//---------------------------------------------------------------------------- // 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 //---------------------------------------------------------------------------- // // Adaptation for 32-bit screen coordinates 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_SCANLINE_STORAGE_BIN_INCLUDED #define AGG_SCANLINE_STORAGE_BIN_INCLUDED #include #include #include "agg_array.h" namespace agg { //-----------------------------------------------scanline_storage_bin class scanline_storage_bin { public: //--------------------------------------------------------------- struct span_data { int32 x; int32 len; }; //--------------------------------------------------------------- struct scanline_data { int y; unsigned num_spans; unsigned start_span; }; //--------------------------------------------------------------- class embedded_scanline { public: //----------------------------------------------------------- class const_iterator { public: const_iterator() : m_storage(0) {} const_iterator(const embedded_scanline* sl) : m_storage(sl->m_storage), m_span_idx(sl->m_scanline.start_span) { m_span = m_storage->span_by_index(m_span_idx); } const span_data& operator*() const { return m_span; } const span_data* operator->() const { return &m_span; } void operator ++ () { ++m_span_idx; m_span = m_storage->span_by_index(m_span_idx); } private: const scanline_storage_bin* m_storage; unsigned m_span_idx; span_data m_span; }; friend class const_iterator; //----------------------------------------------------------- embedded_scanline(scanline_storage_bin& storage) : m_storage(&storage) { setup(0); } //----------------------------------------------------------- void reset(int, int) {} unsigned num_spans() const { return m_scanline.num_spans; } int y() const { return m_scanline.y; } const_iterator begin() const { return const_iterator(this); } //----------------------------------------------------------- void setup(unsigned scanline_idx) { m_scanline_idx = scanline_idx; m_scanline = m_storage->scanline_by_index(m_scanline_idx); } private: scanline_storage_bin* m_storage; scanline_data m_scanline; unsigned m_scanline_idx; }; //--------------------------------------------------------------- scanline_storage_bin() : m_spans(256-2), // Block increment size m_scanlines(), m_min_x(std::numeric_limits::max()), m_min_y(std::numeric_limits::max()), m_max_x(std::numeric_limits::min()), m_max_y(std::numeric_limits::min()), m_cur_scanline(0) { m_fake_scanline.y = 0; m_fake_scanline.num_spans = 0; m_fake_scanline.start_span = 0; m_fake_span.x = 0; m_fake_span.len = 0; } // Renderer Interface //--------------------------------------------------------------- void prepare() { m_scanlines.remove_all(); m_spans.remove_all(); m_min_x = std::numeric_limits::max(); m_min_y = std::numeric_limits::max(); m_max_x = std::numeric_limits::min(); m_max_y = std::numeric_limits::min(); m_cur_scanline = 0; } //--------------------------------------------------------------- template void render(const Scanline& sl) { scanline_data sl_this; int y = sl.y(); if(y < m_min_y) m_min_y = y; if(y > m_max_y) m_max_y = y; sl_this.y = y; sl_this.num_spans = sl.num_spans(); sl_this.start_span = m_spans.size(); typename Scanline::const_iterator span_iterator = sl.begin(); unsigned num_spans = sl_this.num_spans; for(;;) { span_data sp; sp.x = span_iterator->x; sp.len = (int32)std::abs((int)(span_iterator->len)); m_spans.add(sp); int x1 = sp.x; int x2 = sp.x + sp.len - 1; if(x1 < m_min_x) m_min_x = x1; if(x2 > m_max_x) m_max_x = x2; if(--num_spans == 0) break; ++span_iterator; } m_scanlines.add(sl_this); } //--------------------------------------------------------------- // Iterate scanlines interface int min_x() const { return m_min_x; } int min_y() const { return m_min_y; } int max_x() const { return m_max_x; } int max_y() const { return m_max_y; } //--------------------------------------------------------------- bool rewind_scanlines() { m_cur_scanline = 0; return m_scanlines.size() > 0; } //--------------------------------------------------------------- template bool sweep_scanline(Scanline& sl) { sl.reset_spans(); for(;;) { if(m_cur_scanline >= m_scanlines.size()) return false; const scanline_data& sl_this = m_scanlines[m_cur_scanline]; unsigned num_spans = sl_this.num_spans; unsigned span_idx = sl_this.start_span; do { const span_data& sp = m_spans[span_idx++]; sl.add_span(sp.x, sp.len, cover_full); } while(--num_spans); ++m_cur_scanline; if(sl.num_spans()) { sl.finalize(sl_this.y); break; } } return true; } //--------------------------------------------------------------- // Specialization for embedded_scanline bool sweep_scanline(embedded_scanline& sl) { do { if(m_cur_scanline >= m_scanlines.size()) return false; sl.setup(m_cur_scanline); ++m_cur_scanline; } while(sl.num_spans() == 0); return true; } //--------------------------------------------------------------- unsigned byte_size() const { unsigned i; unsigned size = sizeof(int32) * 4; // min_x, min_y, max_x, max_y for(i = 0; i < m_scanlines.size(); ++i) { size += sizeof(int32) * 2 + // Y, num_spans unsigned(m_scanlines[i].num_spans) * sizeof(int32) * 2; // X, span_len } return size; } //--------------------------------------------------------------- static void write_int32(int8u* dst, int32 val) { dst[0] = ((const int8u*)&val)[0]; dst[1] = ((const int8u*)&val)[1]; dst[2] = ((const int8u*)&val)[2]; dst[3] = ((const int8u*)&val)[3]; } //--------------------------------------------------------------- void serialize(int8u* data) const { unsigned i; write_int32(data, min_x()); // min_x data += sizeof(int32); write_int32(data, min_y()); // min_y data += sizeof(int32); write_int32(data, max_x()); // max_x data += sizeof(int32); write_int32(data, max_y()); // max_y data += sizeof(int32); for(i = 0; i < m_scanlines.size(); ++i) { const scanline_data& sl_this = m_scanlines[i]; write_int32(data, sl_this.y); // Y data += sizeof(int32); write_int32(data, sl_this.num_spans); // num_spans data += sizeof(int32); unsigned num_spans = sl_this.num_spans; unsigned span_idx = sl_this.start_span; do { const span_data& sp = m_spans[span_idx++]; write_int32(data, sp.x); // X data += sizeof(int32); write_int32(data, sp.len); // len data += sizeof(int32); } while(--num_spans); } } //--------------------------------------------------------------- const scanline_data& scanline_by_index(unsigned i) const { return (i < m_scanlines.size()) ? m_scanlines[i] : m_fake_scanline; } //--------------------------------------------------------------- const span_data& span_by_index(unsigned i) const { return (i < m_spans.size()) ? m_spans[i] : m_fake_span; } private: pod_bvector m_spans; pod_bvector m_scanlines; span_data m_fake_span; scanline_data m_fake_scanline; int m_min_x; int m_min_y; int m_max_x; int m_max_y; unsigned m_cur_scanline; }; //---------------------------------------serialized_scanlines_adaptor_bin class serialized_scanlines_adaptor_bin { public: typedef bool cover_type; //-------------------------------------------------------------------- class embedded_scanline { public: //---------------------------------------------------------------- class const_iterator { public: struct span { int32 x; int32 len; }; const_iterator() : m_ptr(0) {} const_iterator(const embedded_scanline* sl) : m_ptr(sl->m_ptr), m_dx(sl->m_dx) { m_span.x = read_int32() + m_dx; m_span.len = read_int32(); } const span& operator*() const { return m_span; } const span* operator->() const { return &m_span; } void operator ++ () { m_span.x = read_int32() + m_dx; m_span.len = read_int32(); } private: int read_int32() { int32 val; ((int8u*)&val)[0] = *m_ptr++; ((int8u*)&val)[1] = *m_ptr++; ((int8u*)&val)[2] = *m_ptr++; ((int8u*)&val)[3] = *m_ptr++; return val; } const int8u* m_ptr; span m_span; int m_dx; }; friend class const_iterator; //---------------------------------------------------------------- embedded_scanline() : m_ptr(0), m_y(0), m_num_spans(0) {} //---------------------------------------------------------------- void reset(int, int) {} unsigned num_spans() const { return m_num_spans; } int y() const { return m_y; } const_iterator begin() const { return const_iterator(this); } private: //---------------------------------------------------------------- int read_int32() { int32 val; ((int8u*)&val)[0] = *m_ptr++; ((int8u*)&val)[1] = *m_ptr++; ((int8u*)&val)[2] = *m_ptr++; ((int8u*)&val)[3] = *m_ptr++; return val; } public: //---------------------------------------------------------------- void init(const int8u* ptr, int dx, int dy) { m_ptr = ptr; m_y = read_int32() + dy; m_num_spans = unsigned(read_int32()); m_dx = dx; } private: const int8u* m_ptr; int m_y; unsigned m_num_spans; int m_dx; }; public: //-------------------------------------------------------------------- serialized_scanlines_adaptor_bin() : m_data(0), m_end(0), m_ptr(0), m_dx(0), m_dy(0), m_min_x(std::numeric_limits::max()), m_min_y(std::numeric_limits::max()), m_max_x(std::numeric_limits::min()), m_max_y(std::numeric_limits::min()) {} //-------------------------------------------------------------------- serialized_scanlines_adaptor_bin(const int8u* data, unsigned size, double dx, double dy) : m_data(data), m_end(data + size), m_ptr(data), m_dx(iround(dx)), m_dy(iround(dy)), m_min_x(std::numeric_limits::max()), m_min_y(std::numeric_limits::max()), m_max_x(std::numeric_limits::min()), m_max_y(std::numeric_limits::min()) {} //-------------------------------------------------------------------- void init(const int8u* data, unsigned size, double dx, double dy) { m_data = data; m_end = data + size; m_ptr = data; m_dx = iround(dx); m_dy = iround(dy); m_min_x = std::numeric_limits::max(); m_min_y = std::numeric_limits::max(); m_max_x = std::numeric_limits::min(); m_max_y = std::numeric_limits::min(); } private: //-------------------------------------------------------------------- int read_int32() { int32 val; ((int8u*)&val)[0] = *m_ptr++; ((int8u*)&val)[1] = *m_ptr++; ((int8u*)&val)[2] = *m_ptr++; ((int8u*)&val)[3] = *m_ptr++; return val; } public: // Iterate scanlines interface //-------------------------------------------------------------------- bool rewind_scanlines() { m_ptr = m_data; if(m_ptr < m_end) { m_min_x = read_int32() + m_dx; m_min_y = read_int32() + m_dy; m_max_x = read_int32() + m_dx; m_max_y = read_int32() + m_dy; } return m_ptr < m_end; } //-------------------------------------------------------------------- int min_x() const { return m_min_x; } int min_y() const { return m_min_y; } int max_x() const { return m_max_x; } int max_y() const { return m_max_y; } //-------------------------------------------------------------------- template bool sweep_scanline(Scanline& sl) { sl.reset_spans(); for(;;) { if(m_ptr >= m_end) return false; int y = read_int32() + m_dy; unsigned num_spans = read_int32(); do { int x = read_int32() + m_dx; int len = read_int32(); if(len < 0) len = -len; sl.add_span(x, unsigned(len), cover_full); } while(--num_spans); if(sl.num_spans()) { sl.finalize(y); break; } } return true; } //-------------------------------------------------------------------- // Specialization for embedded_scanline bool sweep_scanline(embedded_scanline& sl) { do { if(m_ptr >= m_end) return false; sl.init(m_ptr, m_dx, m_dy); // Jump to the next scanline //-------------------------- read_int32(); // Y int num_spans = read_int32(); // num_spans m_ptr += num_spans * sizeof(int32) * 2; } while(sl.num_spans() == 0); return true; } private: const int8u* m_data; const int8u* m_end; const int8u* m_ptr; int m_dx; int m_dy; int m_min_x; int m_min_y; int m_max_x; int m_max_y; }; } #endif