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kitty/kitty/graphics.c
Kovid Goyal 78c63e6a18
Show window titles during visual select 
Still has to be implemented on macOS
2021-10-15 14:19:56 +05:30

1856 lines
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/*
* graphics.c
* Copyright (C) 2017 Kovid Goyal <kovid at kovidgoyal.net>
*
* Distributed under terms of the GPL3 license.
*/
#include "graphics.h"
#include "state.h"
#include "disk-cache.h"
#include "iqsort.h"
#include "safe-wrappers.h"
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <sys/mman.h>
#include <stdlib.h>
#include <zlib.h>
#include <structmember.h>
#include "png-reader.h"
PyTypeObject GraphicsManager_Type;
#define DEFAULT_STORAGE_LIMIT 320u * (1024u * 1024u)
#define REPORT_ERROR(...) { log_error(__VA_ARGS__); }
#define FREE_CFD_AFTER_FUNCTION __attribute__((cleanup(cfd_free)))
// caching {{{
#define CACHE_KEY_BUFFER_SIZE 32
static size_t
cache_key(const ImageAndFrame x, char *key) {
return snprintf(key, CACHE_KEY_BUFFER_SIZE, "%llx:%x", x.image_id, x.frame_id);
}
#define CK(x) key, cache_key(x, key)
static bool
add_to_cache(GraphicsManager *self, const ImageAndFrame x, const void *data, const size_t sz) {
char key[CACHE_KEY_BUFFER_SIZE];
return add_to_disk_cache(self->disk_cache, CK(x), data, sz);
}
static bool
remove_from_cache(GraphicsManager *self, const ImageAndFrame x) {
char key[CACHE_KEY_BUFFER_SIZE];
return remove_from_disk_cache(self->disk_cache, CK(x));
}
static bool
read_from_cache(const GraphicsManager *self, const ImageAndFrame x, void **data, size_t *sz) {
char key[CACHE_KEY_BUFFER_SIZE];
return read_from_disk_cache_simple(self->disk_cache, CK(x), data, sz, false);
}
static size_t
cache_size(const GraphicsManager *self) { return disk_cache_total_size(self->disk_cache); }
#undef CK
// }}}
GraphicsManager*
grman_alloc() {
GraphicsManager *self = (GraphicsManager *)GraphicsManager_Type.tp_alloc(&GraphicsManager_Type, 0);
self->images_capacity = self->capacity = 64;
self->images = calloc(self->images_capacity, sizeof(Image));
self->render_data = calloc(self->capacity, sizeof(ImageRenderData));
self->storage_limit = DEFAULT_STORAGE_LIMIT;
if (self->images == NULL || self->render_data == NULL) {
PyErr_NoMemory();
Py_CLEAR(self); return NULL;
}
self->disk_cache = create_disk_cache();
if (!self->disk_cache) { Py_CLEAR(self); return NULL; }
return self;
}
static void
free_refs_data(Image *img) {
free(img->refs); img->refs = NULL;
img->refcnt = 0; img->refcap = 0;
}
static void
free_load_data(LoadData *ld) {
free(ld->buf); ld->buf_used = 0; ld->buf_capacity = 0; ld->buf = NULL;
if (ld->mapped_file) munmap(ld->mapped_file, ld->mapped_file_sz);
ld->mapped_file = NULL; ld->mapped_file_sz = 0;
ld->loading_for = (const ImageAndFrame){0};
}
static void
free_image(GraphicsManager *self, Image *img) {
if (img->texture_id) free_texture(&img->texture_id);
ImageAndFrame key = { .image_id=img->internal_id, .frame_id = img->root_frame.id };
if (!remove_from_cache(self, key) && PyErr_Occurred()) PyErr_Print();
for (unsigned i = 0; i < img->extra_framecnt; i++) {
key.frame_id = img->extra_frames[i].id;
if (!remove_from_cache(self, key) && PyErr_Occurred()) PyErr_Print();
}
if (img->extra_frames) {
free(img->extra_frames);
img->extra_frames = NULL;
}
free_refs_data(img);
self->used_storage -= img->used_storage;
}
static void
dealloc(GraphicsManager* self) {
size_t i;
if (self->images) {
for (i = 0; i < self->image_count; i++) free_image(self, self->images + i);
free(self->images);
}
free(self->render_data);
Py_CLEAR(self->disk_cache);
Py_TYPE(self)->tp_free((PyObject*)self);
}
static id_type internal_id_counter = 1;
static Image*
img_by_internal_id(GraphicsManager *self, id_type id) {
for (size_t i = 0; i < self->image_count; i++) {
if (self->images[i].internal_id == id) return self->images + i;
}
return NULL;
}
static Image*
img_by_client_id(GraphicsManager *self, uint32_t id) {
for (size_t i = 0; i < self->image_count; i++) {
if (self->images[i].client_id == id) return self->images + i;
}
return NULL;
}
static Image*
img_by_client_number(GraphicsManager *self, uint32_t number) {
// get the newest image with the specified number
for (size_t i = self->image_count; i-- > 0; ) {
if (self->images[i].client_number == number) return self->images + i;
}
return NULL;
}
static void
remove_image(GraphicsManager *self, size_t idx) {
free_image(self, self->images + idx);
remove_i_from_array(self->images, idx, self->image_count);
self->layers_dirty = true;
}
static void
remove_images(GraphicsManager *self, bool(*predicate)(Image*), id_type skip_image_internal_id) {
for (size_t i = self->image_count; i-- > 0;) {
Image *img = self->images + i;
if (img->internal_id != skip_image_internal_id && predicate(img)) {
remove_image(self, i);
}
}
}
// Loading image data {{{
static bool
trim_predicate(Image *img) {
return !img->root_frame_data_loaded || !img->refcnt;
}
static void
apply_storage_quota(GraphicsManager *self, size_t storage_limit, id_type currently_added_image_internal_id) {
// First remove unreferenced images, even if they have an id
remove_images(self, trim_predicate, currently_added_image_internal_id);
if (self->used_storage < storage_limit) return;
#define oldest_last(a, b) ((b)->atime < (a)->atime)
QSORT(Image, self->images, self->image_count, oldest_last)
#undef oldest_last
while (self->used_storage > storage_limit && self->image_count > 0) {
remove_image(self, self->image_count - 1);
}
if (!self->image_count) self->used_storage = 0; // sanity check
}
static char command_response[512] = {0};
static void
set_command_failed_response(const char *code, const char *fmt, ...) {
va_list args;
va_start(args, fmt);
const size_t sz = sizeof(command_response)/sizeof(command_response[0]);
const int num = snprintf(command_response, sz, "%s:", code);
vsnprintf(command_response + num, sz - num, fmt, args);
va_end(args);
}
// Decode formats {{{
#define ABRT(code, ...) { set_command_failed_response(#code, __VA_ARGS__); goto err; }
static bool
mmap_img_file(GraphicsManager *self, int fd, size_t sz, off_t offset) {
if (!sz) {
struct stat s;
if (fstat(fd, &s) != 0) ABRT(EBADF, "Failed to fstat() the fd: %d file with error: [%d] %s", fd, errno, strerror(errno));
sz = s.st_size;
}
void *addr = mmap(0, sz, PROT_READ, MAP_SHARED, fd, offset);
if (addr == MAP_FAILED) ABRT(EBADF, "Failed to map image file fd: %d at offset: %zd with size: %zu with error: [%d] %s", fd, offset, sz, errno, strerror(errno));
self->currently_loading.mapped_file = addr;
self->currently_loading.mapped_file_sz = sz;
return true;
err:
return false;
}
static const char*
zlib_strerror(int ret) {
#define Z(x) case x: return #x;
static char buf[128];
switch(ret) {
case Z_ERRNO:
return strerror(errno);
default:
snprintf(buf, sizeof(buf)/sizeof(buf[0]), "Unknown error: %d", ret);
return buf;
Z(Z_STREAM_ERROR);
Z(Z_DATA_ERROR);
Z(Z_MEM_ERROR);
Z(Z_BUF_ERROR);
Z(Z_VERSION_ERROR);
}
#undef Z
}
static bool
inflate_zlib(LoadData *load_data, uint8_t *buf, size_t bufsz) {
bool ok = false;
z_stream z;
uint8_t *decompressed = malloc(load_data->data_sz);
if (decompressed == NULL) fatal("Out of memory allocating decompression buffer");
z.zalloc = Z_NULL;
z.zfree = Z_NULL;
z.opaque = Z_NULL;
z.avail_in = bufsz;
z.next_in = (Bytef*)buf;
z.avail_out = load_data->data_sz;
z.next_out = decompressed;
int ret;
if ((ret = inflateInit(&z)) != Z_OK) ABRT(ENOMEM, "Failed to initialize inflate with error: %s", zlib_strerror(ret));
if ((ret = inflate(&z, Z_FINISH)) != Z_STREAM_END) ABRT(EINVAL, "Failed to inflate image data with error: %s", zlib_strerror(ret));
if (z.avail_out) ABRT(EINVAL, "Image data size post inflation does not match expected size");
free_load_data(load_data);
load_data->buf_capacity = load_data->data_sz;
load_data->buf = decompressed;
load_data->buf_used = load_data->data_sz;
ok = true;
err:
inflateEnd(&z);
if (!ok) free(decompressed);
return ok;
}
static void
png_error_handler(const char *code, const char *msg) {
set_command_failed_response(code, "%s", msg);
}
static bool
inflate_png(LoadData *load_data, uint8_t *buf, size_t bufsz) {
png_read_data d = {.err_handler=png_error_handler};
inflate_png_inner(&d, buf, bufsz);
if (d.ok) {
free_load_data(load_data);
load_data->buf = d.decompressed;
load_data->buf_capacity = d.sz;
load_data->buf_used = d.sz;
load_data->data_sz = d.sz;
load_data->width = d.width; load_data->height = d.height;
}
else free(d.decompressed);
free(d.row_pointers);
return d.ok;
}
#undef ABRT
// }}}
static bool
add_trim_predicate(Image *img) {
return !img->root_frame_data_loaded || (!img->client_id && !img->refcnt);
}
bool
png_path_to_bitmap(const char* path, uint8_t** data, unsigned int* width, unsigned int* height, size_t* sz) {
FILE* fp = fopen(path, "r");
if (fp == NULL) {
log_error("The PNG image: %s could not be opened with error: %s", path, strerror(errno));
return false;
}
size_t capacity = 16*1024, pos = 0;
unsigned char *buf = malloc(capacity);
if (!buf) { log_error("Out of memory reading PNG file at: %s", path); fclose(fp); return false; }
while (!feof(fp)) {
if (capacity - pos < 1024) {
capacity *= 2;
unsigned char *new_buf = realloc(buf, capacity);
if (!new_buf) {
free(buf);
log_error("Out of memory reading PNG file at: %s", path); fclose(fp); return false;
}
buf = new_buf;
}
pos += fread(buf + pos, sizeof(char), capacity - pos, fp);
int saved_errno = errno;
if (ferror(fp) && saved_errno != EINTR) {
log_error("Failed while reading from file: %s with error: %s", path, strerror(saved_errno));
fclose(fp);
free(buf);
return false;
}
}
fclose(fp); fp = NULL;
png_read_data d = {0};
inflate_png_inner(&d, buf, pos);
free(buf);
if (!d.ok) {
free(d.decompressed); free(d.row_pointers);
log_error("Failed to decode PNG image at: %s", path);
return false;
}
*data = d.decompressed;
free(d.row_pointers);
*sz = d.sz;
*height = d.height; *width = d.width;
return true;
}
static Image*
find_or_create_image(GraphicsManager *self, uint32_t id, bool *existing) {
if (id) {
for (size_t i = 0; i < self->image_count; i++) {
if (self->images[i].client_id == id) {
*existing = true;
return self->images + i;
}
}
}
*existing = false;
ensure_space_for(self, images, Image, self->image_count + 1, images_capacity, 64, true);
Image *ans = self->images + self->image_count++;
zero_at_ptr(ans);
return ans;
}
static uint32_t
get_free_client_id(const GraphicsManager *self) {
if (!self->image_count) return 1;
uint32_t *client_ids = malloc(sizeof(uint32_t) * self->image_count);
size_t count = 0;
for (size_t i = 0; i < self->image_count; i++) {
Image *q = self->images + i;
if (q->client_id) client_ids[count++] = q->client_id;
}
if (!count) { free(client_ids); return 1; }
#define int_lt(a, b) ((*a)<(*b))
QSORT(uint32_t, client_ids, count, int_lt)
#undef int_lt
uint32_t prev_id = 0, ans = 1;
for (size_t i = 0; i < count; i++) {
if (client_ids[i] == prev_id) continue;
prev_id = client_ids[i];
if (client_ids[i] != ans) break;
ans = client_ids[i] + 1;
}
free(client_ids);
return ans;
}
#define ABRT(code, ...) { set_command_failed_response(code, __VA_ARGS__); self->currently_loading.loading_completed_successfully = false; free_load_data(&self->currently_loading); return NULL; }
#define MAX_DATA_SZ (4u * 100000000u)
enum FORMATS { RGB=24, RGBA=32, PNG=100 };
static Image*
load_image_data(GraphicsManager *self, Image *img, const GraphicsCommand *g, const unsigned char transmission_type, const uint32_t data_fmt, const uint8_t *payload) {
int fd;
static char fname[2056] = {0};
LoadData *load_data = &self->currently_loading;
switch(transmission_type) {
case 'd': // direct
if (load_data->buf_capacity - load_data->buf_used < g->payload_sz) {
if (load_data->buf_used + g->payload_sz > MAX_DATA_SZ || data_fmt != PNG) ABRT("EFBIG", "Too much data");
load_data->buf_capacity = MIN(2 * load_data->buf_capacity, MAX_DATA_SZ);
load_data->buf = realloc(load_data->buf, load_data->buf_capacity);
if (load_data->buf == NULL) {
load_data->buf_capacity = 0; load_data->buf_used = 0;
ABRT("ENOMEM", "Out of memory");
}
}
memcpy(load_data->buf + load_data->buf_used, payload, g->payload_sz);
load_data->buf_used += g->payload_sz;
if (!g->more) { load_data->loading_completed_successfully = true; load_data->loading_for = (const ImageAndFrame){0}; }
break;
case 'f': // file
case 't': // temporary file
case 's': // POSIX shared memory
if (g->payload_sz > 2048) ABRT("EINVAL", "Filename too long");
snprintf(fname, sizeof(fname)/sizeof(fname[0]), "%.*s", (int)g->payload_sz, payload);
if (transmission_type == 's') fd = safe_shm_open(fname, O_RDONLY, 0);
else fd = safe_open(fname, O_CLOEXEC | O_RDONLY, 0);
if (fd == -1) ABRT("EBADF", "Failed to open file for graphics transmission with error: [%d] %s", errno, strerror(errno));
load_data->loading_completed_successfully = mmap_img_file(self, fd, g->data_sz, g->data_offset);
safe_close(fd, __FILE__, __LINE__);
if (transmission_type == 't') {
if (global_state.boss) { call_boss(safe_delete_temp_file, "s", fname); }
else unlink(fname);
}
else if (transmission_type == 's') shm_unlink(fname);
if (!load_data->loading_completed_successfully) return NULL;
break;
default:
ABRT("EINVAL", "Unknown transmission type: %c", g->transmission_type);
}
return img;
}
static Image*
process_image_data(GraphicsManager *self, Image* img, const GraphicsCommand *g, const unsigned char transmission_type, const uint32_t data_fmt) {
bool needs_processing = g->compressed || data_fmt == PNG;
if (needs_processing) {
uint8_t *buf; size_t bufsz;
#define IB { if (self->currently_loading.buf) { buf = self->currently_loading.buf; bufsz = self->currently_loading.buf_used; } else { buf = self->currently_loading.mapped_file; bufsz = self->currently_loading.mapped_file_sz; } }
switch(g->compressed) {
case 'z':
IB;
if (!inflate_zlib(&self->currently_loading, buf, bufsz)) {
self->currently_loading.loading_completed_successfully = false; return NULL;
}
break;
case 0:
break;
default:
ABRT("EINVAL", "Unknown image compression: %c", g->compressed);
}
switch(data_fmt) {
case PNG:
IB;
if (!inflate_png(&self->currently_loading, buf, bufsz)) {
self->currently_loading.loading_completed_successfully = false; return NULL;
}
break;
default: break;
}
#undef IB
self->currently_loading.data = self->currently_loading.buf;
if (self->currently_loading.buf_used < self->currently_loading.data_sz) {
ABRT("ENODATA", "Insufficient image data: %zu < %zu", self->currently_loading.buf_used, self->currently_loading.data_sz);
}
if (self->currently_loading.mapped_file) {
munmap(self->currently_loading.mapped_file, self->currently_loading.mapped_file_sz);
self->currently_loading.mapped_file = NULL; self->currently_loading.mapped_file_sz = 0;
}
} else {
if (transmission_type == 'd') {
if (self->currently_loading.buf_used < self->currently_loading.data_sz) {
ABRT("ENODATA", "Insufficient image data: %zu < %zu", self->currently_loading.buf_used, self->currently_loading.data_sz);
} else self->currently_loading.data = self->currently_loading.buf;
} else {
if (self->currently_loading.mapped_file_sz < self->currently_loading.data_sz) {
ABRT("ENODATA", "Insufficient image data: %zu < %zu", self->currently_loading.mapped_file_sz, self->currently_loading.data_sz);
} else self->currently_loading.data = self->currently_loading.mapped_file;
}
self->currently_loading.loading_completed_successfully = true;
}
return img;
}
static Image*
initialize_load_data(GraphicsManager *self, const GraphicsCommand *g, Image *img, const unsigned char transmission_type, const uint32_t data_fmt, const uint32_t frame_id) {
free_load_data(&self->currently_loading);
self->currently_loading = (const LoadData){0};
self->currently_loading.start_command = *g;
self->currently_loading.width = g->data_width; self->currently_loading.height = g->data_height;
switch(data_fmt) {
case PNG:
if (g->data_sz > MAX_DATA_SZ) ABRT("EINVAL", "PNG data size too large");
self->currently_loading.is_4byte_aligned = true;
self->currently_loading.is_opaque = false;
self->currently_loading.data_sz = g->data_sz ? g->data_sz : 1024 * 100;
break;
case RGB:
case RGBA:
self->currently_loading.data_sz = (size_t)g->data_width * g->data_height * (data_fmt / 8);
if (!self->currently_loading.data_sz) ABRT("EINVAL", "Zero width/height not allowed");
self->currently_loading.is_4byte_aligned = data_fmt == RGBA || (self->currently_loading.width % 4 == 0);
self->currently_loading.is_opaque = data_fmt == RGB;
break;
default:
ABRT("EINVAL", "Unknown image format: %u", data_fmt);
}
self->currently_loading.loading_for.image_id = img->internal_id;
self->currently_loading.loading_for.frame_id = frame_id;
if (transmission_type == 'd') {
self->currently_loading.buf_capacity = self->currently_loading.data_sz + (g->compressed ? 1024 : 10); // compression header
self->currently_loading.buf = malloc(self->currently_loading.buf_capacity);
self->currently_loading.buf_used = 0;
if (self->currently_loading.buf == NULL) {
self->currently_loading.buf_capacity = 0; self->currently_loading.buf_used = 0;
ABRT("ENOMEM", "Out of memory");
}
}
return img;
}
#define INIT_CHUNKED_LOAD { \
self->currently_loading.start_command.more = g->more; \
self->currently_loading.start_command.payload_sz = g->payload_sz; \
g = &self->currently_loading.start_command; \
tt = g->transmission_type ? g->transmission_type : 'd'; \
fmt = g->format ? g->format : RGBA; \
}
#define MAX_IMAGE_DIMENSION 10000u
static void
upload_to_gpu(GraphicsManager *self, Image *img, const bool is_opaque, const bool is_4byte_aligned, const uint8_t *data) {
if (!self->context_made_current_for_this_command) {
if (!self->window_id) return;
if (!make_window_context_current(self->window_id)) return;
self->context_made_current_for_this_command = true;
}
send_image_to_gpu(&img->texture_id, data, img->width, img->height, is_opaque, is_4byte_aligned, false, REPEAT_CLAMP);
}
static Image*
handle_add_command(GraphicsManager *self, const GraphicsCommand *g, const uint8_t *payload, bool *is_dirty, uint32_t iid) {
bool existing, init_img = true;
Image *img = NULL;
unsigned char tt = g->transmission_type ? g->transmission_type : 'd';
uint32_t fmt = g->format ? g->format : RGBA;
if (tt == 'd' && self->currently_loading.loading_for.image_id) init_img = false;
if (init_img) {
self->currently_loading.loading_for = (const ImageAndFrame){0};
if (g->data_width > MAX_IMAGE_DIMENSION || g->data_height > MAX_IMAGE_DIMENSION) ABRT("EINVAL", "Image too large");
remove_images(self, add_trim_predicate, 0);
img = find_or_create_image(self, iid, &existing);
if (existing) {
img->root_frame_data_loaded = false;
img->is_drawn = false;
img->current_frame_shown_at = 0;
free_refs_data(img);
*is_dirty = true;
self->layers_dirty = true;
} else {
img->internal_id = internal_id_counter++;
img->client_id = iid;
img->client_number = g->image_number;
if (!img->client_id && img->client_number) {
img->client_id = get_free_client_id(self);
iid = img->client_id;
}
}
img->atime = monotonic(); img->used_storage = 0;
if (!initialize_load_data(self, g, img, tt, fmt, 0)) return NULL;
self->currently_loading.start_command.id = iid;
} else {
INIT_CHUNKED_LOAD;
img = img_by_internal_id(self, self->currently_loading.loading_for.image_id);
if (img == NULL) {
self->currently_loading.loading_for = (const ImageAndFrame){0};
ABRT("EILSEQ", "More payload loading refers to non-existent image");
}
}
img = load_image_data(self, img, g, tt, fmt, payload);
if (!img || !self->currently_loading.loading_completed_successfully) return NULL;
self->currently_loading.loading_for = (const ImageAndFrame){0};
img = process_image_data(self, img, g, tt, fmt);
if (!img) return NULL;
size_t required_sz = (size_t)(self->currently_loading.is_opaque ? 3 : 4) * self->currently_loading.width * self->currently_loading.height;
if (self->currently_loading.data_sz != required_sz) ABRT("EINVAL", "Image dimensions: %ux%u do not match data size: %zu, expected size: %zu", self->currently_loading.width, self->currently_loading.height, self->currently_loading.data_sz, required_sz);
if (self->currently_loading.loading_completed_successfully) {
img->width = self->currently_loading.width;
img->height = self->currently_loading.height;
if (img->root_frame.id) remove_from_cache(self, (const ImageAndFrame){.image_id=img->internal_id, .frame_id=img->root_frame.id});
img->root_frame = (const Frame){
.id = ++img->frame_id_counter,
.is_opaque = self->currently_loading.is_opaque,
.is_4byte_aligned = self->currently_loading.is_4byte_aligned,
.width = img->width, .height = img->height,
};
if (!add_to_cache(self, (const ImageAndFrame){.image_id = img->internal_id, .frame_id=img->root_frame.id}, self->currently_loading.data, self->currently_loading.data_sz)) {
if (PyErr_Occurred()) PyErr_Print();
ABRT("ENOSPC", "Failed to store image data in disk cache");
}
upload_to_gpu(self, img, img->root_frame.is_opaque, img->root_frame.is_4byte_aligned, self->currently_loading.data);
self->used_storage += required_sz;
img->used_storage = required_sz;
img->root_frame_data_loaded = true;
}
return img;
#undef MAX_DATA_SZ
}
static const char*
finish_command_response(const GraphicsCommand *g, bool data_loaded) {
static char rbuf[sizeof(command_response)/sizeof(command_response[0]) + 128];
bool is_ok_response = !command_response[0];
if (g->quiet) {
if (is_ok_response || g->quiet > 1) return NULL;
}
if (g->id || g->image_number) {
if (is_ok_response) {
if (!data_loaded) return NULL;
snprintf(command_response, 10, "OK");
}
size_t pos = 0;
rbuf[pos++] = 'G';
#define print(fmt, ...) if (arraysz(rbuf) - 1 > pos) pos += snprintf(rbuf + pos, arraysz(rbuf) - 1 - pos, fmt, __VA_ARGS__)
if (g->id) print("i=%u", g->id);
if (g->image_number) print(",I=%u", g->image_number);
if (g->placement_id) print(",p=%u", g->placement_id);
if (g->num_lines && (g->action == 'f' || g->action == 'a')) print(",r=%u", g->num_lines);
print(";%s", command_response);
return rbuf;
#undef print
}
return NULL;
}
// }}}
// Displaying images {{{
static void
update_src_rect(ImageRef *ref, Image *img) {
// The src rect in OpenGL co-ords [0, 1] with origin at top-left corner of image
ref->src_rect.left = (float)ref->src_x / (float)img->width;
ref->src_rect.right = (float)(ref->src_x + ref->src_width) / (float)img->width;
ref->src_rect.top = (float)ref->src_y / (float)img->height;
ref->src_rect.bottom = (float)(ref->src_y + ref->src_height) / (float)img->height;
}
static void
update_dest_rect(ImageRef *ref, uint32_t num_cols, uint32_t num_rows, CellPixelSize cell) {
uint32_t t;
if (num_cols == 0) {
t = ref->src_width + ref->cell_x_offset;
num_cols = t / cell.width;
if (t > num_cols * cell.width) num_cols += 1;
}
if (num_rows == 0) {
t = ref->src_height + ref->cell_y_offset;
num_rows = t / cell.height;
if (t > num_rows * cell.height) num_rows += 1;
}
ref->effective_num_rows = num_rows;
ref->effective_num_cols = num_cols;
}
static uint32_t
handle_put_command(GraphicsManager *self, const GraphicsCommand *g, Cursor *c, bool *is_dirty, Image *img, CellPixelSize cell) {
if (img == NULL) {
if (g->id) img = img_by_client_id(self, g->id);
else if (g->image_number) img = img_by_client_number(self, g->image_number);
if (img == NULL) { set_command_failed_response("ENOENT", "Put command refers to non-existent image with id: %u and number: %u", g->id, g->image_number); return g->id; }
}
if (!img->root_frame_data_loaded) { set_command_failed_response("ENOENT", "Put command refers to image with id: %u that could not load its data", g->id); return img->client_id; }
ensure_space_for(img, refs, ImageRef, img->refcnt + 1, refcap, 16, true);
*is_dirty = true;
self->layers_dirty = true;
ImageRef *ref = NULL;
if (g->placement_id && img->client_id) {
for (size_t i=0; i < img->refcnt; i++) {
if (img->refs[i].client_id == g->placement_id) {
ref = img->refs + i;
break;
}
}
}
if (ref == NULL) {
ref = img->refs + img->refcnt++;
zero_at_ptr(ref);
}
img->atime = monotonic();
ref->src_x = g->x_offset; ref->src_y = g->y_offset; ref->src_width = g->width ? g->width : img->width; ref->src_height = g->height ? g->height : img->height;
ref->src_width = MIN(ref->src_width, img->width - (img->width > ref->src_x ? ref->src_x : img->width));
ref->src_height = MIN(ref->src_height, img->height - (img->height > ref->src_y ? ref->src_y : img->height));
ref->z_index = g->z_index;
ref->start_row = c->y; ref->start_column = c->x;
ref->cell_x_offset = MIN(g->cell_x_offset, cell.width - 1);
ref->cell_y_offset = MIN(g->cell_y_offset, cell.height - 1);
ref->num_cols = g->num_cells; ref->num_rows = g->num_lines;
if (img->client_id) ref->client_id = g->placement_id;
update_src_rect(ref, img);
update_dest_rect(ref, g->num_cells, g->num_lines, cell);
// Move the cursor, the screen will take care of ensuring it is in bounds
if (g->cursor_movement != 1) {
c->x += ref->effective_num_cols; c->y += ref->effective_num_rows - 1;
}
return img->client_id;
}
static void
set_vertex_data(ImageRenderData *rd, const ImageRef *ref, const ImageRect *dest_rect) {
#define R(n, a, b) rd->vertices[n*4] = ref->src_rect.a; rd->vertices[n*4 + 1] = ref->src_rect.b; rd->vertices[n*4 + 2] = dest_rect->a; rd->vertices[n*4 + 3] = dest_rect->b;
R(0, right, top); R(1, right, bottom); R(2, left, bottom); R(3, left, top);
#undef R
}
void
gpu_data_for_image(ImageRenderData *ans, float left, float top, float right, float bottom) {
// x-axis is from -1 to 1, y axis is from 1 to -1
static const ImageRef source_rect = { .src_rect = { .left=0, .top=0, .bottom=1, .right=1 }};
const ImageRef *ref = &source_rect;
const ImageRect r = { .left = left, .right = right, .top = top, .bottom = bottom };
set_vertex_data(ans, ref, &r);
ans->group_count = 1;
}
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);
}
bool
grman_update_layers(GraphicsManager *self, unsigned int scrolled_by, float screen_left, float screen_top, float dx, float dy, unsigned int num_cols, unsigned int num_rows, CellPixelSize cell) {
if (self->last_scrolled_by != scrolled_by) self->layers_dirty = true;
self->last_scrolled_by = scrolled_by;
if (!self->layers_dirty) return false;
self->layers_dirty = false;
size_t i, j;
self->num_of_below_refs = 0;
self->num_of_negative_refs = 0;
self->num_of_positive_refs = 0;
Image *img; ImageRef *ref;
ImageRect r;
float screen_width = dx * num_cols, screen_height = dy * num_rows;
float screen_bottom = screen_top - screen_height;
float screen_width_px = num_cols * cell.width;
float screen_height_px = num_rows * cell.height;
float y0 = screen_top - dy * scrolled_by;
// Iterate over all visible refs and create render data
self->count = 0;
for (i = 0; i < self->image_count; i++) {
img = self->images + i;
bool was_drawn = img->is_drawn;
img->is_drawn = false;
for (j = 0; j < img->refcnt; j++) { ref = img->refs + j;
r.top = y0 - ref->start_row * dy - dy * (float)ref->cell_y_offset / (float)cell.height;
if (ref->num_rows > 0) r.bottom = y0 - (ref->start_row + (int32_t)ref->num_rows) * dy;
else r.bottom = r.top - screen_height * (float)ref->src_height / screen_height_px;
if (r.top <= screen_bottom || r.bottom >= screen_top) continue; // not visible
r.left = screen_left + ref->start_column * dx + dx * (float)ref->cell_x_offset / (float) cell.width;
if (ref->num_cols > 0) r.right = screen_left + (ref->start_column + (int32_t)ref->num_cols) * dx;
else r.right = r.left + screen_width * (float)ref->src_width / screen_width_px;
if (ref->z_index < ((int32_t)INT32_MIN/2))
self->num_of_below_refs++;
else if (ref->z_index < 0)
self->num_of_negative_refs++;
else
self->num_of_positive_refs++;
ensure_space_for(self, render_data, ImageRenderData, self->count + 1, capacity, 64, true);
ImageRenderData *rd = self->render_data + self->count;
zero_at_ptr(rd);
set_vertex_data(rd, ref, &r);
self->count++;
rd->z_index = ref->z_index; rd->image_id = img->internal_id;
rd->texture_id = img->texture_id;
img->is_drawn = true;
}
if (img->is_drawn && !was_drawn && img->animation_state != ANIMATION_STOPPED && img->extra_framecnt && img->animation_duration) {
self->has_images_needing_animation = true;
global_state.check_for_active_animated_images = true;
}
}
if (!self->count) return false;
// Sort visible refs in draw order (z-index, img)
#define lt(a, b) ( (a)->z_index < (b)->z_index || ((a)->z_index == (b)->z_index && (a)->image_id < (b)->image_id) )
QSORT(ImageRenderData, self->render_data, self->count, lt);
#undef lt
// Calculate the group counts
i = 0;
while (i < self->count) {
id_type image_id = self->render_data[i].image_id, start = i;
if (start == self->count - 1) i = self->count;
else {
while (i < self->count - 1 && self->render_data[++i].image_id == image_id) {}
}
self->render_data[start].group_count = i - start;
}
return true;
}
// }}}
// Animation {{{
#define DEFAULT_GAP 40
static Frame*
current_frame(Image *img) {
if (img->current_frame_index > img->extra_framecnt) return NULL;
return img->current_frame_index ? img->extra_frames + img->current_frame_index - 1 : &img->root_frame;
}
static Frame*
frame_for_id(Image *img, const uint32_t frame_id) {
if (img->root_frame.id == frame_id) return &img->root_frame;
for (unsigned i = 0; i < img->extra_framecnt; i++) {
if (img->extra_frames[i].id == frame_id) return img->extra_frames + i;
}
return NULL;
}
static Frame*
frame_for_number(Image *img, const uint32_t frame_number) {
switch(frame_number) {
case 1:
return &img->root_frame;
case 0:
return NULL;
default:
if (frame_number - 2 < img->extra_framecnt) return img->extra_frames + frame_number - 2;
return NULL;
}
}
static void
change_gap(Image *img, Frame *f, int32_t gap) {
uint32_t prev_gap = f->gap;
f->gap = MAX(0, gap);
img->animation_duration = prev_gap < img->animation_duration ? img->animation_duration - prev_gap : 0;
img->animation_duration += f->gap;
}
typedef struct {
uint8_t *buf;
bool is_4byte_aligned, is_opaque;
} CoalescedFrameData;
static void
blend_on_opaque(uint8_t *under_px, const uint8_t *over_px) {
const float alpha = (float)over_px[3] / 255.f;
const float alpha_op = 1.f - alpha;
for (unsigned i = 0; i < 3; i++) under_px[i] = (uint8_t)(over_px[i] * alpha + under_px[i] * alpha_op);
}
static void
alpha_blend(uint8_t *dest_px, const uint8_t *src_px) {
if (src_px[3]) {
const float dest_a = (float)dest_px[3] / 255.f, src_a = (float)src_px[3] / 255.f;
const float alpha = src_a + dest_a * (1.f - src_a);
dest_px[3] = (uint8_t)(255 * alpha);
if (!dest_px[3]) { dest_px[0] = 0; dest_px[1] = 0; dest_px[2] = 0; return; }
for (unsigned i = 0; i < 3; i++) dest_px[i] = (uint8_t)((src_px[i] * src_a + dest_px[i] * dest_a * (1.f - src_a))/alpha);
}
}
typedef struct {
bool needs_blending;
uint32_t over_px_sz, under_px_sz;
uint32_t over_width, over_height, under_width, under_height, over_offset_x, over_offset_y, under_offset_x, under_offset_y;
uint32_t stride;
} ComposeData;
#define COPY_RGB under_px[0] = over_px[0]; under_px[1] = over_px[1]; under_px[2] = over_px[2];
#define COPY_PIXELS \
if (d.needs_blending) { \
if (d.under_px_sz == 3) { \
ROW_ITER PIX_ITER blend_on_opaque(under_px, over_px); }} \
} else { \
ROW_ITER PIX_ITER alpha_blend(under_px, over_px); }} \
} \
} else { \
if (d.under_px_sz == 4) { \
if (d.over_px_sz == 4) { \
ROW_ITER PIX_ITER COPY_RGB under_px[3] = over_px[3]; }} \
} else { \
ROW_ITER PIX_ITER COPY_RGB under_px[3] = 255; }} \
} \
} else { \
ROW_ITER PIX_ITER COPY_RGB }} \
} \
} \
static void
compose_rectangles(const ComposeData d, uint8_t *under_data, const uint8_t *over_data) {
// compose two equal sized, non-overlapping rectangles at different offsets
// does not do bounds checking on the data arrays
const bool can_copy_rows = !d.needs_blending && d.over_px_sz == d.under_px_sz;
const unsigned min_width = MIN(d.under_width, d.over_width);
#define ROW_ITER for (unsigned y = 0; y < d.under_height && y < d.over_height; y++) { \
uint8_t *under_row = under_data + (y + d.under_offset_y) * d.under_px_sz * d.stride + (d.under_offset_x * d.under_px_sz); \
const uint8_t *over_row = over_data + (y + d.over_offset_y) * d.over_px_sz * d.stride + (d.over_offset_x * d.over_px_sz);
if (can_copy_rows) {
ROW_ITER memcpy(under_row, over_row, (size_t)d.over_px_sz * min_width);}
return;
}
#define PIX_ITER for (unsigned x = 0; x < min_width; x++) { \
uint8_t *under_px = under_row + (d.under_px_sz * x); \
const uint8_t *over_px = over_row + (d.over_px_sz * x);
COPY_PIXELS
#undef PIX_ITER
#undef ROW_ITER
}
static void
compose(const ComposeData d, uint8_t *under_data, const uint8_t *over_data) {
const bool can_copy_rows = !d.needs_blending && d.over_px_sz == d.under_px_sz;
unsigned min_row_sz = d.over_offset_x < d.under_width ? d.under_width - d.over_offset_x : 0;
min_row_sz = MIN(min_row_sz, d.over_width);
#define ROW_ITER for (unsigned y = 0; y + d.over_offset_y < d.under_height && y < d.over_height; y++) { \
uint8_t *under_row = under_data + (y + d.over_offset_y) * d.under_px_sz * d.under_width + d.under_px_sz * d.over_offset_x; \
const uint8_t *over_row = over_data + y * d.over_px_sz * d.over_width;
if (can_copy_rows) {
ROW_ITER memcpy(under_row, over_row, (size_t)d.over_px_sz * min_row_sz);}
return;
}
#define PIX_ITER for (unsigned x = 0; x < min_row_sz; x++) { \
uint8_t *under_px = under_row + (d.under_px_sz * x); \
const uint8_t *over_px = over_row + (d.over_px_sz * x);
COPY_PIXELS
#undef COPY_RGB
#undef PIX_ITER
#undef ROW_ITER
}
static CoalescedFrameData
get_coalesced_frame_data_standalone(const Image *img, const Frame *f, uint8_t *frame_data) {
CoalescedFrameData ans = {0};
bool is_full_frame = f->width == img->width && f->height == img->height && !f->x && !f->y;
if (is_full_frame) {
ans.buf = frame_data;
ans.is_4byte_aligned = f->is_4byte_aligned;
ans.is_opaque = f->is_opaque;
return ans;
}
const unsigned bytes_per_pixel = f->is_opaque ? 3 : 4;
uint8_t *base;
if (f->bgcolor) {
base = malloc((size_t)img->width * img->height * bytes_per_pixel);
if (base) {
uint8_t *p = base;
const uint8_t r = (f->bgcolor >> 24) & 0xff,
g = (f->bgcolor >> 16) & 0xff, b = (f->bgcolor >> 8) & 0xff, a = f->bgcolor & 0xff;
if (bytes_per_pixel == 4) {
for (uint32_t i = 0; i < img->width * img->height; i++) {
*(p++) = r; *(p++) = g; *(p++) = b; *(p++) = a;
}
} else {
for (uint32_t i = 0; i < img->width * img->height; i++) {
*(p++) = r; *(p++) = g; *(p++) = b;
}
}
}
} else base = calloc((size_t)img->width * img->height, bytes_per_pixel);
if (!base) { free(frame_data); return ans; }
ComposeData d = {
.over_px_sz = bytes_per_pixel, .under_px_sz = bytes_per_pixel,
.over_width = f->width, .over_height = f->height, .over_offset_x = f->x, .over_offset_y = f->y,
.under_width = img->width, .under_height = img->height,
.needs_blending = f->alpha_blend && !f->is_opaque
};
compose(d, base, frame_data);
ans.buf = base;
ans.is_4byte_aligned = bytes_per_pixel == 4 || (img->width % 4) == 0;
ans.is_opaque = f->is_opaque;
free(frame_data);
return ans;
}
static CoalescedFrameData
get_coalesced_frame_data_impl(GraphicsManager *self, Image *img, const Frame *f, unsigned count) {
CoalescedFrameData ans = {0};
if (count > 32) return ans; // prevent stack overflows, infinite recursion
size_t frame_data_sz; void *frame_data;
ImageAndFrame key = {.image_id = img->internal_id, .frame_id = f->id};
if (!read_from_cache(self, key, &frame_data, &frame_data_sz)) return ans;
if (!f->base_frame_id) return get_coalesced_frame_data_standalone(img, f, frame_data);
Frame *base = frame_for_id(img, f->base_frame_id);
if (!base) { free(frame_data); return ans; }
CoalescedFrameData base_data = get_coalesced_frame_data_impl(self, img, base, count + 1);
if (!base_data.buf) { free(frame_data); return ans; }
ComposeData d = {
.over_px_sz = f->is_opaque ? 3 : 4,
.under_px_sz = base_data.is_opaque ? 3 : 4,
.over_width = f->width, .over_height = f->height, .over_offset_x = f->x, .over_offset_y = f->y,
.under_width = img->width, .under_height = img->height,
.needs_blending = f->alpha_blend && !f->is_opaque
};
compose(d, base_data.buf, frame_data);
free(frame_data);
return base_data;
}
static CoalescedFrameData
get_coalesced_frame_data(GraphicsManager *self, Image *img, const Frame *f) {
return get_coalesced_frame_data_impl(self, img, f, 0);
}
static void
update_current_frame(GraphicsManager *self, Image *img, const CoalescedFrameData *data) {
bool needs_load = data == NULL;
CoalescedFrameData cfd;
if (needs_load) {
Frame *f = current_frame(img);
if (f == NULL) return;
cfd = get_coalesced_frame_data(self, img, f);
if (!cfd.buf) {
if (PyErr_Occurred()) PyErr_Print();
return;
}
data = &cfd;
}
upload_to_gpu(self, img, data->is_opaque, data->is_4byte_aligned, data->buf);
if (needs_load) free(data->buf);
img->current_frame_shown_at = monotonic();
}
static bool
reference_chain_too_large(Image *img, const Frame *frame) {
uint32_t limit = img->width * img->height * 2;
uint32_t drawn_area = frame->width * frame->height;
unsigned num = 1;
while (drawn_area < limit && num < 5) {
if (!frame->base_frame_id || !(frame = frame_for_id(img, frame->base_frame_id))) break;
drawn_area += frame->width * frame->height;
num++;
}
return num >= 5 || drawn_area >= limit;
}
static Image*
handle_animation_frame_load_command(GraphicsManager *self, GraphicsCommand *g, Image *img, const uint8_t *payload, bool *is_dirty) {
uint32_t frame_number = g->frame_number, fmt = g->format ? g->format : RGBA;
if (!frame_number || frame_number > img->extra_framecnt + 2) frame_number = img->extra_framecnt + 2;
bool is_new_frame = frame_number == img->extra_framecnt + 2;
g->frame_number = frame_number;
unsigned char tt = g->transmission_type ? g->transmission_type : 'd';
if (tt == 'd' && self->currently_loading.loading_for.image_id == img->internal_id) {
INIT_CHUNKED_LOAD;
} else {
self->currently_loading.loading_for = (const ImageAndFrame){0};
if (g->data_width > MAX_IMAGE_DIMENSION || g->data_height > MAX_IMAGE_DIMENSION) ABRT("EINVAL", "Image too large");
if (!initialize_load_data(self, g, img, tt, fmt, frame_number - 1)) return NULL;
}
LoadData *load_data = &self->currently_loading;
img = load_image_data(self, img, g, tt, fmt, payload);
if (!img || !load_data->loading_completed_successfully) return NULL;
self->currently_loading.loading_for = (const ImageAndFrame){0};
img = process_image_data(self, img, g, tt, fmt);
if (!img || !load_data->loading_completed_successfully) return img;
const unsigned long bytes_per_pixel = load_data->is_opaque ? 3 : 4;
if (load_data->data_sz < bytes_per_pixel * load_data->width * load_data->height)
ABRT("ENODATA", "Insufficient image data %zu < %zu", load_data->data_sz, bytes_per_pixel * g->data_width, g->data_height);
if (load_data->width > img->width)
ABRT("EINVAL", "Frame width %u larger than image width: %u", load_data->width, img->width);
if (load_data->height > img->height)
ABRT("EINVAL", "Frame height %u larger than image height: %u", load_data->height, img->height);
if (is_new_frame && cache_size(self) + load_data->data_sz > self->storage_limit * 5) {
remove_images(self, trim_predicate, img->internal_id);
if (is_new_frame && cache_size(self) + load_data->data_sz > self->storage_limit * 5)
ABRT("ENOSPC", "Cache size exceeded cannot add new frames");
}
Frame transmitted_frame = {
.width = load_data->width, .height = load_data->height,
.x = g->x_offset, .y = g->y_offset,
.is_4byte_aligned = load_data->is_4byte_aligned,
.is_opaque = load_data->is_opaque,
.alpha_blend = g->blend_mode != 1 && !load_data->is_opaque,
.gap = g->gap > 0 ? g->gap : (g->gap < 0) ? 0 : DEFAULT_GAP,
.bgcolor = g->bgcolor,
};
Frame *frame;
if (is_new_frame) {
transmitted_frame.id = ++img->frame_id_counter;
Frame *frames = realloc(img->extra_frames, sizeof(img->extra_frames[0]) * (img->extra_framecnt + 1));
if (!frames) ABRT("ENOMEM", "Out of memory");
img->extra_frames = frames;
img->extra_framecnt++;
frame = img->extra_frames + frame_number - 2;
const ImageAndFrame key = { .image_id = img->internal_id, .frame_id = transmitted_frame.id };
if (g->other_frame_number) {
Frame *other_frame = frame_for_number(img, g->other_frame_number);
if (!other_frame) {
img->extra_framecnt--;
ABRT("EINVAL", "No frame with number: %u found", g->other_frame_number);
}
if (other_frame->base_frame_id && reference_chain_too_large(img, other_frame)) {
// since there is a long reference chain to render this frame, make
// it a fully coalesced key frame, for performance
CoalescedFrameData cfd = get_coalesced_frame_data(self, img, other_frame);
if (!cfd.buf) ABRT("EINVAL", "Failed to get data from frame referenced by frame: %u", frame_number);
ComposeData d = {
.over_px_sz = transmitted_frame.is_opaque ? 3 : 4, .under_px_sz = cfd.is_opaque ? 3: 4,
.over_width = transmitted_frame.width, .over_height = transmitted_frame.height,
.over_offset_x = transmitted_frame.x, .over_offset_y = transmitted_frame.y,
.under_width = img->width, .under_height = img->height,
.needs_blending = transmitted_frame.alpha_blend && !transmitted_frame.is_opaque
};
compose(d, cfd.buf, load_data->data);
free_load_data(load_data);
load_data->data = cfd.buf; load_data->data_sz = (size_t)img->width * img->height * d.under_px_sz;
transmitted_frame.width = img->width; transmitted_frame.height = img->height;
transmitted_frame.x = 0; transmitted_frame.y = 0;
transmitted_frame.is_4byte_aligned = cfd.is_4byte_aligned;
transmitted_frame.is_opaque = cfd.is_opaque;
} else {
transmitted_frame.base_frame_id = other_frame->id;
}
}
*frame = transmitted_frame;
if (!add_to_cache(self, key, load_data->data, load_data->data_sz)) {
img->extra_framecnt--;
if (PyErr_Occurred()) PyErr_Print();
ABRT("ENOSPC", "Failed to cache data for image frame");
}
img->animation_duration += frame->gap;
if (img->animation_state == ANIMATION_LOADING) {
self->has_images_needing_animation = true;
global_state.check_for_active_animated_images = true;
}
} else {
frame = frame_for_number(img, frame_number);
if (!frame) ABRT("EINVAL", "No frame with number: %u found", frame_number);
if (g->gap != 0) change_gap(img, frame, transmitted_frame.gap);
CoalescedFrameData cfd = get_coalesced_frame_data(self, img, frame);
if (!cfd.buf) ABRT("EINVAL", "No data associated with frame number: %u", frame_number);
frame->alpha_blend = false; frame->base_frame_id = 0; frame->bgcolor = 0;
frame->is_opaque = cfd.is_opaque; frame->is_4byte_aligned = cfd.is_4byte_aligned;
frame->x = 0; frame->y = 0; frame->width = img->width; frame->height = img->height;
const unsigned bytes_per_pixel = frame->is_opaque ? 3: 4;
ComposeData d = {
.over_px_sz = transmitted_frame.is_opaque ? 3 : 4, .under_px_sz = bytes_per_pixel,
.over_width = transmitted_frame.width, .over_height = transmitted_frame.height,
.over_offset_x = transmitted_frame.x, .over_offset_y = transmitted_frame.y,
.under_width = frame->width, .under_height = frame->height,
.needs_blending = transmitted_frame.alpha_blend && !transmitted_frame.is_opaque
};
compose(d, cfd.buf, load_data->data);
const ImageAndFrame key = { .image_id = img->internal_id, .frame_id = frame->id };
bool added = add_to_cache(self, key, cfd.buf, (size_t)bytes_per_pixel * frame->width * frame->height);
if (added && frame == current_frame(img)) {
update_current_frame(self, img, &cfd);
*is_dirty = true;
}
free(cfd.buf);
if (!added) {
if (PyErr_Occurred()) PyErr_Print();
ABRT("ENOSPC", "Failed to cache data for image frame");
}
}
return img;
}
#undef ABRT
static Image*
handle_delete_frame_command(GraphicsManager *self, const GraphicsCommand *g, bool *is_dirty) {
if (!g->id && !g->image_number) {
REPORT_ERROR("Delete frame data command without image id or number");
return NULL;
}
Image *img = g->id ? img_by_client_id(self, g->id) : img_by_client_number(self, g->image_number);
if (!img) {
REPORT_ERROR("Animation command refers to non-existent image with id: %u and number: %u", g->id, g->image_number);
return NULL;
}
uint32_t frame_number = MIN(img->extra_framecnt + 1, g->frame_number);
if (!frame_number) frame_number = 1;
if (!img->extra_framecnt) return g->delete_action == 'F' ? img : NULL;
*is_dirty = true;
ImageAndFrame key = {.image_id=img->internal_id};
bool remove_root = frame_number == 1;
uint32_t removed_gap = 0;
if (remove_root) {
key.frame_id = img->root_frame.id;
remove_from_cache(self, key);
if (PyErr_Occurred()) PyErr_Print();
removed_gap = img->root_frame.gap;
img->root_frame = img->extra_frames[0];
}
unsigned removed_idx = remove_root ? 0 : frame_number - 2;
if (!remove_root) {
key.frame_id = img->extra_frames[removed_idx].id;
removed_gap = img->extra_frames[removed_idx].gap;
remove_from_cache(self, key);
}
img->animation_duration = removed_gap < img->animation_duration ? img->animation_duration - removed_gap : 0;
if (PyErr_Occurred()) PyErr_Print();
if (removed_idx < img->extra_framecnt - 1) memmove(img->extra_frames + removed_idx, img->extra_frames + removed_idx + 1, sizeof(img->extra_frames[0]) * (img->extra_framecnt - 1 - removed_idx));
img->extra_framecnt--;
if (img->current_frame_index > img->extra_framecnt) {
img->current_frame_index = img->extra_framecnt;
update_current_frame(self, img, NULL);
return NULL;
}
if (removed_idx == img->current_frame_index) update_current_frame(self, img, NULL);
else if (removed_idx < img->current_frame_index) img->current_frame_index--;
return NULL;
}
static void
handle_animation_control_command(GraphicsManager *self, bool *is_dirty, const GraphicsCommand *g, Image *img) {
if (g->frame_number) {
uint32_t frame_idx = g->frame_number - 1;
if (frame_idx <= img->extra_framecnt) {
Frame *f = frame_idx ? img->extra_frames + frame_idx - 1 : &img->root_frame;
if (g->gap) change_gap(img, f, g->gap);
}
}
if (g->other_frame_number) {
uint32_t frame_idx = g->other_frame_number - 1;
if (frame_idx != img->current_frame_index && frame_idx <= img->extra_framecnt) {
img->current_frame_index = frame_idx;
*is_dirty = true;
update_current_frame(self, img, NULL);
}
}
if (g->animation_state) {
AnimationState old_state = img->animation_state;
switch(g->animation_state) {
case 1:
img->animation_state = ANIMATION_STOPPED; break;
case 2:
img->animation_state = ANIMATION_LOADING; break;
case 3:
img->animation_state = ANIMATION_RUNNING; break;
default:
break;
}
if (img->animation_state == ANIMATION_STOPPED) {
img->current_loop = 0;
} else {
if (old_state == ANIMATION_STOPPED) img->current_frame_shown_at = monotonic();
self->has_images_needing_animation = true;
global_state.check_for_active_animated_images = true;
}
img->current_loop = 0;
}
if (g->loop_count) {
img->max_loops = g->loop_count - 1;
global_state.check_for_active_animated_images = true;
}
}
static bool
image_is_animatable(const Image *img) {
return img->animation_state != ANIMATION_STOPPED && img->extra_framecnt && img->is_drawn && img->animation_duration && (
!img->max_loops || img->current_loop < img->max_loops);
}
bool
scan_active_animations(GraphicsManager *self, const monotonic_t now, monotonic_t *minimum_gap, bool os_window_context_set) {
bool dirtied = false;
*minimum_gap = MONOTONIC_T_MAX;
if (!self->has_images_needing_animation) return dirtied;
self->has_images_needing_animation = false;
self->context_made_current_for_this_command = os_window_context_set;
for (size_t i = self->image_count; i-- > 0;) {
Image *img = self->images + i;
if (image_is_animatable(img)) {
Frame *f = current_frame(img);
if (f) {
self->has_images_needing_animation = true;
monotonic_t next_frame_at = img->current_frame_shown_at + ms_to_monotonic_t(f->gap);
if (now >= next_frame_at) {
do {
uint32_t next = (img->current_frame_index + 1) % (img->extra_framecnt + 1);
if (!next) {
if (img->animation_state == ANIMATION_LOADING) goto skip_image;
if (++img->current_loop >= img->max_loops && img->max_loops) goto skip_image;
}
img->current_frame_index = next;
} while (!current_frame(img)->gap);
dirtied = true;
update_current_frame(self, img, NULL);
f = current_frame(img);
next_frame_at = img->current_frame_shown_at + ms_to_monotonic_t(f->gap);
}
if (next_frame_at > now && next_frame_at - now < *minimum_gap) *minimum_gap = next_frame_at - now;
}
}
skip_image:;
}
return dirtied;
}
// }}}
// {{{ composition a=c
static void
cfd_free(void *p) { free(((CoalescedFrameData*)p)->buf); }
static void
handle_compose_command(GraphicsManager *self, bool *is_dirty, const GraphicsCommand *g, Image *img) {
Frame *src_frame = frame_for_number(img, g->frame_number);
if (!src_frame) {
set_command_failed_response("ENOENT", "No source frame number %u exists in image id: %u\n", g->frame_number, img->client_id);
return;
}
Frame *dest_frame = frame_for_number(img, g->other_frame_number);
if (!dest_frame) {
set_command_failed_response("ENOENT", "No destination frame number %u exists in image id: %u\n", g->other_frame_number, img->client_id);
return;
}
const unsigned int width = g->width ? g->width : img->width;
const unsigned int height = g->height ? g->height : img->height;
const unsigned int dest_x = g->x_offset, dest_y = g->y_offset, src_x = g->cell_x_offset, src_y = g->cell_y_offset;
if (dest_x + width > img->width || dest_y + height > img->height) {
set_command_failed_response("EINVAL", "The destination rectangle is out of bounds");
return;
}
if (src_x + width > img->width || src_y + height > img->height) {
set_command_failed_response("EINVAL", "The source rectangle is out of bounds");
return;
}
if (src_frame == dest_frame) {
bool x_overlaps = MAX(src_x, dest_x) < (MIN(src_x, dest_x) + width);
bool y_overlaps = MAX(src_y, dest_y) < (MIN(src_y, dest_y) + height);
if (x_overlaps && y_overlaps) {
set_command_failed_response("EINVAL", "The source and destination rectangles overlap and the src and destination frames are the same");
return;
}
}
FREE_CFD_AFTER_FUNCTION CoalescedFrameData src_data = get_coalesced_frame_data(self, img, src_frame);
if (!src_data.buf) {
set_command_failed_response("EINVAL", "Failed to get data for src frame: %u", g->frame_number - 1);
return;
}
FREE_CFD_AFTER_FUNCTION CoalescedFrameData dest_data = get_coalesced_frame_data(self, img, dest_frame);
if (!dest_data.buf) {
set_command_failed_response("EINVAL", "Failed to get data for destination frame: %u", g->other_frame_number - 1);
return;
}
ComposeData d = {
.over_px_sz = src_data.is_opaque ? 3 : 4, .under_px_sz = dest_data.is_opaque ? 3: 4,
.needs_blending = !g->compose_mode && !src_data.is_opaque,
.over_offset_x = src_x, .over_offset_y = src_y,
.under_offset_x = dest_x, .under_offset_y = dest_y,
.over_width = width, .over_height = height, .under_width = width, .under_height = height,
.stride = img->width
};
compose_rectangles(d, dest_data.buf, src_data.buf);
const ImageAndFrame key = { .image_id = img->internal_id, .frame_id = dest_frame->id };
if (!add_to_cache(self, key, dest_data.buf, ((size_t)(dest_data.is_opaque ? 3 : 4)) * img->width * img->height)) {
if (PyErr_Occurred()) PyErr_Print();
set_command_failed_response("ENOSPC", "Failed to store image data in disk cache");
}
// frame is now a fully coalesced frame
dest_frame->x = 0; dest_frame->y = 0; dest_frame->width = img->width; dest_frame->height = img->height;
dest_frame->base_frame_id = 0; dest_frame->bgcolor = 0;
*is_dirty = (g->other_frame_number - 1) == img->current_frame_index;
if (*is_dirty) update_current_frame(self, img, &dest_data);
}
// }}}
// Image lifetime/scrolling {{{
static void
filter_refs(GraphicsManager *self, const void* data, bool free_images, bool (*filter_func)(const ImageRef*, Image*, const void*, CellPixelSize), CellPixelSize cell, bool only_first_image) {
bool matched = false;
for (size_t i = self->image_count; i-- > 0;) {
Image *img = self->images + i;
for (size_t j = img->refcnt; j-- > 0;) {
ImageRef *ref = img->refs + j;
if (filter_func(ref, img, data, cell)) {
remove_i_from_array(img->refs, j, img->refcnt);
self->layers_dirty = true;
matched = true;
}
}
if (img->refcnt == 0 && (free_images || img->client_id == 0)) remove_image(self, i);
if (only_first_image && matched) break;
}
}
static void
modify_refs(GraphicsManager *self, const void* data, bool (*filter_func)(ImageRef*, Image*, const void*, CellPixelSize), CellPixelSize cell) {
for (size_t i = self->image_count; i-- > 0;) {
Image *img = self->images + i;
for (size_t j = img->refcnt; j-- > 0;) {
if (filter_func(img->refs + j, img, data, cell)) remove_i_from_array(img->refs, j, img->refcnt);
}
if (img->refcnt == 0 && img->client_id == 0 && img->client_number == 0) {
// references have all scrolled off the history buffer and the image has no way to reference it
// to create new references so remove it.
remove_image(self, i);
}
}
}
static bool
scroll_filter_func(ImageRef *ref, Image UNUSED *img, const void *data, CellPixelSize cell UNUSED) {
ScrollData *d = (ScrollData*)data;
ref->start_row += d->amt;
return ref->start_row + (int32_t)ref->effective_num_rows <= d->limit;
}
static bool
ref_within_region(const ImageRef *ref, index_type margin_top, index_type margin_bottom) {
return ref->start_row >= (int32_t)margin_top && ref->start_row + ref->effective_num_rows <= margin_bottom;
}
static bool
ref_outside_region(const ImageRef *ref, index_type margin_top, index_type margin_bottom) {
return ref->start_row + ref->effective_num_rows <= margin_top || ref->start_row > (int32_t)margin_bottom;
}
static bool
scroll_filter_margins_func(ImageRef* ref, Image* img, const void* data, CellPixelSize cell) {
ScrollData *d = (ScrollData*)data;
if (ref_within_region(ref, d->margin_top, d->margin_bottom)) {
ref->start_row += d->amt;
if (ref_outside_region(ref, d->margin_top, d->margin_bottom)) return true;
// Clip the image if scrolling has resulted in part of it being outside the page area
uint32_t clip_amt, clipped_rows;
if (ref->start_row < (int32_t)d->margin_top) {
// image moved up
clipped_rows = d->margin_top - ref->start_row;
clip_amt = cell.height * clipped_rows;
if (ref->src_height <= clip_amt) return true;
ref->src_y += clip_amt; ref->src_height -= clip_amt;
ref->effective_num_rows -= clipped_rows;
update_src_rect(ref, img);
ref->start_row += clipped_rows;
} else if (ref->start_row + ref->effective_num_rows > d->margin_bottom) {
// image moved down
clipped_rows = ref->start_row + ref->effective_num_rows - d->margin_bottom;
clip_amt = cell.height * clipped_rows;
if (ref->src_height <= clip_amt) return true;
ref->src_height -= clip_amt;
ref->effective_num_rows -= clipped_rows;
update_src_rect(ref, img);
}
return ref_outside_region(ref, d->margin_top, d->margin_bottom);
}
return false;
}
void
grman_scroll_images(GraphicsManager *self, const ScrollData *data, CellPixelSize cell) {
if (self->image_count) {
self->layers_dirty = true;
modify_refs(self, data, data->has_margins ? scroll_filter_margins_func : scroll_filter_func, cell);
}
}
static bool
clear_filter_func(const ImageRef *ref, Image UNUSED *img, const void UNUSED *data, CellPixelSize cell UNUSED) {
return ref->start_row + (int32_t)ref->effective_num_rows > 0;
}
static bool
clear_all_filter_func(const ImageRef *ref UNUSED, Image UNUSED *img, const void UNUSED *data, CellPixelSize cell UNUSED) {
return true;
}
void
grman_clear(GraphicsManager *self, bool all, CellPixelSize cell) {
filter_refs(self, NULL, true, all ? clear_all_filter_func : clear_filter_func, cell, false);
}
static bool
id_filter_func(const ImageRef *ref, Image *img, const void *data, CellPixelSize cell UNUSED) {
const GraphicsCommand *g = data;
if (g->id && img->client_id == g->id) return !g->placement_id || ref->client_id == g->placement_id;
return false;
}
static bool
number_filter_func(const ImageRef *ref, Image *img, const void *data, CellPixelSize cell UNUSED) {
const GraphicsCommand *g = data;
if (g->image_number && img->client_number == g->image_number) return !g->placement_id || ref->client_id == g->placement_id;
return false;
}
static bool
x_filter_func(const ImageRef *ref, Image UNUSED *img, const void *data, CellPixelSize cell UNUSED) {
const GraphicsCommand *g = data;
return ref->start_column <= (int32_t)g->x_offset - 1 && ((int32_t)g->x_offset - 1) < ((int32_t)(ref->start_column + ref->effective_num_cols));
}
static bool
y_filter_func(const ImageRef *ref, Image UNUSED *img, const void *data, CellPixelSize cell UNUSED) {
const GraphicsCommand *g = data;
return ref->start_row <= (int32_t)g->y_offset - 1 && ((int32_t)(g->y_offset - 1 < ref->start_row + ref->effective_num_rows));
}
static bool
z_filter_func(const ImageRef *ref, Image UNUSED *img, const void *data, CellPixelSize cell UNUSED) {
const GraphicsCommand *g = data;
return ref->z_index == g->z_index;
}
static bool
point_filter_func(const ImageRef *ref, Image *img, const void *data, CellPixelSize cell) {
return x_filter_func(ref, img, data, cell) && y_filter_func(ref, img, data, cell);
}
static bool
point3d_filter_func(const ImageRef *ref, Image *img, const void *data, CellPixelSize cell) {
return z_filter_func(ref, img, data, cell) && point_filter_func(ref, img, data, cell);
}
static void
handle_delete_command(GraphicsManager *self, const GraphicsCommand *g, Cursor *c, bool *is_dirty, CellPixelSize cell) {
GraphicsCommand d;
bool only_first_image = false;
switch (g->delete_action) {
#define I(u, data, func) filter_refs(self, data, g->delete_action == u, func, cell, only_first_image); *is_dirty = true; break
#define D(l, u, data, func) case l: case u: I(u, data, func)
#define G(l, u, func) D(l, u, g, func)
case 0:
D('a', 'A', NULL, clear_filter_func);
G('i', 'I', id_filter_func);
G('p', 'P', point_filter_func);
G('q', 'Q', point3d_filter_func);
G('x', 'X', x_filter_func);
G('y', 'Y', y_filter_func);
G('z', 'Z', z_filter_func);
case 'c':
case 'C':
d.x_offset = c->x + 1; d.y_offset = c->y + 1;
I('C', &d, point_filter_func);
case 'n':
case 'N':
only_first_image = true;
I('N', g, number_filter_func);
case 'f':
case 'F':
if (handle_delete_frame_command(self, g, is_dirty) != NULL) {
filter_refs(self, g, true, id_filter_func, cell, true);
*is_dirty = true;
}
break;
default:
REPORT_ERROR("Unknown graphics command delete action: %c", g->delete_action);
break;
#undef G
#undef D
#undef I
}
if (!self->image_count && self->count) self->count = 0;
}
// }}}
void
grman_resize(GraphicsManager *self, index_type UNUSED old_lines, index_type UNUSED lines, index_type UNUSED old_columns, index_type UNUSED columns) {
self->layers_dirty = true;
}
void
grman_rescale(GraphicsManager *self, CellPixelSize cell) {
ImageRef *ref; Image *img;
self->layers_dirty = true;
for (size_t i = self->image_count; i-- > 0;) {
img = self->images + i;
for (size_t j = img->refcnt; j-- > 0;) {
ref = img->refs + j;
ref->cell_x_offset = MIN(ref->cell_x_offset, cell.width - 1);
ref->cell_y_offset = MIN(ref->cell_y_offset, cell.height - 1);
update_dest_rect(ref, ref->num_cols, ref->num_rows, cell);
}
}
}
const char*
grman_handle_command(GraphicsManager *self, const GraphicsCommand *g, const uint8_t *payload, Cursor *c, bool *is_dirty, CellPixelSize cell) {
const char *ret = NULL;
command_response[0] = 0;
self->context_made_current_for_this_command = false;
if (g->id && g->image_number) {
set_command_failed_response("EINVAL", "Must not specify both image id and image number");
return finish_command_response(g, false);
}
switch(g->action) {
case 0:
case 't':
case 'T':
case 'q': {
uint32_t iid = g->id, q_iid = iid;
bool is_query = g->action == 'q';
if (is_query) { iid = 0; if (!q_iid) { REPORT_ERROR("Query graphics command without image id"); break; } }
Image *image = handle_add_command(self, g, payload, is_dirty, iid);
if (!self->currently_loading.loading_for.image_id) free_load_data(&self->currently_loading);
GraphicsCommand *lg = &self->currently_loading.start_command;
if (g->quiet) lg->quiet = g->quiet;
if (is_query) ret = finish_command_response(&(const GraphicsCommand){.id=q_iid, .quiet=g->quiet}, image != NULL);
else ret = finish_command_response(lg, image != NULL);
if (lg->action == 'T' && image && image->root_frame_data_loaded) handle_put_command(self, lg, c, is_dirty, image, cell);
id_type added_image_id = image ? image->internal_id : 0;
if (g->action == 'q') remove_images(self, add_trim_predicate, 0);
if (self->used_storage > self->storage_limit) apply_storage_quota(self, self->storage_limit, added_image_id);
break;
}
case 'a':
case 'f': {
if (!g->id && !g->image_number && !self->currently_loading.loading_for.image_id) {
REPORT_ERROR("Add frame data command without image id or number");
break;
}
Image *img;
if (self->currently_loading.loading_for.image_id) img = img_by_internal_id(self, self->currently_loading.loading_for.image_id);
else img = g->id ? img_by_client_id(self, g->id) : img_by_client_number(self, g->image_number);
if (!img) {
set_command_failed_response("ENOENT", "Animation command refers to non-existent image with id: %u and number: %u", g->id, g->image_number);
ret = finish_command_response(g, false);
} else {
GraphicsCommand ag = *g;
if (ag.action == 'f') {
img = handle_animation_frame_load_command(self, &ag, img, payload, is_dirty);
if (!self->currently_loading.loading_for.image_id) free_load_data(&self->currently_loading);
if (g->quiet) ag.quiet = g->quiet;
else ag.quiet = self->currently_loading.start_command.quiet;
ret = finish_command_response(&ag, img != NULL);
} else if (ag.action == 'a') {
handle_animation_control_command(self, is_dirty, &ag, img);
}
}
break;
}
case 'p': {
if (!g->id && !g->image_number) {
REPORT_ERROR("Put graphics command without image id or number");
break;
}
uint32_t image_id = handle_put_command(self, g, c, is_dirty, NULL, cell);
GraphicsCommand rg = *g; rg.id = image_id;
ret = finish_command_response(&rg, true);
break;
}
case 'd':
handle_delete_command(self, g, c, is_dirty, cell);
break;
case 'c':
if (!g->id && !g->image_number) {
REPORT_ERROR("Compose frame data command without image id or number");
break;
}
Image *img = g->id ? img_by_client_id(self, g->id) : img_by_client_number(self, g->image_number);
if (!img) {
set_command_failed_response("ENOENT", "Animation command refers to non-existent image with id: %u and number: %u", g->id, g->image_number);
ret = finish_command_response(g, false);
} else {
handle_compose_command(self, is_dirty, g, img);
ret = finish_command_response(g, true);
}
break;
default:
REPORT_ERROR("Unknown graphics command action: %c", g->action);
break;
}
return ret;
}
// Boilerplate {{{
static PyObject *
new(PyTypeObject UNUSED *type, PyObject UNUSED *args, PyObject UNUSED *kwds) {
PyObject *ans = (PyObject*)grman_alloc();
if (ans == NULL) PyErr_NoMemory();
return ans;
}
static PyObject*
image_as_dict(GraphicsManager *self, Image *img) {
#define U(x) #x, (unsigned int)(img->x)
#define B(x) #x, img->x ? Py_True : Py_False
PyObject *frames = PyTuple_New(img->extra_framecnt);
for (unsigned i = 0; i < img->extra_framecnt; i++) {
Frame *f = img->extra_frames + i;
CoalescedFrameData cfd = get_coalesced_frame_data(self, img, f);
if (!cfd.buf) { PyErr_SetString(PyExc_RuntimeError, "Failed to get data for frame"); return NULL; }
PyTuple_SET_ITEM(frames, i, Py_BuildValue(
"{sI sI sy#}",
"gap", f->gap,
"id", f->id,
"data", cfd.buf, (Py_ssize_t)((cfd.is_opaque ? 3 : 4) * img->width * img->height)
));
free(cfd.buf);
if (PyErr_Occurred()) { Py_CLEAR(frames); return NULL; }
}
CoalescedFrameData cfd = get_coalesced_frame_data(self, img, &img->root_frame);
if (!cfd.buf) { PyErr_SetString(PyExc_RuntimeError, "Failed to get data for root frame"); return NULL; }
PyObject *ans = Py_BuildValue("{sI sI sI sI sI sI sI " "sO sI sO " "sI sI sI " "sI sy# sN}",
U(texture_id), U(client_id), U(width), U(height), U(internal_id), U(refcnt), U(client_number),
B(root_frame_data_loaded), U(animation_state), "is_4byte_aligned", img->root_frame.is_4byte_aligned ? Py_True : Py_False,
U(current_frame_index), "root_frame_gap", img->root_frame.gap, U(current_frame_index),
U(animation_duration), "data", cfd.buf, (Py_ssize_t)((cfd.is_opaque ? 3 : 4) * img->width * img->height), "extra_frames", frames
);
free(cfd.buf);
return ans;
#undef B
#undef U
}
#define W(x) static PyObject* py##x(GraphicsManager UNUSED *self, PyObject *args)
#define PA(fmt, ...) if(!PyArg_ParseTuple(args, fmt, __VA_ARGS__)) return NULL;
W(image_for_client_id) {
unsigned long id = PyLong_AsUnsignedLong(args);
bool existing = false;
Image *img = find_or_create_image(self, id, &existing);
if (!existing) { Py_RETURN_NONE; }
return image_as_dict(self, img);
}
W(image_for_client_number) {
unsigned long num = PyLong_AsUnsignedLong(args);
Image *img = img_by_client_number(self, num);
if (!img) Py_RETURN_NONE;
return image_as_dict(self, img);
}
W(shm_write) {
const char *name, *data;
Py_ssize_t sz;
PA("ss#", &name, &data, &sz);
int fd = shm_open(name, O_CREAT | O_RDWR, S_IRUSR | S_IWUSR);
if (fd == -1) { PyErr_SetFromErrnoWithFilename(PyExc_OSError, name); return NULL; }
int ret = ftruncate(fd, sz);
if (ret != 0) { safe_close(fd, __FILE__, __LINE__); PyErr_SetFromErrnoWithFilename(PyExc_OSError, name); return NULL; }
void *addr = mmap(0, sz, PROT_WRITE, MAP_SHARED, fd, 0);
if (addr == MAP_FAILED) { safe_close(fd, __FILE__, __LINE__); PyErr_SetFromErrnoWithFilename(PyExc_OSError, name); return NULL; }
memcpy(addr, data, sz);
if (munmap(addr, sz) != 0) { safe_close(fd, __FILE__, __LINE__); PyErr_SetFromErrnoWithFilename(PyExc_OSError, name); return NULL; }
safe_close(fd, __FILE__, __LINE__);
Py_RETURN_NONE;
}
W(shm_unlink) {
char *name;
PA("s", &name);
int ret = shm_unlink(name);
if (ret == -1) { PyErr_SetFromErrnoWithFilename(PyExc_OSError, name); return NULL; }
Py_RETURN_NONE;
}
W(update_layers) {
unsigned int scrolled_by, sx, sy; float xstart, ystart, dx, dy;
CellPixelSize cell;
PA("IffffIIII", &scrolled_by, &xstart, &ystart, &dx, &dy, &sx, &sy, &cell.width, &cell.height);
grman_update_layers(self, scrolled_by, xstart, ystart, dx, dy, sx, sy, cell);
PyObject *ans = PyTuple_New(self->count);
for (size_t i = 0; i < self->count; i++) {
ImageRenderData *r = self->render_data + i;
#define R(offset) Py_BuildValue("{sf sf sf sf}", "left", r->vertices[offset + 8], "top", r->vertices[offset + 1], "right", r->vertices[offset], "bottom", r->vertices[offset + 5])
PyTuple_SET_ITEM(ans, i,
Py_BuildValue("{sN sN sI si sK}", "src_rect", R(0), "dest_rect", R(2), "group_count", r->group_count, "z_index", r->z_index, "image_id", r->image_id)
);
#undef R
}
return ans;
}
#define M(x, va) {#x, (PyCFunction)py##x, va, ""}
static PyMethodDef methods[] = {
M(image_for_client_id, METH_O),
M(image_for_client_number, METH_O),
M(update_layers, METH_VARARGS),
{NULL} /* Sentinel */
};
static PyMemberDef members[] = {
{"image_count", T_PYSSIZET, offsetof(GraphicsManager, image_count), READONLY, "image_count"},
{"storage_limit", T_PYSSIZET, offsetof(GraphicsManager, storage_limit), 0, "storage_limit"},
{"disk_cache", T_OBJECT_EX, offsetof(GraphicsManager, disk_cache), READONLY, "disk_cache"},
{NULL},
};
PyTypeObject GraphicsManager_Type = {
PyVarObject_HEAD_INIT(NULL, 0)
.tp_name = "fast_data_types.GraphicsManager",
.tp_basicsize = sizeof(GraphicsManager),
.tp_dealloc = (destructor)dealloc,
.tp_flags = Py_TPFLAGS_DEFAULT,
.tp_doc = "GraphicsManager",
.tp_new = new,
.tp_methods = methods,
.tp_members = members,
};
static PyObject*
pycreate_canvas(PyObject *self UNUSED, PyObject *args) {
unsigned int bytes_per_pixel;
unsigned int over_width, width, height, x, y;
Py_ssize_t over_sz;
const uint8_t *over_data;
if (!PyArg_ParseTuple(args, "y#IIIIII", &over_data, &over_sz, &over_width, &x, &y, &width, &height, &bytes_per_pixel)) return NULL;
size_t canvas_sz = (size_t)width * height * bytes_per_pixel;
PyObject *ans = PyBytes_FromStringAndSize(NULL, canvas_sz);
if (!ans) return NULL;
uint8_t* canvas = (uint8_t*)PyBytes_AS_STRING(ans);
memset(canvas, 0, canvas_sz);
ComposeData cd = {
.needs_blending = bytes_per_pixel == 4,
.over_width = over_width, .over_height = over_sz / (bytes_per_pixel * over_width),
.under_width = width, .under_height = height,
.over_px_sz = bytes_per_pixel, .under_px_sz = bytes_per_pixel,
.over_offset_x = x, .over_offset_y = y
};
compose(cd, canvas, over_data);
return ans;
}
static PyMethodDef module_methods[] = {
M(shm_write, METH_VARARGS),
M(shm_unlink, METH_VARARGS),
M(create_canvas, METH_VARARGS),
{NULL, NULL, 0, NULL} /* Sentinel */
};
bool
init_graphics(PyObject *module) {
if (PyType_Ready(&GraphicsManager_Type) < 0) return false;
if (PyModule_AddObject(module, "GraphicsManager", (PyObject *)&GraphicsManager_Type) != 0) return false;
if (PyModule_AddFunctions(module, module_methods) != 0) return false;
Py_INCREF(&GraphicsManager_Type);
return true;
}
// }}}
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