// Copyright (C) 2022 RozK // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Affero General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Affero General Public License for more details. // // You should have received a copy of the GNU Affero General Public License // along with this program. If not, see . #include "../render.hpp" #include "render_opengles.hpp" #include "../display/display_glx.hpp" #include typedef void (*rk_DrawElementsInstancedBaseInstanceFunc)(rk_uint, rk_uint, rk_uint, const void *, rk_uint, rk_uint); typedef void (*rk_MultiDrawElementsIndirectFunc)(rk_uint, rk_uint, const void *, rk_uint, rk_uint); static rk_DrawElementsInstancedBaseInstanceFunc rk_DrawElementsInstancedBaseInstance = nullptr; static rk_MultiDrawElementsIndirectFunc rk_MultiDrawElementsIndirect = nullptr; static void rk_gl_printf(char const * message) { printf("[GL] %s\n", message); } static void rk_printf(char const * message) { printf("[RK] %s\n", message); } #define rk_gl_error(_message) { if (glGetError() != GL_NO_ERROR) { printf("[GL] %s\n", (_message)); } } static void rk_debug_message_callback( GLenum source, GLenum type, GLuint id, GLenum severity, GLsizei length, GLchar const * message, void const * userParam) { printf("[GL] (id=%d) %s\n", id, message); } void rk_render_initialize( rk_bool debug) { GLubyte const * const vendor = glGetString(GL_VENDOR); GLubyte const * const renderer = glGetString(GL_RENDERER); printf("[GL] vendor: %s, renderer: %s\n", vendor, renderer); GLubyte const * const version = glGetString(GL_VERSION); GLubyte const * const language = glGetString(GL_SHADING_LANGUAGE_VERSION); printf("[GL] version: %s, language: %s\n", version, language); if (debug) { glDebugMessageCallback(rk_debug_message_callback, nullptr); glEnable(GL_DEBUG_OUTPUT); } char const * const gl_exts = reinterpret_cast(glGetString(GL_EXTENSIONS)); // printf("[GL] %s\n", gl_exts); rk_DrawElementsInstancedBaseInstance = reinterpret_cast( rk_resolve_extension(gl_exts, "GL_EXT_base_instance", "DrawElementsInstancedBaseInstance")); if (rk_DrawElementsInstancedBaseInstance) { rk_gl_printf("Using extension GL_EXT_base_instance::DrawElementsInstancedBaseInstance."); rk_MultiDrawElementsIndirect = reinterpret_cast( rk_resolve_extension(gl_exts, "GL_EXT_multi_draw_indirect", "MultiDrawElementsIndirectEXT")); if (rk_MultiDrawElementsIndirect) { rk_gl_printf("Using extension GL_EXT_multi_draw_indirect::MultiDrawElementsIndirectEXT."); } } glDisable(GL_BLEND); glEnable(GL_DITHER); glEnable(GL_DEPTH_TEST); glDisable(GL_SCISSOR_TEST); glDisable(GL_STENCIL_TEST); glEnable(GL_CULL_FACE); glFrontFace(GL_CCW); glCullFace(GL_BACK); glHint(GL_GENERATE_MIPMAP_HINT, GL_NICEST); } void rk_render_terminate() { } static void rk_print_shader_infolog(GLuint shader) { GLsizei length; char infolog[1024]; glGetShaderInfoLog(shader, sizeof(infolog), &length, infolog); if (length > 0) { rk_printf(infolog); } } static void rk_print_program_infolog(GLuint program) { GLsizei length; char infolog[1024]; glGetProgramInfoLog(program, sizeof(infolog), &length, infolog); if (length > 0) { rk_printf(infolog); } } //TODO: error handling rk_shader_t rk_load_shader( rk_uint const vert_nlines, char const ** const vert_lines, rk_uint const frag_nlines, char const ** const frag_lines) { rk_shader * const shader = new rk_shader; shader->vertex = glCreateShader(GL_VERTEX_SHADER); shader->fragment = glCreateShader(GL_FRAGMENT_SHADER); shader->program = glCreateProgram(); if (!vert_nlines || !vert_lines) { rk_printf("Missing vertex shader."); return nullptr; } if (!frag_nlines || !frag_lines) { rk_printf("Missing fragment shader."); return nullptr; } rk_printf("Compiling vertex shader..."); glShaderSource(shader->vertex, vert_nlines, vert_lines, nullptr); glCompileShader(shader->vertex); rk_gl_error("glCompileShader() failed."); rk_print_shader_infolog(shader->vertex); rk_printf("Compiling fragment shader..."); glShaderSource(shader->fragment, frag_nlines, frag_lines, nullptr); glCompileShader(shader->fragment); rk_gl_error("glCompileShader() failed."); rk_print_shader_infolog(shader->fragment); rk_printf("Linking program..."); glAttachShader(shader->program, shader->vertex); glAttachShader(shader->program, shader->fragment); glLinkProgram(shader->program); rk_gl_error("glLinkProgram() failed."); rk_print_program_infolog(shader->program); rk_printf("Done."); glReleaseShaderCompiler(); return reinterpret_cast(shader); } rk_input_t rk_resolve_input( rk_shader_t _shader, char const * name) { rk_shader const * const shader = reinterpret_cast(_shader); if (!shader || !name) { return nullptr; } GLint const uniform = glGetUniformLocation(shader->program, name); return reinterpret_cast(uniform + 1); } rk_param_t rk_resolve_param( rk_shader_t _shader, char const * name) { rk_shader const * const shader = reinterpret_cast(_shader); if (!shader || !name) { return nullptr; } GLint const location = glGetAttribLocation(shader->program, name); return reinterpret_cast(location + 1); } rk_texture_t rk_create_texture( rk_texture_format format, rk_uint width, rk_uint height, rk_uint nlevels, rk_texture_flags flags, rk_ubyte const * pixels) { if (!width || !height || !pixels) { return nullptr; } GLint internal_format; GLenum source_format; GLenum source_type; switch (format) { case RK_TEXTURE_FORMAT_SRGB8_A8: internal_format = GL_SRGB8_ALPHA8; source_format = GL_RGBA; source_type = GL_UNSIGNED_BYTE; break; case RK_TEXTURE_FORMAT_RGBA8: internal_format = GL_RGBA8; source_format = GL_RGBA; source_type = GL_UNSIGNED_BYTE; break; case RK_TEXTURE_FORMAT_RGB10_A2: internal_format = GL_RGB10_A2; source_format = GL_RGBA; source_type = GL_UNSIGNED_INT_2_10_10_10_REV; break; case RK_TEXTURE_FORMAT_FLOAT_32: internal_format = GL_R32F; source_format = GL_RED; source_type = GL_FLOAT; break; default: return nullptr; break; } rk_texture * const texture = new rk_texture; glGenTextures(1, &texture->texture); GLenum target; if (nlevels) { if (flags & RK_TEXTURE_FLAG_3D) { target = GL_TEXTURE_3D; } else { target = GL_TEXTURE_2D_ARRAY; } glBindTexture(target, texture->texture); //TODO: glTexStorage3D glTexImage3D(target, 0, internal_format, width, height, nlevels, 0, source_format, source_type, pixels); } else { target = GL_TEXTURE_2D; glBindTexture(target, texture->texture); //TODO: glTexStorage2D glTexImage2D(target, 0, internal_format, width, height, 0, source_format, source_type, pixels); } if (flags & RK_TEXTURE_FLAG_MIPMAPS) { if (flags & RK_TEXTURE_FLAG_MIN_LINEAR) { glTexParameteri(target, GL_TEXTURE_MIN_FILTER, GL_LINEAR_MIPMAP_LINEAR); } else { glTexParameteri(target, GL_TEXTURE_MIN_FILTER, GL_NEAREST_MIPMAP_LINEAR); } } else { if (flags & RK_TEXTURE_FLAG_MIN_LINEAR) { glTexParameteri(target, GL_TEXTURE_MIN_FILTER, GL_LINEAR); } else { glTexParameteri(target, GL_TEXTURE_MIN_FILTER, GL_NEAREST); } } if (flags & RK_TEXTURE_FLAG_MAG_LINEAR) { glTexParameteri(target, GL_TEXTURE_MAG_FILTER, GL_LINEAR); } else { glTexParameteri(target, GL_TEXTURE_MAG_FILTER, GL_NEAREST); } glTexParameteri(target, GL_TEXTURE_WRAP_S, GL_REPEAT); glTexParameteri(target, GL_TEXTURE_WRAP_T, GL_REPEAT); glTexParameteri(target, GL_TEXTURE_WRAP_R, GL_REPEAT); if (flags & RK_TEXTURE_FLAG_MIPMAPS) { glGenerateMipmap(target); } texture->nlevels = nlevels; glBindTexture(target, 0); return reinterpret_cast(texture); } rk_triangles_t rk_create_triangles( rk_uint nvertices, rk_vec3 const * vertices) { if (!nvertices || !vertices) { return nullptr; } rk_triangles * const triangles = new rk_triangles; triangles->size = nvertices; glGenVertexArrays(1, &triangles->array); glBindVertexArray(triangles->array); glGenBuffers(1, &triangles->vertices); glBindBuffer(GL_ARRAY_BUFFER, triangles->vertices); glBufferData(GL_ARRAY_BUFFER, nvertices * sizeof(rk_vec3), vertices, GL_STATIC_DRAW); glEnableVertexAttribArray(0); glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, 0, 0); glBindBuffer(GL_ARRAY_BUFFER, 0); glBindVertexArray(0); return reinterpret_cast(triangles); } rk_vertices_t rk_create_vertices( rk_vertex_format const * format, rk_uint nvertices, rk_ubyte const * _vertices, rk_uint nindices, rk_ushort const * indices) { if (!format || !nvertices || !_vertices || !nindices || !indices) { return nullptr; } unsigned format_size = 0; unsigned vertex_size = 0; for (rk_vertex_format const * f = format; *f; ++f, ++format_size) { switch (*f & RK_VERTEX_FORMAT_MASK) { case RK_VERTEX_FORMAT_VEC3_FLOAT: vertex_size += sizeof(rk_vec3_float); break; case RK_VERTEX_FORMAT_VEC3_INT10: vertex_size += sizeof(rk_vec3_int10); break; case RK_VERTEX_FORMAT_VEC3_UINT10: vertex_size += sizeof(rk_vec3_uint10); break; default: rk_printf("rk_create_vertices(): invalid format."); return nullptr; break; } } if (!format_size) { rk_printf("rk_create_vertices(): empty format."); return nullptr; } rk_vertices * const vertices = new rk_vertices; vertices->nvertices = nvertices; vertices->nindices = nindices; vertices->format = new rk_vertex_format[format_size + 1]; memcpy(vertices->format, format, (format_size + 1) * sizeof(rk_vertex_format)); vertices->vertices = new rk_ubyte[nvertices * vertex_size]; memcpy(vertices->vertices, _vertices, nvertices * vertex_size); vertices->indices = new rk_ushort[nindices]; memcpy(vertices->indices, indices, nindices * sizeof(rk_ushort)); return reinterpret_cast(vertices); } static void rk_pack_vec3_float( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_vec3_float * __restrict dst = reinterpret_cast(_dst); rk_vec3_float const * const __restrict src = reinterpret_cast(_src); for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { *dst = src[*index]; } } static void rk_pack_vec3_short( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_vec3_short * __restrict dst = reinterpret_cast(_dst); rk_vec3_float const * const __restrict src = reinterpret_cast(_src); for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_vec3_float const & input = src[*index]; dst->x = static_cast(input.x); dst->y = static_cast(input.y); dst->z = static_cast(input.z); dst->pad = 0; } } static void rk_pack_vec3_short_norm( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_vec3_short * __restrict dst = reinterpret_cast(_dst); rk_vec3_float const * const __restrict src = reinterpret_cast(_src); #define _convert(s) (static_cast((s) * ((s) < 0.f ? 32768.f : 32767.f))) for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_vec3_float const & input = src[*index]; dst->x = _convert(input.x); dst->y = _convert(input.y); dst->z = _convert(input.z); dst->pad = 0; } #undef _convert } static void rk_pack_vec3_int10( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_vec3_int10 * __restrict dst = reinterpret_cast(_dst); rk_vec3_float const * const __restrict src = reinterpret_cast(_src); #define _convert(s) (static_cast((s)) & 1023) for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_vec3_float const & input = src[*index]; *dst = _convert(input.x) | (_convert(input.y) << 10) | (_convert(input.z) << 20); } #undef _convert } static void rk_pack_vec3_int10_norm( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_vec3_int10 * __restrict dst = reinterpret_cast(_dst); rk_vec3_float const * const __restrict src = reinterpret_cast(_src); #define _convert(s) (static_cast((s) * ((s) < 0.f ? 512.f : 511.f)) & 1023) for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_vec3_float const & input = src[*index]; *dst = _convert(input.x) | (_convert(input.y) << 10) | (_convert(input.z) << 20); } #undef _convert } static void rk_pack_mat3_float( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_mat3_float * __restrict dst = reinterpret_cast(_dst); rk_mat3_float const * const __restrict src = reinterpret_cast(_src); for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { *dst = src[*index]; } #undef _convert } static void rk_pack_mat3_int10( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_mat3_int10 * __restrict dst = reinterpret_cast(_dst); rk_mat3_float const * const __restrict src = reinterpret_cast(_src); #define _convert(s) (static_cast((s)) & 1023) for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_mat3_float const & input = src[*index]; dst->x = _convert(input.x.x) | (_convert(input.x.y) << 10) | (_convert(input.x.z) << 20); dst->y = _convert(input.y.x) | (_convert(input.y.y) << 10) | (_convert(input.y.z) << 20); dst->z = _convert(input.z.x) | (_convert(input.z.y) << 10) | (_convert(input.z.z) << 20); } #undef _convert } static void rk_pack_mat3_int10_norm( unsigned const count, rk_ushort const * const __restrict indices, rk_ubyte * __restrict _dst, rk_ubyte const * const __restrict _src) { rk_ushort const * const last_index = indices + count; rk_mat3_int10 * __restrict dst = reinterpret_cast(_dst); rk_mat3_float const * const __restrict src = reinterpret_cast(_src); #define _convert(s) (static_cast((s) * ((s) < 0.f ? 512.f : 511.f)) & 1023) for (rk_ushort const * __restrict index = indices; index < last_index; ++index, ++dst) { rk_mat3_float const & input = src[*index]; dst->x = _convert(input.x.x) | (_convert(input.x.y) << 10) | (_convert(input.x.z) << 20); dst->y = _convert(input.y.x) | (_convert(input.y.y) << 10) | (_convert(input.y.z) << 20); dst->z = _convert(input.z.x) | (_convert(input.z.y) << 10) | (_convert(input.z.z) << 20); } #undef _convert } rk_batch_t rk_create_batch( rk_vertices_t _vertices, rk_uint max_size, rk_uint max_meshes, rk_param_format const * params_format) { rk_vertices const * const vertices = reinterpret_cast(_vertices); if (!vertices || !max_size || max_size > RK_BATCH_MAX_SIZE) { rk_printf("rk_create_batch(): invalid parameters."); return nullptr; } unsigned vertex_size = 0; for (rk_vertex_format const * f = vertices->format; *f; ++f) { switch (*f & RK_VERTEX_FORMAT_MASK) { case RK_VERTEX_FORMAT_VEC3_FLOAT: vertex_size += sizeof(rk_vec3_float); break; case RK_VERTEX_FORMAT_VEC3_INT10: vertex_size += sizeof(rk_vec3_int10); break; case RK_VERTEX_FORMAT_VEC3_UINT10: vertex_size += sizeof(rk_vec3_uint10); break; } } unsigned nparams = 0; unsigned params_size = 0; if (params_format) { for (rk_param_format const * f = params_format; *f; ++f, ++nparams) { switch (*f & RK_PARAM_FORMAT_MASK) { case RK_PARAM_FORMAT_VEC3_FLOAT: params_size += sizeof(rk_vec3_float); break; case RK_PARAM_FORMAT_VEC3_SHORT: params_size += sizeof(rk_vec3_short); break; case RK_PARAM_FORMAT_VEC3_INT10: params_size += sizeof(rk_vec3_int10); break; case RK_PARAM_FORMAT_MAT3_FLOAT: params_size += sizeof(rk_mat3_float); break; case RK_PARAM_FORMAT_MAT3_INT10: params_size += sizeof(rk_mat3_int10); break; default: rk_printf("rk_create_batch(): invalid param format."); return nullptr; break; } } } rk_batch * batch = new rk_batch; batch->max_size = max_size; batch->max_meshes = max_meshes; batch->nparams = nparams; batch->indices = new rk_ushort[max_size]; batch->commands = new rk_command[max_meshes]; batch->params = new rk_parameter[nparams]; glGenVertexArrays(1, &batch->vertex_array); glBindVertexArray(batch->vertex_array); glGenBuffers(1, &batch->vertices_buffer); glBindBuffer(GL_ARRAY_BUFFER, batch->vertices_buffer); glBufferData(GL_ARRAY_BUFFER, vertices->nvertices * vertex_size, vertices->vertices, GL_STATIC_DRAW); glBindBuffer(GL_ARRAY_BUFFER, 0); glGenBuffers(1, &batch->indices_buffer); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, batch->indices_buffer); glBufferData(GL_ELEMENT_ARRAY_BUFFER, vertices->nindices * sizeof(rk_ushort), vertices->indices, GL_STATIC_DRAW); if (rk_MultiDrawElementsIndirect) { glGenBuffers(1, &batch->commands_buffer); glBindBuffer(GL_DRAW_INDIRECT_BUFFER, batch->commands_buffer); glBufferData(GL_DRAW_INDIRECT_BUFFER, max_meshes * sizeof(rk_command), nullptr, GL_DYNAMIC_DRAW); glBindBuffer(GL_DRAW_INDIRECT_BUFFER, 0); } if (nparams) { glGenBuffers(1, &batch->params_buffer); glBindBuffer(GL_ARRAY_BUFFER, batch->params_buffer); glBufferData(GL_ARRAY_BUFFER, max_size * params_size, nullptr, GL_DYNAMIC_DRAW); glBindBuffer(GL_ARRAY_BUFFER, 0); } unsigned binding = 0; unsigned attrib = 0; unsigned offset = 0; glBindVertexBuffer(binding, batch->vertices_buffer, 0, vertex_size); for (rk_vertex_format const * f = vertices->format; *f; ++f) { GLboolean const norm = (*f & RK_VERTEX_FORMAT_NORMALIZE) != 0; switch (*f & RK_VERTEX_FORMAT_MASK) { case RK_VERTEX_FORMAT_VEC3_FLOAT: glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_FLOAT, GL_FALSE, offset); glVertexAttribBinding(attrib++, binding); offset += sizeof(rk_vec3_float); break; case RK_VERTEX_FORMAT_VEC3_INT10: glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_INT_2_10_10_10_REV, norm, offset); glVertexAttribBinding(attrib++, binding); offset += sizeof(rk_vec3_int10); break; case RK_VERTEX_FORMAT_VEC3_UINT10: glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_UNSIGNED_INT_2_10_10_10_REV, norm, offset); glVertexAttribBinding(attrib++, binding); offset += sizeof(rk_vec3_uint10); break; } } ++binding; offset = 0; if (nparams) { rk_parameter * param = batch->params; for (rk_param_format const * f = params_format; *f; ++f, ++param, ++binding) { GLboolean const norm = (*f & RK_PARAM_FORMAT_NORMALIZE) != 0; switch (*f & RK_PARAM_FORMAT_MASK) { case RK_PARAM_FORMAT_VEC3_FLOAT: param->binding = binding; param->offset = offset; param->size = sizeof(rk_vec3_float); param->packer = rk_pack_vec3_float; glBindVertexBuffer(binding, batch->params_buffer, param->offset, param->size); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_FLOAT, GL_FALSE, 0); glVertexAttribBinding(attrib++, binding); glVertexBindingDivisor(binding, 1); offset += max_size * param->size; break; case RK_PARAM_FORMAT_VEC3_SHORT: param->binding = binding; param->offset = offset; param->size = sizeof(rk_vec3_short); param->packer = norm ? rk_pack_vec3_short_norm : rk_pack_vec3_short; glBindVertexBuffer(binding, batch->params_buffer, param->offset, param->size); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_SHORT, norm, 0); glVertexAttribBinding(attrib++, binding); glVertexBindingDivisor(binding, 1); offset += max_size * param->size; break; case RK_PARAM_FORMAT_VEC3_INT10: param->binding = binding; param->offset = offset; param->size = sizeof(rk_vec3_int10); param->packer = norm ? rk_pack_vec3_int10_norm : rk_pack_vec3_int10; glBindVertexBuffer(binding, batch->params_buffer, param->offset, param->size); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_INT_2_10_10_10_REV, norm, 0); glVertexAttribBinding(attrib++, binding); glVertexBindingDivisor(binding, 1); offset += max_size * param->size; break; case RK_PARAM_FORMAT_MAT3_FLOAT: param->binding = binding; param->offset = offset; param->size = sizeof(rk_mat3_float); param->packer = rk_pack_mat3_float; glBindVertexBuffer(binding, batch->params_buffer, param->offset, param->size); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_FLOAT, GL_FALSE, offsetof(rk_mat3_float, x)); glVertexAttribBinding(attrib++, binding); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_FLOAT, GL_FALSE, offsetof(rk_mat3_float, y)); glVertexAttribBinding(attrib++, binding); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 3, GL_FLOAT, GL_FALSE, offsetof(rk_mat3_float, z)); glVertexAttribBinding(attrib++, binding); glVertexBindingDivisor(binding, 1); offset += max_size * param->size; break; case RK_PARAM_FORMAT_MAT3_INT10: param->binding = binding; param->offset = offset; param->size = sizeof(rk_mat3_int10); param->packer = norm ? rk_pack_mat3_int10_norm : rk_pack_mat3_int10; glBindVertexBuffer(binding, batch->params_buffer, param->offset, param->size); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_INT_2_10_10_10_REV, norm, offsetof(rk_mat3_int10, x)); glVertexAttribBinding(attrib++, binding); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_INT_2_10_10_10_REV, norm, offsetof(rk_mat3_int10, y)); glVertexAttribBinding(attrib++, binding); glEnableVertexAttribArray(attrib); glVertexAttribFormat(attrib, 4, GL_INT_2_10_10_10_REV, norm, offsetof(rk_mat3_int10, z)); glVertexAttribBinding(attrib++, binding); glVertexBindingDivisor(binding, 1); offset += max_size * param->size; break; } } } glBindVertexArray(0); return reinterpret_cast(batch); } void rk_begin_frame() { glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT | GL_STENCIL_BUFFER_BIT); } void rk_select_shader( rk_shader_t _shader) { rk_shader * const shader = reinterpret_cast(_shader); if (shader) { glUseProgram(shader->program); } } void rk_set_input_float( rk_input_t _input, float value) { GLint const input = reinterpret_cast(_input) - 1; if (input > -1) { glUniform1f(input, value); } } void rk_set_input_vec3( rk_input_t _input, rk_vec3 const & value) { GLint const input = reinterpret_cast(_input) - 1; if (input > -1) { glUniform3fv(input, 1, glm::value_ptr(value)); } } void rk_set_input_mat3( rk_input_t _input, rk_mat3 const & value) { GLint const input = reinterpret_cast(_input) - 1; if (input > -1) { glUniformMatrix3fv(input, 1, GL_FALSE, glm::value_ptr(value)); } } void rk_set_input_mat4( rk_input_t _input, rk_mat4 const & value) { GLint const input = reinterpret_cast(_input) - 1; if (input > -1) { glUniformMatrix4fv(input, 1, GL_FALSE, glm::value_ptr(value)); } } void rk_set_param_vec3( rk_param_t _param, rk_vec3 const & value) { GLint const param = reinterpret_cast(_param) - 1; if (param > -1) { glVertexAttrib3fv(param, glm::value_ptr(value)); } } void rk_set_param_mat3( rk_param_t _param, rk_mat3 const & value) { GLint const param = reinterpret_cast(_param) - 1; if (param > -1) { glVertexAttrib3fv(param + 0, glm::value_ptr(value[0])); glVertexAttrib3fv(param + 1, glm::value_ptr(value[1])); glVertexAttrib3fv(param + 2, glm::value_ptr(value[2])); } } void rk_select_texture( rk_uint slot, rk_texture_t _texture, rk_input_t _sampler) { rk_texture const * const texture = reinterpret_cast(_texture); GLint const sampler = reinterpret_cast(_sampler) - 1; if (texture && sampler > -1) { glActiveTexture(GL_TEXTURE0 + slot); if (texture->nlevels) { glBindTexture(GL_TEXTURE_2D_ARRAY, texture->texture); } else { glBindTexture(GL_TEXTURE_2D, texture->texture); } glUniform1i(sampler, slot); } } RK_EXPORT void rk_draw_triangles( rk_triangles_t _triangles) { rk_triangles const * const triangles = reinterpret_cast(_triangles); if (triangles) { glBindVertexArray(triangles->array); glDrawArrays(GL_TRIANGLES, 0, triangles->size); glBindVertexArray(0); } } static unsigned rk_batch_filter( rk_batch const & batch, unsigned const size, rk_instance_flags const * flags) { rk_ushort * indices = batch.indices; for (unsigned index = 0; index < size; ++index, ++flags) { if ((*flags & RK_INSTANCE_FLAGS_SPAWNED_VISIBLE) == RK_INSTANCE_FLAGS_SPAWNED_VISIBLE) { *indices++ = static_cast(index); } } return indices - batch.indices; } static unsigned rk_batch_build_commands( rk_batch const & batch, unsigned const ninstances, rk_mesh const * const meshes) { rk_command * const last_command = batch.commands + batch.max_meshes; rk_command * command = batch.commands; rk_ushort * base = batch.indices; rk_ushort * const last = batch.indices + ninstances; for (rk_ushort * first = batch.indices; first < last && command < last_command; base = first, ++command) { rk_mesh const & mesh = meshes[*first++]; for ( ; first < last && meshes[*first].packed == mesh.packed; ++first) { } for (rk_ushort * second = first; second < last; ++second) { unsigned const index = *second; if (meshes[index].packed == mesh.packed) { *second = *first; *first++ = static_cast(index); } } command->nvertices = static_cast(mesh.ntriangles) * 3; command->ninstances = first - base; command->base_index = mesh.base_index; command->base_vertex = 0; command->base_instance = base - batch.indices; } return command - batch.commands; } static void rk_batch_pack( rk_batch const & batch, unsigned const ninstances, rk_ubyte const ** srcs) { rk_parameter const * const last_param = batch.params + batch.nparams; for (rk_parameter const * param = batch.params; param < last_param; ++param) { rk_ubyte const * const src = *srcs++; if (src) { rk_ubyte * const dst = reinterpret_cast( glMapBufferRange(GL_ARRAY_BUFFER, param->offset, ninstances * param->size, GL_MAP_WRITE_BIT | GL_MAP_INVALIDATE_RANGE_BIT | GL_MAP_UNSYNCHRONIZED_BIT)); if (dst) { param->packer(ninstances, batch.indices, dst, src); glUnmapBuffer(GL_ARRAY_BUFFER); } } } } void rk_draw_batch( rk_batch_t _batch, rk_uint count, rk_instance_flags const * flags, rk_mesh const * meshes, rk_ubyte const ** params) { rk_batch const * const batch = reinterpret_cast(_batch); if (!batch || !count || count > batch->max_size || !flags || !meshes) { return; } unsigned const ninstances = rk_batch_filter(*batch, count, flags); if (!ninstances) { return; } glBindVertexArray(batch->vertex_array); unsigned const ncommands = rk_batch_build_commands(*batch, ninstances, meshes); if (rk_MultiDrawElementsIndirect) { glBindBuffer(GL_DRAW_INDIRECT_BUFFER, batch->commands_buffer); glBufferSubData(GL_DRAW_INDIRECT_BUFFER, 0, ncommands * sizeof(rk_command), batch->commands); } if (batch->nparams && params) { glBindBuffer(GL_ARRAY_BUFFER, batch->params_buffer); rk_batch_pack(*batch, ninstances, params); } if (rk_DrawElementsInstancedBaseInstance) { if (rk_MultiDrawElementsIndirect) { rk_MultiDrawElementsIndirect(GL_TRIANGLES, GL_UNSIGNED_SHORT, nullptr, ncommands, sizeof(rk_command)); } else { rk_command const * const last_command = batch->commands + ncommands; for (rk_command const * command = batch->commands; command < last_command; ++command) { rk_DrawElementsInstancedBaseInstance( GL_TRIANGLES, command->nvertices, GL_UNSIGNED_SHORT, reinterpret_cast(command->base_index << 1), command->ninstances, command->base_instance); } } } else { unsigned param_index = 0; rk_command const * const last_command = batch->commands + ncommands; rk_parameter const * const last_param = batch->params + batch->nparams; for (rk_command const * command = batch->commands; command < last_command; ++command) { for (rk_parameter const * param = batch->params; param < last_param; ++param) { glBindVertexBuffer(param->binding, batch->params_buffer, param->offset + param_index * param->size, param->size); } param_index += command->ninstances; glDrawElementsInstanced( GL_TRIANGLES, command->nvertices, GL_UNSIGNED_SHORT, reinterpret_cast(command->base_index << 1), command->ninstances); } } if (rk_MultiDrawElementsIndirect) { glBindBuffer(GL_DRAW_INDIRECT_BUFFER, 0); } if (batch->nparams && params) { glBindBuffer(GL_ARRAY_BUFFER, 0); } glBindVertexArray(0); } void rk_unselect_texture( rk_uint slot, rk_texture_t _texture) { rk_texture const * const texture = reinterpret_cast(_texture); if (texture) { glActiveTexture(GL_TEXTURE0 + slot); if (texture->nlevels) { glBindTexture(GL_TEXTURE_2D, 0); } else { glBindTexture(GL_TEXTURE_2D_ARRAY, 0); } } } void rk_unselect_shader( rk_shader_t _shader) { glUseProgram(0); } void rk_end_frame() { } void rk_destroy_batch( rk_batch_t _batch) { rk_batch * const batch = reinterpret_cast(_batch); if (batch) { delete[] batch->indices; delete[] batch->commands; if (rk_MultiDrawElementsIndirect) { glDeleteBuffers(1, &batch->commands_buffer); } if (batch->nparams) { delete[] batch->params; glDeleteBuffers(1, &batch->params_buffer); } glDeleteBuffers(1, &batch->indices_buffer); glDeleteBuffers(1, &batch->vertices_buffer); glDeleteVertexArrays(1, &batch->vertex_array); delete batch; } } void rk_destroy_triangles( rk_triangles_t _triangles) { rk_triangles * const triangles = reinterpret_cast(_triangles); if (triangles) { glDeleteBuffers(1, &triangles->vertices); glDeleteVertexArrays(1, &triangles->array); delete triangles; } } void rk_destroy_vertices( rk_vertices_t _vertices) { rk_vertices * const vertices = reinterpret_cast(_vertices); if (vertices) { delete[] vertices->format; delete[] vertices->vertices; delete[] vertices->indices; delete vertices; } } void rk_destroy_texture( rk_texture_t _texture) { rk_texture * const texture = reinterpret_cast(_texture); if (texture) { glDeleteTextures(1, &texture->texture); delete texture; } } void rk_destroy_shader( rk_shader_t _shader) { rk_shader * const shader = reinterpret_cast(_shader); if (shader) { glDeleteShader(shader->vertex); glDeleteShader(shader->fragment); glDeleteProgram(shader->program); delete shader; } }