// example3.cpp // This file demonstrates how to use FreeType's stand-alone B/W renderer. // // Copy the files ftraster.c, ftimage.h, and ftmisc.h into the same // directory as this file, then say // // g++ -D STANDALONE_ \ // -o example3 example3.cpp // // You need FreeType version 2.3.10 or newer. // // Written Sep. 2009 by Werner Lemberg, // based on code contributed by Erik Möller. // // Public domain. #include "ftraster.c" #include // Define an acorn-like shape to test with. struct Vec2 { Vec2(float a, float b) : x(a), y(b) { } float x, y; }; static Vec2 k_shape[] = { Vec2(-3, -18), Vec2(0, -12), Vec2(6, -10), Vec2(12, -6), Vec2(12, -4), Vec2(11, -4), Vec2(10, -5), Vec2(10, 1), Vec2(9, 6), Vec2(7, 10), Vec2(5, 12), Vec2(4, 15), Vec2(3, 14), Vec2(1, 13), Vec2(-1, 13), Vec2(-5, 11), Vec2(-8, 8), Vec2(-11, 2), Vec2(-11, -2), Vec2(-14, 0), Vec2(-14, -2), Vec2(-11, -7), Vec2(-9, -9), Vec2(-8, -9), Vec2(-5, -12), Vec2(-5, -14), Vec2(-7, -15), Vec2(-8, -14), Vec2(-9, -15), Vec2(-9, -17), Vec2(-7, -17), Vec2(-6, -18) }; void* MY_Alloc_Func(FT_Memory /* memory */, long size) { return malloc((size_t)size); } void MY_Free_Func(FT_Memory /* memory */, void *block) { free(block); } void* MY_Realloc_Func(FT_Memory /* memory */, long /* cur_size */, long new_size, void* block) { return realloc(block, (size_t)new_size); } static FT_Memory mem; // Render a shape and dump it out as out-mono.pbm (b/w) and // out-gray.pgm (grayscale). int main() { // Set up the memory management. mem = new FT_MemoryRec; mem->alloc = MY_Alloc_Func; mem->free = MY_Free_Func; mem->realloc = MY_Realloc_Func; // Build an outline manually. FT_Outline_ outline; outline.n_contours = 1; outline.n_points = sizeof (k_shape) / sizeof (Vec2); outline.points = new FT_Vector[outline.n_points]; for (int i = 0; i < outline.n_points; ++i) { FT_Vector v; // Offset it to fit in the image and scale it up 10 times. v.x = (20 + k_shape[i].x) * 10 * 64; v.y = (20 + k_shape[i].y) * 10 * 64; outline.points[i] = v; } outline.tags = new char[outline.n_points]; for (int i = 0; i < outline.n_points; ++i) outline.tags[i] = 1; outline.contours = new short[outline.n_contours]; outline.contours[0] = outline.n_points - 1; outline.flags = 0; const int width = 500; const int rows = 400; // 1 bit per pixel. const int pitch_mono = (width + 7) >> 3; FT_Bitmap bmp; FT_Raster raster; FT_Raster_Params params; // Allocate a chunk of memory for the render pool. const int kRenderPoolSize = 1024 * 1024; unsigned char *renderPool = new unsigned char[kRenderPoolSize]; // Set up a bitmap. bmp.buffer = new unsigned char[rows * pitch_mono]; memset(bmp.buffer, 0, rows * pitch_mono); bmp.width = width; bmp.rows = rows; bmp.pitch = pitch_mono; bmp.pixel_mode = FT_PIXEL_MODE_MONO; // Set up the necessary raster parameters. memset(¶ms, 0, sizeof (params)); params.source = &outline; params.target = &bmp; // Initialize the rasterer and get it to render into the bitmap. ft_standard_raster.raster_new(mem, &raster); ft_standard_raster.raster_reset(raster, renderPool, kRenderPoolSize); ft_standard_raster.raster_render(raster, ¶ms); // Dump out the raw image data (in PBM format). std::ofstream out_mono("out-mono.pbm", std::ios::binary); out_mono << "P4 " << width << " " << rows << "\n"; out_mono.write((const char *)bmp.buffer, rows * pitch_mono); // Cleanup. delete[] renderPool; delete[] bmp.buffer; delete[] outline.points; delete[] outline.tags; delete[] outline.contours; delete mem; return 0; }