#define __NR_PIXBLOCK_SCALER_CPP__ /* * Functions for blitting pixblocks using scaling * * Author: * Niko Kiirala * * Copyright (C) 2006,2009 Niko Kiirala * * Released under GNU GPL, read the file 'COPYING' for more information */ #include #include #if defined (SOLARIS) && (SOLARIS == 8) #include "round.h" using Inkscape::round; #endif using std::floor; #include "display/nr-filter-utils.h" #include "libnr/nr-pixblock.h" #include "libnr/nr-blit.h" #include <2geom/forward.h> namespace NR { struct RGBA { double r, g, b, a; }; /** Calculates cubically interpolated value of the four given pixel values. * The pixel values should be from four adjacent pixels in source image or * four adjacent interpolated values. len should be the x- or y-coordinate * (depending on interpolation direction) of the center of the target pixel * in source image coordinates. */ __attribute__ ((const)) inline static double sample(double const a, double const b, double const c, double const d, double const len) { double lena = 1.5 + (len - round(len)); double lenb = 0.5 + (len - round(len)); double lenc = 0.5 - (len - round(len)); double lend = 1.5 - (len - round(len)); double const f = -0.5; // corresponds to cubic Hermite spline double sum = 0; sum += ((((f * lena) - 5.0 * f) * lena + 8.0 * f) * lena - 4 * f) * a; sum += (((f + 2.0) * lenb - (f + 3.0)) * lenb * lenb + 1.0) * b; sum += (((f + 2.0) * lenc - (f + 3.0)) * lenc * lenc + 1.0) * c; sum += ((((f * lend) - 5.0 * f) * lend + 8.0 * f) * lend - 4 * f) * d; return sum; } /** * Sanity check function for indexing pixblocks. * Catches reading and writing outside the pixblock area. * When enabled, decreases filter rendering speed massively. */ inline static void _check_index(NRPixBlock const * const pb, int const location, int const line) { if(false) { int max_loc = pb->rs * (pb->area.y1 - pb->area.y0); if (location < 0 || (location + 4) > max_loc) g_warning("Location %d out of bounds (0 ... %d) at line %d", location, max_loc, line); } } static void scale_bicubic_rgba(NRPixBlock *to, NRPixBlock *from, Geom::Matrix const &trans) { if (NR_PIXBLOCK_BPP(from) != 4 || NR_PIXBLOCK_BPP(to) != 4) { g_warning("A non-32-bpp image passed to scale_bicubic_rgba: scaling aborted."); return; } bool free_from_on_exit = false; if (from->mode != to->mode){ NRPixBlock *o_from = from; from = new NRPixBlock; nr_pixblock_setup_fast(from, to->mode, o_from->area.x0, o_from->area.y0, o_from->area.x1, o_from->area.y1, false); nr_blit_pixblock_pixblock(from, o_from); free_from_on_exit = true; } // Precalculate sizes of source and destination pixblocks int from_width = from->area.x1 - from->area.x0; int from_height = from->area.y1 - from->area.y0; int to_width = to->area.x1 - to->area.x0; int to_height = to->area.y1 - to->area.y0; // from_step: when advancing one pixel in destination image, // how much we should advance in source image double from_stepx = 1.0 / trans[0]; double from_stepy = 1.0 / trans[3]; double from_diffx = from_stepx * (-trans[4]); double from_diffy = from_stepy * (-trans[5]); from_diffx = (to->area.x0 * from_stepx + from_diffx) - from->area.x0; from_diffy = (to->area.y0 * from_stepy + from_diffy) - from->area.y0; // Loop through every pixel of destination image, a line at a time for (int to_y = 0 ; to_y < to_height ; to_y++) { double from_y = (to_y + 0.5) * from_stepy + from_diffy; // Pre-calculate beginning of the four horizontal lines, from // which we should read int from_line[4]; for (int i = 0 ; i < 4 ; i++) { int fy_line = (int)round(from_y) + i - 2; if (fy_line >= 0) { if (fy_line < from_height) { from_line[i] = fy_line * from->rs; } else { from_line[i] = (from_height - 1) * from->rs; } } else { from_line[i] = 0; } } // Loop through this horizontal line in destination image // For every pixel, calculate the color of pixel with // bicubic interpolation and set the pixel value in destination image for (int to_x = 0 ; to_x < to_width ; to_x++) { double from_x = (to_x + 0.5) * from_stepx + from_diffx; RGBA line[4]; for (int i = 0 ; i < 4 ; i++) { int k = (int)round(from_x) + i - 2; if (k < 0) k = 0; if (k >= from_width) k = from_width - 1; k *= 4; _check_index(from, from_line[0] + k, __LINE__); _check_index(from, from_line[1] + k, __LINE__); _check_index(from, from_line[2] + k, __LINE__); _check_index(from, from_line[3] + k, __LINE__); line[i].r = sample(NR_PIXBLOCK_PX(from)[from_line[0] + k], NR_PIXBLOCK_PX(from)[from_line[1] + k], NR_PIXBLOCK_PX(from)[from_line[2] + k], NR_PIXBLOCK_PX(from)[from_line[3] + k], from_y); line[i].g = sample(NR_PIXBLOCK_PX(from)[from_line[0] + k + 1], NR_PIXBLOCK_PX(from)[from_line[1] + k + 1], NR_PIXBLOCK_PX(from)[from_line[2] + k + 1], NR_PIXBLOCK_PX(from)[from_line[3] + k + 1], from_y); line[i].b = sample(NR_PIXBLOCK_PX(from)[from_line[0] + k + 2], NR_PIXBLOCK_PX(from)[from_line[1] + k + 2], NR_PIXBLOCK_PX(from)[from_line[2] + k + 2], NR_PIXBLOCK_PX(from)[from_line[3] + k + 2], from_y); line[i].a = sample(NR_PIXBLOCK_PX(from)[from_line[0] + k + 3], NR_PIXBLOCK_PX(from)[from_line[1] + k + 3], NR_PIXBLOCK_PX(from)[from_line[2] + k + 3], NR_PIXBLOCK_PX(from)[from_line[3] + k + 3], from_y); } RGBA result; result.r = round(sample(line[0].r, line[1].r, line[2].r, line[3].r, from_x)); result.g = round(sample(line[0].g, line[1].g, line[2].g, line[3].g, from_x)); result.b = round(sample(line[0].b, line[1].b, line[2].b, line[3].b, from_x)); result.a = round(sample(line[0].a, line[1].a, line[2].a, line[3].a, from_x)); _check_index(to, to_y * to->rs + to_x * 4, __LINE__); using Inkscape::Filters::clamp; using Inkscape::Filters::clamp_alpha; if (to->mode == NR_PIXBLOCK_MODE_R8G8B8A8P) { /* Clamp the colour channels to range from 0 to result.a to * make sure, we don't exceed 100% per colour channel with * images that have premultiplied alpha */ int const alpha = clamp((int)result.a); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4] = clamp_alpha((int)result.r, alpha); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 1] = clamp_alpha((int)result.g, alpha); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 2] = clamp_alpha((int)result.b, alpha); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 3] = alpha; } else { NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4] = clamp((int)result.r); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 1] = clamp((int)result.g); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 2] = clamp((int)result.b); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x * 4 + 3] = clamp((int)result.a); } } } if (free_from_on_exit) { nr_pixblock_release(from); delete from; } } void scale_bicubic_alpha(NRPixBlock *to, NRPixBlock *from, Geom::Matrix const &trans) { if (NR_PIXBLOCK_BPP(from) != 1 || NR_PIXBLOCK_BPP(to) != 1) { g_warning("A non-8-bpp image passed to scale_bicubic_alpha: scaling aborted."); return; } // Precalculate sizes of source and destination pixblocks int from_width = from->area.x1 - from->area.x0; int from_height = from->area.y1 - from->area.y0; int to_width = to->area.x1 - to->area.x0; int to_height = to->area.y1 - to->area.y0; // from_step: when advancing one pixel in destination image, // how much we should advance in source image double from_stepx = 1.0 / trans[0]; double from_stepy = 1.0 / trans[3]; double from_diffx = from_stepx * (-trans[4]); double from_diffy = from_stepy * (-trans[5]); from_diffx = (to->area.x0 * from_stepx + from_diffx) - from->area.x0; from_diffy = (to->area.y0 * from_stepy + from_diffy) - from->area.y0; // Loop through every pixel of destination image, a line at a time for (int to_y = 0 ; to_y < to_height ; to_y++) { double from_y = (to_y + 0.5) * from_stepy - from_diffy; // Pre-calculate beginning of the four horizontal lines, from // which we should read int from_line[4]; for (int i = 0 ; i < 4 ; i++) { int fy_line = (int)round(from_y) + i - 2; if (fy_line >= 0) { if (fy_line < from_height) { from_line[i] = fy_line * from->rs; } else { from_line[i] = (from_height - 1) * from->rs; } } else { from_line[i] = 0; } } // Loop through this horizontal line in destination image // For every pixel, calculate the color of pixel with // bicubic interpolation and set the pixel value in destination image for (int to_x = 0 ; to_x < to_width ; to_x++) { double from_x = (to_x + 0.5) * from_stepx - from_diffx; double line[4]; for (int i = 0 ; i < 4 ; i++) { int k = (int)round(from_x) + i - 2; if (k < 0) k = 0; if (k >= from_width) k = from_width - 1; _check_index(from, from_line[0] + k, __LINE__); _check_index(from, from_line[1] + k, __LINE__); _check_index(from, from_line[2] + k, __LINE__); _check_index(from, from_line[3] + k, __LINE__); line[i] = sample(NR_PIXBLOCK_PX(from)[from_line[0] + k], NR_PIXBLOCK_PX(from)[from_line[1] + k], NR_PIXBLOCK_PX(from)[from_line[2] + k], NR_PIXBLOCK_PX(from)[from_line[3] + k], from_y); } int result; result = (int)round(sample(line[0], line[1], line[2], line[3], from_x)); _check_index(to, to_y * to->rs + to_x, __LINE__); NR_PIXBLOCK_PX(to)[to_y * to->rs + to_x] = Inkscape::Filters::clamp(result); } } } void scale_bicubic(NRPixBlock *to, NRPixBlock *from, Geom::Matrix const &trans) { if (NR_PIXBLOCK_BPP(to) == 4 && NR_PIXBLOCK_BPP(from) == 4) { scale_bicubic_rgba(to, from, trans); } else if (NR_PIXBLOCK_BPP(to) == 1 && NR_PIXBLOCK_BPP(from) == 1) { scale_bicubic_alpha(to, from, trans); } else { g_warning("NR::scale_bicubic: unsupported bitdepths for scaling: to %d, from %d", NR_PIXBLOCK_BPP(to), NR_PIXBLOCK_BPP(from)); } } } /* namespace NR */ /* Local Variables: mode:c++ c-file-style:"stroustrup" c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +)) indent-tabs-mode:nil fill-column:99 End: */ // vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:encoding=utf-8:textwidth=99 :