/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 by Linus Nielsen Feltzing * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ /* 2005-04-16 Tomas Salfischberger: - New BMP loader function, based on the old one (borrowed a lot of calculations and checks there.) - Conversion part needs some optimization, doing unneeded calulations now. 2006-11-18 Jens Arnold: complete rework - All canonical formats supported now (1, 4, 8, 15/16, 24 and 32 bit) - better protection against malformed / non-standard BMPs - code heavily optimised for both size and speed - dithering for 2 bit targets 2008-11-02 Akio Idehara: refactor for scaler frontend 2008-12-08 Andrew Mahone: partial-line reading, scaler frontend - read_part_line does the actual source BMP reading, return columns read and updates fields in a struct bmp_args with the new data and current reader state - skip_lines_bmp and store_part_bmp implement the scaler callbacks to skip ahead by whole lines, or read the next chunk of the current line */ #include #include #include #include "inttypes.h" #include "system.h" #ifndef PLUGIN #include "debug.h" #endif #include "lcd.h" #include "file.h" #include "bmp.h" #ifdef HAVE_REMOTE_LCD #include "lcd-remote.h" #endif #ifdef ROCKBOX_DEBUG_BMP_LOADER #define BDEBUGF DEBUGF #else #define BDEBUGF(...) #endif #ifndef __PCTOOL__ #include "config.h" #include "resize.h" #else #undef DEBUGF #define DEBUGF(...) #endif #ifdef __GNUC__ #define STRUCT_PACKED __attribute__((packed)) #else #define STRUCT_PACKED #pragma pack (push, 2) #endif /* BMP header structure */ struct bmp_header { uint16_t type; /* signature - 'BM' */ uint32_t size; /* file size in bytes */ uint16_t reserved1; /* 0 */ uint16_t reserved2; /* 0 */ uint32_t off_bits; /* offset to bitmap */ uint32_t struct_size; /* size of this struct (40) */ int32_t width; /* bmap width in pixels */ int32_t height; /* bmap height in pixels */ uint16_t planes; /* num planes - always 1 */ uint16_t bit_count; /* bits per pixel */ uint32_t compression; /* compression flag */ uint32_t size_image; /* image size in bytes */ int32_t x_pels_per_meter; /* horz resolution */ int32_t y_pels_per_meter; /* vert resolution */ uint32_t clr_used; /* 0 -> color table size */ uint32_t clr_important; /* important color count */ } STRUCT_PACKED; /* masks for supported BI_BITFIELDS encodings (16/32 bit) */ static const struct uint8_rgb bitfields[][4] = { /* 15bit */ { { .blue = 0x00, .green = 0x7c, .red = 0x00, .alpha = 0x00 }, { .blue = 0xe0, .green = 0x03, .red = 0x00, .alpha = 0x00 }, { .blue = 0x1f, .green = 0x00, .red = 0x00, .alpha = 0x00 }, { .blue = 0x00, .green = 0x00, .red = 0x00, .alpha = 0x00 }, }, /* 16bit */ { { .blue = 0x00, .green = 0xf8, .red = 0x00, .alpha = 0x00 }, { .blue = 0xe0, .green = 0x07, .red = 0x00, .alpha = 0x00 }, { .blue = 0x1f, .green = 0x00, .red = 0x00, .alpha = 0x00 }, { .blue = 0x00, .green = 0x00, .red = 0x00, .alpha = 0x00 }, }, /* 32bit BGRA */ { { .blue = 0x00, .green = 0x00, .red = 0xff, .alpha = 0x00 }, { .blue = 0x00, .green = 0xff, .red = 0x00, .alpha = 0x00 }, { .blue = 0xff, .green = 0x00, .red = 0x00, .alpha = 0x00 }, { .blue = 0x00, .green = 0x00, .red = 0x00, .alpha = 0xff }, }, /* 32bit ABGR */ { { .blue = 0x00, .green = 0x00, .red = 0x00, .alpha = 0xff }, { .blue = 0x00, .green = 0x00, .red = 0xff, .alpha = 0x00 }, { .blue = 0x00, .green = 0xff, .red = 0x00, .alpha = 0x00 }, { .blue = 0xff, .green = 0x00, .red = 0x00, .alpha = 0x00 }, }, }; #if (LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1) /* the full 16x16 Bayer dither matrix may be calculated quickly with this table */ const unsigned char dither_table[16] = { 0,192, 48,240, 12,204, 60,252, 3,195, 51,243, 15,207, 63,255 }; #endif #if ((LCD_DEPTH == 2) && (LCD_PIXELFORMAT == VERTICAL_INTERLEAVED)) \ || (defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH == 2) \ && (LCD_REMOTE_PIXELFORMAT == VERTICAL_INTERLEAVED)) const unsigned short vi_pattern[4] = { 0x0101, 0x0100, 0x0001, 0x0000 }; #endif /****************************************************************************** * read_bmp_file() * * Reads a BMP file and puts the data in rockbox format in *bitmap. * *****************************************************************************/ int read_bmp_file(const char* filename, struct bitmap *bm, int maxsize, int format, const struct custom_format *cformat) { int fd, ret; fd = open(filename, O_RDONLY); /* Exit if file opening failed */ if (fd < 0) { DEBUGF("read_bmp_file: can't open '%s', rc: %d\n", filename, fd); return fd * 10 - 1; } BDEBUGF("read_bmp_file: '%s' remote: %d resize: %d keep_aspect: %d\n", filename, !!(format & FORMAT_REMOTE), !!(format & FORMAT_RESIZE), !!(format & FORMAT_KEEP_ASPECT)); ret = read_bmp_fd(fd, bm, maxsize, format, cformat); close(fd); return ret; } enum color_order { /* only used for different types of 32bpp images */ BGRA, /* should be most common */ ABGR /* generated by some GIMP versions */ }; struct bmp_args { /* needs to be at least 2byte aligned for faster 16bit reads. * but aligning to cache should be even faster */ unsigned char buf[BM_MAX_WIDTH * 4] CACHEALIGN_AT_LEAST_ATTR(2); int fd; short padded_width; short read_width; short width; short depth; enum color_order order; struct uint8_rgb *palette; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) int cur_row; int cur_col; struct img_part part; #endif /* as read_part_line() goes through the rows it'll set this to true * if it finds transparency. Initialize to 0 before calling */ int alpha_detected; /* for checking transparency it checks the against the very first byte * of the bitmap. Initalize to 0x80 before calling */ unsigned char first_alpha_byte; }; static unsigned int read_part_line(struct bmp_args *ba) { const int padded_width = ba->padded_width; const int read_width = ba->read_width; const int width = ba->width; int depth = ba->depth; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) int cur_row = ba->cur_row; int cur_col = ba->cur_col; #endif const int fd = ba->fd; uint8_t *ibuf; struct uint8_rgb *buf = (struct uint8_rgb *)(ba->buf); const struct uint8_rgb *palette = ba->palette; uint32_t component, data; int ret; int i, cols, len; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) cols = MIN(width - cur_col,(int)BM_MAX_WIDTH); BDEBUGF("reading %d cols (width: %d, max: %d)\n",cols,width,BM_MAX_WIDTH); len = (cols * (depth == 15 ? 16 : depth) + 7) >> 3; #else cols = width; len = read_width; #endif ibuf = ((unsigned char *)buf) + (BM_MAX_WIDTH << 2) - len; BDEBUGF("read_part_line: cols=%d len=%d\n",cols,len); ret = read(fd, ibuf, len); if (ret != len) { DEBUGF("read_part_line: error reading image, read returned %d " "expected %d\n", ret, len); #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) BDEBUGF("cur_row: %d cur_col: %d cols: %d len: %d\n", cur_row, cur_col, cols, len); #endif return 0; } /* detect if the image has useful alpha information. * if all alpha bits are 0xff or 0x00 discard the information. * if it has other bits, or is mixed with 0x00 and 0xff then interpret * as alpha. assume no alpha until the opposite is proven. as mixed * is alpha, compare to the first byte instead of 0xff and 0x00 separately */ if (depth == 32 && ba->first_alpha_byte == 0x80) ba->first_alpha_byte = ibuf[3] ? 0xff : 0x0; /* select different color orders within the switch-case to avoid * nested if/switch */ if (depth == 32) depth += ba->order; while (ibuf < ba->buf + (BM_MAX_WIDTH << 2)) { switch (depth) { case 1: data = *ibuf++; for (i = 0; i < 8; i++) { *buf++ = palette[data & 0x80 ? 1 : 0]; data <<= 1; } break; case 4: data = *ibuf++; *buf++ = palette[data >> 4]; *buf++ = palette[data & 0xf]; break; case 8: *buf++ = palette[*ibuf++]; break; case 15: case 16: data = letoh16(*(uint16_t*)ibuf); component = (data << 3) & 0xf8; component |= component >> 5; buf->blue = component; if (depth == 15) { data >>= 2; component = data & 0xf8; component |= component >> 5; } else { data >>= 3; component = data & 0xfc; component |= component >> 6; } buf->green = component; data >>= 5; component = data & 0xf8; component |= component >> 5; buf->red = component; buf->alpha = 0xff; buf++; ibuf += 2; break; case 24: buf->blue = *ibuf++; buf->green = *ibuf++; buf->red = *ibuf++; buf->alpha = 0xff; buf++; break; case 32 + BGRA: buf->blue = *ibuf++; buf->green = *ibuf++; buf->red = *ibuf++; buf->alpha = *ibuf++; ba->alpha_detected |= (buf->alpha != ba->first_alpha_byte); buf++; break; case 32 + ABGR: buf->alpha = *ibuf++; buf->blue = *ibuf++; buf->green = *ibuf++; buf->red = *ibuf++; ba->alpha_detected |= (buf->alpha != ba->first_alpha_byte); buf++; break; } } #if !defined(HAVE_LCD_COLOR) && \ ((LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) || \ defined(PLUGIN)) ibuf = ba->buf; buf = (struct uint8_rgb*)ba->buf; while (ibuf < ba->buf + cols) *ibuf++ = brightness(*buf++); #endif #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) cur_col += cols; if (cur_col == width) { #endif int pad = padded_width - read_width; if (pad > 0) { BDEBUGF("seeking %d bytes to next line\n",pad); lseek(fd, pad, SEEK_CUR); } #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) cur_col = 0; BDEBUGF("read_part_line: completed row %d\n", cur_row); cur_row += 1; } ba->cur_row = cur_row; ba->cur_col = cur_col; #endif return cols; } #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) static struct img_part *store_part_bmp(void *args) { struct bmp_args *ba = (struct bmp_args *)args; ba->part.len = read_part_line(ba); #ifdef HAVE_LCD_COLOR ba->part.buf = (struct uint8_rgb *)ba->buf; #else ba->part.buf = (uint8_t *)ba->buf; #endif if (ba->part.len) return &(ba->part); else return NULL; } #endif static inline int rgbcmp(const struct uint8_rgb *rgb1, const struct uint8_rgb *rgb2) { return memcmp(rgb1, rgb2, sizeof(struct uint8_rgb)); } #if LCD_DEPTH > 1 #if !defined(PLUGIN) && !defined(HAVE_JPEG) && !defined(HAVE_BMP_SCALING) static inline #endif void output_row_8_native(uint32_t row, void * row_in, struct scaler_context *ctx) { int col; int fb_width = BM_WIDTH(ctx->bm->width,FORMAT_NATIVE,0); uint8_t dy = DITHERY(row); #ifdef HAVE_LCD_COLOR struct uint8_rgb *qp = (struct uint8_rgb*)row_in; #else uint8_t *qp = (uint8_t*)row_in; #endif BDEBUGF("output_row: y: %lu in: %p\n",row, row_in); #if LCD_DEPTH == 2 #if LCD_PIXELFORMAT == HORIZONTAL_PACKING /* greyscale iPods */ fb_data *dest = (fb_data *)ctx->bm->data + fb_width * row; int shift = 6; int delta = 127; unsigned bright; unsigned data = 0; for (col = 0; col < ctx->bm->width; col++) { if (ctx->dither) delta = DITHERXDY(col,dy); bright = *qp++; bright = (3 * bright + (bright >> 6) + delta) >> 8; data |= (~bright & 3) << shift; shift -= 2; if (shift < 0) { *dest++ = data; data = 0; shift = 6; } } if (shift < 6) *dest++ = data; #elif LCD_PIXELFORMAT == VERTICAL_PACKING /* iriver H1x0 */ fb_data *dest = (fb_data *)ctx->bm->data + fb_width * (row >> 2); int shift = 2 * (row & 3); int delta = 127; unsigned bright; for (col = 0; col < ctx->bm->width; col++) { if (ctx->dither) delta = DITHERXDY(col,dy); bright = *qp++; bright = (3 * bright + (bright >> 6) + delta) >> 8; *dest++ |= (~bright & 3) << shift; } #elif LCD_PIXELFORMAT == VERTICAL_INTERLEAVED /* iAudio M3 */ fb_data *dest = (fb_data *)ctx->bm->data + fb_width * (row >> 3); int shift = row & 7; int delta = 127; unsigned bright; for (col = 0; col < ctx->bm->width; col++) { if (ctx->dither) delta = DITHERXDY(col,dy); bright = *qp++; bright = (3 * bright + (bright >> 6) + delta) >> 8; *dest++ |= vi_pattern[bright] << shift; } #endif /* LCD_PIXELFORMAT */ #elif LCD_DEPTH == 16 /* iriver h300, colour iPods, X5 */ (void)fb_width; fb_data *dest = STRIDE_MAIN((fb_data *)ctx->bm->data + fb_width * row, (fb_data *)ctx->bm->data + row); int delta = 127; unsigned r, g, b; /* setup alpha channel buffer */ unsigned char *bm_alpha = NULL; if (ctx->bm->alpha_offset > 0) bm_alpha = ctx->bm->data + ctx->bm->alpha_offset; if (bm_alpha) bm_alpha += ALIGN_UP(ctx->bm->width, 2) * row/2; for (col = 0; col < ctx->bm->width; col++) { if (ctx->dither) delta = DITHERXDY(col,dy); r = qp->red; g = qp->green; b = qp->blue; r = (31 * r + (r >> 3) + delta) >> 8; g = (63 * g + (g >> 2) + delta) >> 8; b = (31 * b + (b >> 3) + delta) >> 8; *dest = LCD_RGBPACK_LCD(r, g, b); dest += STRIDE_MAIN(1, ctx->bm->height); if (bm_alpha) { /* pack alpha channel for 2 pixels into 1 byte and negate * according to the interal alpha channel format */ uint8_t alpha = ~qp->alpha; if (col%2) *bm_alpha++ |= alpha&0xf0; else *bm_alpha = alpha>>4; } qp++; } #endif /* LCD_DEPTH */ } #endif /****************************************************************************** * read_bmp_fd() * * Reads a BMP file in an open file descriptor and puts the data in rockbox * format in *bitmap. * *****************************************************************************/ int read_bmp_fd(int fd, struct bitmap *bm, int maxsize, int format, const struct custom_format *cformat) { struct bmp_header bmph; int padded_width; int read_width; int depth, numcolors, compression, totalsize; int ret, hdr_size; bool return_size = format & FORMAT_RETURN_SIZE; bool read_alpha = format & FORMAT_TRANSPARENT; enum color_order order = BGRA; unsigned char *bitmap = bm->data; struct uint8_rgb palette[256]; struct rowset rset; struct dim src_dim; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) || \ defined(PLUGIN) bool dither = false; #endif #ifdef HAVE_REMOTE_LCD bool remote = false; if (format & FORMAT_REMOTE) { remote = true; #if LCD_REMOTE_DEPTH == 1 format = FORMAT_MONO; #endif } #endif /* HAVE_REMOTE_LCD */ #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) unsigned int resize = IMG_NORESIZE; if (format & FORMAT_RESIZE) { resize = IMG_RESIZE; } #else (void)format; #endif /*(LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1)*/ #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) || \ defined(PLUGIN) if (format & FORMAT_DITHER) { dither = true; } #endif /* read fileheader */ ret = read(fd, &bmph, sizeof(struct bmp_header)); if (ret < 0) { return ret * 10 - 2; } if (ret != sizeof(struct bmp_header)) { DEBUGF("read_bmp_fd: can't read BMP header."); return -3; } src_dim.width = letoh32(bmph.width); src_dim.height = letoh32(bmph.height); if (src_dim.height < 0) { /* Top-down BMP file */ src_dim.height = -src_dim.height; rset.rowstep = 1; } else { /* normal BMP */ rset.rowstep = -1; } depth = letoh16(bmph.bit_count); /* 4-byte boundary aligned */ read_width = ((src_dim.width * (depth == 15 ? 16 : depth) + 7) >> 3); padded_width = (read_width + 3) & ~3; BDEBUGF("width: %d height: %d depth: %d padded_width: %d\n", src_dim.width, src_dim.height, depth, padded_width); #if (LCD_DEPTH > 1) || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1) if ((format & 3) == FORMAT_ANY) { if (depth == 1) format = (format & ~3); else format = (format & ~3) | FORMAT_NATIVE; } bm->format = format & 1; if ((format & 1) == FORMAT_MONO) { #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) resize &= ~IMG_RESIZE; resize |= IMG_NORESIZE; #endif #ifdef HAVE_REMOTE_LCD remote = false; #endif } #elif !defined(PLUGIN) if (src_dim.width > BM_MAX_WIDTH) return -6; #endif /*(LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1)*/ #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) if (resize & IMG_RESIZE) { if(format & FORMAT_KEEP_ASPECT) { /* keep aspect ratio.. */ struct dim resize_dim = { .width = bm->width, .height = bm->height, }; if (recalc_dimension(&resize_dim, &src_dim)) resize = IMG_NORESIZE; bm->width = resize_dim.width; bm->height = resize_dim.height; } } if (!(resize & IMG_RESIZE)) { #endif /* returning image size */ bm->width = src_dim.width; bm->height = src_dim.height; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) } #endif #if LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1) format &= 1; #endif if (rset.rowstep > 0) { /* Top-down BMP file */ rset.rowstart = 0; rset.rowstop = bm->height; } else { /* normal BMP */ rset.rowstart = bm->height - 1; rset.rowstop = -1; } /* need even rows (see lcd-16bit-common.c for details) */ int alphasize = ALIGN_UP(bm->width, 2) * bm->height / 2; if (cformat) totalsize = cformat->get_size(bm); else { totalsize = BM_SIZE(bm->width,bm->height,format,remote); #ifdef HAVE_REMOTE_LCD if (!remote) #endif if (depth == 32 && read_alpha) /* account for possible 4bit alpha per pixel */ totalsize += alphasize; } if(return_size) { #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) if(resize) totalsize += BM_SCALED_SIZE(bm->width, 0, 0, 0); else if (bm->width > BM_MAX_WIDTH) totalsize += bm->width*4; #endif return totalsize; } /* Check if this fits the buffer */ if (totalsize > maxsize) { DEBUGF("read_bmp_fd: Bitmap too large for buffer: " "%d bytes.\n", totalsize); return -6; } hdr_size = letoh32(bmph.struct_size); compression = letoh32(bmph.compression); if (depth <= 8) { numcolors = letoh32(bmph.clr_used); if (numcolors == 0) numcolors = BIT_N(depth); /* forward to the color table */ lseek(fd, 14+hdr_size, SEEK_SET); } else { numcolors = 0; if (compression == 3) { if (hdr_size >= 56) numcolors = 4; else /* hdr_size == 52 */ numcolors = 3; } } /* read color tables. for BI_BITFIELDS this actually * reads the color masks */ if (numcolors > 0 && numcolors <= 256) { int i; for (i = 0; i < numcolors; i++) { if (read(fd, &palette[i], sizeof(struct uint8_rgb)) != (int)sizeof(struct uint8_rgb)) { DEBUGF("read_bmp_fd: Can't read color palette\n"); return -7; } } } switch (depth) { case 16: #if LCD_DEPTH >= 16 /* don't dither 16 bit BMP to LCD with same or larger depth */ #ifdef HAVE_REMOTE_LCD if (!remote) #endif dither = false; #endif if (compression == 0) { /* BI_RGB, i.e. 15 bit */ depth = 15; break; } /* else fall through */ case 32: if (compression == 3) { /* BI_BITFIELDS */ bool found = false; int i, j; /* (i == 0) is 15bit, (i == 1) is 16bit, (i == {2,3}) is 32bit */ for (i = 0; i < ARRAY_SIZE(bitfields) && !found; i++) { /* for 15bpp and higher numcolors has the number of color masks */ for (j = 0; j < numcolors; j++) { if (!rgbcmp(&palette[j], &bitfields[i][j])) { found = true; } else { found = false; break; } } } if (found) { if (i == 1) /* 15bit */ depth = 15; else if (i == 4) /* 32bit, ABGR bitmap */ order = ABGR; break; } } /* else fall through */ default: if (compression != 0) { /* not BI_RGB */ DEBUGF("read_bmp_fd: Unsupported compression (type %d)\n", compression); return -8; } break; } /* Search to the beginning of the image data */ lseek(fd, (off_t)letoh32(bmph.off_bits), SEEK_SET); memset(bitmap, 0, totalsize); #ifdef HAVE_LCD_COLOR if (read_alpha && depth == 32) bm->alpha_offset = totalsize - alphasize; else bm->alpha_offset = 0; #endif struct bmp_args ba = { .fd = fd, .padded_width = padded_width, .read_width = read_width, .width = src_dim.width, .depth = depth, .palette = palette, #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) .cur_row = 0, .cur_col = 0, .part = {0,0}, #endif .alpha_detected = false, .first_alpha_byte = 0x80, .order = order, }; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) if (resize) { if (resize_on_load(bm, dither, &src_dim, &rset, bitmap + totalsize, maxsize - totalsize, cformat, IF_PIX_FMT(0,) store_part_bmp, &ba)) return totalsize; else return 0; } #endif /* LCD_DEPTH */ #if LCD_DEPTH > 1 || defined(PLUGIN) struct scaler_context ctx = { .bm = bm, .dither = dither, }; #endif #if defined(PLUGIN) || defined(HAVE_JPEG) || defined(HAVE_BMP_SCALING) #if LCD_DEPTH > 1 void (*output_row_8)(uint32_t, void*, struct scaler_context*) = output_row_8_native; #elif defined(PLUGIN) void (*output_row_8)(uint32_t, void*, struct scaler_context*) = NULL; #endif #if LCD_DEPTH > 1 || defined(PLUGIN) if (cformat) output_row_8 = cformat->output_row_8; #endif #endif unsigned char *buf = ba.buf; #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) || \ defined(PLUGIN) if (bm->width > BM_MAX_WIDTH) { #if defined(HAVE_BMP_SCALING) || defined(PLUGIN) unsigned int len = maxsize - totalsize; buf = bitmap + totalsize; ALIGN_BUFFER(buf, len, sizeof(uint32_t)); if (bm->width*4 > (int)len) #endif return -6; } #endif int row; /* loop to read rows and put them to buffer */ for (row = rset.rowstart; row != rset.rowstop; row += rset.rowstep) { #if (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) && \ defined(HAVE_BMP_SCALING) || defined(PLUGIN) if (bm->width > BM_MAX_WIDTH) { #if defined(HAVE_LCD_COLOR) struct uint8_rgb *p = (struct uint8_rgb *)buf; #else uint8_t* p = buf; #endif do { int len = read_part_line(&ba); if (!len) return -9; memcpy(p, ba.buf, len*sizeof(*p)); p += len; } while (ba.cur_col); } else #endif if (!read_part_line(&ba)) return -9; #ifndef PLUGIN #if !defined(HAVE_LCD_COLOR) && \ (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) uint8_t* qp = buf; #else struct uint8_rgb *qp = (struct uint8_rgb *)buf; #endif #endif /* Convert to destination format */ #if ((LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1)) && \ !defined(PLUGIN) if (format == FORMAT_NATIVE) { #if defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1 if (remote) { unsigned char dy = DITHERY(row); #if (LCD_REMOTE_DEPTH == 2) && (LCD_REMOTE_PIXELFORMAT == VERTICAL_INTERLEAVED) /* iAudio X5/M5 remote */ fb_remote_data *dest = (fb_remote_data *)bitmap + bm->width * (row >> 3); int shift = row & 7; int delta = 127; unsigned bright; int col; for (col = 0; col < bm->width; col++) { if (dither) delta = DITHERXDY(col,dy); #if !defined(HAVE_LCD_COLOR) && \ (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) bright = *qp++; #else bright = brightness(*qp++); #endif bright = (3 * bright + (bright >> 6) + delta) >> 8; *dest++ |= vi_pattern[bright] << shift; } #endif /* LCD_REMOTE_DEPTH / LCD_REMOTE_PIXELFORMAT */ } else #endif /* defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1 */ #endif /* (LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1) */ #if LCD_DEPTH > 1 || defined(PLUGIN) { #if !defined(PLUGIN) && !defined(HAVE_JPEG) && !defined(HAVE_BMP_SCALING) output_row_8_native(row, buf, &ctx); #else output_row_8(row, buf, &ctx); #endif } #endif #if ((LCD_DEPTH > 1) || defined(HAVE_REMOTE_LCD) && (LCD_REMOTE_DEPTH > 1)) && \ !defined(PLUGIN) } #ifndef PLUGIN else #endif #endif #ifndef PLUGIN { unsigned char *p = bitmap + bm->width * (row >> 3); unsigned char mask = BIT_N(row & 7); int col; for (col = 0; col < bm->width; col++, p++) #if !defined(HAVE_LCD_COLOR) && \ (LCD_DEPTH > 1 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_DEPTH > 1)) if (*qp++ < 128) *p |= mask; #else if (brightness(*qp++) < 128) *p |= mask; #endif } #endif } #ifdef HAVE_LCD_COLOR if (!ba.alpha_detected) { /* if this has an alpha channel, totalsize accounts for it as well * subtract if no actual alpha information was found */ if (bm->alpha_offset > 0) totalsize -= alphasize; bm->alpha_offset = 0; } #endif return totalsize; /* return the used buffer size. */ }