#include #include #include #include #include #include #include #include #include #include #include "c_utils.h" #include "image.h" jclass jclass_NullPointerException; jclass jclass_RuntimeException; jclass jclass_Options; jfieldID jclass_Options_inJustDecodeBounds; jfieldID jclass_Options_outHeight; jfieldID jclass_Options_outWidth; const uint32_t PGPhotoEnhanceHistogramBins = 256; const uint32_t PGPhotoEnhanceSegments = 4; jclass createGlobarRef(JNIEnv *env, jclass class) { if (class) { return (*env)->NewGlobalRef(env, class); } return 0; } jint imageOnJNILoad(JavaVM *vm, JNIEnv *env) { jclass_NullPointerException = createGlobarRef(env, (*env)->FindClass(env, "java/lang/NullPointerException")); if (jclass_NullPointerException == 0) { return JNI_FALSE; } jclass_RuntimeException = createGlobarRef(env, (*env)->FindClass(env, "java/lang/RuntimeException")); if (jclass_RuntimeException == 0) { return JNI_FALSE; } jclass_Options = createGlobarRef(env, (*env)->FindClass(env, "android/graphics/BitmapFactory$Options")); if (jclass_Options == 0) { return JNI_FALSE; } jclass_Options_inJustDecodeBounds = (*env)->GetFieldID(env, jclass_Options, "inJustDecodeBounds", "Z"); if (jclass_Options_inJustDecodeBounds == 0) { return JNI_FALSE; } jclass_Options_outHeight = (*env)->GetFieldID(env, jclass_Options, "outHeight", "I"); if (jclass_Options_outHeight == 0) { return JNI_FALSE; } jclass_Options_outWidth = (*env)->GetFieldID(env, jclass_Options, "outWidth", "I"); if (jclass_Options_outWidth == 0) { return JNI_FALSE; } return JNI_TRUE; } static inline uint64_t getColors(const uint8_t *p) { return p[0] + (p[1] << 16) + ((uint64_t) p[2] << 32) + ((uint64_t) p[3] << 48); } static inline uint64_t getColors565(const uint8_t *p) { uint16_t *ps = (uint16_t *) p; return ((((ps[0] & 0xF800) >> 11) * 255) / 31) + (((((ps[0] & 0x07E0) >> 5) * 255) / 63) << 16) + ((uint64_t) (((ps[0] & 0x001F) * 255) / 31) << 32); } static void fastBlurMore(int32_t w, int32_t h, int32_t stride, uint8_t *pix, int32_t radius) { const int32_t r1 = radius + 1; const int32_t div = radius * 2 + 1; if (radius > 15 || div >= w || div >= h || w * h > 150 * 150 || stride > w * 4) { return; } uint64_t *rgb = malloc(w * h * sizeof(uint64_t)); if (rgb == NULL) { return; } int32_t x, y, i; int32_t yw = 0; const int32_t we = w - r1; for (y = 0; y < h; y++) { uint64_t cur = getColors(&pix[yw]); uint64_t rgballsum = -radius * cur; uint64_t rgbsum = cur * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { cur = getColors(&pix[yw + i * 4]); rgbsum += cur * (r1 - i); rgballsum += cur; } x = 0; #define update(start, middle, end) \ rgb[y * w + x] = (rgbsum >> 6) & 0x00FF00FF00FF00FF; \ rgballsum += getColors(&pix[yw + (start) * 4]) - 2 * getColors(&pix[yw + (middle) * 4]) + getColors(&pix[yw + (end) * 4]); \ rgbsum += rgballsum; \ x++; \ while (x < r1) { update (0, x, x + r1); } while (x < we) { update (x - r1, x, x + r1); } while (x < w) { update (x - r1, x, w - 1); } #undef update yw += stride; } const int32_t he = h - r1; for (x = 0; x < w; x++) { uint64_t rgballsum = -radius * rgb[x]; uint64_t rgbsum = rgb[x] * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { rgbsum += rgb[i * w + x] * (r1 - i); rgballsum += rgb[i * w + x]; } y = 0; int32_t yi = x * 4; #define update(start, middle, end) \ int64_t res = rgbsum >> 6; \ pix[yi] = res; \ pix[yi + 1] = res >> 16; \ pix[yi + 2] = res >> 32; \ pix[yi + 3] = res >> 48; \ rgballsum += rgb[x + (start) * w] - 2 * rgb[x + (middle) * w] + rgb[x + (end) * w]; \ rgbsum += rgballsum; \ y++; \ yi += stride; while (y < r1) { update (0, y, y + r1); } while (y < he) { update (y - r1, y, y + r1); } while (y < h) { update (y - r1, y, h - 1); } #undef update } } static void fastBlur(int32_t w, int32_t h, int32_t stride, uint8_t *pix, int32_t radius) { if (pix == NULL) { return; } const int32_t r1 = radius + 1; const int32_t div = radius * 2 + 1; int32_t shift; if (radius == 1) { shift = 2; } else if (radius == 3) { shift = 4; } else if (radius == 7) { shift = 6; } else if (radius == 15) { shift = 8; } else { return; } if (radius > 15 || div >= w || div >= h || w * h > 150 * 150 || stride > w * 4) { return; } uint64_t *rgb = malloc(w * h * sizeof(uint64_t)); if (rgb == NULL) { return; } int32_t x, y, i; int32_t yw = 0; const int32_t we = w - r1; for (y = 0; y < h; y++) { uint64_t cur = getColors(&pix[yw]); uint64_t rgballsum = -radius * cur; uint64_t rgbsum = cur * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { cur = getColors(&pix[yw + i * 4]); rgbsum += cur * (r1 - i); rgballsum += cur; } x = 0; #define update(start, middle, end) \ rgb[y * w + x] = (rgbsum >> shift) & 0x00FF00FF00FF00FFLL; \ rgballsum += getColors(&pix[yw + (start) * 4]) - 2 * getColors(&pix[yw + (middle) * 4]) + getColors(&pix[yw + (end) * 4]); \ rgbsum += rgballsum; \ x++; \ while (x < r1) { update (0, x, x + r1); } while (x < we) { update (x - r1, x, x + r1); } while (x < w) { update (x - r1, x, w - 1); } #undef update yw += stride; } const int32_t he = h - r1; for (x = 0; x < w; x++) { uint64_t rgballsum = -radius * rgb[x]; uint64_t rgbsum = rgb[x] * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { rgbsum += rgb[i * w + x] * (r1 - i); rgballsum += rgb[i * w + x]; } y = 0; int32_t yi = x * 4; #define update(start, middle, end) \ int64_t res = rgbsum >> shift; \ pix[yi] = res; \ pix[yi + 1] = res >> 16; \ pix[yi + 2] = res >> 32; \ pix[yi + 3] = res >> 48; \ rgballsum += rgb[x + (start) * w] - 2 * rgb[x + (middle) * w] + rgb[x + (end) * w]; \ rgbsum += rgballsum; \ y++; \ yi += stride; while (y < r1) { update (0, y, y + r1); } while (y < he) { update (y - r1, y, y + r1); } while (y < h) { update (y - r1, y, h - 1); } #undef update } free(rgb); } static void fastBlurMore565(int32_t w, int32_t h, int32_t stride, uint8_t *pix, int32_t radius) { const int32_t r1 = radius + 1; const int32_t div = radius * 2 + 1; if (radius > 15 || div >= w || div >= h || w * h > 150 * 150 || stride > w * 2) { return; } uint64_t *rgb = malloc(w * h * sizeof(uint64_t)); if (rgb == NULL) { return; } int32_t x, y, i; int32_t yw = 0; const int32_t we = w - r1; for (y = 0; y < h; y++) { uint64_t cur = getColors565(&pix[yw]); uint64_t rgballsum = -radius * cur; uint64_t rgbsum = cur * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { cur = getColors565(&pix[yw + i * 2]); rgbsum += cur * (r1 - i); rgballsum += cur; } x = 0; #define update(start, middle, end) \ rgb[y * w + x] = (rgbsum >> 6) & 0x00FF00FF00FF00FF; \ rgballsum += getColors565(&pix[yw + (start) * 2]) - 2 * getColors565(&pix[yw + (middle) * 2]) + getColors565(&pix[yw + (end) * 2]); \ rgbsum += rgballsum; \ x++; \ while (x < r1) { update (0, x, x + r1); } while (x < we) { update (x - r1, x, x + r1); } while (x < w) { update (x - r1, x, w - 1); } #undef update yw += stride; } const int32_t he = h - r1; for (x = 0; x < w; x++) { uint64_t rgballsum = -radius * rgb[x]; uint64_t rgbsum = rgb[x] * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { rgbsum += rgb[i * w + x] * (r1 - i); rgballsum += rgb[i * w + x]; } y = 0; int32_t yi = x * 2; #define update(start, middle, end) \ int64_t res = rgbsum >> 6; \ pix[yi] = ((res >> 13) & 0xe0) | ((res >> 35) & 0x1f); \ pix[yi + 1] = (res & 0xf8) | ((res >> 21) & 0x7); \ rgballsum += rgb[x + (start) * w] - 2 * rgb[x + (middle) * w] + rgb[x + (end) * w]; \ rgbsum += rgballsum; \ y++; \ yi += stride; while (y < r1) { update (0, y, y + r1); } while (y < he) { update (y - r1, y, y + r1); } while (y < h) { update (y - r1, y, h - 1); } #undef update } } static void fastBlur565(int32_t w, int32_t h, int32_t stride, uint8_t *pix, int32_t radius) { if (pix == NULL) { return; } const int32_t r1 = radius + 1; const int32_t div = radius * 2 + 1; int32_t shift; if (radius == 1) { shift = 2; } else if (radius == 3) { shift = 4; } else if (radius == 7) { shift = 6; } else if (radius == 15) { shift = 8; } else { return; } if (radius > 15 || div >= w || div >= h || w * h > 150 * 150 || stride > w * 2) { return; } uint64_t *rgb = malloc(w * h * sizeof(uint64_t)); if (rgb == NULL) { return; } int32_t x, y, i; int32_t yw = 0; const int32_t we = w - r1; for (y = 0; y < h; y++) { uint64_t cur = getColors565(&pix[yw]); uint64_t rgballsum = -radius * cur; uint64_t rgbsum = cur * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { cur = getColors565(&pix[yw + i * 2]); rgbsum += cur * (r1 - i); rgballsum += cur; } x = 0; #define update(start, middle, end) \ rgb[y * w + x] = (rgbsum >> shift) & 0x00FF00FF00FF00FFLL; \ rgballsum += getColors565(&pix[yw + (start) * 2]) - 2 * getColors565(&pix[yw + (middle) * 2]) + getColors565(&pix[yw + (end) * 2]); \ rgbsum += rgballsum; \ x++; while (x < r1) { update(0, x, x + r1); } while (x < we) { update(x - r1, x, x + r1); } while (x < w) { update(x - r1, x, w - 1); } #undef update yw += stride; } const int32_t he = h - r1; for (x = 0; x < w; x++) { uint64_t rgballsum = -radius * rgb[x]; uint64_t rgbsum = rgb[x] * ((r1 * (r1 + 1)) >> 1); for (i = 1; i <= radius; i++) { rgbsum += rgb[i * w + x] * (r1 - i); rgballsum += rgb[i * w + x]; } y = 0; int32_t yi = x * 2; #define update(start, middle, end) \ uint64_t res = rgbsum >> shift; \ pix[yi] = ((res >> 13) & 0xe0) | ((res >> 35) & 0x1f); \ pix[yi + 1] = (res & 0xf8) | ((res >> 21) & 0x7); \ rgballsum += rgb[x + (start) * w] - 2 * rgb[x + (middle) * w] + rgb[x + (end) * w]; \ rgbsum += rgballsum; \ y++; \ yi += stride; while (y < r1) { update (0, y, y + r1); } while (y < he) { update (y - r1, y, y + r1); } while (y < h) { update (y - r1, y, h - 1); } #undef update } free(rgb); } JNIEXPORT int Java_org_telegram_messenger_Utilities_needInvert(JNIEnv *env, jclass class, jobject bitmap, jint unpin, jint width, jint height, jint stride) { if (!bitmap) { return 0; } if (!width || !height || !stride || stride != width * 4 || width * height > 150 * 150) { return 0; } void *pixels = 0; if (AndroidBitmap_lockPixels(env, bitmap, &pixels) < 0) { return 0; } if (pixels == NULL) { return 0; } uint8_t *pix = (uint8_t *) pixels; int32_t hasAlpha = 0; float matching = 0; float total = 0; for (int32_t y = 0; y < height; y++) { for (int32_t x = 0; x < width; x++) { int32_t index = y * stride + x * 4; uint8_t a = pix[index + 3]; float alpha = a / 255.0f; uint8_t r = (uint8_t) (pix[index] * alpha); uint8_t g = (uint8_t) (pix[index + 1] * alpha); uint8_t b = (uint8_t) (pix[index + 2] * alpha); uint8_t cmax = (r > g) ? r : g; if (b > cmax) { cmax = b; } uint8_t cmin = (r < g) ? r : g; if (b < cmin) { cmin = b; } float saturation; float brightness = ((float) cmax) / 255.0f; if (cmax != 0) { saturation = ((float) (cmax - cmin)) / ((float) cmax); } else { saturation = 0; } if (alpha < 1.0) { hasAlpha = 1; } if (alpha > 0.0) { total += 1; if (saturation < 0.1f && brightness < 0.25f) { matching += 1; } } } } if (unpin) { AndroidBitmap_unlockPixels(env, bitmap); } return hasAlpha && matching / total > 0.85; } JNIEXPORT void Java_org_telegram_messenger_Utilities_blurBitmap(JNIEnv *env, jclass class, jobject bitmap, jint radius, jint unpin, jint width, jint height, jint stride) { if (!bitmap) { return; } if (!width || !height || !stride) { return; } void *pixels = 0; if (AndroidBitmap_lockPixels(env, bitmap, &pixels) < 0) { return; } if (stride == width * 2) { if (radius <= 3) { fastBlur565(width, height, stride, pixels, radius); } else { fastBlurMore565(width, height, stride, pixels, radius); } } else { if (radius <= 3) { fastBlur(width, height, stride, pixels, radius); } else { fastBlurMore(width, height, stride, pixels, radius); } } if (unpin) { AndroidBitmap_unlockPixels(env, bitmap); } } JNIEXPORT void Java_org_telegram_messenger_Utilities_calcCDT(JNIEnv *env, jclass class, jobject hsvBuffer, jint width, jint height, jobject buffer) { float imageWidth = width; float imageHeight = height; float _clipLimit = 1.25f; uint32_t totalSegments = PGPhotoEnhanceSegments * PGPhotoEnhanceSegments; uint32_t tileArea = (uint32_t) (floorf(imageWidth / PGPhotoEnhanceSegments) * floorf(imageHeight / PGPhotoEnhanceSegments)); uint32_t clipLimit = (uint32_t) MAX(1, _clipLimit * tileArea / (float) PGPhotoEnhanceHistogramBins); float scale = 255.0f / (float) tileArea; unsigned char *bytes = (*env)->GetDirectBufferAddress(env, hsvBuffer); uint32_t **hist = calloc(totalSegments, sizeof(uint32_t *)); uint32_t **cdfs = calloc(totalSegments, sizeof(uint32_t *)); uint32_t *cdfsMin = calloc(totalSegments, sizeof(uint32_t)); uint32_t *cdfsMax = calloc(totalSegments, sizeof(uint32_t)); for (uint32_t a = 0; a < totalSegments; a++) { hist[a] = calloc(PGPhotoEnhanceHistogramBins, sizeof(uint32_t)); cdfs[a] = calloc(PGPhotoEnhanceHistogramBins, sizeof(uint32_t)); } float xMul = PGPhotoEnhanceSegments / imageWidth; float yMul = PGPhotoEnhanceSegments / imageHeight; for (uint32_t y = 0; y < imageHeight; y++) { uint32_t yOffset = y * width * 4; for (uint32_t x = 0; x < imageWidth; x++) { uint32_t index = x * 4 + yOffset; uint32_t tx = (uint32_t)(x * xMul); uint32_t ty = (uint32_t)(y * yMul); uint32_t t = ty * PGPhotoEnhanceSegments + tx; hist[t][bytes[index + 2]]++; } } for (uint32_t i = 0; i < totalSegments; i++) { if (clipLimit > 0) { uint32_t clipped = 0; for (uint32_t j = 0; j < PGPhotoEnhanceHistogramBins; ++j) { if (hist[i][j] > clipLimit) { clipped += hist[i][j] - clipLimit; hist[i][j] = clipLimit; } } uint32_t redistBatch = clipped / PGPhotoEnhanceHistogramBins; uint32_t residual = clipped - redistBatch * PGPhotoEnhanceHistogramBins; for (uint32_t j = 0; j < PGPhotoEnhanceHistogramBins; ++j) { hist[i][j] += redistBatch; } for (uint32_t j = 0; j < residual; ++j) { hist[i][j]++; } } memcpy(cdfs[i], hist[i], PGPhotoEnhanceHistogramBins * sizeof(uint32_t)); uint32_t hMin = PGPhotoEnhanceHistogramBins - 1; for (uint32_t j = 0; j < hMin; ++j) { if (cdfs[j] != 0) { hMin = j; } } uint32_t cdf = 0; for (uint32_t j = hMin; j < PGPhotoEnhanceHistogramBins; ++j) { cdf += cdfs[i][j]; cdfs[i][j] = (uint8_t) MIN(255, cdf * scale); } cdfsMin[i] = cdfs[i][hMin]; cdfsMax[i] = cdfs[i][PGPhotoEnhanceHistogramBins - 1]; } uint32_t resultSize = 4 * PGPhotoEnhanceHistogramBins * totalSegments; uint32_t resultBytesPerRow = 4 * PGPhotoEnhanceHistogramBins; unsigned char *result = (*env)->GetDirectBufferAddress(env, buffer); for (uint32_t tile = 0; tile < totalSegments; tile++) { uint32_t yOffset = tile * resultBytesPerRow; for (uint32_t i = 0; i < PGPhotoEnhanceHistogramBins; i++) { uint32_t index = i * 4 + yOffset; result[index] = (uint8_t)cdfs[tile][i]; result[index + 1] = (uint8_t)cdfsMin[tile]; result[index + 2] = (uint8_t)cdfsMax[tile]; result[index + 3] = 255; } } for (uint32_t a = 0; a < totalSegments; a++) { free(hist[a]); free(cdfs[a]); } free(hist); free(cdfs); free(cdfsMax); free(cdfsMin); } JNIEXPORT jint Java_org_telegram_messenger_Utilities_pinBitmap(JNIEnv *env, jclass class, jobject bitmap) { if (bitmap == NULL) { return 0; } unsigned char *pixels; return AndroidBitmap_lockPixels(env, bitmap, &pixels) >= 0 ? 1 : 0; } JNIEXPORT void Java_org_telegram_messenger_Utilities_unpinBitmap(JNIEnv *env, jclass class, jobject bitmap) { if (bitmap == NULL) { return; } AndroidBitmap_unlockPixels(env, bitmap); } JNIEXPORT jboolean Java_org_telegram_messenger_Utilities_loadWebpImage(JNIEnv *env, jclass class, jobject outputBitmap, jobject buffer, jint len, jobject options, jboolean unpin) { if (!buffer) { (*env)->ThrowNew(env, jclass_NullPointerException, "Input buffer can not be null"); return 0; } jbyte *inputBuffer = (*env)->GetDirectBufferAddress(env, buffer); int32_t bitmapWidth = 0; int32_t bitmapHeight = 0; if (!WebPGetInfo((uint8_t*)inputBuffer, len, &bitmapWidth, &bitmapHeight)) { (*env)->ThrowNew(env, jclass_RuntimeException, "Invalid WebP format"); return 0; } if (options && (*env)->GetBooleanField(env, options, jclass_Options_inJustDecodeBounds) == JNI_TRUE) { (*env)->SetIntField(env, options, jclass_Options_outWidth, bitmapWidth); (*env)->SetIntField(env, options, jclass_Options_outHeight, bitmapHeight); return 1; } if (!outputBitmap) { (*env)->ThrowNew(env, jclass_NullPointerException, "output bitmap can not be null"); return 0; } AndroidBitmapInfo bitmapInfo; if (AndroidBitmap_getInfo(env, outputBitmap, &bitmapInfo) != ANDROID_BITMAP_RESUT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "Failed to get Bitmap information"); return 0; } void *bitmapPixels = 0; if (AndroidBitmap_lockPixels(env, outputBitmap, &bitmapPixels) != ANDROID_BITMAP_RESUT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "Failed to lock Bitmap pixels"); return 0; } if (!WebPDecodeRGBAInto((uint8_t*)inputBuffer, len, (uint8_t*)bitmapPixels, bitmapInfo.height * bitmapInfo.stride, bitmapInfo.stride)) { AndroidBitmap_unlockPixels(env, outputBitmap); (*env)->ThrowNew(env, jclass_RuntimeException, "Failed to decode webp image"); return 0; } if (unpin && AndroidBitmap_unlockPixels(env, outputBitmap) != ANDROID_BITMAP_RESUT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "Failed to unlock Bitmap pixels"); return 0; } return 1; } #define SQUARE(i) ((i)*(i)) inline static void zeroClearInt(int* p, size_t count) { memset(p, 0, sizeof(int) * count); } JNIEXPORT void Java_org_telegram_messenger_Utilities_stackBlurBitmap(JNIEnv* env, jclass class, jobject bitmap, jint radius) { if (radius < 1) return; AndroidBitmapInfo info; if (AndroidBitmap_getInfo(env, bitmap, &info) != ANDROID_BITMAP_RESULT_SUCCESS) return; if (info.format != ANDROID_BITMAP_FORMAT_RGBA_8888) return; int w = info.width; int h = info.height; int stride = info.stride; unsigned char *pixels = 0; AndroidBitmap_lockPixels(env, bitmap, (void **) &pixels); if (!pixels) { return; } // Constants //const int radius = (int)inradius; // Transform unsigned into signed for further operations const int wm = w - 1; const int hm = h - 1; const int wh = w * h; const int div = radius + radius + 1; const int r1 = radius + 1; const int divsum = SQUARE((div + 1) >> 1); // Small buffers int stack[div * 3]; zeroClearInt(stack, div * 3); int vmin[MAX(w, h)]; zeroClearInt(vmin, MAX(w, h)); // Large buffers int *r = malloc(wh * sizeof(int)); int *g = malloc(wh * sizeof(int)); int *b = malloc(wh * sizeof(int)); zeroClearInt(r, wh); zeroClearInt(g, wh); zeroClearInt(b, wh); const size_t dvcount = 256 * divsum; int *dv = malloc(sizeof(int) * dvcount); int i; for (i = 0; (size_t) i < dvcount; i++) { dv[i] = (i / divsum); } // Variables int x, y; int *sir; int routsum, goutsum, boutsum; int rinsum, ginsum, binsum; int rsum, gsum, bsum, p, yp; int stackpointer; int stackstart; int rbs; int yw = 0, yi = 0; for (y = 0; y < h; y++) { rinsum = ginsum = binsum = routsum = goutsum = boutsum = rsum = gsum = bsum = 0; for (i = -radius; i <= radius; i++) { sir = &stack[(i + radius) * 3]; int offset = (y * stride + (MIN(wm, MAX(i, 0))) * 4); sir[0] = pixels[offset]; sir[1] = pixels[offset + 1]; sir[2] = pixels[offset + 2]; rbs = r1 - abs(i); rsum += sir[0] * rbs; gsum += sir[1] * rbs; bsum += sir[2] * rbs; if (i > 0) { rinsum += sir[0]; ginsum += sir[1]; binsum += sir[2]; } else { routsum += sir[0]; goutsum += sir[1]; boutsum += sir[2]; } } stackpointer = radius; for (x = 0; x < w; x++) { r[yi] = dv[rsum]; g[yi] = dv[gsum]; b[yi] = dv[bsum]; rsum -= routsum; gsum -= goutsum; bsum -= boutsum; stackstart = stackpointer - radius + div; sir = &stack[(stackstart % div) * 3]; routsum -= sir[0]; goutsum -= sir[1]; boutsum -= sir[2]; if (y == 0) { vmin[x] = MIN(x + radius + 1, wm); } int offset = (y * stride + vmin[x] * 4); sir[0] = pixels[offset]; sir[1] = pixels[offset + 1]; sir[2] = pixels[offset + 2]; rinsum += sir[0]; ginsum += sir[1]; binsum += sir[2]; rsum += rinsum; gsum += ginsum; bsum += binsum; stackpointer = (stackpointer + 1) % div; sir = &stack[(stackpointer % div) * 3]; routsum += sir[0]; goutsum += sir[1]; boutsum += sir[2]; rinsum -= sir[0]; ginsum -= sir[1]; binsum -= sir[2]; yi++; } yw += w; } for (x = 0; x < w; x++) { rinsum = ginsum = binsum = routsum = goutsum = boutsum = rsum = gsum = bsum = 0; yp = -radius * w; for (i = -radius; i <= radius; i++) { yi = MAX(0, yp) + x; sir = &stack[(i + radius) * 3]; sir[0] = r[yi]; sir[1] = g[yi]; sir[2] = b[yi]; rbs = r1 - abs(i); rsum += r[yi] * rbs; gsum += g[yi] * rbs; bsum += b[yi] * rbs; if (i > 0) { rinsum += sir[0]; ginsum += sir[1]; binsum += sir[2]; } else { routsum += sir[0]; goutsum += sir[1]; boutsum += sir[2]; } if (i < hm) { yp += w; } } stackpointer = radius; for (y = 0; y < h; y++) { int offset = stride * y + x * 4; pixels[offset] = dv[rsum]; pixels[offset + 1] = dv[gsum]; pixels[offset + 2] = dv[bsum]; rsum -= routsum; gsum -= goutsum; bsum -= boutsum; stackstart = stackpointer - radius + div; sir = &stack[(stackstart % div) * 3]; routsum -= sir[0]; goutsum -= sir[1]; boutsum -= sir[2]; if (x == 0) { vmin[y] = (MIN(y + r1, hm)) * w; } p = x + vmin[y]; sir[0] = r[p]; sir[1] = g[p]; sir[2] = b[p]; rinsum += sir[0]; ginsum += sir[1]; binsum += sir[2]; rsum += rinsum; gsum += ginsum; bsum += binsum; stackpointer = (stackpointer + 1) % div; sir = &stack[stackpointer * 3]; routsum += sir[0]; goutsum += sir[1]; boutsum += sir[2]; rinsum -= sir[0]; ginsum -= sir[1]; binsum -= sir[2]; yi += w; } } free(r); free(g); free(b); free(dv); AndroidBitmap_unlockPixels(env, bitmap); } JNIEXPORT void Java_org_telegram_messenger_Utilities_drawDitheredGradient(JNIEnv* env, jclass class, jobject bitmap, jintArray colors, jint startX, jint startY, jint endX, jint endY) { AndroidBitmapInfo info; void* pixelsBuffer; int reason; if ((reason = AndroidBitmap_getInfo(env, bitmap, &info)) != ANDROID_BITMAP_RESULT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "AndroidBitmap_getInfo failed with a reason: " + reason); return; } if (info.format != ANDROID_BITMAP_FORMAT_RGBA_8888) { (*env)->ThrowNew(env, jclass_RuntimeException, "Bitmap must be in ARGB_8888 format"); return; } if ((reason = AndroidBitmap_lockPixels(env, bitmap, &pixelsBuffer)) != ANDROID_BITMAP_RESULT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "AndroidBitmap_lockPixels failed with a reason: " + reason); return; } uint8_t i, j, n; // gradient colors extracting jint *colorsBuffer = (*env)->GetIntArrayElements(env, colors, 0); uint8_t *colorsComponents = (uint8_t *) colorsBuffer; float colorsF[4][2]; for (i = 0; i < 4; i++) { // swap red and green channels n = (uint8_t) (i == 0 ? 2 : (i == 2 ? 0 : i)); for (j = 0; j < 2; j++) { colorsF[n][j] = colorsComponents[j * 4 + i] / 255.F; } } (*env)->ReleaseIntArrayElements(env, colors, colorsBuffer, JNI_ABORT); // gradient vector const int32_t vx = endX - startX; const int32_t vy = endY - startY; const float vSquaredMag = vx * vx + vy * vy; float noise, fraction, error, componentF; float *pixelsComponentsF = malloc(info.height * info.stride * 4 * sizeof(float)); memset(pixelsComponentsF, 0, info.height * info.stride * 4 * sizeof(float)); uint8_t *bitmapPixelsComponents = (uint8_t *) pixelsBuffer; int32_t x, y; int32_t offset; int32_t position; for (y = 0; y < info.height; y++) { offset = y * info.stride; for (x = 0; x < info.width; x++) { // triangular probability density function dither noise noise = (rand() - rand()) / 255.F / RAND_MAX; // alpha channel bitmapPixelsComponents[offset + x * 4 + 3] = 255; for (i = 0; i < 3; i++) { position = offset + x * 4 + i; fraction = (vx * (x - startX) + vy * (y - startY)) / vSquaredMag; // gradient interpolation and noise pixelsComponentsF[position] += colorsF[i][0] + fraction * (colorsF[i][1] - colorsF[i][0]) + noise; // clamp if (pixelsComponentsF[position] > 1.F) { pixelsComponentsF[position] = 1.F; } else if (pixelsComponentsF[position] < 0.F) { pixelsComponentsF[position] = 0.F; } // draw componentF = roundf(pixelsComponentsF[position] * 255.F); bitmapPixelsComponents[position] = (uint8_t) componentF; // floyd-steinberg dithering error = pixelsComponentsF[position] - componentF / 255.F; if (x + 1 < info.width) { pixelsComponentsF[position + 4] += error * 7.F / 16.F; if (y + 1 < info.height) { pixelsComponentsF[position + info.height + 4] += error * 1.F / 16.F; } } if (y + 1 < info.height) { pixelsComponentsF[position + info.height] += error * 5.F / 16.F; if (x - 1 >= 0) { pixelsComponentsF[position + info.height - 4] += error * 3.F / 16.F; } } } } } free(pixelsComponentsF); if ((reason = AndroidBitmap_unlockPixels(env, bitmap)) != ANDROID_BITMAP_RESULT_SUCCESS) { (*env)->ThrowNew(env, jclass_RuntimeException, "AndroidBitmap_unlockPixels failed with a reason: " + reason); return; } }