ref: fc55f5c1b127721c26809a0732ba1b6893e9c6cc
dir: /pt_pal_editor/src/palette.c/
#include <stdio.h> #include <string.h> #include "gui.h" #include "palette.h" #include "tinyfiledialogs/tinyfiledialogs.h" // 12-bit RGB values uint16_t palette[8]; uint16_t vuColors[48]; uint16_t analyzerColors[36]; // 12-bit RGB values static const uint16_t originalPalette[8] = { 0x000, // 00- PAL_BACKGRD 0xBBB, // 01- PAL_BORDER 0x888, // 02- PAL_GENBKG 0x555, // 03- PAL_GENBKG2 0xFD0, // 04- PAL_QADSCP 0xD04, // 05- PAL_PATCURSOR 0x000, // 06- PAL_GENTXT 0x34F // 07- PAL_PATTXT }; // 12-bit RGB values static const uint16_t vuOriginalColors[48] = { 0xF00, 0xF00, 0xF10, 0xF10, 0xF20, 0xF20, 0xF30, 0xF30, 0xF40, 0xF50, 0xF60, 0xF70, 0xF80, 0xF90, 0xFA0, 0xFB0, 0xFC0, 0xFD0, 0xFE0, 0xFF0, 0xFF0, 0xEF0, 0xEF0, 0xDF0, 0xDF0, 0xCF0, 0xCF0, 0xBF0, 0xBF0, 0xAF0, 0x9F0, 0x9F0, 0x8F0, 0x8F0, 0x7F0, 0x7F0, 0x6F0, 0x6F0, 0x5F0, 0x5F0, 0x4F0, 0x4F0, 0x3F0, 0x3F0, 0x2F0, 0x1F0, 0x0F0, 0x0E0 }; // 12-bit RGB values static const uint16_t analyzerOriginalColors[48] = { 0xF00, 0xF10, 0xF20, 0xF30, 0xF40, 0xF50, 0xF60, 0xF70, 0xF80, 0xF90, 0xFA0, 0xFB0, 0xFC0, 0xFD0, 0xFE0, 0xFF0, 0xEF0, 0xDF0, 0xCF0, 0xBF0, 0xAF0, 0x9F0, 0x8F0, 0x7F0, 0x6F0, 0x5F0, 0x4F0, 0x3F0, 0x2F0, 0x1F0, 0x0F0, 0x0E0, 0x0D0, 0x0C0, 0x0B0, 0x0A0 }; static uint16_t undo1Col, undo1ColIndex, can1Cols[8]; static uint16_t undo2Col, undo2ColIndex, can2ColsVu[48], can2ColsAna[36]; // these will be generated in realtime based on vuColors uint32_t spectrumAnalyzerBMP[36], vuMeterBMP[480], patternCursorBMP[154]; void fillCancel1Colors(void) { memcpy(can1Cols, palette, sizeof (palette)); } void cancel1Color(void) { memcpy(palette, can1Cols, sizeof (palette)); } void setUndo1Color(uint8_t paletteIndex) { undo1ColIndex = paletteIndex; undo1Col = palette[undo1ColIndex]; } void undo1Color(void) { uint16_t oldColor = palette[undo1ColIndex]; palette[undo1ColIndex] = undo1Col; undo1Col = oldColor; } void fillCancel2Colors(void) { memcpy(can2ColsVu, vuColors, sizeof (vuColors)); memcpy(can2ColsAna, analyzerColors, sizeof (analyzerColors)); } void cancel2Color(void) { if (theRightColors == vuColors) memcpy(vuColors, can2ColsVu, sizeof (vuColors)); else memcpy(analyzerColors, can2ColsAna, sizeof (analyzerColors)); } void setUndo2Color(uint8_t colorIndex) { undo2ColIndex = colorIndex; undo2Col = theRightColors[colorIndex]; } void undo2Color(void) { uint16_t oldColor = theRightColors[undo2ColIndex]; theRightColors[undo2ColIndex] = undo2Col; undo2Col = oldColor; } void setDefaultPalette(void) { memcpy(palette, originalPalette, sizeof (palette)); } void setDefaultVuColors(void) { memcpy(vuColors, vuOriginalColors, sizeof (vuColors)); } void setDefaultAnalyzerColors(void) { memcpy(analyzerColors, analyzerOriginalColors, sizeof (analyzerColors)); } uint16_t colorPicker(uint16_t inputColor) { uint8_t aDefaultRGB[3], aoResultRGB[3]; uint32_t pixel32, defaultCol24; defaultCol24 = RGB12_to_RGB24(inputColor); aDefaultRGB[0] = R24(defaultCol24); aDefaultRGB[1] = G24(defaultCol24); aDefaultRGB[2] = B24(defaultCol24); if (tinyfd_colorChooser("Pick a color", NULL, aDefaultRGB, aoResultRGB) == NULL) return 0xFFFF; // cancel/exit pixel32 = (aoResultRGB[0] << 16) | (aoResultRGB[1] << 8) | aoResultRGB[2]; return RGB24_to_RGB12(pixel32); } void updatePatternCursorBMP(void) { uint8_t r8, g8, b8; int32_t x; uint32_t pixel24; pixel24 = RGB12_to_RGB24(palette[PAL_PATCURSOR]); for (int32_t y = 0; y < 14; y++) { // top two rows have a lighter color if (y < 2) { r8 = R24(pixel24); g8 = G24(pixel24); b8 = B24(pixel24); if (r8 <= 0xFF-0x33) r8 += 0x33; else r8 = 0xFF; if (g8 <= 0xFF-0x33) g8 += 0x33; else g8 = 0xFF; if (b8 <= 0xFF-0x33) b8 += 0x33; else b8 = 0xFF; for (x = 0; x < 11; x++) patternCursorBMP[(y * 11) + x] = RGB24(r8, g8, b8); } // sides (same color) if (y >= 2 && y <= 12) { patternCursorBMP[(y * 11) + 0] = pixel24; for (x = 1; x < 10; x++) patternCursorBMP[(y * 11) + x] = RGB24_COLORKEY; patternCursorBMP[(y * 11) + 10] = pixel24; } // bottom two rows have a darker color if (y > 11) { r8 = R24(pixel24); g8 = G24(pixel24); b8 = B24(pixel24); if (r8 >= 0x33) r8 -= 0x33; else r8 = 0x00; if (g8 >= 0x33) g8 -= 0x33; else g8 = 0x00; if (b8 >= 0x33) b8 -= 0x33; else b8 = 0x00; for (x = 0; x < 11; x++) patternCursorBMP[(y * 11) + x] = RGB24(r8, g8, b8); } } } void updateSpectrumAnalyzerBMP(void) { for (int32_t i = 0; i < 36; i++) spectrumAnalyzerBMP[i] = RGB12_to_RGB24(analyzerColors[35-i]); } void updateVuMeterBMP(void) { uint8_t r8, g8, b8, r8_2, g8_2, b8_2; uint16_t pixel12; uint32_t pixel24; for (int32_t i = 0; i < 48; i++) { pixel12 = vuColors[47-i]; r8_2 = r8 = R12_to_R24(pixel12); g8_2 = g8 = G12_to_G24(pixel12); b8_2 = b8 = B12_to_B24(pixel12); // brighter pixels on the left side if (r8_2 <= 0xFF-0x33) r8_2 += 0x33; else r8_2 = 0xFF; if (g8_2 <= 0xFF-0x33) g8_2 += 0x33; else g8_2 = 0xFF; if (b8_2 <= 0xFF-0x33) b8_2 += 0x33; else b8_2 = 0xFF; pixel24 = RGB24(r8_2, g8_2, b8_2); vuMeterBMP[(i * 10) + 0] = pixel24; vuMeterBMP[(i * 10) + 1] = pixel24; // main pixels for (int32_t j = 2; j < 8; j++) vuMeterBMP[(i * 10) + j] = RGB24(r8, g8, b8); // darker pixels on the right side r8_2 = r8; g8_2 = g8; b8_2 = b8; if (r8_2 >= 0x33) r8_2 -= 0x33; else r8_2 = 0x00; if (g8_2 >= 0x33) g8_2 -= 0x33; else g8_2 = 0x00; if (b8_2 >= 0x33) b8_2 -= 0x33; else b8_2 = 0x00; pixel24 = RGB24(r8_2, g8_2, b8_2); vuMeterBMP[(i * 10) + 8] = pixel24; vuMeterBMP[(i * 10) + 9] = pixel24; } } void updateBMPs(void) { updatePatternCursorBMP(); updateSpectrumAnalyzerBMP(); updateVuMeterBMP(); }