/* * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef IMAGE_IMAGEOPS_H #define IMAGE_IMAGEOPS_H #include #include #include #include namespace image { // Concatenates images horizontally to create a filmstrip atlas, similar to numpy's hstack. UTILS_PUBLIC LinearImage horizontalStack(std::initializer_list images); UTILS_PUBLIC LinearImage horizontalStack(LinearImage const* img, size_t count); // Concatenates images vertically to create a filmstrip atlas, similar to numpy's vstack. UTILS_PUBLIC LinearImage verticalStack(std::initializer_list images); UTILS_PUBLIC LinearImage verticalStack(LinearImage const* img, size_t count); // Horizontally or vertically mirror the given image. UTILS_PUBLIC LinearImage horizontalFlip(const LinearImage& image); UTILS_PUBLIC LinearImage verticalFlip(const LinearImage& image); // Transforms normals (components live in [-1,+1]) into colors (components live in [0,+1]). UTILS_PUBLIC LinearImage vectorsToColors(const LinearImage& image); UTILS_PUBLIC LinearImage colorsToVectors(const LinearImage& image); // Creates a single-channel image by extracting the selected channel. UTILS_PUBLIC LinearImage extractChannel(const LinearImage& image, uint32_t channel); // Constructs a multi-channel image by copying data from a sequence of single-channel images. UTILS_PUBLIC LinearImage combineChannels(std::initializer_list images); UTILS_PUBLIC LinearImage combineChannels(LinearImage const* img, size_t count); // Generates a new image with rows & columns swapped. UTILS_PUBLIC LinearImage transpose(const LinearImage& image); // Extracts pixels by specifying a crop window where (0,0) is the top-left corner of the image. // The boundary is specified as Left Top Right Bottom. UTILS_PUBLIC LinearImage cropRegion(const LinearImage& image, uint32_t l, uint32_t t, uint32_t r, uint32_t b); // Lexicographically compares two images, similar to memcmp. UTILS_PUBLIC int compare(const LinearImage& a, const LinearImage& b, float epsilon = 0.0f); // Sets all pixels in all channels to the given value. UTILS_PUBLIC void clearToValue(LinearImage& img, float value); // Called by the coordinate field generator to query if a pixel is within the region of interest. using PresenceCallback = bool(*)(const LinearImage& img, uint32_t col, uint32_t row, void* user); // Generates a two-channel field of non-normalized coordinates that indicate the nearest pixel // whose presence function returns true. This is the first step before generating a distance // field or generalized Voronoi map. UTILS_PUBLIC LinearImage computeCoordField(const LinearImage& src, PresenceCallback presence, void* user); // Generates a single-channel Euclidean distance field with positive values outside the region // of interest in the source image, and zero values inside. If sqrt is false, the computed // distances are squared. If signed distance (SDF) is desired, this function can be called a second // time using an inverted source field. UTILS_PUBLIC LinearImage edtFromCoordField(const LinearImage& coordField, bool sqrt); // Dereferences the given coordinate field. Useful for creating Voronoi diagrams or dilated images. UTILS_PUBLIC LinearImage voronoiFromCoordField(const LinearImage& coordField, const LinearImage& src); // Copies content of a source image into a target image. Requires width/height/channels to match. UTILS_PUBLIC void blitImage(LinearImage& target, const LinearImage& source); } // namespace image #endif /* IMAGE_LINEARIMAGE_H */