uint8 LoadSpriteV1(SpriteLoader::Sprite *sprite, uint8 file_slot, size_t file_pos, SpriteType sprite_type, bool load_32bpp)
{
/* Check the requested colour depth. */
if (load_32bpp) return 0;
/* Open the right file and go to the correct position */
FioSeekToFile(file_slot, file_pos);
/* Read the size and type */
int num = FioReadWord();
byte type = FioReadByte();
/* Type 0xFF indicates either a colourmap or some other non-sprite info; we do not handle them here */
if (type == 0xFF) return 0;
ZoomLevel zoom_lvl = (sprite_type == ST_NORMAL) ? ZOOM_LVL_OUT_4X : ZOOM_LVL_NORMAL;
sprite[zoom_lvl].height = FioReadByte();
sprite[zoom_lvl].width = FioReadWord();
sprite[zoom_lvl].x_offs = FioReadWord();
sprite[zoom_lvl].y_offs = FioReadWord();
if (sprite[zoom_lvl].width > INT16_MAX) {
WarnCorruptSprite(file_slot, file_pos, __LINE__);
return 0;
}
/* 0x02 indicates it is a compressed sprite, so we can't rely on 'num' to be valid.
* In case it is uncompressed, the size is 'num' - 8 (header-size). */
num = (type & 0x02) ? sprite[zoom_lvl].width * sprite[zoom_lvl].height : num - 8;
if (DecodeSingleSprite(&sprite[zoom_lvl], file_slot, file_pos, sprite_type, num, type, zoom_lvl, SCC_PAL, 1)) return 1 << zoom_lvl;
return 0;
}
/**
* Decode the image data of a single sprite.
* @param[in,out] sprite Filled with the sprite image data.
* @param file_slot File slot.
* @param file_pos File position.
* @param sprite_type Type of the sprite we're decoding.
* @param num Size of the decompressed sprite.
* @param type Type of the encoded sprite.
* @param zoom_lvl Requested zoom level.
* @param colour_fmt Colour format of the sprite.
* @param container_format Container format of the GRF this sprite is in.
* @return True if the sprite was successfully loaded.
*/
bool DecodeSingleSprite(SpriteLoader::Sprite *sprite, uint8 file_slot, size_t file_pos, SpriteType sprite_type, int64 num, byte type, ZoomLevel zoom_lvl, byte colour_fmt, byte container_format)
{
AutoFreePtr<byte> dest_orig(MallocT<byte>(num));
byte *dest = dest_orig;
const int64 dest_size = num;
/* Read the file, which has some kind of compression */
while (num > 0) {
int8 code = FioReadByte();
if (code >= 0) {
/* Plain bytes to read */
int size = (code == 0) ? 0x80 : code;
num -= size;
if (num < 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
for (; size > 0; size--) {
*dest = FioReadByte();
dest++;
}
} else {
/* Copy bytes from earlier in the sprite */
const uint data_offset = ((code & 7) << 8) | FioReadByte();
if (dest - data_offset < dest_orig) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
int size = -(code >> 3);
num -= size;
if (num < 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
for (; size > 0; size--) {
*dest = *(dest - data_offset);
dest++;
}
}
}
if (num != 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
sprite->AllocateData(zoom_lvl, sprite->width * sprite->height);
/* Convert colour depth to pixel size. */
int bpp = 0;
if (colour_fmt & SCC_RGB) bpp += 3; // Has RGB data.
if (colour_fmt & SCC_ALPHA) bpp++; // Has alpha data.
if (colour_fmt & SCC_PAL) bpp++; // Has palette data.
/* When there are transparency pixels, this format has another trick.. decode it */
if (type & 0x08) {
for (int y = 0; y < sprite->height; y++) {
bool last_item = false;
/* Look up in the header-table where the real data is stored for this row */
int offset;
if (container_format >= 2 && dest_size > UINT16_MAX) {
offset = (dest_orig[y * 4 + 3] << 24) | (dest_orig[y * 4 + 2] << 16) | (dest_orig[y * 4 + 1] << 8) | dest_orig[y * 4];
} else {
offset = (dest_orig[y * 2 + 1] << 8) | dest_orig[y * 2];
}
/* Go to that row */
dest = dest_orig + offset;
do {
if (dest + (container_format >= 2 && sprite->width > 256 ? 4 : 2) > dest_orig + dest_size) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
SpriteLoader::CommonPixel *data;
/* Read the header. */
int length, skip;
if (container_format >= 2 && sprite->width > 256) {
/* 0 .. 14 - length
* 15 - last_item
* 16 .. 31 - transparency bytes */
last_item = (dest[1] & 0x80) != 0;
length = ((dest[1] & 0x7F) << 8) | dest[0];
skip = (dest[3] << 8) | dest[2];
dest += 4;
} else {
/* 0 .. 6 - length
* 7 - last_item
* 8 .. 15 - transparency bytes */
last_item = ((*dest) & 0x80) != 0;
length = (*dest++) & 0x7F;
skip = *dest++;
}
data = &sprite->data[y * sprite->width + skip];
if (skip + length > sprite->width || dest + length * bpp > dest_orig + dest_size) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
for (int x = 0; x < length; x++) {
if (colour_fmt & SCC_RGB) {
data->r = *dest++;
data->g = *dest++;
data->b = *dest++;
}
data->a = (colour_fmt & SCC_ALPHA) ? *dest++ : 0xFF;
if (colour_fmt & SCC_PAL) {
switch (sprite_type) {
case ST_NORMAL: data->m = _palette_remap_grf[file_slot] ? _palmap_w2d[*dest] : *dest; break;
case ST_FONT: data->m = min(*dest, 2u); break;
default: data->m = *dest; break;
}
/* Magic blue. */
if (colour_fmt == SCC_PAL && *dest == 0) data->a = 0x00;
dest++;
}
data++;
}
} while (!last_item);
}
} else {
if (dest_size < sprite->width * sprite->height * bpp) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
if (dest_size > sprite->width * sprite->height * bpp) {
static byte warning_level = 0;
DEBUG(sprite, warning_level, "Ignoring " OTTD_PRINTF64 " unused extra bytes from the sprite from %s at position %i", dest_size - sprite->width * sprite->height * bpp, FioGetFilename(file_slot), (int)file_pos);
warning_level = 6;
}
dest = dest_orig;
for (int i = 0; i < sprite->width * sprite->height; i++) {
byte *pixel = &dest[i * bpp];
if (colour_fmt & SCC_RGB) {
sprite->data[i].r = *pixel++;
sprite->data[i].g = *pixel++;
sprite->data[i].b = *pixel++;
}
sprite->data[i].a = (colour_fmt & SCC_ALPHA) ? *pixel++ : 0xFF;
if (colour_fmt & SCC_PAL) {
switch (sprite_type) {
case ST_NORMAL: sprite->data[i].m = _palette_remap_grf[file_slot] ? _palmap_w2d[*pixel] : *pixel; break;
case ST_FONT: sprite->data[i].m = min(*pixel, 2u); break;
default: sprite->data[i].m = *pixel; break;
}
/* Magic blue. */
if (colour_fmt == SCC_PAL && *pixel == 0) sprite->data[i].a = 0x00;
pixel++;
}
}
}
return true;
}
uint8 LoadSpriteV2(SpriteLoader::Sprite *sprite, uint8 file_slot, size_t file_pos, SpriteType sprite_type, bool load_32bpp)
{
static const ZoomLevel zoom_lvl_map[6] = {ZOOM_LVL_OUT_4X, ZOOM_LVL_NORMAL, ZOOM_LVL_OUT_2X, ZOOM_LVL_OUT_8X, ZOOM_LVL_OUT_16X, ZOOM_LVL_OUT_32X};
/* Is the sprite not present/stripped in the GRF? */
if (file_pos == SIZE_MAX) return 0;
/* Open the right file and go to the correct position */
FioSeekToFile(file_slot, file_pos);
uint32 id = FioReadDword();
uint8 loaded_sprites = 0;
do {
int64 num = FioReadDword();
size_t start_pos = FioGetPos();
byte type = FioReadByte();
/* Type 0xFF indicates either a colourmap or some other non-sprite info; we do not handle them here. */
if (type == 0xFF) return 0;
byte colour = type & SCC_MASK;
byte zoom = FioReadByte();
if (colour != 0 && (load_32bpp ? colour != SCC_PAL : colour == SCC_PAL) && (sprite_type == ST_NORMAL ? zoom < lengthof(zoom_lvl_map) : zoom == 0)) {
ZoomLevel zoom_lvl = (sprite_type == ST_NORMAL) ? zoom_lvl_map[zoom] : ZOOM_LVL_NORMAL;
if (HasBit(loaded_sprites, zoom_lvl)) {
/* We already have this zoom level, skip sprite. */
DEBUG(sprite, 1, "Ignoring duplicate zoom level sprite %u from %s", id, FioGetFilename(file_slot));
FioSkipBytes(num - 2);
continue;
}
sprite[zoom_lvl].height = FioReadWord();
sprite[zoom_lvl].width = FioReadWord();
sprite[zoom_lvl].x_offs = FioReadWord();
sprite[zoom_lvl].y_offs = FioReadWord();
if (sprite[zoom_lvl].width > INT16_MAX || sprite[zoom_lvl].height > INT16_MAX) {
WarnCorruptSprite(file_slot, file_pos, __LINE__);
return 0;
}
/* Mask out colour information. */
type = type & ~SCC_MASK;
/* Convert colour depth to pixel size. */
int bpp = 0;
if (colour & SCC_RGB) bpp += 3; // Has RGB data.
if (colour & SCC_ALPHA) bpp++; // Has alpha data.
if (colour & SCC_PAL) bpp++; // Has palette data.
/* For chunked encoding we store the decompressed size in the file,
* otherwise we can calculate it from the image dimensions. */
uint decomp_size = (type & 0x08) ? FioReadDword() : sprite[zoom_lvl].width * sprite[zoom_lvl].height * bpp;
bool valid = DecodeSingleSprite(&sprite[zoom_lvl], file_slot, file_pos, sprite_type, decomp_size, type, zoom_lvl, colour, 2);
if (FioGetPos() != start_pos + num) {
WarnCorruptSprite(file_slot, file_pos, __LINE__);
return 0;
}
if (valid) SetBit(loaded_sprites, zoom_lvl);
} else {
/* Not the wanted zoom level or colour depth, continue searching. */
FioSkipBytes(num - 2);
}
} while (FioReadDword() == id);
return loaded_sprites;
}
bool SpriteLoaderGrf::LoadSprite(SpriteLoader::Sprite *sprite, uint8 file_slot, size_t file_pos, SpriteType sprite_type)
{
/* Open the right file and go to the correct position */
FioSeekToFile(file_slot, file_pos);
/* Read the size and type */
int num = FioReadWord();
byte type = FioReadByte();
/* Type 0xFF indicates either a colourmap or some other non-sprite info; we do not handle them here */
if (type == 0xFF) return false;
sprite->height = FioReadByte();
sprite->width = FioReadWord();
sprite->x_offs = FioReadWord();
sprite->y_offs = FioReadWord();
/* 0x02 indicates it is a compressed sprite, so we can't rely on 'num' to be valid.
* In case it is uncompressed, the size is 'num' - 8 (header-size). */
num = (type & 0x02) ? sprite->width * sprite->height : num - 8;
byte *dest_orig = AllocaM(byte, num);
byte *dest = dest_orig;
const int dest_size = num;
/* Read the file, which has some kind of compression */
while (num > 0) {
int8 code = FioReadByte();
if (code >= 0) {
/* Plain bytes to read */
int size = (code == 0) ? 0x80 : code;
num -= size;
if (num < 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
for (; size > 0; size--) {
*dest = FioReadByte();
dest++;
}
} else {
/* Copy bytes from earlier in the sprite */
const uint data_offset = ((code & 7) << 8) | FioReadByte();
if (dest - data_offset < dest_orig) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
int size = -(code >> 3);
num -= size;
if (num < 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
for (; size > 0; size--) {
*dest = *(dest - data_offset);
dest++;
}
}
}
if (num != 0) return WarnCorruptSprite(file_slot, file_pos, __LINE__);
sprite->AllocateData(sprite->width * sprite->height * ZOOM_LVL_BASE * ZOOM_LVL_BASE);
/* When there are transparency pixels, this format has another trick.. decode it */
if (type & 0x08) {
for (int y = 0; y < sprite->height; y++) {
bool last_item = false;
/* Look up in the header-table where the real data is stored for this row */
int offset = (dest_orig[y * 2 + 1] << 8) | dest_orig[y * 2];
/* Go to that row */
dest = dest_orig + offset;
do {
if (dest + 2 > dest_orig + dest_size) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
SpriteLoader::CommonPixel *data;
/* Read the header:
* 0 .. 14 - length
* 15 - last_item
* 16 .. 31 - transparency bytes */
last_item = ((*dest) & 0x80) != 0;
int length = (*dest++) & 0x7F;
int skip = *dest++;
data = &sprite->data[y * sprite->width + skip];
if (skip + length > sprite->width || dest + length > dest_orig + dest_size) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
for (int x = 0; x < length; x++) {
switch (sprite_type) {
case ST_NORMAL: data->m = _palette_remap_grf[file_slot] ? _palmap_w2d[*dest] : *dest; break;
case ST_FONT: data->m = min(*dest, 2u); break;
default: data->m = *dest; break;
}
dest++;
data++;
}
} while (!last_item);
}
} else {
if (dest_size < sprite->width * sprite->height) {
return WarnCorruptSprite(file_slot, file_pos, __LINE__);
}
if (dest_size > sprite->width * sprite->height) {
static byte warning_level = 0;
DEBUG(sprite, warning_level, "Ignoring %i unused extra bytes from the sprite from %s at position %i", dest_size - sprite->width * sprite->height, FioGetFilename(file_slot), (int)file_pos);
warning_level = 6;
}
dest = dest_orig;
for (int i = 0; i < sprite->width * sprite->height; i++) {
switch (sprite_type) {
case ST_NORMAL: sprite->data[i].m = _palette_remap_grf[file_slot] ? _palmap_w2d[dest[i]] : dest[i]; break;
case ST_FONT: sprite->data[i].m = min(dest[i], 2u); break;
default: sprite->data[i].m = dest[i]; break;
}
}
}
if (ZOOM_LVL_BASE != 1 && sprite_type == ST_NORMAL) {
/* Simple scaling, back-to-front so that no intermediate buffers are needed. */
int width = sprite->width * ZOOM_LVL_BASE;
int height = sprite->height * ZOOM_LVL_BASE;
for (int y = height - 1; y >= 0; y--) {
for (int x = width - 1; x >= 0; x--) {
sprite->data[y * width + x] = sprite->data[y / ZOOM_LVL_BASE * sprite->width + x / ZOOM_LVL_BASE];
}
}
sprite->width *= ZOOM_LVL_BASE;
sprite->height *= ZOOM_LVL_BASE;
sprite->x_offs *= ZOOM_LVL_BASE;
sprite->y_offs *= ZOOM_LVL_BASE;
}
/* Make sure to mark all transparent pixels transparent on the alpha channel too */
for (int i = 0; i < sprite->width * sprite->height; i++) {
if (sprite->data[i].m != 0) sprite->data[i].a = 0xFF;
}
return true;
}
