//---------------------------------------------------------------------------- // Anti-Grain Geometry - Version 2.3 // Copyright (C) 2002-2005 Maxim Shemanarev (http://www.antigrain.com) // // Permission to copy, use, modify, sell and distribute this software // is granted provided this copyright notice appears in all copies. // This software is provided "as is" without express or implied // warranty, and with no claim as to its suitability for any purpose. // //---------------------------------------------------------------------------- // Contact: mcseem@antigrain.com // mcseemagg@yahoo.com // http://www.antigrain.com //---------------------------------------------------------------------------- // // Adaptation for high precision colors has been sponsored by // Liberty Technology Systems, Inc., visit http://lib-sys.com // // Liberty Technology Systems, Inc. is the provider of // PostScript and PDF technology for software developers. // //---------------------------------------------------------------------------- #ifndef AGG_SPAN_IMAGE_FILTER_GRAY_INCLUDED #define AGG_SPAN_IMAGE_FILTER_GRAY_INCLUDED #include "agg_basics.h" #include "agg_color_gray.h" #include "agg_span_image_filter.h" namespace agg { //==============================================span_image_filter_gray_nn template > class span_image_filter_gray_nn : public span_image_filter { public: typedef ColorT color_type; typedef Interpolator interpolator_type; typedef Allocator alloc_type; typedef span_image_filter base_type; typedef typename color_type::value_type value_type; typedef typename color_type::calc_type calc_type; enum { base_shift = color_type::base_shift, base_mask = color_type::base_mask }; //-------------------------------------------------------------------- span_image_filter_gray_nn(alloc_type& alloc) : base_type(alloc) {} //-------------------------------------------------------------------- span_image_filter_gray_nn(alloc_type& alloc, const rendering_buffer& src, const color_type& back_color, interpolator_type& inter) : base_type(alloc, src, back_color, inter, 0) {} //-------------------------------------------------------------------- color_type* generate(int x, int y, unsigned len) { base_type::interpolator().begin(x + base_type::filter_dx_dbl(), y + base_type::filter_dy_dbl(), len); calc_type fg; calc_type src_alpha; color_type* span = base_type::allocator().span(); int maxx = base_type::source_image().width() - 1; int maxy = base_type::source_image().height() - 1; do { base_type::interpolator().coordinates(&x, &y); x >>= image_subpixel_shift; y >>= image_subpixel_shift; if(x >= 0 && y >= 0 && x <= maxx && y <= maxy) { fg = *((const value_type*)base_type::source_image().row(y) + x); src_alpha = base_mask; } else { fg = base_type::background_color().v; src_alpha = base_type::background_color().a; } span->v = (value_type)fg; span->a = (value_type)src_alpha; ++span; ++base_type::interpolator(); } while(--len); return base_type::allocator().span(); } }; //========================================span_image_filter_gray_bilinear template > class span_image_filter_gray_bilinear : public span_image_filter { public: typedef ColorT color_type; typedef Interpolator interpolator_type; typedef Allocator alloc_type; typedef span_image_filter base_type; typedef typename color_type::value_type value_type; typedef typename color_type::calc_type calc_type; enum { base_shift = color_type::base_shift, base_mask = color_type::base_mask }; //-------------------------------------------------------------------- span_image_filter_gray_bilinear(alloc_type& alloc) : base_type(alloc) {} //-------------------------------------------------------------------- span_image_filter_gray_bilinear(alloc_type& alloc, const rendering_buffer& src, const color_type& back_color, interpolator_type& inter) : base_type(alloc, src, back_color, inter, 0) {} //-------------------------------------------------------------------- color_type* generate(int x, int y, unsigned len) { base_type::interpolator().begin(x + base_type::filter_dx_dbl(), y + base_type::filter_dy_dbl(), len); calc_type fg; calc_type src_alpha; value_type back_v = base_type::background_color().v; value_type back_a = base_type::background_color().a; const value_type *fg_ptr; color_type* span = base_type::allocator().span(); int maxx = base_type::source_image().width() - 1; int maxy = base_type::source_image().height() - 1; do { int x_hr; int y_hr; base_type::interpolator().coordinates(&x_hr, &y_hr); x_hr -= base_type::filter_dx_int(); y_hr -= base_type::filter_dy_int(); int x_lr = x_hr >> image_subpixel_shift; int y_lr = y_hr >> image_subpixel_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr < maxx && y_lr < maxy) { fg = image_subpixel_size * image_subpixel_size / 2; x_hr &= image_subpixel_mask; y_hr &= image_subpixel_mask; fg_ptr = (const value_type*)base_type::source_image().row(y_lr) + x_lr; fg += *fg_ptr++ * (image_subpixel_size - x_hr) * (image_subpixel_size - y_hr); fg += *fg_ptr++ * (image_subpixel_size - y_hr) * x_hr; fg_ptr = (const value_type*)base_type::source_image().next_row(fg_ptr - 2); fg += *fg_ptr++ * (image_subpixel_size - x_hr) * y_hr; fg += *fg_ptr++ * x_hr * y_hr; fg >>= image_subpixel_shift * 2; src_alpha = base_mask; } else { unsigned weight; if(x_lr < -1 || y_lr < -1 || x_lr > maxx || y_lr > maxy) { fg = back_v; src_alpha = back_a; } else { fg = src_alpha = image_subpixel_size * image_subpixel_size / 2; x_hr &= image_subpixel_mask; y_hr &= image_subpixel_mask; weight = (image_subpixel_size - x_hr) * (image_subpixel_size - y_hr); if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr++; weight = x_hr * (image_subpixel_size - y_hr); if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr--; y_lr++; weight = (image_subpixel_size - x_hr) * y_hr; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr++; weight = x_hr * y_hr; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } fg >>= image_subpixel_shift * 2; src_alpha >>= image_subpixel_shift * 2; } } span->v = (value_type)fg; span->a = (value_type)src_alpha; ++span; ++base_type::interpolator(); } while(--len); return base_type::allocator().span(); } }; //========================================span_image_filter_gray_2x2 template > class span_image_filter_gray_2x2 : public span_image_filter { public: typedef ColorT color_type; typedef Interpolator interpolator_type; typedef Allocator alloc_type; typedef span_image_filter base_type; typedef typename color_type::value_type value_type; typedef typename color_type::calc_type calc_type; enum { base_shift = color_type::base_shift, base_mask = color_type::base_mask }; //-------------------------------------------------------------------- span_image_filter_gray_2x2(alloc_type& alloc) : base_type(alloc) {} //-------------------------------------------------------------------- span_image_filter_gray_2x2(alloc_type& alloc, const rendering_buffer& src, const color_type& back_color, interpolator_type& inter, const image_filter_lut& filter) : base_type(alloc, src, back_color, inter, &filter) {} //-------------------------------------------------------------------- color_type* generate(int x, int y, unsigned len) { base_type::interpolator().begin(x + base_type::filter_dx_dbl(), y + base_type::filter_dy_dbl(), len); calc_type fg; calc_type src_alpha; value_type back_v = base_type::background_color().v; value_type back_a = base_type::background_color().a; const value_type *fg_ptr; color_type* span = base_type::allocator().span(); const int16* weight_array = base_type::filter().weight_array() + ((base_type::filter().diameter()/2 - 1) << image_subpixel_shift); int maxx = base_type::source_image().width() - 1; int maxy = base_type::source_image().height() - 1; do { int x_hr; int y_hr; base_type::interpolator().coordinates(&x_hr, &y_hr); x_hr -= base_type::filter_dx_int(); y_hr -= base_type::filter_dy_int(); int x_lr = x_hr >> image_subpixel_shift; int y_lr = y_hr >> image_subpixel_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr < maxx && y_lr < maxy) { fg = image_filter_size / 2; x_hr &= image_subpixel_mask; y_hr &= image_subpixel_mask; fg_ptr = (const value_type*)base_type::source_image().row(y_lr) + x_lr; fg += *fg_ptr++ * ((weight_array[x_hr + image_subpixel_size] * weight_array[y_hr + image_subpixel_size] + image_filter_size / 2) >> image_filter_shift); fg += *fg_ptr++ * ((weight_array[x_hr] * weight_array[y_hr + image_subpixel_size] + image_filter_size / 2) >> image_filter_shift); fg_ptr = (const value_type*)base_type::source_image().next_row(fg_ptr - 2); fg += *fg_ptr++ * ((weight_array[x_hr + image_subpixel_size] * weight_array[y_hr] + image_filter_size / 2) >> image_filter_shift); fg += *fg_ptr++ * ((weight_array[x_hr] * weight_array[y_hr] + image_filter_size / 2) >> image_filter_shift); fg >>= image_filter_shift; if(fg > base_mask) fg = base_mask; src_alpha = base_mask; } else { unsigned weight; if(x_lr < -1 || y_lr < -1 || x_lr > maxx || y_lr > maxy) { fg = back_v; src_alpha = back_a; } else { fg = src_alpha = image_filter_size / 2; x_hr &= image_subpixel_mask; y_hr &= image_subpixel_mask; weight = (weight_array[x_hr + image_subpixel_size] * weight_array[y_hr + image_subpixel_size] + image_filter_size / 2) >> image_filter_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr++; weight = (weight_array[x_hr] * weight_array[y_hr + image_subpixel_size] + image_filter_size / 2) >> image_filter_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr--; y_lr++; weight = (weight_array[x_hr + image_subpixel_size] * weight_array[y_hr] + image_filter_size / 2) >> image_filter_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_lr++; weight = (weight_array[x_hr] * weight_array[y_hr] + image_filter_size / 2) >> image_filter_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr <= maxx && y_lr <= maxy) { fg += weight * *((const value_type*)base_type::source_image().row(y_lr) + x_lr); src_alpha += weight * base_mask; } else { fg += back_v * weight; src_alpha += back_a * weight; } fg >>= image_filter_shift; src_alpha >>= image_filter_shift; if(src_alpha > base_mask) src_alpha = base_mask; if(fg > src_alpha) fg = src_alpha; } } span->v = (value_type)fg; span->a = (value_type)src_alpha; ++span; ++base_type::interpolator(); } while(--len); return base_type::allocator().span(); } }; //================================================span_image_filter_gray template > class span_image_filter_gray : public span_image_filter { public: typedef ColorT color_type; typedef Interpolator interpolator_type; typedef Allocator alloc_type; typedef span_image_filter base_type; typedef typename color_type::value_type value_type; typedef typename color_type::calc_type calc_type; enum { base_shift = color_type::base_shift, base_mask = color_type::base_mask }; //-------------------------------------------------------------------- span_image_filter_gray(alloc_type& alloc) : base_type(alloc) {} //-------------------------------------------------------------------- span_image_filter_gray(alloc_type& alloc, const rendering_buffer& src, const color_type& back_color, interpolator_type& inter, const image_filter_lut& filter) : base_type(alloc, src, back_color, inter, &filter) {} //-------------------------------------------------------------------- color_type* generate(int x, int y, unsigned len) { base_type::interpolator().begin(x + base_type::filter_dx_dbl(), y + base_type::filter_dy_dbl(), len); int fg; int src_alpha; value_type back_v = base_type::background_color().v; value_type back_a = base_type::background_color().a; const value_type* fg_ptr; unsigned diameter = base_type::filter().diameter(); int start = base_type::filter().start(); int start1 = start - 1; const int16* weight_array = base_type::filter().weight_array(); color_type* span = base_type::allocator().span(); int maxx = base_type::source_image().width() + start - 2; int maxy = base_type::source_image().height() + start - 2; int maxx2 = base_type::source_image().width() - start - 1; int maxy2 = base_type::source_image().height() - start - 1; int x_count; int weight_y; do { base_type::interpolator().coordinates(&x, &y); x -= base_type::filter_dx_int(); y -= base_type::filter_dy_int(); int x_hr = x; int y_hr = y; int x_lr = x_hr >> image_subpixel_shift; int y_lr = y_hr >> image_subpixel_shift; fg = image_filter_size / 2; int x_fract = x_hr & image_subpixel_mask; unsigned y_count = diameter; if(x_lr >= -start && y_lr >= -start && x_lr <= maxx && y_lr <= maxy) { y_hr = image_subpixel_mask - (y_hr & image_subpixel_mask); fg_ptr = (const value_type*)base_type::source_image().row(y_lr + start) + x_lr + start; do { x_count = diameter; weight_y = weight_array[y_hr]; x_hr = image_subpixel_mask - x_fract; do { fg += *fg_ptr++ * ((weight_y * weight_array[x_hr] + image_filter_size / 2) >> image_filter_shift); x_hr += image_subpixel_size; } while(--x_count); y_hr += image_subpixel_size; fg_ptr = (const value_type*)base_type::source_image().next_row(fg_ptr - diameter); } while(--y_count); fg >>= image_filter_shift; if(fg < 0) fg = 0; if(fg > base_mask) fg = base_mask; src_alpha = base_mask; } else { if(x_lr < start1 || y_lr < start1 || x_lr > maxx2 || y_lr > maxy2) { fg = back_v; src_alpha = back_a; } else { src_alpha = image_filter_size / 2; y_lr = (y >> image_subpixel_shift) + start; y_hr = image_subpixel_mask - (y_hr & image_subpixel_mask); do { x_count = diameter; weight_y = weight_array[y_hr]; x_lr = (x >> image_subpixel_shift) + start; x_hr = image_subpixel_mask - x_fract; do { int weight = (weight_y * weight_array[x_hr] + image_filter_size / 2) >> image_filter_shift; if(x_lr >= 0 && y_lr >= 0 && x_lr < int(base_type::source_image().width()) && y_lr < int(base_type::source_image().height())) { fg_ptr = (const value_type*)base_type::source_image().row(y_lr) + x_lr; fg += *fg_ptr++ * weight; src_alpha += base_mask * weight; } else { fg += back_v * weight; src_alpha += back_a * weight; } x_hr += image_subpixel_size; x_lr++; } while(--x_count); y_hr += image_subpixel_size; y_lr++; } while(--y_count); fg >>= image_filter_shift; src_alpha >>= image_filter_shift; if(fg < 0) fg = 0; if(src_alpha < 0) src_alpha = 0; if(src_alpha > base_mask) src_alpha = base_mask; if(fg > src_alpha) fg = src_alpha; } } span->v = (value_type)fg; span->a = (value_type)src_alpha; ++span; ++base_type::interpolator(); } while(--len); return base_type::allocator().span(); } }; } #endif