//---------------------------------------------------------------------------- // Anti-Grain Geometry - Version 2.4 // 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 //---------------------------------------------------------------------------- #ifndef AGG_GAMMA_LUT_INCLUDED #define AGG_GAMMA_LUT_INCLUDED #include #include "agg_basics.h" #include "agg_gamma_functions.h" namespace agg { template class gamma_lut { public: typedef gamma_lut self_type; enum gamma_scale_e { gamma_shift = GammaShift, gamma_size = 1 << gamma_shift, gamma_mask = gamma_size - 1 }; enum hi_res_scale_e { hi_res_shift = HiResShift, hi_res_size = 1 << hi_res_shift, hi_res_mask = hi_res_size - 1 }; ~gamma_lut() { pod_allocator::deallocate(m_inv_gamma, hi_res_size); pod_allocator::deallocate(m_dir_gamma, gamma_size); } gamma_lut() : m_gamma(1.0), m_dir_gamma(pod_allocator::allocate(gamma_size)), m_inv_gamma(pod_allocator::allocate(hi_res_size)) { unsigned i; for(i = 0; i < gamma_size; i++) { m_dir_gamma[i] = HiResT(i << (hi_res_shift - gamma_shift)); } for(i = 0; i < hi_res_size; i++) { m_inv_gamma[i] = LoResT(i >> (hi_res_shift - gamma_shift)); } } gamma_lut(double g) : m_gamma(1.0), m_dir_gamma(pod_allocator::allocate(gamma_size)), m_inv_gamma(pod_allocator::allocate(hi_res_size)) { gamma(g); } void gamma(double g) { m_gamma = g; unsigned i; for(i = 0; i < gamma_size; i++) { m_dir_gamma[i] = (HiResT) uround(pow(i / double(gamma_mask), m_gamma) * double(hi_res_mask)); } double inv_g = 1.0 / g; for(i = 0; i < hi_res_size; i++) { m_inv_gamma[i] = (LoResT) uround(pow(i / double(hi_res_mask), inv_g) * double(gamma_mask)); } } double gamma() const { return m_gamma; } HiResT dir(LoResT v) const { return m_dir_gamma[unsigned(v)]; } LoResT inv(HiResT v) const { return m_inv_gamma[unsigned(v)]; } private: gamma_lut(const self_type&); const self_type& operator = (const self_type&); double m_gamma; HiResT* m_dir_gamma; LoResT* m_inv_gamma; }; // // sRGB support classes // // Optimized sRGB lookup table. The direct conversion (sRGB to linear) // is a straightforward lookup. The inverse conversion (linear to sRGB) // is implemented using binary search. template class sRGB_lut_base { public: LinearType dir(int8u v) const { return m_dir_table[v]; } int8u inv(LinearType v) const { // Unrolled binary search. int8u x = 0; if (v > m_inv_table[128]) x = 128; if (v > m_inv_table[x + 64]) x += 64; if (v > m_inv_table[x + 32]) x += 32; if (v > m_inv_table[x + 16]) x += 16; if (v > m_inv_table[x + 8]) x += 8; if (v > m_inv_table[x + 4]) x += 4; if (v > m_inv_table[x + 2]) x += 2; if (v > m_inv_table[x + 1]) x += 1; return x; } protected: LinearType m_dir_table[256]; LinearType m_inv_table[256]; // Only derived classes may instantiate. sRGB_lut_base() { } }; // sRGB_lut - implements sRGB conversion for the various types. // Base template is undefined, specializations are provided below. template class sRGB_lut; template<> class sRGB_lut : public sRGB_lut_base { public: sRGB_lut() { // Generate lookup tables. m_dir_table[0] = 0; m_inv_table[0] = 0; for (unsigned i = 1; i <= 255; ++i) { // Floating-point RGB is in range [0,1]. m_dir_table[i] = float(sRGB_to_linear(i / 255.0)); m_inv_table[i] = float(sRGB_to_linear((i - 0.5) / 255.0)); } } }; template<> class sRGB_lut : public sRGB_lut_base { public: sRGB_lut() { // Generate lookup tables. m_dir_table[0] = 0; m_inv_table[0] = 0; for (unsigned i = 1; i <= 255; ++i) { // 16-bit RGB is in range [0,65535]. m_dir_table[i] = uround(65535.0 * sRGB_to_linear(i / 255.0)); m_inv_table[i] = uround(65535.0 * sRGB_to_linear((i - 0.5) / 255.0)); } } }; template<> class sRGB_lut : public sRGB_lut_base { public: sRGB_lut() { // Generate lookup tables. m_dir_table[0] = 0; m_inv_table[0] = 0; for (unsigned i = 1; i <= 255; ++i) { // 8-bit RGB is handled with simple bidirectional lookup tables. m_dir_table[i] = uround(255.0 * sRGB_to_linear(i / 255.0)); m_inv_table[i] = uround(255.0 * linear_to_sRGB(i / 255.0)); } } int8u inv(int8u v) const { // In this case, the inverse transform is a simple lookup. return m_inv_table[v]; } }; // Common base class for sRGB_conv objects. Defines an internal // sRGB_lut object so that users don't have to. template class sRGB_conv_base { public: static T rgb_from_sRGB(int8u x) { return lut.dir(x); } static int8u rgb_to_sRGB(T x) { return lut.inv(x); } private: static sRGB_lut lut; }; // Definition of sRGB_conv_base::lut. Due to the fact that this a template, // we don't need to place the definition in a cpp file. Hurrah. template sRGB_lut sRGB_conv_base::lut; // Wrapper for sRGB-linear conversion. // Base template is undefined, specializations are provided below. template class sRGB_conv; template<> class sRGB_conv : public sRGB_conv_base { public: static float alpha_from_sRGB(int8u x) { return float(x / 255.0); } static int8u alpha_to_sRGB(float x) { if (x <= 0) return 0; else if (x >= 1) return 255; else return int8u(0.5 + x * 255); } }; template<> class sRGB_conv : public sRGB_conv_base { public: static int16u alpha_from_sRGB(int8u x) { return (x << 8) | x; } static int8u alpha_to_sRGB(int16u x) { return x >> 8; } }; template<> class sRGB_conv : public sRGB_conv_base { public: static int8u alpha_from_sRGB(int8u x) { return x; } static int8u alpha_to_sRGB(int8u x) { return x; } }; } #endif