc(s->origPek, newLen + LOOP_FIX_LEN); if (newPtr != NULL) { s->origPek = newPtr; s->pek = s->origPek + SMP_DAT_OFFSET; } s->repL >>= 1; s->repS >>= 1; s->len >>= 1; s->typ &= ~16; // remove 16-bit flag fixSample(s); resumeAudio(); editor.updateCurSmp = true; setSongModifiedFlag(); setMouseBusy(false); return true; (void)ptr; } void rbSample8bit(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (okBox(2, "System request", "Convert sampledata?") == 1) { mouseAnimOn(); thread = SDL_CreateThread(convSmp8Bit, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); return; } else { lockMixerCallback(); restoreSample(s); s->typ &= ~16; // remove 16-bit flag fixSample(s); unlockMixerCallback(); updateSampleEditorSample(); updateSampleEditor(); setSongModifiedFlag(); } } static int32_t SDLCALL convSmp16Bit(void *ptr) { sampleTyp *s = getCurSample(); pauseAudio(); restoreSample(s); assert(s->origPek != NULL); int8_t *newPtr = (int8_t *)realloc(s->origPek, (s->len * 2) + LOOP_FIX_LEN); if (newPtr == NULL) { okBoxThreadSafe(0, "System message", "Not enough memory!"); return true; } else { s->origPek = newPtr; s->pek = s->origPek + SMP_DAT_OFFSET; } int16_t *dst16 = (int16_t *)s->pek; for (int32_t i = s->len-1; i >= 0; i--) dst16[i] = s->pek[i] << 8; s->len <<= 1; s->repL <<= 1; s->repS <<= 1; s->typ |= 16; // add 16-bit flag fixSample(s); resumeAudio(); editor.updateCurSmp = true; setSongModifiedFlag(); setMouseBusy(false); return true; (void)ptr; } void rbSample16bit(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (okBox(2, "System request", "Convert sampledata?") == 1) { mouseAnimOn(); thread = SDL_CreateThread(convSmp16Bit, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); return; } else { lockMixerCallback(); restoreSample(s); s->typ |= 16; // add 16-bit flag // make sure stuff is 2-byte aligned for 16-bit mode s->repS &= 0xFFFFFFFE; s->repL &= 0xFFFFFFFE; s->len &= 0xFFFFFFFE; fixSample(s); unlockMixerCallback(); updateSampleEditorSample(); updateSampleEditor(); setSongModifiedFlag(); } } void clearSample(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (okBox(1, "System request", "Clear sample?") != 1) return; freeSample(editor.curInstr, editor.curSmp); updateNewSample(); setSongModifiedFlag(); } void sampMin(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (okBox(1, "System request", "Minimize sample?") != 1) return; const bool hasLoop = s->typ & 3; if (hasLoop && s->len > s->repS+s->repL && s->repL < s->len) { lockMixerCallback(); s->len = s->repS + s->repL; int8_t *newPtr = (int8_t *)realloc(s->origPek, s->len + LOOP_FIX_LEN); if (newPtr != NULL) { s->origPek = newPtr; s->pek = s->origPek + SMP_DAT_OFFSET; } // Note: we don't need to make a call to fixSample() unlockMixerCallback(); updateSampleEditorSample(); updateSampleEditor(); setSongModifiedFlag(); } } void sampRepeatUp(void) { int32_t addVal, lenSub; sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (s->typ & 16) { lenSub = 4; addVal = 2; } else { lenSub = 2; addVal = 1; } int32_t repS = curSmpRepS; int32_t repL = curSmpRepL; if (repS < s->len-lenSub) repS += addVal; if (repS+repL > s->len) repL = s->len - repS; curSmpRepS = (s->typ & 16) ? (int32_t)(repS & 0xFFFFFFFE) : repS; curSmpRepL = (s->typ & 16) ? (int32_t)(repL & 0xFFFFFFFE) : repL; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } void sampRepeatDown(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; int32_t repS = (s->typ & 16) ? curSmpRepS-2 : curSmpRepS-1; if (repS < 0) repS = 0; curSmpRepS = (s->typ & 16) ? (int32_t)(repS & 0xFFFFFFFE) : repS; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } void sampReplenUp(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; int32_t repL = (s->typ & 16) ? curSmpRepL+2 : curSmpRepL+1; if (curSmpRepS+repL > s->len) repL = s->len - curSmpRepS; curSmpRepL = (s->typ & 16) ? (int32_t)(repL & 0xFFFFFFFE) : repL; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } void sampReplenDown(void) { int32_t repL; sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; if (s->typ & 16) repL = curSmpRepL - 2; else repL = curSmpRepL - 1; if (repL < 0) repL = 0; curSmpRepL = (s->typ & 16) ? (int32_t)(repL & 0xFFFFFFFE) : repL; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } void hideSampleEditor(void) { hidePushButton(PB_SAMP_SCROLL_LEFT); hidePushButton(PB_SAMP_SCROLL_RIGHT); hidePushButton(PB_SAMP_PNOTE_UP); hidePushButton(PB_SAMP_PNOTE_DOWN); hidePushButton(PB_SAMP_STOP); hidePushButton(PB_SAMP_PWAVE); hidePushButton(PB_SAMP_PRANGE); hidePushButton(PB_SAMP_PDISPLAY); hidePushButton(PB_SAMP_SHOW_RANGE); hidePushButton(PB_SAMP_RANGE_ALL); hidePushButton(PB_SAMP_CLR_RANGE); hidePushButton(PB_SAMP_ZOOM_OUT); hidePushButton(PB_SAMP_SHOW_ALL); hidePushButton(PB_SAMP_SAVE_RNG); hidePushButton(PB_SAMP_CUT); hidePushButton(PB_SAMP_COPY); hidePushButton(PB_SAMP_PASTE); hidePushButton(PB_SAMP_CROP); hidePushButton(PB_SAMP_VOLUME); hidePushButton(PB_SAMP_XFADE); hidePushButton(PB_SAMP_EXIT); hidePushButton(PB_SAMP_CLEAR); hidePushButton(PB_SAMP_MIN); hidePushButton(PB_SAMP_REPEAT_UP); hidePushButton(PB_SAMP_REPEAT_DOWN); hidePushButton(PB_SAMP_REPLEN_UP); hidePushButton(PB_SAMP_REPLEN_DOWN); hideRadioButtonGroup(RB_GROUP_SAMPLE_LOOP); hideRadioButtonGroup(RB_GROUP_SAMPLE_DEPTH); hideScrollBar(SB_SAMP_SCROLL); ui.sampleEditorShown = false; hideSprite(SPRITE_LEFT_LOOP_PIN); hideSprite(SPRITE_RIGHT_LOOP_PIN); } void exitSampleEditor(void) { hideSampleEditor(); if (ui.sampleEditorExtShown) hideSampleEditorExt(); showPatternEditor(); } void showSampleEditor(void) { if (ui.extended) exitPatternEditorExtended(); hideInstEditor(); hidePatternEditor(); ui.sampleEditorShown = true; drawFramework(0, 329, 632, 17, FRAMEWORK_TYPE1); drawFramework(0, 346, 115, 54, FRAMEWORK_TYPE1); drawFramework(115, 346, 133, 54, FRAMEWORK_TYPE1); drawFramework(248, 346, 49, 54, FRAMEWORK_TYPE1); drawFramework(297, 346, 56, 54, FRAMEWORK_TYPE1); drawFramework(353, 346, 74, 54, FRAMEWORK_TYPE1); drawFramework(427, 346, 205, 54, FRAMEWORK_TYPE1); drawFramework(2, 366, 34, 15, FRAMEWORK_TYPE2); textOutShadow(5, 352, PAL_FORGRND, PAL_DSKTOP2, "Play:"); textOutShadow(371, 352, PAL_FORGRND, PAL_DSKTOP2, "No loop"); textOutShadow(371, 369, PAL_FORGRND, PAL_DSKTOP2, "Forward"); textOutShadow(371, 386, PAL_FORGRND, PAL_DSKTOP2, "Pingpong"); textOutShadow(446, 369, PAL_FORGRND, PAL_DSKTOP2, "8-bit"); textOutShadow(445, 384, PAL_FORGRND, PAL_DSKTOP2, "16-bit"); textOutShadow(488, 350, PAL_FORGRND, PAL_DSKTOP2, "Display"); textOutShadow(488, 362, PAL_FORGRND, PAL_DSKTOP2, "Length"); textOutShadow(488, 375, PAL_FORGRND, PAL_DSKTOP2, "Repeat"); textOutShadow(488, 387, PAL_FORGRND, PAL_DSKTOP2, "Replen."); showPushButton(PB_SAMP_SCROLL_LEFT); showPushButton(PB_SAMP_SCROLL_RIGHT); showPushButton(PB_SAMP_PNOTE_UP); showPushButton(PB_SAMP_PNOTE_DOWN); showPushButton(PB_SAMP_STOP); showPushButton(PB_SAMP_PWAVE); showPushButton(PB_SAMP_PRANGE); showPushButton(PB_SAMP_PDISPLAY); showPushButton(PB_SAMP_SHOW_RANGE); showPushButton(PB_SAMP_RANGE_ALL); showPushButton(PB_SAMP_CLR_RANGE); showPushButton(PB_SAMP_ZOOM_OUT); showPushButton(PB_SAMP_SHOW_ALL); showPushButton(PB_SAMP_SAVE_RNG); showPushButton(PB_SAMP_CUT); showPushButton(PB_SAMP_COPY); showPushButton(PB_SAMP_PASTE); showPushButton(PB_SAMP_CROP); showPushButton(PB_SAMP_VOLUME); showPushButton(PB_SAMP_XFADE); showPushButton(PB_SAMP_EXIT); showPushButton(PB_SAMP_CLEAR); showPushButton(PB_SAMP_MIN); showPushButton(PB_SAMP_REPEAT_UP); showPushButton(PB_SAMP_REPEAT_DOWN); showPushButton(PB_SAMP_REPLEN_UP); showPushButton(PB_SAMP_REPLEN_DOWN); showRadioButtonGroup(RB_GROUP_SAMPLE_LOOP); showRadioButtonGroup(RB_GROUP_SAMPLE_DEPTH); showScrollBar(SB_SAMP_SCROLL); // clear two lines that are never written to when the sampler is open hLine(0, 173, SAMPLE_AREA_WIDTH, PAL_BCKGRND); hLine(0, 328, SAMPLE_AREA_WIDTH, PAL_BCKGRND); updateSampleEditor(); writeSample(true); } void toggleSampleEditor(void) { hideInstEditor(); if (ui.sampleEditorShown) { exitSampleEditor(); } else { hidePatternEditor(); showSampleEditor(); } } static void writeSmpXORLine(int32_t x) { if (x < 0 || x >= SCREEN_W) return; uint32_t *ptr32 = &video.frameBuffer[(174 * SCREEN_W) + x]; for (int32_t y = 0; y < SAMPLE_AREA_HEIGHT; y++, ptr32 += SCREEN_W) *ptr32 = video.palette[(*ptr32 >> 24) ^ 1]; // ">> 24" to get palette, XOR 1 to switch between normal/inverted mode } static void writeSamplePosLine(void) { uint8_t ins, smp; assert(editor.curSmpChannel < MAX_VOICES); lastChInstr_t *c = &lastChInstr[editor.curSmpChannel]; if (c->instrNr == 130) // "Play Wave/Range/Display" in Smp. Ed. { ins = editor.curPlayInstr; smp = editor.curPlaySmp; } else { ins = c->instrNr; smp = c->sampleNr; } if (editor.curInstr == ins && editor.curSmp == smp) { const int32_t smpPos = getSamplePosition(editor.curSmpChannel); if (smpPos != -1) { // convert sample position to screen position const int32_t scrPos = smpPos2Scr(smpPos); if (scrPos != -1) { if (scrPos != smpEd_OldSmpPosLine) { writeSmpXORLine(smpEd_OldSmpPosLine); // remove old line writeSmpXORLine(scrPos); // write new line } smpEd_OldSmpPosLine = scrPos; return; } } } if (smpEd_OldSmpPosLine != -1) writeSmpXORLine(smpEd_OldSmpPosLine); smpEd_OldSmpPosLine = -1; } void handleSamplerRedrawing(void) { // update sample editor if (!ui.sampleEditorShown || editor.samplingAudioFlag) return; if (writeSampleFlag) { writeSampleFlag = false; writeSample(true); } else if (smpEd_Rx1 != old_Rx1 || smpEd_Rx2 != old_Rx2 || smpEd_ScrPos != old_SmpScrPos || smpEd_ViewSize != old_ViewSize) { writeSample(false); } writeSamplePosLine(); } static void setLeftLoopPinPos(int32_t x) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; int32_t newPos = scr2SmpPos(x) - curSmpRepS; int32_t repS = curSmpRepS + newPos; int32_t repL = curSmpRepL - newPos; if (repS < 0) { repL += repS; repS = 0; } if (repL < 0) { repL = 0; repS = curSmpRepS + curSmpRepL; } if (s->typ & 16) { repS &= 0xFFFFFFFE; repL &= 0xFFFFFFFE; } curSmpRepS = repS; curSmpRepL = repL; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } static void setRightLoopPinPos(int32_t x) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; int32_t repL = scr2SmpPos(x) - curSmpRepS; if (repL < 0) repL = 0; if (repL+curSmpRepS > s->len) repL = s->len - curSmpRepS; if (repL < 0) repL = 0; if (s->typ & 16) repL &= 0xFFFFFFFE; curSmpRepL = repL; fixRepeatGadgets(); updateLoopsOnMouseUp = true; } static int32_t mouseYToSampleY(int32_t my) { my -= 174; // 0..SAMPLE_AREA_HEIGHT-1 const double dTmp = round(my * (256.0 / SAMPLE_AREA_HEIGHT)); const int32_t tmp32 = (const int32_t)dTmp; return 255 - CLAMP(tmp32, 0, 255); } static void editSampleData(bool mouseButtonHeld) { int8_t *ptr8; int16_t *ptr16; int32_t tmp32, p, vl, tvl, r, rl, rvl, start, end; sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; int32_t mx = mouse.x; if (mx > SCREEN_W) mx = SCREEN_W; int32_t my = mouse.y; if (!mouseButtonHeld) { pauseAudio(); restoreSample(s); editor.editSampleFlag = true; lastDrawX = scr2SmpPos(mx); if (s->typ & 16) lastDrawX >>= 1; lastDrawY = mouseYToSampleY(my); lastMouseX = mx; lastMouseY = my; } else if (mx == lastMouseX && my == lastMouseY) { return; // don't continue if we didn't move the mouse } if (mx != lastMouseX) { p = scr2SmpPos(mx); if (s->typ & 16) p >>= 1; } else { p = lastDrawX; } if (!keyb.leftShiftPressed && my != lastMouseY) vl = mouseYToSampleY(my); else vl = lastDrawY; lastMouseX = mx; lastMouseY = my; r = p; rvl = vl; // swap x/y if needed if (p > lastDrawX) { // swap x tmp32 = p; p = lastDrawX; lastDrawX = tmp32; // swap y tmp32 = lastDrawY; lastDrawY = vl; vl = tmp32; } if (s->typ & 16) { // 16-bit ptr16 = (int16_t *)s->pek; start = p; end = lastDrawX+1; if (start < 0) start = 0; tmp32 = s->len >> 1; if (end > tmp32) end = tmp32; if (p == lastDrawX) { const int16_t smpVal = (int16_t)((vl << 8) ^ 0x8000); for (rl = start; rl < end; rl++) ptr16[rl] = smpVal; } else { int32_t y = lastDrawY - vl; int32_t x = lastDrawX - p; if (x != 0) { double dMul = 1.0 / x; int32_t i = 0; for (rl = start; rl < end; rl++) { tvl = y * i; tvl = (int32_t)(tvl * dMul); // tvl /= x tvl += vl; tvl <<= 8; tvl ^= 0x8000; ptr16[rl] = (int16_t)tvl; i++; } } } } else { // 8-bit ptr8 = s->pek; start = p; if (start < 0) start = 0; end = lastDrawX+1; if (end > s->len) end = s->len; if (p == lastDrawX) { const int8_t smpVal = (int8_t)(vl ^ 0x80); for (rl = start; rl < end; rl++) ptr8[rl] = smpVal; } else { int32_t y = lastDrawY - vl; int32_t x = lastDrawX - p; if (x != 0) { double dMul = 1.0 / x; int32_t i = 0; for (rl = start; rl < end; rl++) { tvl = y * i; tvl = (int32_t)(tvl * dMul); // tvl /= x tvl += vl; tvl ^= 0x80; ptr8[rl] = (int8_t)tvl; i++; } } } } lastDrawY = rvl; lastDrawX = r; writeSample(true); } void handleSampleDataMouseDown(bool mouseButtonHeld) { if (editor.curInstr == 0) return; const int32_t mx = CLAMP(mouse.x, 0, SCREEN_W+8); // allow some pixels outside of the screen const int32_t my = CLAMP(mouse.y, 0, SCREEN_H-1); if (!mouseButtonHeld) { ui.rightLoopPinMoving = false; ui.leftLoopPinMoving = false; ui.sampleDataOrLoopDrag = -1; mouseXOffs = 0; lastMouseX = mx; lastMouseY = my; mouse.lastUsedObjectType = OBJECT_SMPDATA; if (mouse.leftButtonPressed) { // move loop pins if (my < 183) { const int32_t leftLoopPinPos = getSpritePosX(SPRITE_LEFT_LOOP_PIN); if (mx >= leftLoopPinPos && mx <= leftLoopPinPos+16) { mouseXOffs = (leftLoopPinPos + 8) - mx; ui.sampleDataOrLoopDrag = true; setLeftLoopPinState(true); lastMouseX = mx; ui.leftLoopPinMoving = true; return; } } else if (my > 318) { const int32_t rightLoopPinPos = getSpritePosX(SPRITE_RIGHT_LOOP_PIN); if (mx >= rightLoopPinPos && mx <= rightLoopPinPos+16) { mouseXOffs = (rightLoopPinPos + 8) - mx; ui.sampleDataOrLoopDrag = true; setRightLoopPinState(true); lastMouseX = mx; ui.rightLoopPinMoving = true; return; } } // mark data lastMouseX = mx; ui.sampleDataOrLoopDrag = mx; setSampleRange(mx, mx); } else if (mouse.rightButtonPressed) { // edit data ui.sampleDataOrLoopDrag = true; editSampleData(false); } return; } if (mouse.rightButtonPressed) { editSampleData(true); return; } if (mx != lastMouseX) { if (mouse.leftButtonPressed) { if (ui.leftLoopPinMoving) { lastMouseX = mx; setLeftLoopPinPos(mouseXOffs + mx); } else if (ui.rightLoopPinMoving) { lastMouseX = mx; setRightLoopPinPos(mouseXOffs + mx); } else if (ui.sampleDataOrLoopDrag >= 0) { // mark data lastMouseX = mx; if (lastMouseX > ui.sampleDataOrLoopDrag) setSampleRange(ui.sampleDataOrLoopDrag, mx); else if (lastMouseX == ui.sampleDataOrLoopDrag) setSampleRange(ui.sampleDataOrLoopDrag, ui.sampleDataOrLoopDrag); else if (lastMouseX < ui.sampleDataOrLoopDrag) setSampleRange(mx, ui.sampleDataOrLoopDrag); } } } } // SAMPLE EDITOR EXTENSION void handleSampleEditorExtRedrawing(void) { hexOutBg(35, 96, PAL_FORGRND, PAL_DESKTOP, smpEd_Rx1, 8); hexOutBg(99, 96, PAL_FORGRND, PAL_DESKTOP, smpEd_Rx2, 8); hexOutBg(99, 110, PAL_FORGRND, PAL_DESKTOP, smpEd_Rx2 - smpEd_Rx1, 8); hexOutBg(99, 124, PAL_FORGRND, PAL_DESKTOP, smpCopySize, 8); hexOutBg(226, 96, PAL_FORGRND, PAL_DESKTOP, editor.srcInstr, 2); hexOutBg(274, 96, PAL_FORGRND, PAL_DESKTOP, editor.srcSmp, 2); hexOutBg(226, 109, PAL_FORGRND, PAL_DESKTOP, editor.curInstr, 2); hexOutBg(274, 109, PAL_FORGRND, PAL_DESKTOP, editor.curSmp, 2); } void drawSampleEditorExt(void) { drawFramework(0, 92, 158, 44, FRAMEWORK_TYPE1); drawFramework(0, 136, 158, 37, FRAMEWORK_TYPE1); drawFramework(158, 92, 133, 81, FRAMEWORK_TYPE1); textOutShadow( 4, 96, PAL_FORGRND, PAL_DSKTOP2, "Rng.:"); charOutShadow(91, 95, PAL_FORGRND, PAL_DSKTOP2, '-'); textOutShadow( 4, 110, PAL_FORGRND, PAL_DSKTOP2, "Range size"); textOutShadow( 4, 124, PAL_FORGRND, PAL_DSKTOP2, "Copy buf. size"); textOutShadow(162, 96, PAL_FORGRND, PAL_DSKTOP2, "Src.instr."); textOutShadow(245, 96, PAL_FORGRND, PAL_DSKTOP2, "smp."); textOutShadow(162, 109, PAL_FORGRND, PAL_DSKTOP2, "Dest.instr."); textOutShadow(245, 109, PAL_FORGRND, PAL_DSKTOP2, "smp."); showPushButton(PB_SAMP_EXT_CLEAR_COPYBUF); showPushButton(PB_SAMP_EXT_CONV); showPushButton(PB_SAMP_EXT_ECHO); showPushButton(PB_SAMP_EXT_BACKWARDS); showPushButton(PB_SAMP_EXT_CONV_W); showPushButton(PB_SAMP_EXT_MORPH); showPushButton(PB_SAMP_EXT_COPY_INS); showPushButton(PB_SAMP_EXT_COPY_SMP); showPushButton(PB_SAMP_EXT_XCHG_INS); showPushButton(PB_SAMP_EXT_XCHG_SMP); showPushButton(PB_SAMP_EXT_RESAMPLE); showPushButton(PB_SAMP_EXT_MIX_SAMPLE); } void showSampleEditorExt(void) { hideTopScreen(); showTopScreen(false); if (ui.extended) exitPatternEditorExtended(); if (!ui.sampleEditorShown) showSampleEditor(); ui.sampleEditorExtShown = true; ui.scopesShown = false; drawSampleEditorExt(); } void hideSampleEditorExt(void) { ui.sampleEditorExtShown = false; hidePushButton(PB_SAMP_EXT_CLEAR_COPYBUF); hidePushButton(PB_SAMP_EXT_CONV); hidePushButton(PB_SAMP_EXT_ECHO); hidePushButton(PB_SAMP_EXT_BACKWARDS); hidePushButton(PB_SAMP_EXT_CONV_W); hidePushButton(PB_SAMP_EXT_MORPH); hidePushButton(PB_SAMP_EXT_COPY_INS); hidePushButton(PB_SAMP_EXT_COPY_SMP); hidePushButton(PB_SAMP_EXT_XCHG_INS); hidePushButton(PB_SAMP_EXT_XCHG_SMP); hidePushButton(PB_SAMP_EXT_RESAMPLE); hidePushButton(PB_SAMP_EXT_MIX_SAMPLE); ui.scopesShown = true; drawScopeFramework(); } void toggleSampleEditorExt(void) { if (ui.sampleEditorExtShown) hideSampleEditorExt(); else showSampleEditorExt(); } static int32_t SDLCALL sampleBackwardsThread(void *ptr) { int8_t tmp8, *ptrStart, *ptrEnd; int16_t tmp16, *ptrStart16, *ptrEnd16; sampleTyp *s = getCurSample(); if (s->typ & 16) { if (smpEd_Rx1 >= smpEd_Rx2) { ptrStart16 = (int16_t *)s->pek; ptrEnd16 = (int16_t *)&s->pek[s->len-2]; } else { ptrStart16 = (int16_t *)&s->pek[smpEd_Rx1]; ptrEnd16 = (int16_t *)&s->pek[smpEd_Rx2-2]; } pauseAudio(); restoreSample(s); while (ptrStart16 < ptrEnd16) { tmp16 = *ptrStart16; *ptrStart16++ = *ptrEnd16; *ptrEnd16-- = tmp16; } fixSample(s); resumeAudio(); } else { if (smpEd_Rx1 >= smpEd_Rx2) { ptrStart = s->pek; ptrEnd = &s->pek[s->len-1]; } else { ptrStart = &s->pek[smpEd_Rx1]; ptrEnd = &s->pek[smpEd_Rx2-1]; } pauseAudio(); restoreSample(s); while (ptrStart < ptrEnd) { tmp8 = *ptrStart; *ptrStart++ = *ptrEnd; *ptrEnd-- = tmp8; } fixSample(s); resumeAudio(); } setSongModifiedFlag(); setMouseBusy(false); writeSampleFlag = true; return true; (void)ptr; } void sampleBackwards(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len < 2) return; mouseAnimOn(); thread = SDL_CreateThread(sampleBackwardsThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static int32_t SDLCALL sampleConvThread(void *ptr) { int8_t *ptr8; int16_t *ptr16; int32_t i, len; sampleTyp *s = getCurSample(); pauseAudio(); restoreSample(s); if (s->typ & 16) { len = s->len / 2; ptr16 = (int16_t *)s->pek; for (i = 0; i < len; i++) ptr16[i] ^= 0x8000; } else { len = s->len; ptr8 = s->pek; for (i = 0; i < len; i++) ptr8[i] ^= 0x80; } fixSample(s); resumeAudio(); setSongModifiedFlag(); setMouseBusy(false); writeSampleFlag = true; return true; (void)ptr; } void sampleConv(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; mouseAnimOn(); thread = SDL_CreateThread(sampleConvThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static int32_t SDLCALL sampleConvWThread(void *ptr) { sampleTyp *s = getCurSample(); pauseAudio(); restoreSample(s); int32_t len = s->len / 2; int8_t *ptr8 = s->pek; for (int32_t i = 0; i < len; i++, ptr8 += 2) { const int8_t tmp = ptr8[0]; ptr8[0] = ptr8[1]; ptr8[1] = tmp; } fixSample(s); resumeAudio(); setSongModifiedFlag(); setMouseBusy(false); writeSampleFlag = true; return true; (void)ptr; } void sampleConvW(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; mouseAnimOn(); thread = SDL_CreateThread(sampleConvWThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } static int32_t SDLCALL fixDCThread(void *ptr) { int8_t *ptr8; int16_t *ptr16; int32_t i, len, smpSub, smp32; sampleTyp *s = getCurSample(); int64_t averageDC = 0; if (s->typ & 16) { if (smpEd_Rx1 >= smpEd_Rx2) { assert(!(s->len & 1)); ptr16 = (int16_t *)s->pek; len = s->len >> 1; } else { assert(!(smpEd_Rx1 & 1)); assert(!(smpEd_Rx2 & 1)); ptr16 = (int16_t *)&s->pek[smpEd_Rx1]; len = (smpEd_Rx2 - smpEd_Rx1) >> 1; } if (len < 0 || len > s->len>>1) { setMouseBusy(false); return true; } pauseAudio(); restoreSample(s); for (i = 0; i < len; i++) averageDC += ptr16[i]; averageDC /= len; smpSub = (int32_t)averageDC; for (i = 0; i < len; i++) { smp32 = ptr16[i] - smpSub; CLAMP16(smp32); ptr16[i] = (int16_t)smp32; } fixSample(s); resumeAudio(); } else { if (smpEd_Rx1 >= smpEd_Rx2) { ptr8 = s->pek; len = s->len; } else { ptr8 = &s->pek[smpEd_Rx1]; len = smpEd_Rx2 - smpEd_Rx1; } if (len < 0 || len > s->len) { setMouseBusy(false); return true; } pauseAudio(); restoreSample(s); for (i = 0; i < len; i++) averageDC += ptr8[i]; averageDC /= len; smpSub = (int32_t)averageDC; for (i = 0; i < len; i++) { smp32 = ptr8[i] - smpSub; CLAMP8(smp32); ptr8[i] = (int8_t)smp32; } fixSample(s); resumeAudio(); } writeSampleFlag = true; setSongModifiedFlag(); setMouseBusy(false); return true; (void)ptr; } void fixDC(void) { sampleTyp *s = getCurSample(); if (s == NULL || s->pek == NULL || s->len <= 0) return; mouseAnimOn(); thread = SDL_CreateThread(fixDCThread, NULL, NULL); if (thread == NULL) { okBox(0, "System message", "Couldn't create thread!"); return; } SDL_DetachThread(thread); } void smpEdStop(void) { // safely kills all voices lockMixerCallback(); unlockMixerCallback(); } void testSmpEdMouseUp(void) // used for setting new loop points { if (updateLoopsOnMouseUp) { updateLoopsOnMouseUp = false; sampleTyp *s = getCurSample(); if (s == NULL) return; if (s->repS != curSmpRepS || s->repL != curSmpRepL) { lockMixerCallback(); restoreSample(s); setSongModifiedFlag(); s->repS = curSmpRepS; s->repL = curSmpRepL; fixSample(s); unlockMixerCallback(); writeSample(true); } } }