averello/kitty-mirror
1
0
Fork 0
mirror of https://github.com/kovidgoyal/kitty.git synced 2026-02-01 11:34:59 +01:00
Code Issues Packages Projects Releases Wiki Activity
Files
cli
kitty-mirror/kitty/shaders.c
Kovid Goyal 4b38818dca Make CodeQL happy
2025-02-06 10:13:48 +05:30

1410 lines
66 KiB
C
Raw Permalink Blame History

/*
* shaders.c
* Copyright (C) 2017 Kovid Goyal <kovid at kovidgoyal.net>
*
* Distributed under terms of the GPL3 license.
*/
#include "fonts.h"
#include "gl.h"
#include "cleanup.h"
#include "colors.h"
#include <stddef.h>
#include "window_logo.h"
#include "srgb_gamma.h"
#include "uniforms_generated.h"
#define BLEND_ONTO_OPAQUE glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); // blending onto opaque colors
#define BLEND_ONTO_OPAQUE_WITH_OPAQUE_OUTPUT glBlendFuncSeparate(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA, GL_ZERO, GL_ONE); // blending onto opaque colors with final color having alpha 1
#define BLEND_PREMULT glBlendFunc(GL_ONE, GL_ONE_MINUS_SRC_ALPHA); // blending of pre-multiplied colors
enum { CELL_PROGRAM, CELL_BG_PROGRAM, CELL_SPECIAL_PROGRAM, CELL_FG_PROGRAM, BORDERS_PROGRAM, GRAPHICS_PROGRAM, GRAPHICS_PREMULT_PROGRAM, GRAPHICS_ALPHA_MASK_PROGRAM, BGIMAGE_PROGRAM, TINT_PROGRAM, TRAIL_PROGRAM, NUM_PROGRAMS };
enum { SPRITE_MAP_UNIT, GRAPHICS_UNIT, BGIMAGE_UNIT, SPRITE_DECORATIONS_MAP_UNIT };
// Sprites {{{
typedef struct {
int xnum, ynum, x, y, z, last_num_of_layers, last_ynum;
GLuint texture_id;
GLint max_texture_size, max_array_texture_layers;
struct decorations_map {
GLuint texture_id;
unsigned width, height;
size_t count;
} decorations_map;
} SpriteMap;
static const SpriteMap NEW_SPRITE_MAP = { .xnum = 1, .ynum = 1, .last_num_of_layers = 1, .last_ynum = -1 };
static GLint max_texture_size = 0, max_array_texture_layers = 0;
static GLfloat
srgb_color(uint8_t color) {
return srgb_lut[color];
}
static void
color_vec3(GLint location, color_type color) {
glUniform3f(location, srgb_lut[(color >> 16) & 0xFF], srgb_lut[(color >> 8) & 0xFF], srgb_lut[color & 0xFF]);
}
static void
color_vec4_premult(GLint location, color_type color, GLfloat alpha) {
glUniform4f(location, srgb_lut[(color >> 16) & 0xFF]*alpha, srgb_lut[(color >> 8) & 0xFF]*alpha, srgb_lut[color & 0xFF]*alpha, alpha);
}
SPRITE_MAP_HANDLE
alloc_sprite_map(void) {
if (!max_texture_size) {
glGetIntegerv(GL_MAX_TEXTURE_SIZE, &(max_texture_size));
glGetIntegerv(GL_MAX_ARRAY_TEXTURE_LAYERS, &(max_array_texture_layers));
#ifdef __APPLE__
// Since on Apple we could have multiple GPUs, with different capabilities,
// upper bound the values according to the data from https://developer.apple.com/graphicsimaging/opengl/capabilities/
max_texture_size = MIN(8192, max_texture_size);
max_array_texture_layers = MIN(512, max_array_texture_layers);
#endif
sprite_tracker_set_limits(max_texture_size, max_array_texture_layers);
}
SpriteMap *ans = calloc(1, sizeof(SpriteMap));
if (!ans) fatal("Out of memory allocating a sprite map");
*ans = NEW_SPRITE_MAP;
ans->max_texture_size = max_texture_size;
ans->max_array_texture_layers = max_array_texture_layers;
return (SPRITE_MAP_HANDLE)ans;
}
void
free_sprite_data(FONTS_DATA_HANDLE fg) {
SpriteMap *sprite_map = (SpriteMap*)fg->sprite_map;
if (sprite_map) {
if (sprite_map->texture_id) free_texture(&sprite_map->texture_id);
if (sprite_map->decorations_map.texture_id) free_texture(&sprite_map->texture_id);
free(sprite_map);
fg->sprite_map = NULL;
}
}
static void
copy_32bit_texture(GLuint old_texture, GLuint new_texture, GLenum texture_type) {
// requires new texture to be at least as big as old texture. Assumes textures are 32bits per pixel
GLint width, height, layers;
glBindTexture(texture_type, old_texture);
glGetTexLevelParameteriv(texture_type, 0, GL_TEXTURE_WIDTH, &width);
glGetTexLevelParameteriv(texture_type, 0, GL_TEXTURE_HEIGHT, &height);
glGetTexLevelParameteriv(texture_type, 0, GL_TEXTURE_DEPTH, &layers);
if (GLAD_GL_ARB_copy_image) { glCopyImageSubData(old_texture, texture_type, 0, 0, 0, 0, new_texture, texture_type, 0, 0, 0, 0, width, height, layers); return; }
static bool copy_image_warned = false;
// ARB_copy_image not available, do a slow roundtrip copy
if (!copy_image_warned) {
copy_image_warned = true;
log_error("WARNING: Your system's OpenGL implementation does not have glCopyImageSubData, falling back to a slower implementation");
}
GLint internal_format;
glGetTexLevelParameteriv(texture_type, 0, GL_TEXTURE_INTERNAL_FORMAT, &internal_format);
GLenum format, type;
switch(internal_format) {
case GL_R8UI: case GL_R8I: case GL_R16UI: case GL_R16I: case GL_R32UI: case GL_R32I: case GL_RG8UI: case GL_RG8I:
case GL_RG16UI: case GL_RG16I: case GL_RG32UI: case GL_RG32I: case GL_RGB8UI: case GL_RGB8I: case GL_RGB16UI:
case GL_RGB16I: case GL_RGB32UI: case GL_RGB32I: case GL_RGBA8UI: case GL_RGBA8I: case GL_RGBA16UI: case GL_RGBA16I:
case GL_RGBA32UI: case GL_RGBA32I:
format = GL_RED_INTEGER;
type = GL_UNSIGNED_INT;
break;
default:
format = GL_RGBA;
type = GL_UNSIGNED_INT_8_8_8_8;
break;
}
glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
RAII_ALLOC(uint8_t, pixels, malloc((size_t)width * height * layers * 4u));
if (!pixels) fatal("Out of memory");
glGetTexImage(texture_type, 0, format, type, pixels);
glBindTexture(texture_type, new_texture);
glPixelStorei(GL_PACK_ALIGNMENT, 4);
if (texture_type == GL_TEXTURE_2D_ARRAY) glTexSubImage3D(GL_TEXTURE_2D_ARRAY, 0, 0, 0, 0, width, height, layers, format, type, pixels);
else glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, width, height, format, type, pixels);
}
static GLuint
setup_new_sprites_texture(GLenum texture_type) {
GLuint tex;
glGenTextures(1, &tex);
glBindTexture(texture_type, tex);
// We use GL_NEAREST otherwise glyphs that touch the edge of the cell
// often show a border between cells
glTexParameteri(texture_type, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameteri(texture_type, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameteri(texture_type, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(texture_type, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
return tex;
}
static void
realloc_sprite_decorations_texture_if_needed(FONTS_DATA_HANDLE fg) {
#define dm (sm->decorations_map)
SpriteMap *sm = (SpriteMap*)fg->sprite_map;
size_t current_capacity = (size_t)dm.width * dm.height;
if (dm.count < current_capacity && dm.texture_id) return;
GLint new_capacity = dm.count + 256;
GLint width = new_capacity, height = 1;
if (new_capacity > sm->max_texture_size) {
width = sm->max_texture_size;
height = 1 + new_capacity / width;
}
if (height > sm->max_texture_size) fatal("Max texture size too small for sprite decorations map, maybe switch to using a GL_TEXTURE_2D_ARRAY");
const GLenum texture_type = GL_TEXTURE_2D;
GLuint tex = setup_new_sprites_texture(texture_type);
glTexImage2D(texture_type, 0, GL_R32UI, width, height, 0, GL_RED_INTEGER, GL_UNSIGNED_INT, NULL);
if (dm.texture_id) { // copy data from old texture
copy_32bit_texture(dm.texture_id, tex, texture_type);
glDeleteTextures(1, &dm.texture_id);
}
glBindTexture(texture_type, 0);
dm.texture_id = tex; dm.width = width; dm.height = height;
#undef dm
}
static void
realloc_sprite_texture(FONTS_DATA_HANDLE fg) {
unsigned int xnum, ynum, z, znum, width, height;
sprite_tracker_current_layout(fg, &xnum, &ynum, &z);
znum = z + 1;
SpriteMap *sprite_map = (SpriteMap*)fg->sprite_map;
width = xnum * fg->fcm.cell_width; height = ynum * (fg->fcm.cell_height + 1);
const GLenum texture_type = GL_TEXTURE_2D_ARRAY;
GLuint tex = setup_new_sprites_texture(texture_type);
glTexStorage3D(texture_type, 1, GL_SRGB8_ALPHA8, width, height, znum);
if (sprite_map->texture_id) { // copy old texture data into new texture
copy_32bit_texture(sprite_map->texture_id, tex, texture_type);
glDeleteTextures(1, &sprite_map->texture_id);
}
glBindTexture(texture_type, 0);
sprite_map->last_num_of_layers = znum;
sprite_map->last_ynum = ynum;
sprite_map->texture_id = tex;
}
static void
ensure_sprite_map(FONTS_DATA_HANDLE fg) {
SpriteMap *sprite_map = (SpriteMap*)fg->sprite_map;
if (!sprite_map->texture_id) realloc_sprite_texture(fg);
if (!sprite_map->decorations_map.texture_id) realloc_sprite_decorations_texture_if_needed(fg);
// We have to rebind since we don't know if the texture was ever bound
// in the context of the current OSWindow
glActiveTexture(GL_TEXTURE0 + SPRITE_DECORATIONS_MAP_UNIT);
glBindTexture(GL_TEXTURE_2D, sprite_map->decorations_map.texture_id);
glActiveTexture(GL_TEXTURE0 + SPRITE_MAP_UNIT);
glBindTexture(GL_TEXTURE_2D_ARRAY, sprite_map->texture_id);
}
void
send_sprite_to_gpu(FONTS_DATA_HANDLE fg, sprite_index idx, pixel *buf, sprite_index decoration_idx) {
SpriteMap *sprite_map = (SpriteMap*)fg->sprite_map;
unsigned int xnum, ynum, znum, x, y, z;
#define dm (sprite_map->decorations_map)
if (idx >= dm.count) dm.count = idx + 1;
realloc_sprite_decorations_texture_if_needed(fg);
div_t d = div(idx, dm.width);
x = d.rem; y = d.quot;
glActiveTexture(GL_TEXTURE0 + SPRITE_DECORATIONS_MAP_UNIT);
glBindTexture(GL_TEXTURE_2D, dm.texture_id);
glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
glTexSubImage2D(GL_TEXTURE_2D, 0, x, y, 1, 1, GL_RED_INTEGER, GL_UNSIGNED_INT, &decoration_idx);
#undef dm
sprite_tracker_current_layout(fg, &xnum, &ynum, &znum);
if ((int)znum >= sprite_map->last_num_of_layers || (znum == 0 && (int)ynum > sprite_map->last_ynum)) {
realloc_sprite_texture(fg);
sprite_tracker_current_layout(fg, &xnum, &ynum, &znum);
}
glActiveTexture(GL_TEXTURE0 + SPRITE_MAP_UNIT);
glBindTexture(GL_TEXTURE_2D_ARRAY, sprite_map->texture_id);
glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
sprite_index_to_pos(idx, xnum, ynum, &x, &y, &z);
x *= fg->fcm.cell_width; y *= (fg->fcm.cell_height + 1);
glTexSubImage3D(GL_TEXTURE_2D_ARRAY, 0, x, y, z, fg->fcm.cell_width, fg->fcm.cell_height + 1, 1, GL_RGBA, GL_UNSIGNED_INT_8_8_8_8, buf);
}
void
send_image_to_gpu(GLuint *tex_id, const void* data, GLsizei width, GLsizei height, bool is_opaque, bool is_4byte_aligned, bool linear, RepeatStrategy repeat) {
if (!(*tex_id)) { glGenTextures(1, tex_id); }
glBindTexture(GL_TEXTURE_2D, *tex_id);
glPixelStorei(GL_UNPACK_ALIGNMENT, is_4byte_aligned ? 4 : 1);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, linear ? GL_LINEAR : GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, linear ? GL_LINEAR : GL_NEAREST);
RepeatStrategy r;
switch (repeat) {
case REPEAT_MIRROR:
r = GL_MIRRORED_REPEAT; break;
case REPEAT_CLAMP: {
static const GLfloat border_color[4] = {0};
glTexParameterfv(GL_TEXTURE_2D, GL_TEXTURE_BORDER_COLOR, border_color);
r = GL_CLAMP_TO_BORDER;
break;
}
default:
r = GL_REPEAT;
}
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, r);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, r);
glTexImage2D(GL_TEXTURE_2D, 0, GL_SRGB_ALPHA, width, height, 0, is_opaque ? GL_RGB : GL_RGBA, GL_UNSIGNED_BYTE, data);
}
// }}}
// Cell {{{
typedef struct CellRenderData {
struct {
GLfloat xstart, ystart, dx, dy, width, height;
} gl;
float x_ratio, y_ratio;
} CellRenderData;
typedef struct {
UniformBlock render_data;
ArrayInformation color_table;
CellUniforms uniforms;
} CellProgramLayout;
static CellProgramLayout cell_program_layouts[NUM_PROGRAMS];
typedef struct {
GraphicsUniforms uniforms;
} GraphicsProgramLayout;
static GraphicsProgramLayout graphics_program_layouts[NUM_PROGRAMS];
typedef struct {
BgimageUniforms uniforms;
} BGImageProgramLayout;
static BGImageProgramLayout bgimage_program_layout;
typedef struct {
TintUniforms uniforms;
} TintProgramLayout;
static TintProgramLayout tint_program_layout;
static void
init_cell_program(void) {
for (int i = CELL_PROGRAM; i < BORDERS_PROGRAM; i++) {
cell_program_layouts[i].render_data.index = block_index(i, "CellRenderData");
cell_program_layouts[i].render_data.size = block_size(i, cell_program_layouts[i].render_data.index);
cell_program_layouts[i].color_table.size = get_uniform_information(i, "color_table[0]", GL_UNIFORM_SIZE);
cell_program_layouts[i].color_table.offset = get_uniform_information(i, "color_table[0]", GL_UNIFORM_OFFSET);
cell_program_layouts[i].color_table.stride = get_uniform_information(i, "color_table[0]", GL_UNIFORM_ARRAY_STRIDE);
get_uniform_locations_cell(i, &cell_program_layouts[i].uniforms);
bind_program(i);
glUniform1fv(cell_program_layouts[i].uniforms.gamma_lut, arraysz(srgb_lut), srgb_lut);
}
// Sanity check to ensure the attribute location binding worked
#define C(p, name, expected) { int aloc = attrib_location(p, #name); if (aloc != expected && aloc != -1) fatal("The attribute location for %s is %d != %d in program: %d", #name, aloc, expected, p); }
for (int p = CELL_PROGRAM; p < BORDERS_PROGRAM; p++) {
C(p, colors, 0); C(p, sprite_idx, 1); C(p, is_selected, 2); C(p, decorations_sprite_map, 3);
}
#undef C
for (int i = GRAPHICS_PROGRAM; i <= GRAPHICS_ALPHA_MASK_PROGRAM; i++) {
get_uniform_locations_graphics(i, &graphics_program_layouts[i].uniforms);
}
get_uniform_locations_bgimage(BGIMAGE_PROGRAM, &bgimage_program_layout.uniforms);
get_uniform_locations_tint(TINT_PROGRAM, &tint_program_layout.uniforms);
}
#define CELL_BUFFERS enum { cell_data_buffer, selection_buffer, uniform_buffer };
ssize_t
create_cell_vao(void) {
ssize_t vao_idx = create_vao();
#define A(name, size, dtype, offset, stride) \
add_attribute_to_vao(CELL_PROGRAM, vao_idx, #name, \
/*size=*/size, /*dtype=*/dtype, /*stride=*/stride, /*offset=*/offset, /*divisor=*/1);
#define A1(name, size, dtype, offset) A(name, size, dtype, (void*)(offsetof(GPUCell, offset)), sizeof(GPUCell))
add_buffer_to_vao(vao_idx, GL_ARRAY_BUFFER);
A1(sprite_idx, 2, GL_UNSIGNED_INT, sprite_idx);
A1(colors, 3, GL_UNSIGNED_INT, fg);
add_buffer_to_vao(vao_idx, GL_ARRAY_BUFFER);
A(is_selected, 1, GL_UNSIGNED_BYTE, NULL, 0);
size_t bufnum = add_buffer_to_vao(vao_idx, GL_UNIFORM_BUFFER);
alloc_vao_buffer(vao_idx, cell_program_layouts[CELL_PROGRAM].render_data.size, bufnum, GL_STREAM_DRAW);
return vao_idx;
#undef A
#undef A1
}
ssize_t
create_graphics_vao(void) {
ssize_t vao_idx = create_vao();
add_buffer_to_vao(vao_idx, GL_ARRAY_BUFFER);
add_attribute_to_vao(GRAPHICS_PROGRAM, vao_idx, "src", 4, GL_FLOAT, 0, NULL, 0);
return vao_idx;
}
#define IS_SPECIAL_COLOR(name) (screen->color_profile->overridden.name.type == COLOR_IS_SPECIAL || (screen->color_profile->overridden.name.type == COLOR_NOT_SET && screen->color_profile->configured.name.type == COLOR_IS_SPECIAL))
static void
pick_cursor_color(Line *line, const ColorProfile *color_profile, color_type cell_fg, color_type cell_bg, index_type cell_color_x, color_type *cursor_fg, color_type *cursor_bg, color_type default_fg, color_type default_bg) {
ARGB32 fg, bg, dfg, dbg;
(void) line; (void) color_profile; (void) cell_color_x;
fg.rgb = cell_fg; bg.rgb = cell_bg;
*cursor_fg = cell_bg; *cursor_bg = cell_fg;
double cell_contrast = rgb_contrast(fg, bg);
if (cell_contrast < 2.5) {
dfg.rgb = default_fg; dbg.rgb = default_bg;
if (rgb_contrast(dfg, dbg) > cell_contrast) {
*cursor_fg = default_bg; *cursor_bg = default_fg;
}
}
}
static void
cell_update_uniform_block(ssize_t vao_idx, Screen *screen, int uniform_buffer, const CellRenderData *crd, CursorRenderInfo *cursor, OSWindow *os_window) {
struct GPUCellRenderData {
GLfloat xstart, ystart, dx, dy, use_cell_bg_for_selection_fg, use_cell_fg_for_selection_color, use_cell_for_selection_bg;
GLuint default_fg, highlight_fg, highlight_bg, cursor_fg, cursor_bg, url_color, url_style, inverted;
GLuint xnum, ynum, sprites_xnum, sprites_ynum, cursor_fg_sprite_idx, cell_height;
GLuint cursor_x1, cursor_x2, cursor_y1, cursor_y2;
GLfloat cursor_opacity;
GLuint bg_colors0, bg_colors1, bg_colors2, bg_colors3, bg_colors4, bg_colors5, bg_colors6, bg_colors7;
GLfloat bg_opacities0, bg_opacities1, bg_opacities2, bg_opacities3, bg_opacities4, bg_opacities5, bg_opacities6, bg_opacities7;
};
// Send the uniform data
struct GPUCellRenderData *rd = (struct GPUCellRenderData*)map_vao_buffer(vao_idx, uniform_buffer, GL_WRITE_ONLY);
ColorProfile *cp = screen->paused_rendering.expires_at ? &screen->paused_rendering.color_profile : screen->color_profile;
if (UNLIKELY(cp->dirty || screen->reload_all_gpu_data)) {
copy_color_table_to_buffer(cp, (GLuint*)rd, cell_program_layouts[CELL_PROGRAM].color_table.offset / sizeof(GLuint), cell_program_layouts[CELL_PROGRAM].color_table.stride / sizeof(GLuint));
}
#define COLOR(name) colorprofile_to_color(cp, cp->overridden.name, cp->configured.name).rgb
rd->default_fg = COLOR(default_fg);
rd->highlight_fg = COLOR(highlight_fg); rd->highlight_bg = COLOR(highlight_bg);
rd->bg_colors0 = COLOR(default_bg);
rd->bg_opacities0 = os_window->is_semi_transparent ? os_window->background_opacity : 1.0f;
#define SETBG(which) colorprofile_to_transparent_color(cp, which - 1, &rd->bg_colors##which, &rd->bg_opacities##which)
SETBG(1); SETBG(2); SETBG(3); SETBG(4); SETBG(5); SETBG(6); SETBG(7);
#undef SETBG
// selection
if (IS_SPECIAL_COLOR(highlight_fg)) {
if (IS_SPECIAL_COLOR(highlight_bg)) {
rd->use_cell_bg_for_selection_fg = 1.f; rd->use_cell_fg_for_selection_color = 0.f;
} else {
rd->use_cell_bg_for_selection_fg = 0.f; rd->use_cell_fg_for_selection_color = 1.f;
}
} else {
rd->use_cell_bg_for_selection_fg = 0.f; rd->use_cell_fg_for_selection_color = 0.f;
}
rd->use_cell_for_selection_bg = IS_SPECIAL_COLOR(highlight_bg) ? 1. : 0.;
// Cursor position
enum { BLOCK_IDX = 0, BEAM_IDX = 2, UNDERLINE_IDX = 3, UNFOCUSED_IDX = 4 };
Line *line_for_cursor = NULL;
if (cursor->opacity > 0) {
rd->cursor_x1 = cursor->x, rd->cursor_y1 = cursor->y;
rd->cursor_x2 = cursor->x, rd->cursor_y2 = cursor->y;
rd->cursor_opacity = cursor->opacity;
CursorShape cs = (cursor->is_focused || OPT(cursor_shape_unfocused) == NO_CURSOR_SHAPE) ? cursor->shape : OPT(cursor_shape_unfocused);
switch(cs) {
case CURSOR_BEAM:
rd->cursor_fg_sprite_idx = BEAM_IDX; break;
case CURSOR_UNDERLINE:
rd->cursor_fg_sprite_idx = UNDERLINE_IDX; break;
case CURSOR_BLOCK: case NUM_OF_CURSOR_SHAPES: case NO_CURSOR_SHAPE:
rd->cursor_fg_sprite_idx = BLOCK_IDX; break;
case CURSOR_HOLLOW:
rd->cursor_fg_sprite_idx = UNFOCUSED_IDX; break;
};
color_type cell_fg = rd->default_fg, cell_bg = rd->bg_colors0;
index_type cell_color_x = cursor->x;
bool reversed = false;
if (cursor->x < screen->columns && cursor->y < screen->lines) {
if (screen->paused_rendering.expires_at) {
linebuf_init_line(screen->paused_rendering.linebuf, cursor->y); line_for_cursor = screen->paused_rendering.linebuf->line;
} else {
linebuf_init_line(screen->linebuf, cursor->y); line_for_cursor = screen->linebuf->line;
}
}
if (line_for_cursor) {
colors_for_cell(line_for_cursor, cp, &cell_color_x, &cell_fg, &cell_bg, &reversed);
const CPUCell *cursor_cell;
const bool large_cursor = ((cursor_cell = &line_for_cursor->cpu_cells[cursor->x])->is_multicell) && cursor_cell->x == 0 && cursor_cell->y == 0;
if (large_cursor) {
switch(cs) {
case CURSOR_BEAM:
rd->cursor_y2 += cursor_cell->scale - 1; break;
case CURSOR_UNDERLINE:
rd->cursor_y1 += cursor_cell->scale - 1;
rd->cursor_y2 = rd->cursor_y1;
rd->cursor_x2 += mcd_x_limit(cursor_cell) - 1;
break;
case CURSOR_BLOCK:
rd->cursor_y2 += cursor_cell->scale - 1;
rd->cursor_x2 += mcd_x_limit(cursor_cell) - 1;
break;
case CURSOR_HOLLOW: case NUM_OF_CURSOR_SHAPES: case NO_CURSOR_SHAPE: break;
};
}
}
if (IS_SPECIAL_COLOR(cursor_color)) {
if (line_for_cursor) pick_cursor_color(line_for_cursor, cp, cell_fg, cell_bg, cell_color_x, &rd->cursor_fg, &rd->cursor_bg, rd->default_fg, rd->bg_colors0);
else { rd->cursor_fg = rd->bg_colors0; rd->cursor_bg = rd->default_fg; }
if (cell_bg == cell_fg) {
rd->cursor_fg = rd->bg_colors0; rd->cursor_bg = rd->default_fg;
} else { rd->cursor_fg = cell_bg; rd->cursor_bg = cell_fg; }
} else {
rd->cursor_bg = COLOR(cursor_color);
if (IS_SPECIAL_COLOR(cursor_text_color)) rd->cursor_fg = cell_bg;
else rd->cursor_fg = COLOR(cursor_text_color);
}
// store last rendered cursor color for trail rendering
screen->last_rendered.cursor_bg = rd->cursor_bg;
} else {
rd->cursor_x1 = screen->columns + 1; rd->cursor_x2 = screen->columns;
rd->cursor_y1 = screen->lines + 1; rd->cursor_y2 = screen->lines;
}
rd->xnum = screen->columns; rd->ynum = screen->lines;
rd->xstart = crd->gl.xstart; rd->ystart = crd->gl.ystart; rd->dx = crd->gl.dx; rd->dy = crd->gl.dy;
unsigned int x, y, z;
sprite_tracker_current_layout(os_window->fonts_data, &x, &y, &z);
rd->sprites_xnum = x; rd->sprites_ynum = y;
rd->inverted = screen_invert_colors(screen) ? 1 : 0;
rd->cell_height = os_window->fonts_data->fcm.cell_height;
#undef COLOR
rd->url_color = OPT(url_color); rd->url_style = OPT(url_style);
unmap_vao_buffer(vao_idx, uniform_buffer); rd = NULL;
}
static bool
cell_prepare_to_render(ssize_t vao_idx, Screen *screen, GLfloat xstart, GLfloat ystart, GLfloat dx, GLfloat dy, FONTS_DATA_HANDLE fonts_data) {
size_t sz;
CELL_BUFFERS;
void *address;
bool changed = false;
ensure_sprite_map(fonts_data);
const Cursor *cursor = screen->paused_rendering.expires_at ? &screen->paused_rendering.cursor : screen->cursor;
bool cursor_pos_changed = cursor->x != screen->last_rendered.cursor_x
|| cursor->y != screen->last_rendered.cursor_y;
bool disable_ligatures = screen->disable_ligatures == DISABLE_LIGATURES_CURSOR;
bool screen_resized = screen->last_rendered.columns != screen->columns || screen->last_rendered.lines != screen->lines;
#define update_cell_data { \
sz = sizeof(GPUCell) * screen->lines * screen->columns; \
address = alloc_and_map_vao_buffer(vao_idx, sz, cell_data_buffer, GL_STREAM_DRAW, GL_WRITE_ONLY); \
screen_update_cell_data(screen, address, fonts_data, disable_ligatures && cursor_pos_changed); \
unmap_vao_buffer(vao_idx, cell_data_buffer); address = NULL; \
changed = true; \
}
if (screen->paused_rendering.expires_at) {
if (!screen->paused_rendering.cell_data_updated) update_cell_data;
} else if (screen->reload_all_gpu_data || screen->scroll_changed || screen->is_dirty || screen_resized || (disable_ligatures && cursor_pos_changed)) update_cell_data;
if (cursor_pos_changed) {
screen->last_rendered.cursor_x = cursor->x;
screen->last_rendered.cursor_y = cursor->y;
}
#define update_selection_data { \
sz = (size_t)screen->lines * screen->columns; \
address = alloc_and_map_vao_buffer(vao_idx, sz, selection_buffer, GL_STREAM_DRAW, GL_WRITE_ONLY); \
screen_apply_selection(screen, address, sz); \
unmap_vao_buffer(vao_idx, selection_buffer); address = NULL; \
changed = true; \
}
#define update_graphics_data(grman) \
grman_update_layers(grman, screen->scrolled_by, xstart, ystart, dx, dy, screen->columns, screen->lines, screen->cell_size)
if (screen->paused_rendering.expires_at) {
if (!screen->paused_rendering.cell_data_updated) {
update_selection_data; update_graphics_data(screen->paused_rendering.grman);
}
screen->paused_rendering.cell_data_updated = true;
screen->last_rendered.scrolled_by = screen->paused_rendering.scrolled_by;
} else {
if (screen->reload_all_gpu_data || screen_resized || screen_is_selection_dirty(screen)) update_selection_data;
if (update_graphics_data(screen->grman)) changed = true;
screen->last_rendered.scrolled_by = screen->scrolled_by;
}
#undef update_selection_data
#undef update_cell_data
screen->last_rendered.columns = screen->columns;
screen->last_rendered.lines = screen->lines;
return changed;
}
static void
draw_background_image(OSWindow *w) {
blank_canvas(w->is_semi_transparent ? OPT(background_opacity) : 1.0f, OPT(background));
bind_program(BGIMAGE_PROGRAM);
glUniform1i(bgimage_program_layout.uniforms.image, BGIMAGE_UNIT);
glUniform1f(bgimage_program_layout.uniforms.opacity, OPT(background_opacity));
#ifdef __APPLE__
int window_width = w->window_width, window_height = w->window_height;
#else
int window_width = w->viewport_width, window_height = w->viewport_height;
#endif
GLfloat iwidth = (GLfloat)w->bgimage->width;
GLfloat iheight = (GLfloat)w->bgimage->height;
GLfloat vwidth = (GLfloat)window_width;
GLfloat vheight = (GLfloat)window_height;
if (CENTER_SCALED == OPT(background_image_layout)) {
GLfloat ifrac = iwidth / iheight;
if (ifrac > (vwidth / vheight)) {
iheight = vheight;
iwidth = iheight * ifrac;
} else {
iwidth = vwidth;
iheight = iwidth / ifrac;
}
}
glUniform4f(bgimage_program_layout.uniforms.sizes,
vwidth, vheight, iwidth, iheight);
glUniform1f(bgimage_program_layout.uniforms.premult, w->is_semi_transparent ? 1.f : 0.f);
GLfloat tiled = 0.f;;
GLfloat left = -1.0, top = 1.0, right = 1.0, bottom = -1.0;
switch (OPT(background_image_layout)) {
case TILING: case MIRRORED: case CLAMPED:
tiled = 1.f; break;
case SCALED:
break;
case CENTER_CLAMPED:
case CENTER_SCALED: {
GLfloat wfrac = (vwidth - iwidth) / vwidth;
GLfloat hfrac = (vheight - iheight) / vheight;
left += wfrac;
right -= wfrac;
top -= hfrac;
bottom += hfrac;
} break;
}
glUniform1f(bgimage_program_layout.uniforms.tiled, tiled);
glUniform4f(bgimage_program_layout.uniforms.positions, left, top, right, bottom);
glActiveTexture(GL_TEXTURE0 + BGIMAGE_UNIT);
glBindTexture(GL_TEXTURE_2D, w->bgimage->texture_id);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
unbind_program();
}
static void
draw_graphics(int program, ssize_t vao_idx, ImageRenderData *data, GLuint start, GLuint count, ImageRect viewport) {
bind_program(program);
glActiveTexture(GL_TEXTURE0 + GRAPHICS_UNIT);
GraphicsUniforms *u = &graphics_program_layouts[program].uniforms;
glUniform4f(u->viewport, viewport.left, viewport.top, viewport.right, viewport.bottom);
glEnable(GL_CLIP_DISTANCE0); glEnable(GL_CLIP_DISTANCE1); glEnable(GL_CLIP_DISTANCE2); glEnable(GL_CLIP_DISTANCE3);
for (GLuint i=0; i < count;) {
ImageRenderData *group = data + start + i;
glBindTexture(GL_TEXTURE_2D, group->texture_id);
if (group->group_count == 0) { i++; continue; }
for (GLuint k=0; k < group->group_count; k++, i++) {
ImageRenderData *rd = data + start + i;
glUniform4f(u->src_rect, rd->src_rect.left, rd->src_rect.top, rd->src_rect.right, rd->src_rect.bottom);
glUniform4f(u->dest_rect, rd->dest_rect.left, rd->dest_rect.top, rd->dest_rect.right, rd->dest_rect.bottom);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
}
}
glDisable(GL_CLIP_DISTANCE0); glDisable(GL_CLIP_DISTANCE1); glDisable(GL_CLIP_DISTANCE2); glDisable(GL_CLIP_DISTANCE3);
bind_vertex_array(vao_idx);
}
static ImageRenderData*
load_alpha_mask_texture(size_t width, size_t height, uint8_t *canvas) {
static ImageRenderData data = {.group_count=1};
if (!data.texture_id) { glGenTextures(1, &data.texture_id); }
glBindTexture(GL_TEXTURE_2D, data.texture_id);
glPixelStorei(GL_UNPACK_ALIGNMENT, 1);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RED, width, height, 0, GL_RED, GL_UNSIGNED_BYTE, canvas);
return &data;
}
static void
gpu_data_for_centered_image(ImageRenderData *ans, unsigned int screen_width_px, unsigned int screen_height_px, unsigned int width, unsigned int height) {
float width_frac = 2 * MIN(1, width / (float)screen_width_px), height_frac = 2 * MIN(1, height / (float)screen_height_px);
float hmargin = (2 - width_frac) / 2;
float vmargin = (2 - height_frac) / 2;
gpu_data_for_image(ans, -1 + hmargin, 1 - vmargin, -1 + hmargin + width_frac, 1 - vmargin - height_frac);
}
void
draw_centered_alpha_mask(OSWindow *os_window, size_t screen_width, size_t screen_height, size_t width, size_t height, uint8_t *canvas, float background_opacity) {
ImageRenderData *data = load_alpha_mask_texture(width, height, canvas);
gpu_data_for_centered_image(data, screen_width, screen_height, width, height);
bind_program(GRAPHICS_ALPHA_MASK_PROGRAM);
glUniform1i(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.image, GRAPHICS_UNIT);
color_vec3(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.amask_fg, OPT(foreground));
color_vec4_premult(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.amask_bg_premult, OPT(background), background_opacity);
glEnable(GL_BLEND);
if (os_window->is_semi_transparent) {
BLEND_PREMULT;
} else {
BLEND_ONTO_OPAQUE;
}
draw_graphics(GRAPHICS_ALPHA_MASK_PROGRAM, 0, data, 0, 1, (ImageRect){-1, 1, 1, -1});
glDisable(GL_BLEND);
}
static ImageRect
viewport_for_cells(const CellRenderData *crd) {
return (ImageRect){crd->gl.xstart, crd->gl.ystart, crd->gl.xstart + crd->gl.width, crd->gl.ystart - crd->gl.height};
}
static void
draw_cells_simple(ssize_t vao_idx, Screen *screen, const CellRenderData *crd, GraphicsRenderData grd, bool is_semi_transparent) {
bind_program(CELL_PROGRAM);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
if (grd.count) {
glEnable(GL_BLEND);
int program = GRAPHICS_PROGRAM;
if (is_semi_transparent) { BLEND_PREMULT; program = GRAPHICS_PREMULT_PROGRAM; } else { BLEND_ONTO_OPAQUE; }
draw_graphics(program, vao_idx, grd.images, 0, grd.count, viewport_for_cells(crd));
glDisable(GL_BLEND);
}
}
static bool
has_bgimage(OSWindow *w) {
return w->bgimage && w->bgimage->texture_id > 0;
}
static void
draw_tint(bool premult, Screen *screen, const CellRenderData *crd) {
if (premult) { BLEND_PREMULT } else { BLEND_ONTO_OPAQUE_WITH_OPAQUE_OUTPUT }
bind_program(TINT_PROGRAM);
color_type window_bg = colorprofile_to_color(screen->color_profile, screen->color_profile->overridden.default_bg, screen->color_profile->configured.default_bg).rgb;
#define C(shift) srgb_color((window_bg >> shift) & 0xFF) * premult_factor
GLfloat premult_factor = premult ? OPT(background_tint) : 1.0f;
glUniform4f(tint_program_layout.uniforms.tint_color, C(16), C(8), C(0), OPT(background_tint));
#undef C
glUniform4f(tint_program_layout.uniforms.edges, crd->gl.xstart, crd->gl.ystart - crd->gl.height, crd->gl.xstart + crd->gl.width, crd->gl.ystart);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
}
static bool
draw_scroll_indicator(bool premult, Screen *screen, const CellRenderData *crd) {
if (OPT(scrollback_indicator_opacity) <= 0 || screen->linebuf != screen->main_linebuf || !screen->scrolled_by) return false;
glEnable(GL_BLEND);
if (premult) { BLEND_PREMULT } else { BLEND_ONTO_OPAQUE }
bind_program(TINT_PROGRAM);
const color_type bar_color = colorprofile_to_color(screen->color_profile, screen->color_profile->overridden.highlight_bg, screen->color_profile->configured.highlight_bg).rgb;
GLfloat alpha = OPT(scrollback_indicator_opacity);
float frac = (float)screen->scrolled_by / (float)screen->historybuf->count;
const GLfloat bar_height = crd->gl.dy;
GLfloat bottom = (crd->gl.ystart - crd->gl.height);
bottom += MAX(0, crd->gl.height - bar_height) * frac;
#define C(shift) srgb_color((bar_color >> shift) & 0xFF) * premult_factor
GLfloat premult_factor = premult ? alpha : 1.0f;
glUniform4f(tint_program_layout.uniforms.tint_color, C(16), C(8), C(0), alpha);
#undef C
GLfloat width = 0.5f * crd->gl.dx;
GLfloat left = (GLfloat)(crd->gl.xstart + (screen->columns * crd->gl.dx - width));
glUniform4f(tint_program_layout.uniforms.edges, left, bottom, left + width, bottom + bar_height);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
glDisable(GL_BLEND);
return true;
}
static float prev_inactive_text_alpha = -1;
static void
set_cell_uniforms(float current_inactive_text_alpha, bool force) {
static bool constants_set = false;
if (!constants_set || force) {
float text_contrast = 1.0f + OPT(text_contrast) * 0.01f;
float text_gamma_adjustment = OPT(text_gamma_adjustment) < 0.01f ? 1.0f : 1.0f / OPT(text_gamma_adjustment);
for (int i = GRAPHICS_PROGRAM; i <= GRAPHICS_PREMULT_PROGRAM; i++) {
bind_program(i); glUniform1i(graphics_program_layouts[i].uniforms.image, GRAPHICS_UNIT);
}
for (int i = CELL_PROGRAM; i <= CELL_FG_PROGRAM; i++) {
bind_program(i); const CellUniforms *cu = &cell_program_layouts[i].uniforms;
switch(i) {
case CELL_PROGRAM: case CELL_FG_PROGRAM:
glUniform1i(cu->sprites, SPRITE_MAP_UNIT);
glUniform1i(cu->sprite_decorations_map, SPRITE_DECORATIONS_MAP_UNIT);
glUniform1f(cu->dim_opacity, OPT(dim_opacity));
glUniform1f(cu->text_contrast, text_contrast);
glUniform1f(cu->text_gamma_adjustment, text_gamma_adjustment);
break;
}
}
constants_set = true;
}
if (current_inactive_text_alpha != prev_inactive_text_alpha || force) {
prev_inactive_text_alpha = current_inactive_text_alpha;
for (int i = GRAPHICS_PROGRAM; i <= GRAPHICS_PREMULT_PROGRAM; i++) {
bind_program(i); glUniform1f(graphics_program_layouts[i].uniforms.inactive_text_alpha, current_inactive_text_alpha);
}
#define S(prog, loc) bind_program(prog); glUniform1f(cell_program_layouts[prog].uniforms.inactive_text_alpha, current_inactive_text_alpha);
S(CELL_PROGRAM, cploc); S(CELL_FG_PROGRAM, cfploc);
#undef S
}
}
static GLfloat
render_a_bar(OSWindow *os_window, Screen *screen, const CellRenderData *crd, WindowBarData *bar, PyObject *title, bool along_bottom) {
GLfloat left = os_window->viewport_width * (crd->gl.xstart + 1.f) / 2.f;
GLfloat right = left + os_window->viewport_width * crd->gl.width / 2.f;
unsigned bar_height = os_window->fonts_data->fcm.cell_height + 2;
if (!bar_height || right <= left) return 0;
unsigned bar_width = (unsigned)ceilf(right - left);
if (!bar->buf || bar->width != bar_width || bar->height != bar_height) {
free(bar->buf);
bar->buf = malloc((size_t)4 * bar_width * bar_height);
if (!bar->buf) return 0;
bar->height = bar_height;
bar->width = bar_width;
bar->needs_render = true;
}
if (bar->last_drawn_title_object_id != title || bar->needs_render) {
static char titlebuf[2048] = {0};
if (!title) return 0;
snprintf(titlebuf, arraysz(titlebuf), " %s", PyUnicode_AsUTF8(title));
#define RGBCOL(which, fallback) ( 0xff000000 | colorprofile_to_color_with_fallback(screen->color_profile, screen->color_profile->overridden.which, screen->color_profile->configured.which, screen->color_profile->overridden.fallback, screen->color_profile->configured.fallback))
if (!draw_window_title(os_window, titlebuf, RGBCOL(highlight_fg, default_fg), RGBCOL(highlight_bg, default_bg), bar->buf, bar_width, bar_height)) return 0;
#undef RGBCOL
Py_CLEAR(bar->last_drawn_title_object_id);
bar->last_drawn_title_object_id = title;
Py_INCREF(bar->last_drawn_title_object_id);
}
static ImageRenderData data = {.group_count=1};
GLfloat xstart, ystart;
xstart = clamp_position_to_nearest_pixel(crd->gl.xstart, os_window->viewport_width);
GLfloat height_gl = gl_size(bar_height, os_window->viewport_height);
if (along_bottom) ystart = crd->gl.ystart - crd->gl.height + height_gl;
else ystart = clamp_position_to_nearest_pixel(crd->gl.ystart, os_window->viewport_height);
gpu_data_for_image(&data, xstart, ystart, xstart + crd->gl.width, ystart - height_gl);
if (!data.texture_id) { glGenTextures(1, &data.texture_id); }
glBindTexture(GL_TEXTURE_2D, data.texture_id);
glPixelStorei(GL_UNPACK_ALIGNMENT, 1);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
glTexImage2D(GL_TEXTURE_2D, 0, GL_SRGB_ALPHA, bar_width, bar_height, 0, GL_RGBA, GL_UNSIGNED_BYTE, bar->buf);
set_cell_uniforms(1.f, false);
bind_program(GRAPHICS_PROGRAM);
glEnable(GL_BLEND);
if (os_window->is_semi_transparent) { BLEND_PREMULT; } else { BLEND_ONTO_OPAQUE; }
draw_graphics(GRAPHICS_PROGRAM, 0, &data, 0, 1, viewport_for_cells(crd));
glDisable(GL_BLEND);
return height_gl;
}
static void
draw_hyperlink_target(OSWindow *os_window, Screen *screen, const CellRenderData *crd, Window *window) {
WindowBarData *bd = &window->url_target_bar_data;
if (bd->hyperlink_id_for_title_object != screen->current_hyperlink_under_mouse.id) {
bd->hyperlink_id_for_title_object = screen->current_hyperlink_under_mouse.id;
Py_CLEAR(bd->last_drawn_title_object_id);
const char *url = get_hyperlink_for_id(screen->hyperlink_pool, bd->hyperlink_id_for_title_object, true);
if (url == NULL) url = "";
bd->last_drawn_title_object_id = PyObject_CallMethod(global_state.boss, "sanitize_url_for_dispay_to_user", "s", url);
if (bd->last_drawn_title_object_id == NULL) { PyErr_Print(); return; }
bd->needs_render = true;
}
if (bd->last_drawn_title_object_id == NULL) return;
const bool along_bottom = screen->current_hyperlink_under_mouse.y < 3;
PyObject *ref = bd->last_drawn_title_object_id;
Py_INCREF(ref);
render_a_bar(os_window, screen, crd, &window->title_bar_data, bd->last_drawn_title_object_id, along_bottom);
Py_DECREF(ref);
}
static void
draw_window_logo(ssize_t vao_idx, OSWindow *os_window, const WindowLogoRenderData *wl, const CellRenderData *crd) {
if (os_window->live_resize.in_progress) return;
BLEND_PREMULT;
GLfloat logo_width_gl = gl_size(wl->instance->width, os_window->viewport_width);
GLfloat logo_height_gl = gl_size(wl->instance->height, os_window->viewport_height);
if (OPT(window_logo_scale.width) > 0 || OPT(window_logo_scale.height) > 0) {
unsigned int scaled_wl_width = os_window->viewport_width;
unsigned int scaled_wl_height = os_window->viewport_height;
// [sx] Scales logo to sx % of the viewports shortest dimension, preserving aspect ratio
if (OPT(window_logo_scale.height) < 0) {
if (os_window->viewport_height < os_window->viewport_width) {
scaled_wl_height = (int)(os_window->viewport_height * OPT(window_logo_scale.width) / 100);
scaled_wl_width = wl->instance->width * scaled_wl_height / wl->instance->height;
} else {
scaled_wl_width = (int)(os_window->viewport_width * OPT(window_logo_scale.width) / 100);
scaled_wl_height = wl->instance->height * scaled_wl_width / wl->instance->width;
}
}
// [0 sy] Scales logo's y dimension to sy % of viewporty keeping original x dimension
else if (OPT(window_logo_scale.width) == 0.0) {
scaled_wl_height = (int)(scaled_wl_height * OPT(window_logo_scale.height) / 100);
scaled_wl_width = wl->instance->width;
}
// [sx 0] Scales logo's x dimension to sx % of viewportx keeping original y dimension
else if (OPT(window_logo_scale.height) == 0.0) {
scaled_wl_width = (int)(scaled_wl_width * OPT(window_logo_scale.width) / 100);
scaled_wl_height = wl->instance->height;
}
// [sx sy] Scales logo's x and y dimension to sx and sy % of viewportx and viewporty respectively
else {
scaled_wl_height = (int)(scaled_wl_height * OPT(window_logo_scale.height) / 100);
scaled_wl_width = (int)(scaled_wl_width * OPT(window_logo_scale.width) / 100);
}
logo_height_gl = gl_size(scaled_wl_height, os_window->viewport_height);
logo_width_gl = gl_size(scaled_wl_width, os_window->viewport_width);
}
GLfloat logo_left_gl = clamp_position_to_nearest_pixel(
crd->gl.xstart + crd->gl.width * wl->position.canvas_x - logo_width_gl * wl->position.image_x, os_window->viewport_width);
GLfloat logo_top_gl = clamp_position_to_nearest_pixel(
crd->gl.ystart - crd->gl.height * wl->position.canvas_y + logo_height_gl * wl->position.image_y, os_window->viewport_height);
static ImageRenderData ird = {.group_count=1};
ird.texture_id = wl->instance->texture_id;
gpu_data_for_image(&ird, logo_left_gl, logo_top_gl, logo_left_gl + logo_width_gl, logo_top_gl - logo_height_gl);
bind_program(GRAPHICS_PREMULT_PROGRAM);
glUniform1f(graphics_program_layouts[GRAPHICS_PREMULT_PROGRAM].uniforms.inactive_text_alpha, prev_inactive_text_alpha * wl->alpha);
draw_graphics(GRAPHICS_PREMULT_PROGRAM, vao_idx, &ird, 0, 1, viewport_for_cells(crd));
glUniform1f(graphics_program_layouts[GRAPHICS_PREMULT_PROGRAM].uniforms.inactive_text_alpha, prev_inactive_text_alpha);
}
static void
draw_window_number(OSWindow *os_window, Screen *screen, const CellRenderData *crd, Window *window) {
GLfloat left = os_window->viewport_width * (crd->gl.xstart + 1.f) / 2.f;
GLfloat right = left + os_window->viewport_width * crd->gl.width / 2.f;
GLfloat title_bar_height = 0;
size_t requested_height = (size_t)(os_window->viewport_height * crd->gl.height / 2.f);
if (window->title && PyUnicode_Check(window->title) && (requested_height > (os_window->fonts_data->fcm.cell_height + 1) * 2)) {
title_bar_height = render_a_bar(os_window, screen, crd, &window->title_bar_data, window->title, false);
}
GLfloat ystart = crd->gl.ystart, height = crd->gl.height, xstart = crd->gl.xstart, width = crd->gl.width;
if (title_bar_height > 0) {
ystart -= title_bar_height;
height -= title_bar_height;
}
ystart -= crd->gl.dy / 2.f; height -= crd->gl.dy; // top and bottom margins
xstart += crd->gl.dx / 2.f; width -= crd->gl.dx; // left and right margins
GLfloat height_gl = MIN(MIN(12 * crd->gl.dy, height), width);
requested_height = (size_t)(os_window->viewport_height * height_gl / 2.f);
if (requested_height < 4) return;
#define lr screen->last_rendered_window_char
if (!lr.canvas || lr.ch != screen->display_window_char || lr.requested_height != requested_height) {
free(lr.canvas); lr.canvas = NULL;
lr.requested_height = requested_height; lr.height_px = requested_height; lr.ch = 0;
lr.canvas = draw_single_ascii_char(screen->display_window_char, &lr.width_px, &lr.height_px);
if (lr.height_px < 4 || lr.width_px < 4 || !lr.canvas) return;
lr.ch = screen->display_window_char;
}
GLfloat width_gl = gl_size(lr.width_px, os_window->viewport_width);
height_gl = gl_size(lr.height_px, os_window->viewport_height);
left = xstart + (width - width_gl) / 2.f;
left = clamp_position_to_nearest_pixel(left, os_window->viewport_width);
right = left + width_gl;
GLfloat top = ystart - (height - height_gl) / 2.f;
top = clamp_position_to_nearest_pixel(top, os_window->viewport_height);
GLfloat bottom = top - height_gl;
bind_program(GRAPHICS_ALPHA_MASK_PROGRAM);
ImageRenderData *ird = load_alpha_mask_texture(lr.width_px, lr.height_px, lr.canvas);
#undef lr
gpu_data_for_image(ird, left, top, right, bottom);
glEnable(GL_BLEND);
BLEND_PREMULT;
glUniform1i(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.image, GRAPHICS_UNIT);
color_type digit_color = colorprofile_to_color_with_fallback(screen->color_profile, screen->color_profile->overridden.highlight_bg, screen->color_profile->configured.highlight_bg, screen->color_profile->overridden.default_fg, screen->color_profile->configured.default_fg);
color_vec3(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.amask_fg, digit_color);
glUniform4f(graphics_program_layouts[GRAPHICS_ALPHA_MASK_PROGRAM].uniforms.amask_bg_premult, 0.f, 0.f, 0.f, 0.f);
draw_graphics(GRAPHICS_ALPHA_MASK_PROGRAM, 0, ird, 0, 1, viewport_for_cells(crd));
glDisable(GL_BLEND);
}
static void
draw_visual_bell_flash(GLfloat intensity, const CellRenderData *crd, Screen *screen) {
glEnable(GL_BLEND);
// BLEND_PREMULT
glBlendFuncSeparate(GL_ONE, GL_ONE_MINUS_SRC_ALPHA, GL_ZERO, GL_ONE);
bind_program(TINT_PROGRAM);
GLfloat attenuation = 0.4f;
#define COLOR(name, fallback) colorprofile_to_color_with_fallback(screen->color_profile, screen->color_profile->overridden.name, screen->color_profile->configured.name, screen->color_profile->overridden.fallback, screen->color_profile->configured.fallback)
const color_type flash = !IS_SPECIAL_COLOR(highlight_bg) ? COLOR(visual_bell_color, highlight_bg) : COLOR(visual_bell_color, default_fg);
#undef COLOR
#define C(shift) srgb_color((flash >> shift) & 0xFF)
const GLfloat r = C(16), g = C(8), b = C(0);
const GLfloat max_channel = r > g ? (r > b ? r : b) : (g > b ? g : b);
#undef C
#define C(x) (x * intensity * attenuation)
if (max_channel > 0.45) attenuation = 0.6f; // light color
glUniform4f(tint_program_layout.uniforms.tint_color, C(r), C(g), C(b), C(1));
#undef C
glUniform4f(tint_program_layout.uniforms.edges, crd->gl.xstart, crd->gl.ystart - crd->gl.height, crd->gl.xstart + crd->gl.width, crd->gl.ystart);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
glDisable(GL_BLEND);
}
static void
draw_cells_interleaved(ssize_t vao_idx, Screen *screen, OSWindow *w, const CellRenderData *crd, GraphicsRenderData grd, const WindowLogoRenderData *wl) {
glEnable(GL_BLEND);
BLEND_ONTO_OPAQUE;
// draw background for all cells
if (!has_bgimage(w)) {
bind_program(CELL_BG_PROGRAM);
glUniform1ui(cell_program_layouts[CELL_BG_PROGRAM].uniforms.draw_bg_bitfield, 3);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
} else if (OPT(background_tint) > 0) {
draw_tint(false, screen, crd);
BLEND_ONTO_OPAQUE;
}
if (grd.num_of_below_refs || has_bgimage(w) || wl) {
if (wl) {
draw_window_logo(vao_idx, w, wl, crd);
BLEND_ONTO_OPAQUE;
}
if (grd.num_of_below_refs) draw_graphics(
GRAPHICS_PROGRAM, vao_idx, grd.images, 0, grd.num_of_below_refs, viewport_for_cells(crd));
bind_program(CELL_BG_PROGRAM);
// draw background for non-default bg cells
glUniform1ui(cell_program_layouts[CELL_BG_PROGRAM].uniforms.draw_bg_bitfield, 2);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
}
if (grd.num_of_negative_refs) draw_graphics(GRAPHICS_PROGRAM, vao_idx, grd.images, grd.num_of_below_refs, grd.num_of_negative_refs, viewport_for_cells(crd));
bind_program(CELL_SPECIAL_PROGRAM);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
bind_program(CELL_FG_PROGRAM);
BLEND_PREMULT;
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
BLEND_ONTO_OPAQUE;
if (grd.num_of_positive_refs) draw_graphics(GRAPHICS_PROGRAM, vao_idx, grd.images, grd.num_of_negative_refs + grd.num_of_below_refs, grd.num_of_positive_refs, viewport_for_cells(crd));
glDisable(GL_BLEND);
}
static void
draw_cells_interleaved_premult(ssize_t vao_idx, Screen *screen, OSWindow *os_window, const CellRenderData *crd, GraphicsRenderData grd, const WindowLogoRenderData *wl) {
if (OPT(background_tint) > 0.f) {
glEnable(GL_BLEND);
draw_tint(true, screen, crd);
glDisable(GL_BLEND);
}
bind_program(CELL_BG_PROGRAM);
if (!has_bgimage(os_window)) {
// draw background for all cells
glUniform1ui(cell_program_layouts[CELL_BG_PROGRAM].uniforms.draw_bg_bitfield, 3);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
}
glEnable(GL_BLEND);
BLEND_PREMULT;
if (grd.num_of_below_refs || has_bgimage(os_window) || wl) {
if (wl) {
draw_window_logo(vao_idx, os_window, wl, crd);
BLEND_PREMULT;
}
if (grd.num_of_below_refs) draw_graphics(
GRAPHICS_PREMULT_PROGRAM, vao_idx, grd.images, 0, grd.num_of_below_refs, viewport_for_cells(crd));
bind_program(CELL_BG_PROGRAM);
// Draw background for non-default bg cells
glUniform1ui(cell_program_layouts[CELL_BG_PROGRAM].uniforms.draw_bg_bitfield, 2);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
} else {
// Apply background_opacity
glUniform1ui(cell_program_layouts[CELL_BG_PROGRAM].uniforms.draw_bg_bitfield, 0);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
}
if (grd.num_of_negative_refs) {
draw_graphics(GRAPHICS_PREMULT_PROGRAM, vao_idx, grd.images, grd.num_of_below_refs, grd.num_of_negative_refs, viewport_for_cells(crd));
}
bind_program(CELL_SPECIAL_PROGRAM);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
bind_program(CELL_FG_PROGRAM);
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, screen->lines * screen->columns);
if (grd.num_of_positive_refs) draw_graphics(GRAPHICS_PREMULT_PROGRAM, vao_idx, grd.images, grd.num_of_negative_refs + grd.num_of_below_refs, grd.num_of_positive_refs, viewport_for_cells(crd));
glDisable(GL_BLEND);
}
void
blank_canvas(float background_opacity, color_type color) {
// See https://github.com/glfw/glfw/issues/1538 for why we use pre-multiplied alpha
#define C(shift) srgb_color((color >> shift) & 0xFF)
glClearColor(C(16), C(8), C(0), background_opacity);
#undef C
glClear(GL_COLOR_BUFFER_BIT);
}
bool
send_cell_data_to_gpu(ssize_t vao_idx, GLfloat xstart, GLfloat ystart, GLfloat dx, GLfloat dy, Screen *screen, OSWindow *os_window) {
bool changed = false;
if (os_window->fonts_data) {
if (cell_prepare_to_render(vao_idx, screen, xstart, ystart, dx, dy, os_window->fonts_data)) changed = true;
}
return changed;
}
static Animation *default_visual_bell_animation = NULL;
static float
get_visual_bell_intensity(Screen *screen) {
if (screen->start_visual_bell_at > 0) {
if (!default_visual_bell_animation) {
default_visual_bell_animation = alloc_animation();
if (!default_visual_bell_animation) fatal("Out of memory");
add_cubic_bezier_animation(default_visual_bell_animation, 0, 1, EASE_IN_OUT);
add_cubic_bezier_animation(default_visual_bell_animation, 1, 0, EASE_IN_OUT);
}
const monotonic_t progress = monotonic() - screen->start_visual_bell_at;
const monotonic_t duration = OPT(visual_bell_duration) / 2;
if (progress <= duration) {
Animation *a = animation_is_valid(OPT(animation.visual_bell)) ? OPT(animation.visual_bell) : default_visual_bell_animation;
return (float)apply_easing_curve(a, progress / (double)duration, duration);
}
screen->start_visual_bell_at = 0;
}
return 0.0f;
}
void
draw_cells(ssize_t vao_idx, const WindowRenderData *srd, OSWindow *os_window, bool is_active_window, bool is_tab_bar, bool is_single_window, Window *window) {
float x_ratio = 1., y_ratio = 1.;
if (os_window->live_resize.in_progress) {
x_ratio = (float) os_window->viewport_width / (float) os_window->live_resize.width;
y_ratio = (float) os_window->viewport_height / (float) os_window->live_resize.height;
}
Screen *screen = srd->screen;
CELL_BUFFERS;
CellRenderData crd = {
.gl={.xstart = srd->xstart, .ystart = srd->ystart, .dx = srd->dx * x_ratio, .dy = srd->dy * y_ratio},
.x_ratio=x_ratio, .y_ratio=y_ratio
};
crd.gl.width = crd.gl.dx * screen->columns; crd.gl.height = crd.gl.dy * screen->lines;
cell_update_uniform_block(vao_idx, screen, uniform_buffer, &crd, &screen->cursor_render_info, os_window);
bind_vao_uniform_buffer(vao_idx, uniform_buffer, cell_program_layouts[CELL_PROGRAM].render_data.index);
bind_vertex_array(vao_idx);
// We draw with inactive text alpha if:
// - We're not drawing the tab bar
// - There's only a single window and the os window is not focused
// - There are multiple windows and the current window is not active
float current_inactive_text_alpha = is_tab_bar || (!is_single_window && is_active_window) || (is_single_window && screen->cursor_render_info.is_focused) ? 1.0f : (float)OPT(inactive_text_alpha);
set_cell_uniforms(current_inactive_text_alpha, screen->reload_all_gpu_data);
screen->reload_all_gpu_data = false;
bool has_underlying_image = has_bgimage(os_window);
WindowLogoRenderData *wl;
if (window && (wl = &window->window_logo) && wl->id && (wl->instance = find_window_logo(global_state.all_window_logos, wl->id)) && wl->instance && wl->instance->load_from_disk_ok) {
has_underlying_image = true;
set_on_gpu_state(window->window_logo.instance, true);
} else wl = NULL;
ImageRenderData *scaled_render_data = NULL;
GraphicsManager *grman = screen->paused_rendering.expires_at && screen->paused_rendering.grman ? screen->paused_rendering.grman : screen->grman;
GraphicsRenderData grd = grman_render_data(grman);
if (os_window->live_resize.in_progress && grd.count && (crd.x_ratio != 1 || crd.y_ratio != 1)) {
scaled_render_data = malloc(sizeof(scaled_render_data[0]) * grd.count);
if (scaled_render_data) {
memcpy(scaled_render_data, grd.images, sizeof(scaled_render_data[0]) * grd.count);
grd.images = scaled_render_data;
for (size_t i = 0; i < grd.count; i++)
scale_rendered_graphic(grd.images + i, srd->xstart, srd->ystart, crd.x_ratio, crd.y_ratio);
}
}
bool use_premult = false;
has_underlying_image |= grd.num_of_below_refs > 0 || grd.num_of_negative_refs > 0;
if (os_window->is_semi_transparent) {
if (has_underlying_image) { draw_cells_interleaved_premult(vao_idx, screen, os_window, &crd, grd, wl); use_premult = true; }
else draw_cells_simple(vao_idx, screen, &crd, grd, os_window->is_semi_transparent);
} else {
if (has_underlying_image) draw_cells_interleaved(vao_idx, screen, os_window, &crd, grd, wl);
else draw_cells_simple(vao_idx, screen, &crd, grd, os_window->is_semi_transparent);
}
draw_scroll_indicator(use_premult, screen, &crd);
if (screen->start_visual_bell_at) {
GLfloat intensity = get_visual_bell_intensity(screen);
if (intensity > 0.0f) draw_visual_bell_flash(intensity, &crd, screen);
}
if (window && screen->display_window_char) draw_window_number(os_window, screen, &crd, window);
if (OPT(show_hyperlink_targets) && window && screen->current_hyperlink_under_mouse.id && !is_mouse_hidden(os_window)) draw_hyperlink_target(os_window, screen, &crd, window);
free(scaled_render_data);
}
// }}}
// Borders {{{
typedef struct BorderProgramLayout {
BorderUniforms uniforms;
} BorderProgramLayout;
static BorderProgramLayout border_program_layout;
static void
init_borders_program(void) {
get_uniform_locations_border(BORDERS_PROGRAM, &border_program_layout.uniforms);
bind_program(BORDERS_PROGRAM);
glUniform1fv(border_program_layout.uniforms.gamma_lut, 256, srgb_lut);
}
ssize_t
create_border_vao(void) {
ssize_t vao_idx = create_vao();
add_buffer_to_vao(vao_idx, GL_ARRAY_BUFFER);
add_attribute_to_vao(BORDERS_PROGRAM, vao_idx, "rect",
/*size=*/4, /*dtype=*/GL_FLOAT, /*stride=*/sizeof(BorderRect), /*offset=*/(void*)offsetof(BorderRect, left), /*divisor=*/1);
add_attribute_to_vao(BORDERS_PROGRAM, vao_idx, "rect_color",
/*size=*/1, /*dtype=*/GL_UNSIGNED_INT, /*stride=*/sizeof(BorderRect), /*offset=*/(void*)(offsetof(BorderRect, color)), /*divisor=*/1);
return vao_idx;
}
void
draw_borders(ssize_t vao_idx, unsigned int num_border_rects, BorderRect *rect_buf, bool rect_data_is_dirty, uint32_t viewport_width, uint32_t viewport_height, color_type active_window_bg, unsigned int num_visible_windows, bool all_windows_have_same_bg, OSWindow *w) {
float background_opacity = w->is_semi_transparent ? w->background_opacity: 1.0f;
float tint_opacity = background_opacity;
float tint_premult = background_opacity;
bind_vertex_array(vao_idx);
if (has_bgimage(w)) {
glEnable(GL_BLEND);
BLEND_ONTO_OPAQUE;
draw_background_image(w);
BLEND_ONTO_OPAQUE;
background_opacity = 1.0f;
tint_opacity = OPT(background_tint) * OPT(background_tint_gaps);
tint_premult = w->is_semi_transparent ? OPT(background_tint) : 1.0f;
}
if (num_border_rects) {
bind_program(BORDERS_PROGRAM);
if (rect_data_is_dirty) {
const size_t sz = sizeof(BorderRect) * num_border_rects;
void *borders_buf_address = alloc_and_map_vao_buffer(vao_idx, sz, 0, GL_STATIC_DRAW, GL_WRITE_ONLY);
if (borders_buf_address) memcpy(borders_buf_address, rect_buf, sz);
unmap_vao_buffer(vao_idx, 0);
}
color_type default_bg = (num_visible_windows > 1 && !all_windows_have_same_bg) ? OPT(background) : active_window_bg;
GLuint colors[9] = {
default_bg, OPT(active_border_color), OPT(inactive_border_color), 0,
OPT(bell_border_color), OPT(tab_bar_background), OPT(tab_bar_margin_color),
w->tab_bar_edge_color.left, w->tab_bar_edge_color.right
};
glUniform1uiv(border_program_layout.uniforms.colors, arraysz(colors), colors);
glUniform1f(border_program_layout.uniforms.background_opacity, background_opacity);
glUniform1f(border_program_layout.uniforms.tint_opacity, tint_opacity);
glUniform1f(border_program_layout.uniforms.tint_premult, tint_premult);
glUniform2ui(border_program_layout.uniforms.viewport, viewport_width, viewport_height);
if (has_bgimage(w)) {
if (w->is_semi_transparent) { BLEND_PREMULT; }
else { BLEND_ONTO_OPAQUE_WITH_OPAQUE_OUTPUT; }
}
glDrawArraysInstanced(GL_TRIANGLE_FAN, 0, 4, num_border_rects);
unbind_program();
}
unbind_vertex_array();
if (has_bgimage(w)) glDisable(GL_BLEND);
}
// }}}
// Cursor Trail {{{
typedef struct {
TrailUniforms uniforms;
} TrailProgramLayout;
static TrailProgramLayout trail_program_layout;
static void
init_trail_program(void) {
get_uniform_locations_trail(TRAIL_PROGRAM, &trail_program_layout.uniforms);
}
void
draw_cursor_trail(CursorTrail *trail, Window *active_window) {
bind_program(TRAIL_PROGRAM);
glEnable(GL_BLEND);
BLEND_ONTO_OPAQUE;
glUniform4fv(trail_program_layout.uniforms.x_coords, 1, trail->corner_x);
glUniform4fv(trail_program_layout.uniforms.y_coords, 1, trail->corner_y);
glUniform2fv(trail_program_layout.uniforms.cursor_edge_x, 1, trail->cursor_edge_x);
glUniform2fv(trail_program_layout.uniforms.cursor_edge_y, 1, trail->cursor_edge_y);
color_vec3(trail_program_layout.uniforms.trail_color, active_window ? active_window->render_data.screen->last_rendered.cursor_bg : OPT(foreground));
glUniform1fv(trail_program_layout.uniforms.trail_opacity, 1, &trail->opacity);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
glDisable(GL_BLEND);
unbind_program();
}
// }}}
// Python API {{{
static bool
attach_shaders(PyObject *sources, GLuint program_id, GLenum shader_type) {
RAII_ALLOC(const GLchar*, c_sources, calloc(PyTuple_GET_SIZE(sources), sizeof(GLchar*)));
for (Py_ssize_t i = 0; i < PyTuple_GET_SIZE(sources); i++) {
PyObject *temp = PyTuple_GET_ITEM(sources, i);
if (!PyUnicode_Check(temp)) { PyErr_SetString(PyExc_TypeError, "shaders must be strings"); return false; }
c_sources[i] = PyUnicode_AsUTF8(temp);
}
GLuint shader_id = compile_shaders(shader_type, PyTuple_GET_SIZE(sources), c_sources);
if (shader_id == 0) return false;
glAttachShader(program_id, shader_id);
glDeleteShader(shader_id);
return true;
}
static PyObject*
compile_program(PyObject UNUSED *self, PyObject *args) {
PyObject *vertex_shaders, *fragment_shaders;
int which, allow_recompile = 0;
if (!PyArg_ParseTuple(args, "iO!O!|p", &which, &PyTuple_Type, &vertex_shaders, &PyTuple_Type, &fragment_shaders, &allow_recompile)) return NULL;
if (which < 0 || which >= NUM_PROGRAMS) { PyErr_Format(PyExc_ValueError, "Unknown program: %d", which); return NULL; }
Program *program = program_ptr(which);
if (program->id != 0) {
if (allow_recompile) { glDeleteProgram(program->id); program->id = 0; }
else { PyErr_SetString(PyExc_ValueError, "program already compiled"); return NULL; }
}
#define fail_compile() { glDeleteProgram(program->id); return NULL; }
program->id = glCreateProgram();
if (!attach_shaders(vertex_shaders, program->id, GL_VERTEX_SHADER)) fail_compile();
if (!attach_shaders(fragment_shaders, program->id, GL_FRAGMENT_SHADER)) fail_compile();
glLinkProgram(program->id);
GLint ret = GL_FALSE;
glGetProgramiv(program->id, GL_LINK_STATUS, &ret);
if (ret != GL_TRUE) {
GLsizei len;
static char glbuf[4096];
glGetProgramInfoLog(program->id, sizeof(glbuf), &len, glbuf);
PyErr_Format(PyExc_ValueError, "Failed to link GLSL shaders:\n%s", glbuf);
fail_compile();
}
#undef fail_compile
init_uniforms(which);
return Py_BuildValue("I", program->id);
}
#define PYWRAP0(name) static PyObject* py##name(PYNOARG)
#define PYWRAP1(name) static PyObject* py##name(PyObject UNUSED *self, PyObject *args)
#define PA(fmt, ...) if(!PyArg_ParseTuple(args, fmt, __VA_ARGS__)) return NULL;
#define ONE_INT(name) PYWRAP1(name) { name(PyLong_AsSsize_t(args)); Py_RETURN_NONE; }
#define TWO_INT(name) PYWRAP1(name) { int a, b; PA("ii", &a, &b); name(a, b); Py_RETURN_NONE; }
#define NO_ARG(name) PYWRAP0(name) { name(); Py_RETURN_NONE; }
#define NO_ARG_INT(name) PYWRAP0(name) { return PyLong_FromSsize_t(name()); }
ONE_INT(bind_program)
NO_ARG(unbind_program)
PYWRAP0(create_vao) {
int ans = create_vao();
if (ans < 0) return NULL;
return Py_BuildValue("i", ans);
}
ONE_INT(bind_vertex_array)
NO_ARG(unbind_vertex_array)
TWO_INT(unmap_vao_buffer)
NO_ARG(init_borders_program)
NO_ARG(init_cell_program)
NO_ARG(init_trail_program)
static PyObject*
sprite_map_set_limits(PyObject UNUSED *self, PyObject *args) {
unsigned int w, h;
if(!PyArg_ParseTuple(args, "II", &w, &h)) return NULL;
sprite_tracker_set_limits(w, h);
max_texture_size = w; max_array_texture_layers = h;
Py_RETURN_NONE;
}
#define M(name, arg_type) {#name, (PyCFunction)name, arg_type, NULL}
#define MW(name, arg_type) {#name, (PyCFunction)py##name, arg_type, NULL}
static PyMethodDef module_methods[] = {
M(compile_program, METH_VARARGS),
M(sprite_map_set_limits, METH_VARARGS),
MW(create_vao, METH_NOARGS),
MW(bind_vertex_array, METH_O),
MW(unbind_vertex_array, METH_NOARGS),
MW(unmap_vao_buffer, METH_VARARGS),
MW(bind_program, METH_O),
MW(unbind_program, METH_NOARGS),
MW(init_borders_program, METH_NOARGS),
MW(init_cell_program, METH_NOARGS),
MW(init_trail_program, METH_NOARGS),
{NULL, NULL, 0, NULL} /* Sentinel */
};
static void
finalize(void) {
default_visual_bell_animation = free_animation(default_visual_bell_animation);
}
bool
init_shaders(PyObject *module) {
#define C(x) if (PyModule_AddIntConstant(module, #x, x) != 0) { PyErr_NoMemory(); return false; }
C(CELL_PROGRAM); C(CELL_BG_PROGRAM); C(CELL_SPECIAL_PROGRAM); C(CELL_FG_PROGRAM); C(BORDERS_PROGRAM); C(GRAPHICS_PROGRAM); C(GRAPHICS_PREMULT_PROGRAM); C(GRAPHICS_ALPHA_MASK_PROGRAM); C(BGIMAGE_PROGRAM); C(TINT_PROGRAM); C(TRAIL_PROGRAM);
C(GLSL_VERSION);
C(GL_VERSION);
C(GL_VENDOR);
C(GL_SHADING_LANGUAGE_VERSION);
C(GL_RENDERER);
C(GL_TRIANGLE_FAN); C(GL_TRIANGLE_STRIP); C(GL_TRIANGLES); C(GL_LINE_LOOP);
C(GL_COLOR_BUFFER_BIT);
C(GL_VERTEX_SHADER);
C(GL_FRAGMENT_SHADER);
C(GL_TRUE);
C(GL_FALSE);
C(GL_COMPILE_STATUS);
C(GL_LINK_STATUS);
C(GL_TEXTURE0); C(GL_TEXTURE1); C(GL_TEXTURE2); C(GL_TEXTURE3); C(GL_TEXTURE4); C(GL_TEXTURE5); C(GL_TEXTURE6); C(GL_TEXTURE7); C(GL_TEXTURE8);
C(GL_MAX_ARRAY_TEXTURE_LAYERS); C(GL_TEXTURE_BINDING_BUFFER); C(GL_MAX_TEXTURE_BUFFER_SIZE);
C(GL_MAX_TEXTURE_SIZE);
C(GL_TEXTURE_2D_ARRAY);
C(GL_LINEAR); C(GL_CLAMP_TO_EDGE); C(GL_NEAREST);
C(GL_TEXTURE_MIN_FILTER); C(GL_TEXTURE_MAG_FILTER);
C(GL_TEXTURE_WRAP_S); C(GL_TEXTURE_WRAP_T);
C(GL_UNPACK_ALIGNMENT);
C(GL_R8); C(GL_RED); C(GL_UNSIGNED_BYTE); C(GL_UNSIGNED_SHORT); C(GL_R32UI); C(GL_RGB32UI); C(GL_RGBA);
C(GL_TEXTURE_BUFFER); C(GL_STATIC_DRAW); C(GL_STREAM_DRAW); C(GL_DYNAMIC_DRAW);
C(GL_SRC_ALPHA); C(GL_ONE_MINUS_SRC_ALPHA);
C(GL_WRITE_ONLY); C(GL_READ_ONLY); C(GL_READ_WRITE);
C(GL_BLEND); C(GL_FLOAT); C(GL_UNSIGNED_INT); C(GL_ARRAY_BUFFER); C(GL_UNIFORM_BUFFER);
#undef C
if (PyModule_AddFunctions(module, module_methods) != 0) return false;
register_at_exit_cleanup_func(SHADERS_CLEANUP_FUNC, finalize);
return true;
}
// }}}
Reference in New Issue View Git Blame Copy Permalink