/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Grayscale framework * Low level pixel drawing functions * * This is a generic framework to use grayscale display within Rockbox * plugins. It obviously does not work for the player. * * Copyright (C) 2004 Jens Arnold * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #ifndef SIMULATOR /* not for simulator by now */ #include "plugin.h" #if CONFIG_LCD == LCD_SSD1815 /* only for Recorder/Ondio */ #include "gray.h" /* Prototypes */ static void _writepixel(int x, int y, unsigned long pattern); static void _invertpixel(int x, int y, unsigned long pattern); /* function pointer array */ void (* const _gray_pixelfuncs[4])(int x, int y, unsigned long pattern) = { _invertpixel, _writepixel, _writepixel, _writepixel }; /* Set a pixel to a specific bit pattern (low level routine) */ static void _writepixel(int x, int y, unsigned long pattern) { register unsigned mask, random; register unsigned char *address; /* Some (pseudo-)random function must be used here to shift the bit * pattern randomly, otherwise you would get flicker and/or moire. * Since rand() is relatively slow, I've implemented a simple, but very * fast pseudo-random generator based on linear congruency in assembler. * It delivers max. 16 pseudo-random bits in each iteration. */ /* simple but fast pseudo-random generator */ asm ( "mov #75,r1 \n" "mulu %1,r1 \n" /* multiply by 75 */ "sts macl,%1 \n" /* get result */ "add #74,%1 \n" /* add another 74 */ /* Since the lower bits are not very random: */ "swap.b %1,%0 \n" /* get bits 8..15 (need max. 5) */ "and %2,%0 \n" /* mask out unneeded bits */ : /* outputs */ /* %0 */ "=&r"(random), /* %1, in & out */ "+r"(_gray_random_buffer) : /* inputs */ /* %2 */ "r"(_graybuf->randmask) : /* clobbers */ "r1", "macl" ); /* precalculate mask and byte address in first bitplane */ asm ( "mov %3,%0 \n" /* take y as base for address offset */ "shlr2 %0 \n" /* shift right by 3 (= divide by 8) */ "shlr %0 \n" "mulu %0,%2 \n" /* multiply with width */ "and #7,%3 \n" /* get lower 3 bits of y */ "sts macl,%0 \n" /* get mulu result */ "add %4,%0 \n" /* add base + x to get final address */ "mov %3,%1 \n" /* move lower 3 bits of y out of r0 */ "mova .wp_masktable,%3\n" /* get address of mask table in r0 */ "bra .wp_predone \n" /* skip the table */ "mov.b @(%3,%1),%1 \n" /* get entry from mask table */ ".align 2 \n" ".wp_masktable: \n" /* mask table */ ".byte 0x01 \n" ".byte 0x02 \n" ".byte 0x04 \n" ".byte 0x08 \n" ".byte 0x10 \n" ".byte 0x20 \n" ".byte 0x40 \n" ".byte 0x80 \n" ".wp_predone: \n" : /* outputs */ /* %0 */ "=&r"(address), /* %1 */ "=&r"(mask) : /* inputs */ /* %2 */ "r"(_graybuf->width), /* %3 = r0 */ "z"(y), /* %4 */ "r"(_graybuf->data + x) : /* clobbers */ "macl" ); /* the hard part: set bits in all bitplanes according to pattern */ asm volatile ( "cmp/hs %1,%5 \n" /* random >= depth ? */ "bf .wp_ntrim \n" "sub %1,%5 \n" /* yes: random -= depth */ /* it's sufficient to do this once, since the mask guarantees * random < 2 * depth */ ".wp_ntrim: \n" /* calculate some addresses */ "mulu %4,%1 \n" /* end address offset */ "not %3,r1 \n" /* get inverse mask (for "and") */ "sts macl,%1 \n" /* result of mulu */ "mulu %4,%5 \n" /* address offset of 'th plane */ "add %2,%1 \n" /* end offset -> end address */ "sts macl,%5 \n" /* result of mulu */ "add %2,%5 \n" /* address of 'th plane */ "bra .wp_start1 \n" "mov %5,r2 \n" /* copy address */ /* first loop: set bits from 'th bitplane to last */ ".wp_loop1: \n" "mov.b @r2,r3 \n" /* get data byte */ "shlr %0 \n" /* shift bit mask, sets t bit */ "and r1,r3 \n" /* reset bit (-> "white") */ "bf .wp_white1 \n" /* t=0? -> "white" bit */ "or %3,r3 \n" /* set bit ("black" bit) */ ".wp_white1: \n" "mov.b r3,@r2 \n" /* store data byte */ "add %4,r2 \n" /* advance address to next bitplane */ ".wp_start1: \n" "cmp/hi r2,%1 \n" /* address < end address ? */ "bt .wp_loop1 \n" "bra .wp_start2 \n" "nop \n" /* second loop: set bits from first to 'th bitplane * Bit setting works the other way round here to equalize average * execution times for bright and dark pixels */ ".wp_loop2: \n" "mov.b @%2,r3 \n" /* get data byte */ "shlr %0 \n" /* shift bit mask, sets t bit */ "or %3,r3 \n" /* set bit (-> "black") */ "bt .wp_black2 \n" /* t=1? -> "black" bit */ "and r1,r3 \n" /* reset bit ("white" bit) */ ".wp_black2: \n" "mov.b r3,@%2 \n" /* store data byte */ "add %4,%2 \n" /* advance address to next bitplane */ ".wp_start2: \n" "cmp/hi %2,%5 \n" /* address < 'th address ? */ "bt .wp_loop2 \n" : /* outputs */ : /* inputs */ /* %0 */ "r"(pattern), /* %1 */ "r"(_graybuf->depth), /* %2 */ "r"(address), /* %3 */ "r"(mask), /* %4 */ "r"(_graybuf->plane_size), /* %5 */ "r"(random) : /* clobbers */ "r1", "r2", "r3", "macl" ); } /* invert all bits for one pixel (low level routine) */ static void _invertpixel(int x, int y, unsigned long pattern) { register unsigned mask; register unsigned char *address; (void) pattern; /* not used for invert */ /* precalculate mask and byte address in first bitplane */ asm ( "mov %3,%0 \n" /* take y as base for address offset */ "shlr2 %0 \n" /* shift right by 3 (= divide by 8) */ "shlr %0 \n" "mulu %0,%2 \n" /* multiply with width */ "and #7,%3 \n" /* get lower 3 bits of y */ "sts macl,%0 \n" /* get mulu result */ "add %4,%0 \n" /* add base + x to get final address */ "mov %3,%1 \n" /* move lower 3 bits of y out of r0 */ "mova .ip_masktable,%3\n" /* get address of mask table in r0 */ "bra .ip_predone \n" /* skip the table */ "mov.b @(%3,%1),%1 \n" /* get entry from mask table */ ".align 2 \n" ".ip_masktable: \n" /* mask table */ ".byte 0x01 \n" ".byte 0x02 \n" ".byte 0x04 \n" ".byte 0x08 \n" ".byte 0x10 \n" ".byte 0x20 \n" ".byte 0x40 \n" ".byte 0x80 \n" ".ip_predone: \n" : /* outputs */ /* %0 */ "=&r"(address), /* %1 */ "=&r"(mask) : /* inputs */ /* %2 */ "r"(_graybuf->width), /* %3 = r0 */ "z"(y), /* %4 */ "r"(_graybuf->data + x) : /* clobbers */ "macl" ); /* invert bits in all bitplanes */ asm volatile ( "mov #0,r1 \n" /* current_plane = 0 */ ".ip_loop: \n" "mov.b @%1,r2 \n" /* get data byte */ "add #1,r1 \n" /* current_plane++; */ "xor %2,r2 \n" /* invert bits */ "mov.b r2,@%1 \n" /* store data byte */ "add %3,%1 \n" /* advance address to next bitplane */ "cmp/hi r1,%0 \n" /* current_plane < depth ? */ "bt .ip_loop \n" : /* outputs */ : /* inputs */ /* %0 */ "r"(_graybuf->depth), /* %1 */ "r"(address), /* %2 */ "r"(mask), /* %3 */ "r"(_graybuf->plane_size) : /* clobbers */ "r1", "r2" ); } #endif // #ifdef HAVE_LCD_BITMAP #endif // #ifndef SIMULATOR