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Remove unused function ImageFind::ComputeRectangleColors
Fixes: a1c22fb0d0
("Fixed issue #557")
Signed-off-by: Stefan Weil <sw@weilnetz.de>
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@ -46,10 +46,6 @@ const double kMaxRectangularFraction = 0.75;
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const double kMaxRectangularGradient = 0.1; // About 6 degrees.
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// Minimum image size to be worth looking for images on.
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const int kMinImageFindSize = 100;
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// Scale factor for the rms color fit error.
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const double kRMSFitScaling = 8.0;
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// Min color difference to call it two colors.
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const int kMinColorDifference = 16;
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// Pixel padding for noise blobs and partitions when rendering on the image
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// mask to encourage them to join together. Make it too big and images
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// will fatten out too much and have to be clipped to text.
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@ -417,131 +413,6 @@ uint8_t ImageFind::ClipToByte(double pixel) {
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return static_cast<uint8_t>(pixel);
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}
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// Computes the light and dark extremes of color in the given rectangle of
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// the given pix, which is factor smaller than the coordinate system in rect.
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// The light and dark points are taken to be the upper and lower 8th-ile of
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// the most deviant of R, G and B. The value of the other 2 channels are
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// computed by linear fit against the most deviant.
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// The colors of the two points are returned in color1 and color2, with the
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// alpha channel set to a scaled mean rms of the fits.
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// If color_map1 is not null then it and color_map2 get rect pasted in them
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// with the two calculated colors, and rms map gets a pasted rect of the rms.
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// color_map1, color_map2 and rms_map are assumed to be the same scale as pix.
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void ImageFind::ComputeRectangleColors(const TBOX &rect, Image pix, int factor, Image color_map1,
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Image color_map2, Image rms_map, uint8_t *color1,
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uint8_t *color2) {
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ASSERT_HOST(pix != nullptr && pixGetDepth(pix) == 32);
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// Pad the rectangle outwards by 2 (scaled) pixels if possible to get more
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// background.
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int width = pixGetWidth(pix);
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int height = pixGetHeight(pix);
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int left_pad = std::max(rect.left() - 2 * factor, 0) / factor;
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int top_pad = (rect.top() + 2 * factor + (factor - 1)) / factor;
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top_pad = std::min(height, top_pad);
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int right_pad = (rect.right() + 2 * factor + (factor - 1)) / factor;
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right_pad = std::min(width, right_pad);
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int bottom_pad = std::max(rect.bottom() - 2 * factor, 0) / factor;
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int width_pad = right_pad - left_pad;
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int height_pad = top_pad - bottom_pad;
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if (width_pad < 1 || height_pad < 1 || width_pad + height_pad < 4) {
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return;
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}
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// Now crop the pix to the rectangle.
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Box *scaled_box = boxCreate(left_pad, height - top_pad, width_pad, height_pad);
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Image scaled = pixClipRectangle(pix, scaled_box, nullptr);
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// Compute stats over the whole image.
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STATS red_stats(0, 255);
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STATS green_stats(0, 255);
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STATS blue_stats(0, 255);
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uint32_t *data = pixGetData(scaled);
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ASSERT_HOST(pixGetWpl(scaled) == width_pad);
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for (int y = 0; y < height_pad; ++y) {
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for (int x = 0; x < width_pad; ++x, ++data) {
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int r = GET_DATA_BYTE(data, COLOR_RED);
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int g = GET_DATA_BYTE(data, COLOR_GREEN);
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int b = GET_DATA_BYTE(data, COLOR_BLUE);
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red_stats.add(r, 1);
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green_stats.add(g, 1);
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blue_stats.add(b, 1);
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}
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}
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// Find the RGB component with the greatest 8th-ile-range.
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// 8th-iles are used instead of quartiles to get closer to the true
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// foreground color, which is going to be faint at best because of the
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// pre-scaling of the input image.
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int best_l8 = static_cast<int>(red_stats.ile(0.125f));
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int best_u8 = static_cast<int>(ceil(red_stats.ile(0.875f)));
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int best_i8r = best_u8 - best_l8;
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int x_color = COLOR_RED;
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int y1_color = COLOR_GREEN;
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int y2_color = COLOR_BLUE;
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int l8 = static_cast<int>(green_stats.ile(0.125f));
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int u8 = static_cast<int>(ceil(green_stats.ile(0.875f)));
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if (u8 - l8 > best_i8r) {
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best_i8r = u8 - l8;
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best_l8 = l8;
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best_u8 = u8;
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x_color = COLOR_GREEN;
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y1_color = COLOR_RED;
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}
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l8 = static_cast<int>(blue_stats.ile(0.125f));
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u8 = static_cast<int>(ceil(blue_stats.ile(0.875f)));
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if (u8 - l8 > best_i8r) {
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best_i8r = u8 - l8;
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best_l8 = l8;
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best_u8 = u8;
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x_color = COLOR_BLUE;
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y1_color = COLOR_GREEN;
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y2_color = COLOR_RED;
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}
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if (best_i8r >= kMinColorDifference) {
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LLSQ line1;
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LLSQ line2;
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uint32_t *data = pixGetData(scaled);
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for (int im_y = 0; im_y < height_pad; ++im_y) {
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for (int im_x = 0; im_x < width_pad; ++im_x, ++data) {
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int x = GET_DATA_BYTE(data, x_color);
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int y1 = GET_DATA_BYTE(data, y1_color);
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int y2 = GET_DATA_BYTE(data, y2_color);
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line1.add(x, y1);
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line2.add(x, y2);
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}
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}
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double m1 = line1.m();
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double c1 = line1.c(m1);
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double m2 = line2.m();
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double c2 = line2.c(m2);
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double rms = line1.rms(m1, c1) + line2.rms(m2, c2);
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rms *= kRMSFitScaling;
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// Save the results.
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color1[x_color] = ClipToByte(best_l8);
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color1[y1_color] = ClipToByte(m1 * best_l8 + c1 + 0.5);
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color1[y2_color] = ClipToByte(m2 * best_l8 + c2 + 0.5);
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color1[L_ALPHA_CHANNEL] = ClipToByte(rms);
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color2[x_color] = ClipToByte(best_u8);
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color2[y1_color] = ClipToByte(m1 * best_u8 + c1 + 0.5);
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color2[y2_color] = ClipToByte(m2 * best_u8 + c2 + 0.5);
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color2[L_ALPHA_CHANNEL] = ClipToByte(rms);
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} else {
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// There is only one color.
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color1[COLOR_RED] = ClipToByte(red_stats.median());
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color1[COLOR_GREEN] = ClipToByte(green_stats.median());
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color1[COLOR_BLUE] = ClipToByte(blue_stats.median());
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color1[L_ALPHA_CHANNEL] = 0;
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memcpy(color2, color1, 4);
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}
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if (color_map1 != nullptr) {
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pixSetInRectArbitrary(color_map1, scaled_box,
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ComposeRGB(color1[COLOR_RED], color1[COLOR_GREEN], color1[COLOR_BLUE]));
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pixSetInRectArbitrary(color_map2, scaled_box,
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ComposeRGB(color2[COLOR_RED], color2[COLOR_GREEN], color2[COLOR_BLUE]));
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pixSetInRectArbitrary(rms_map, scaled_box, color1[L_ALPHA_CHANNEL]);
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}
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scaled.destroy();
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boxDestroy(&scaled_box);
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}
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// ================ CUTTING POLYGONAL IMAGES FROM A RECTANGLE ================
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// The following functions are responsible for cutting a polygonal image from
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// a rectangle: CountPixelsInRotatedBox, AttemptToShrinkBox, CutChunkFromParts
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@ -89,20 +89,6 @@ public:
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// Returns the input value clipped to a uint8_t.
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static uint8_t ClipToByte(double pixel);
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// Computes the light and dark extremes of color in the given rectangle of
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// the given pix, which is factor smaller than the coordinate system in rect.
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// The light and dark points are taken to be the upper and lower 8th-ile of
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// the most deviant of R, G and B. The value of the other 2 channels are
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// computed by linear fit against the most deviant.
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// The colors of the two point are returned in color1 and color2, with the
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// alpha channel set to a scaled mean rms of the fits.
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// If color_map1 is not null then it and color_map2 get rect pasted in them
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// with the two calculated colors, and rms map gets a pasted rect of the rms.
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// color_map1, color_map2 and rms_map are assumed to be the same scale as pix.
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static void ComputeRectangleColors(const TBOX &rect, Image pix, int factor, Image color_map1,
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Image color_map2, Image rms_map, uint8_t *color1,
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uint8_t *color2);
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// Returns true if there are no black pixels in between the boxes.
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// The im_box must represent the bounding box of the pix in tesseract
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// coordinates, which may be negative, due to rotations to make the textlines
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