#include "DrawUtils.h" #include "dc.h" #include "logger.h" #include "utils.h" #include #include #include #include #include #include // buffer width #define DRC_WIDTH 0x380 bool DrawUtils::mIsBackBuffer; uint8_t *DrawUtils::mTVBuffer = nullptr; uint32_t DrawUtils::mTVSize = 0; uint8_t *DrawUtils::mDRCBuffer = nullptr; uint32_t DrawUtils::mDRCSize = 0; uint32_t DrawUtils::mUsedTVWidth = 1280; float DrawUtils::mUsedTVScale = 1.5f; static SFT pFont = {}; static Color font_col(0xFFFFFFFF); void DrawUtils::initBuffers(void *tvBuffer, const uint32_t tvSize, void *drcBuffer, const uint32_t drcSize) { DrawUtils::mTVBuffer = static_cast(tvBuffer); DrawUtils::mTVSize = tvSize; DrawUtils::mDRCBuffer = static_cast(drcBuffer); DrawUtils::mDRCSize = drcSize; bool bigScale = true; switch (TVEGetCurrentPort()) { case TVE_PORT_HDMI: bigScale = true; break; case TVE_PORT_COMPONENT: case TVE_PORT_COMPOSITE: case TVE_PORT_SCART: bigScale = false; break; } AVMTvResolution tvResolution = AVM_TV_RESOLUTION_720P; if (AVMGetTVScanMode(&tvResolution)) { switch (tvResolution) { case AVM_TV_RESOLUTION_480P: case AVM_TV_RESOLUTION_720P: case AVM_TV_RESOLUTION_720P_3D: case AVM_TV_RESOLUTION_1080I: case AVM_TV_RESOLUTION_1080P: case AVM_TV_RESOLUTION_576P: case AVM_TV_RESOLUTION_720P_50HZ: case AVM_TV_RESOLUTION_1080I_50HZ: case AVM_TV_RESOLUTION_1080P_50HZ: bigScale = true; break; case AVM_TV_RESOLUTION_576I: case AVM_TV_RESOLUTION_480I: case AVM_TV_RESOLUTION_480I_PAL60: break; } } auto tvScanBufferWidth = DCReadReg32(SCREEN_TV, D1GRPH_X_END_REG); if (tvScanBufferWidth == 640) { // 480i/480p/576i 4:3 DrawUtils::mUsedTVWidth = 640; SetDCPitchReg(SCREEN_TV, 640); DrawUtils::mUsedTVScale = bigScale ? 0.75 : 0.75f; } else if (tvScanBufferWidth == 854) { // 480i/480p/576i 16:9 DrawUtils::mUsedTVWidth = 896; SetDCPitchReg(SCREEN_TV, 896); DrawUtils::mUsedTVScale = bigScale ? 1.0 : 1.0f; } else if (tvScanBufferWidth == 1280) { // 720p 16:9 DrawUtils::mUsedTVWidth = 1280; SetDCPitchReg(SCREEN_TV, 1280); if (bigScale) { DrawUtils::mUsedTVScale = 1.5; } else { DrawUtils::mUsedTVScale = 0.75f; if (tvResolution == AVM_TV_RESOLUTION_480I_PAL60 || tvResolution == AVM_TV_RESOLUTION_480I) { AVMTvAspectRatio tvAspectRatio; if (AVMGetTVAspectRatio(&tvAspectRatio) && tvAspectRatio == AVM_TV_ASPECT_RATIO_16_9) { DEBUG_FUNCTION_LINE_WARN("force big scaling for 480i + 16:9"); DrawUtils::mUsedTVScale = 1.5; } } } } else if (tvScanBufferWidth == 1920) { // 1080i/1080p 16:9 DrawUtils::mUsedTVWidth = 1920; SetDCPitchReg(SCREEN_TV, 1920); DrawUtils::mUsedTVScale = bigScale ? 2.25 : 1.125f; } else { DrawUtils::mUsedTVWidth = tvScanBufferWidth; SetDCPitchReg(SCREEN_TV, tvScanBufferWidth); DrawUtils::mUsedTVScale = 1.0f; DEBUG_FUNCTION_LINE_WARN("Unknown tv width detected, config menu might not show properly"); } } void DrawUtils::beginDraw() { const uint32_t pixel = *reinterpret_cast(mTVBuffer); // check which buffer is currently used OSScreenPutPixelEx(SCREEN_TV, 0, 0, 0xABCDEF90); if (*reinterpret_cast(mTVBuffer) == 0xABCDEF90) { mIsBackBuffer = false; } else { mIsBackBuffer = true; } // restore the pixel we used for checking *reinterpret_cast(mTVBuffer) = pixel; } void DrawUtils::endDraw() { // OSScreenFlipBuffersEx already flushes the cache? // DCFlushRange(tvBuffer, tvSize); // DCFlushRange(drcBuffer, drcSize); OSScreenFlipBuffersEx(SCREEN_DRC); OSScreenFlipBuffersEx(SCREEN_TV); } void DrawUtils::clear(const Color col) { OSScreenClearBufferEx(SCREEN_TV, col.color); OSScreenClearBufferEx(SCREEN_DRC, col.color); } void DrawUtils::drawPixel(const uint32_t x, const uint32_t y, const uint8_t r, const uint8_t g, const uint8_t b, const uint8_t a) { if (a == 0) { return; } const float opacity = a / 255.0f; // put pixel in the drc buffer uint32_t i = (x + y * DRC_WIDTH) * 4; if (i + 3 < mDRCSize / 2) { if (mIsBackBuffer) { i += mDRCSize / 2; } if (a == 0xFF) { mDRCBuffer[i] = r; mDRCBuffer[i + 1] = g; mDRCBuffer[i + 2] = b; } else { mDRCBuffer[i] = r * opacity + mDRCBuffer[i] * (1 - opacity); mDRCBuffer[i + 1] = g * opacity + mDRCBuffer[i + 1] * (1 - opacity); mDRCBuffer[i + 2] = b * opacity + mDRCBuffer[i + 2] * (1 - opacity); } } // scale and put pixel in the tv buffer for (uint32_t yy = (y * DrawUtils::mUsedTVScale); yy < ((y * DrawUtils::mUsedTVScale) + (uint32_t) DrawUtils::mUsedTVScale); yy++) { for (uint32_t xx = (x * DrawUtils::mUsedTVScale); xx < ((x * DrawUtils::mUsedTVScale) + (uint32_t) DrawUtils::mUsedTVScale); xx++) { uint32_t i = (xx + yy * DrawUtils::mUsedTVWidth) * 4; if (i + 3 < mTVSize / 2) { if (mIsBackBuffer) { i += mTVSize / 2; } if (a == 0xFF) { mTVBuffer[i] = r; mTVBuffer[i + 1] = g; mTVBuffer[i + 2] = b; } else { mTVBuffer[i] = r * opacity + mTVBuffer[i] * (1 - opacity); mTVBuffer[i + 1] = g * opacity + mTVBuffer[i + 1] * (1 - opacity); mTVBuffer[i + 2] = b * opacity + mTVBuffer[i + 2] * (1 - opacity); } } } } } void DrawUtils::drawRectFilled(const uint32_t x, const uint32_t y, const uint32_t w, const uint32_t h, const Color col) { for (uint32_t yy = y; yy < y + h; yy++) { for (uint32_t xx = x; xx < x + w; xx++) { drawPixel(xx, yy, col); } } } void DrawUtils::drawRect(const uint32_t x, const uint32_t y, const uint32_t w, const uint32_t h, const uint32_t borderSize, const Color col) { drawRectFilled(x, y, w, borderSize, col); drawRectFilled(x, y + h - borderSize, w, borderSize, col); drawRectFilled(x, y, borderSize, h, col); drawRectFilled(x + w - borderSize, y, borderSize, h, col); } void DrawUtils::drawBitmap(const uint32_t x, const uint32_t y, const uint32_t target_width, const uint32_t target_height, const uint8_t *data) { if (data[0] != 'B' || data[1] != 'M') { // invalid header return; } uint32_t dataPos = __builtin_bswap32(*(uint32_t *) &(data[0x0A])); const uint32_t width = __builtin_bswap32(*(uint32_t *) &(data[0x12])); const uint32_t height = __builtin_bswap32(*(uint32_t *) &(data[0x16])); if (dataPos == 0) { dataPos = 54; } data += dataPos; // TODO flip image since bitmaps are stored upside down for (uint32_t yy = y; yy < y + target_height; yy++) { for (uint32_t xx = x; xx < x + target_width; xx++) { uint32_t i = (((xx - x) * width / target_width) + ((yy - y) * height / target_height) * width) * 3; drawPixel(xx, yy, data[i + 2], data[i + 1], data[i], 0xFF); } } } static void png_read_data(png_structp png_ptr, png_bytep outBytes, png_size_t byteCountToRead) { void **data = static_cast(png_get_io_ptr(png_ptr)); memcpy(outBytes, *data, byteCountToRead); *reinterpret_cast(data) += byteCountToRead; } void DrawUtils::drawPNG(const uint32_t x, const uint32_t y, const uint8_t *data) { png_structp png_ptr = png_create_read_struct(PNG_LIBPNG_VER_STRING, nullptr, nullptr, nullptr); if (png_ptr == nullptr) { return; } png_infop info_ptr = png_create_info_struct(png_ptr); if (info_ptr == nullptr) { png_destroy_read_struct(&png_ptr, nullptr, nullptr); return; } png_set_read_fn(png_ptr, (void *) &data, png_read_data); png_read_info(png_ptr, info_ptr); uint32_t width = 0; uint32_t height = 0; int bitDepth = 0; int colorType = -1; const uint32_t retval = png_get_IHDR(png_ptr, info_ptr, &width, &height, &bitDepth, &colorType, nullptr, nullptr, nullptr); if (retval != 1) { return; } const uint32_t bytesPerRow = png_get_rowbytes(png_ptr, info_ptr); auto *rowData = new uint8_t[bytesPerRow]; for (uint32_t yy = y; yy < y + height; yy++) { png_read_row(png_ptr, (png_bytep) rowData, nullptr); for (uint32_t xx = x; xx < x + width; xx++) { if (colorType == PNG_COLOR_TYPE_RGB_ALPHA) { uint32_t i = (xx - x) * 4; drawPixel(xx, yy, rowData[i], rowData[i + 1], rowData[i + 2], rowData[i + 3]); } else if (colorType == PNG_COLOR_TYPE_RGB) { uint32_t i = (xx - x) * 3; drawPixel(xx, yy, rowData[i], rowData[i + 1], rowData[i + 2], 0xFF); } } } delete[] rowData; png_destroy_read_struct(&png_ptr, &info_ptr, nullptr); } bool DrawUtils::initFont() { void *font = nullptr; uint32_t size = 0; OSGetSharedData(OS_SHAREDDATATYPE_FONT_STANDARD, 0, &font, &size); if (font && size) { pFont.xScale = 20; pFont.yScale = 20, pFont.flags = SFT_DOWNWARD_Y; pFont.font = sft_loadmem(font, size); if (!pFont.font) { return false; } OSMemoryBarrier(); return true; } return false; } void DrawUtils::deinitFont() { sft_freefont(pFont.font); pFont.font = nullptr; pFont = {}; } void DrawUtils::setFontSize(uint32_t size) { pFont.xScale = size; pFont.yScale = size; SFT_LMetrics metrics; sft_lmetrics(&pFont, &metrics); } void DrawUtils::setFontColor(const Color col) { font_col = col; } static void draw_freetype_bitmap(const SFT_Image *bmp, const int32_t x, const int32_t y) { int32_t i, j, p, q; int32_t x_max = x + bmp->width; int32_t y_max = y + bmp->height; const auto *src = static_cast(bmp->pixels); for (i = x, p = 0; i < x_max; i++, p++) { for (j = y, q = 0; j < y_max; j++, q++) { if (i < 0 || j < 0 || i >= SCREEN_WIDTH || j >= SCREEN_HEIGHT) { continue; } const float opacity = src[q * bmp->width + p] / 255.0f; DrawUtils::drawPixel(i, j, font_col.r, font_col.g, font_col.b, font_col.a * opacity); } } } void DrawUtils::print(const uint32_t x, const uint32_t y, const char *string, const bool alignRight) { auto *buffer = new wchar_t[strlen(string) + 1]; size_t num = mbstowcs(buffer, string, strlen(string)); if (num > 0) { buffer[num] = 0; } else { wchar_t *tmp = buffer; while ((*tmp++ = *string++)) ; } print(x, y, buffer, alignRight); delete[] buffer; } void DrawUtils::print(const uint32_t x, const uint32_t y, const wchar_t *string, const bool alignRight) { auto penX = static_cast(x); auto penY = static_cast(y); if (alignRight) { penX -= getTextWidth(string); } uint16_t textureWidth = 0, textureHeight = 0; for (; *string; string++) { SFT_Glyph gid; // unsigned long gid; if (sft_lookup(&pFont, *string, &gid) >= 0) { SFT_GMetrics mtx; if (sft_gmetrics(&pFont, gid, &mtx) < 0) { DEBUG_FUNCTION_LINE_ERR("Failed to get glyph metrics"); return; } if (*string == '\n') { penY += mtx.minHeight; penX = x; continue; } textureWidth = (mtx.minWidth + 3) & ~3; textureHeight = mtx.minHeight; if (textureWidth == 0) { textureWidth = 4; } if (textureHeight == 0) { textureHeight = 4; } SFT_Image img = { .pixels = nullptr, .width = textureWidth, .height = textureHeight, }; auto buffer = make_unique_nothrow((uint32_t) (img.width * img.height)); if (!buffer) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate memory for glyph"); return; } img.pixels = buffer.get(); if (sft_render(&pFont, gid, img) < 0) { DEBUG_FUNCTION_LINE_ERR("Failed to render glyph"); return; } else { draw_freetype_bitmap(&img, static_cast(penX + mtx.leftSideBearing), penY + mtx.yOffset); penX += static_cast(mtx.advanceWidth); } } } } uint32_t DrawUtils::getTextWidth(const char *string) { auto *buffer = new wchar_t[strlen(string) + 1]; if (const size_t num = mbstowcs(buffer, string, strlen(string)); num > 0) { buffer[num] = 0; } else { wchar_t *tmp = buffer; while ((*tmp++ = *string++)) ; } const uint32_t width = getTextWidth(buffer); delete[] buffer; return width; } uint32_t DrawUtils::getTextWidth(const wchar_t *string) { uint32_t width = 0; for (; *string; string++) { SFT_Glyph gid; // unsigned long gid; if (sft_lookup(&pFont, *string, &gid) >= 0) { SFT_GMetrics mtx; if (sft_gmetrics(&pFont, gid, &mtx) < 0) { DEBUG_FUNCTION_LINE_ERR("bad glyph metrics"); } width += static_cast(mtx.advanceWidth); } } return width; }