diff options
author | Will Newton <will.newton@gmail.com> | 2009-07-27 12:20:27 +0100 |
---|---|---|
committer | Peter Korsgaard <jacmet@sunsite.dk> | 2009-07-27 17:17:04 +0200 |
commit | 6fecd53e99591775a4117e9e1ba18043fda36b27 (patch) | |
tree | f52a4490494a8c968522c3d2efd575589095775c /package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch | |
parent | 33a3e7ba2e3fe9ba0b5d198c0488d006f28eb273 (diff) | |
download | buildroot-novena-6fecd53e99591775a4117e9e1ba18043fda36b27.tar.gz buildroot-novena-6fecd53e99591775a4117e9e1ba18043fda36b27.zip |
mplayer: Update mplayer to version 1.0rc2.
Closes #331.
- Remove patches applied upstream
- Add updated avr32 patch from Hans-Christian Egtvedt.
Signed-off-by: Kelvin Cheung <keguang.zhang@gmail.com>
Signed-off-by: Will Newton <will.newton@gmail.com>
Signed-off-by: Peter Korsgaard <jacmet@sunsite.dk>
Diffstat (limited to 'package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch')
-rwxr-xr-x | package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch | 6262 |
1 files changed, 6262 insertions, 0 deletions
diff --git a/package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch b/package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch new file mode 100755 index 000000000..0de695f81 --- /dev/null +++ b/package/multimedia/mplayer/mplayer-1.0rc2-100-atmel.1.patch @@ -0,0 +1,6262 @@ +--- a/cfg-common.h ++++ b/cfg-common.h +@@ -240,6 +240,10 @@ + {"psprobe", &ps_probe, CONF_TYPE_POSITION, 0, 0, TS_MAX_PROBE_SIZE, NULL}, + {"tskeepbroken", &ts_keep_broken, CONF_TYPE_FLAG, 0, 0, 1, NULL}, + ++#ifdef ARCH_AVR32 ++ {"use-pico", &avr32_use_pico, CONF_TYPE_FLAG, 0, 0, 1, NULL}, ++ {"nouse-pico", &avr32_use_pico, CONF_TYPE_FLAG, 0, 1, 0, NULL}, ++#endif + // draw by slices or whole frame (useful with libmpeg2/libavcodec) + {"slices", &vd_use_slices, CONF_TYPE_FLAG, 0, 0, 1, NULL}, + {"noslices", &vd_use_slices, CONF_TYPE_FLAG, 0, 1, 0, NULL}, +--- a/cfg-mencoder.h ++++ b/cfg-mencoder.h +@@ -5,6 +5,10 @@ + + #include "cfg-common.h" + ++#ifdef ARCH_AVR32 ++extern int avr32_use_pico; ++#endif ++ + #ifdef USE_FAKE_MONO + extern int fakemono; // defined in dec_audio.c + #endif +--- a/cfg-mplayer.h ++++ b/cfg-mplayer.h +@@ -7,6 +7,10 @@ + extern int key_fifo_size; + extern unsigned doubleclick_time; + ++#ifdef ARCH_AVR32 ++extern int avr32_use_pico; ++#endif ++ + #ifdef HAVE_FBDEV + extern char *fb_mode_cfgfile; + extern char *fb_mode_name; +--- a/configure ++++ b/configure +@@ -1631,7 +1631,7 @@ EOF + fi + + +-_arch_all='X86 X86_32 X86_64 IA64 SPARC ARM ARMV4L SH3 POWERPC PPC ALPHA SGI_MIPS PA_RISC S390 S390X VAX BFIN GENERIC' ++_arch_all='X86 X86_32 X86_64 IA64 SPARC ARM ARMV4L AVR32 SH3 POWERPC PPC ALPHA SGI_MIPS PA_RISC S390 S390X VAX BFIN GENERIC' + case "$host_arch" in + i[3-9]86|x86|x86pc|k5|k6|k6-2|k6-3|pentium*|athlon*|i586-i686) + _arch='X86 X86_32' +@@ -1994,6 +1994,16 @@ EOF + _optimizing="$proc" + ;; + ++ avr32) ++ _arch='AVR32' ++ _target_arch='ARCH_AVR32 = yes' ++ iproc='avr32' ++ proc='' ++ _march='' ++ _mcpu='' ++ _optimizing='' ++ ;; ++ + arm|armv4l|armv5tel) + _arch='ARM ARMV4L' + _target_arch='ARCH_ARMV4L = yes' +--- a/libavcodec/Makefile ++++ b/libavcodec/Makefile +@@ -372,6 +372,11 @@ ASM_OBJS-$(ARCH_ARMV4L) + + OBJS-$(ARCH_ARMV4L) += armv4l/dsputil_arm.o \ + armv4l/mpegvideo_arm.o \ + ++ASM_OBJS-$(ARCH_AVR32) += avr32/idct.o avr32/fdct.o \ ++ avr32/mc.o avr32/h264idct.o ++ ++OBJS-$(ARCH_AVR32) += avr32/dsputil_avr32.o ++ + OBJS-$(HAVE_IWMMXT) += armv4l/dsputil_iwmmxt.o \ + armv4l/mpegvideo_iwmmxt.o \ + +@@ -445,6 +450,7 @@ clean:: + rm -f \ + alpha/*.o alpha/*~ \ + armv4l/*.o armv4l/*~ \ ++ avr32/*.o avr32/*~ \ + bfin/*.o bfin/*~ \ + i386/*.o i386/*~ \ + mlib/*.o mlib/*~ \ +--- /dev/null ++++ b/libavcodec/avr32/dsputil_avr32.c +@@ -0,0 +1,2638 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++ ++#include "../dsputil.h" ++#include "pico.h" ++ ++int avr32_use_pico = 1; ++ ++#ifdef CHECK_DSP_FUNCS_AGAINST_C ++#define DSP_FUNC_NAME(name) test_ ## name ++#else ++#define DSP_FUNC_NAME(name) name ++#endif ++ ++union doubleword { ++ int64_t doubleword; ++ struct { ++ int32_t top; ++ int32_t bottom; ++ } words; ++}; ++ ++#undef LD16 ++#undef LD32 ++#undef LD64 ++ ++#define LD16(a) (*((uint16_t*)(a))) ++#define LD32(a) (*((uint32_t*)(a))) ++#define LD64(a) (*((uint64_t*)(a))) ++#define LD64_UNALIGNED(a) \ ++ ({ union doubleword __tmp__; \ ++ __tmp__.words.top = LD32(a); \ ++ __tmp__.words.bottom = LD32(a + 4); \ ++ __tmp__.doubleword; }) ++ ++#undef ST32 ++#undef ST16 ++ ++#define ST16(a, b) *((uint16_t*)(a)) = (b) ++#define ST32(a, b) *((uint32_t*)(a)) = (b) ++ ++#undef rnd_avg32 ++#define rnd_avg32(a, b) \ ++ ({ uint32_t __tmp__;\ ++ asm("pavg.ub\t%0, %1, %2" : "=r"(__tmp__) : "r"(a), "r"(b));\ ++ __tmp__;}) ++ ++void idct_avr32(DCTELEM *data); ++void fdct_avr32(DCTELEM *data); ++ ++void idct_put_avr32(uint8_t *dest, int line_size, DCTELEM *data); ++void idct_add_avr32(uint8_t *dest, int line_size, DCTELEM *data); ++ ++void h264_idct_add_avr32(uint8_t *dest, DCTELEM *data, int stride); ++void h264_idct8_add_avr32(uint8_t *dest, DCTELEM *data, int stride); ++ ++#define extern_dspfunc(PFX, NUM) \ ++ void PFX ## _pixels ## NUM ## _avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _h_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _v_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _hv_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ) ++ ++extern_dspfunc(put, 8); ++extern_dspfunc(put_no_rnd, 8); ++extern_dspfunc(avg, 8); ++extern_dspfunc(avg_no_rnd, 8); ++#undef extern_dspfunc ++ ++#ifdef CHECK_DSP_FUNCS_AGAINST_C ++#define extern_dspfunc(PFX, NUM) \ ++ void PFX ## _pixels ## NUM ## _c(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _x2_c(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _y2_c(uint8_t *dst, const uint8_t *pixels, int line_size, int h ); \ ++ void PFX ## _pixels ## NUM ## _xy2_c(uint8_t *dst, const uint8_t *pixels, int line_size, int h ) ++ ++extern_dspfunc(put, 4); ++extern_dspfunc(put_no_rnd, 4); ++extern_dspfunc(put, 8); ++extern_dspfunc(put_no_rnd, 8); ++extern_dspfunc(put, 16); ++extern_dspfunc(put_no_rnd, 16); ++extern_dspfunc(avg, 8); ++extern_dspfunc(avg_no_rnd, 8); ++extern_dspfunc(avg, 16); ++extern_dspfunc(avg_no_rnd, 16); ++ ++ ++#undef extern_dspfunc ++#define extern_dspfunc(PFX, NUM) \ ++void PFX ## NUM ## _mc00_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc10_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc20_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc30_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc01_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc11_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc21_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc31_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc02_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc12_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc22_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc32_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc03_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc13_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc23_c(uint8_t *dst, uint8_t *src, int stride); \ ++void PFX ## NUM ## _mc33_c(uint8_t *dst, uint8_t *src, int stride); \ ++ ++extern_dspfunc(put_h264_qpel, 16); ++extern_dspfunc(put_h264_qpel, 8); ++extern_dspfunc(put_h264_qpel, 4); ++extern_dspfunc(avg_h264_qpel, 16); ++extern_dspfunc(avg_h264_qpel, 8); ++extern_dspfunc(avg_h264_qpel, 4); ++ ++#undef extern_dspfunc ++ ++void put_h264_chroma_mc2_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++void put_h264_chroma_mc4_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++void put_h264_chroma_mc8_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++ ++void avg_h264_chroma_mc2_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++void avg_h264_chroma_mc4_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++void avg_h264_chroma_mc8_c(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y); ++ ++ ++void dump_block8(uint8_t *block, int line_size, int h); ++void dump_block4(uint8_t *block, int line_size, int h); ++void dump_block(uint8_t *block, int line_size, int h, int w); ++ ++void check_block8(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, char *name, int max_dev); ++void check_block4(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, char *name, int max_dev); ++void check_block(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, int width, char *name, int max_dev); ++ ++#define PIXOP2( OPNAME, OP ) \ ++void OPNAME ## _pixels4_c(uint8_t *block, const uint8_t *pixels, int line_size, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ OP(*((uint32_t*)(block )), LD32(pixels ));\ ++ pixels+=line_size;\ ++ block +=line_size;\ ++ }\ ++}\ ++void OPNAME ## _pixels8_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ uint32_t a,b;\ ++ a= LD32(&src1[i*src_stride1 ]);\ ++ b= LD32(&src2[i*src_stride2 ]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride ]), rnd_avg32(a, b));\ ++ a= LD32(&src1[i*src_stride1+4]);\ ++ b= LD32(&src2[i*src_stride2+4]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride+4]), rnd_avg32(a, b));\ ++ }\ ++}\ ++\ ++void OPNAME ## _pixels4_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ uint32_t a,b;\ ++ a= LD32(&src1[i*src_stride1 ]);\ ++ b= LD32(&src2[i*src_stride2 ]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride ]), rnd_avg32(a, b));\ ++ }\ ++}\ ++\ ++void OPNAME ## _pixels16_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ OPNAME ## _pixels8_l2(dst , src1 , src2 , dst_stride, src_stride1, src_stride2, h);\ ++ OPNAME ## _pixels8_l2(dst+8, src1+8, src2+8, dst_stride, src_stride1, src_stride2, h);\ ++}\ ++ ++#else ++#define PIXOP2( OPNAME, OP ) \ ++static void OPNAME ## _pixels4_c(uint8_t *block, const uint8_t *pixels, int line_size, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ OP(*((uint32_t*)(block )), LD32(pixels ));\ ++ pixels+=line_size;\ ++ block +=line_size;\ ++ }\ ++}\ ++static void OPNAME ## _pixels8_c(uint8_t *block, const uint8_t *pixels, int line_size, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ OP(*((uint32_t*)(block )), LD32(pixels ));\ ++ OP(*((uint32_t*)(block+4)), LD32(pixels+4));\ ++ pixels+=line_size;\ ++ block +=line_size;\ ++ }\ ++}\ ++static void OPNAME ## _pixels16_c(uint8_t *block, const uint8_t *pixels, int line_size, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ OP(*((uint32_t*)(block )), LD32(pixels ));\ ++ OP(*((uint32_t*)(block+4)), LD32(pixels+4));\ ++ OP(*((uint32_t*)(block+8)), LD32(pixels+8));\ ++ OP(*((uint32_t*)(block+12)), LD32(pixels+12));\ ++ pixels+=line_size;\ ++ block +=line_size;\ ++ }\ ++}\ ++static void OPNAME ## _pixels8_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ uint32_t a,b;\ ++ a= LD32(&src1[i*src_stride1 ]);\ ++ b= LD32(&src2[i*src_stride2 ]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride ]), rnd_avg32(a, b));\ ++ a= LD32(&src1[i*src_stride1+4]);\ ++ b= LD32(&src2[i*src_stride2+4]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride+4]), rnd_avg32(a, b));\ ++ }\ ++}\ ++\ ++static void OPNAME ## _pixels4_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ int i;\ ++ for(i=0; i<h; i++){\ ++ uint32_t a,b;\ ++ a= LD32(&src1[i*src_stride1 ]);\ ++ b= LD32(&src2[i*src_stride2 ]);\ ++ OP(*((uint32_t*)&dst[i*dst_stride ]), rnd_avg32(a, b));\ ++ }\ ++}\ ++\ ++static void OPNAME ## _pixels16_l2(uint8_t *dst, const uint8_t *src1, const uint8_t *src2, int dst_stride, \ ++ int src_stride1, int src_stride2, int h){\ ++ OPNAME ## _pixels8_l2(dst , src1 , src2 , dst_stride, src_stride1, src_stride2, h);\ ++ OPNAME ## _pixels8_l2(dst+8, src1+8, src2+8, dst_stride, src_stride1, src_stride2, h);\ ++}\ ++ ++#endif ++ ++#define op_avg(a, b) a = rnd_avg32(a, b) ++#define op_put(a, b) a = b ++ ++PIXOP2(avg, op_avg) ++PIXOP2(put, op_put) ++#undef op_avg ++#undef op_put ++ ++ ++ ++static void clear_blocks_avr32(DCTELEM *blocks) ++{ ++ int n = 12; ++ uint64_t tmp1, tmp2; ++ blocks += 6*64; ++ asm volatile ( "mov\t%1, 0\n" ++ "mov\t%m1, 0\n" ++ "mov\t%2, 0\n" ++ "mov\t%m2, 0\n" ++ "0:\n" ++ "stm\t--%3, %1, %m1, %2, %m2\n" ++ "stm\t--%3, %1, %m1, %2, %m2\n" ++ "stm\t--%3, %1, %m1, %2, %m2\n" ++ "stm\t--%3, %1, %m1, %2, %m2\n" ++ "sub\t%0, 1\n" ++ "brne\t0b\n" ++ : "+r"(n), "=&r"(tmp1), "=&r"(tmp2), ++ "+r"(blocks)); ++} ++ ++ ++static void put_h264_chroma_mc2_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y); ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ ++ int src0 = LD32(src); ++ int src1 = LD32(src + stride); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 0, 4, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 1, 5, 0); ++ src += stride; ++ ST16(dst,(short)PICO_GET_W(PICO_OUTPIX0)); ++ dst += stride; ++ } ++} ++ ++ ++static void put_h264_chroma_mc4_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y);\ ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ /* ++ OP(dst[0], (A*src[0] + B*src[1] + C*src[stride+0] + D*src[stride+1])); ++ OP(dst[1], (A*src[1] + B*src[2] + C*src[stride+1] + D*src[stride+2])); ++ OP(dst[2], (A*src[2] + B*src[3] + C*src[stride+2] + D*src[stride+3])); ++ OP(dst[3], (A*src[3] + B*src[4] + C*src[stride+3] + D*src[stride+4])); ++ dst+= stride; ++ src+= stride; ++ */ ++ ++ int src0 = LD32(src); ++ int src1 = (((int)src[4] << 24) | (int)src[stride]); ++ int src2 = LD32(src + stride + 1); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ src += stride; ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ ++ dst += stride; ++ } ++} ++ ++static void put_h264_chroma_mc8_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y); ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ /* ++ OP(dst[0], (A*src[0] + B*src[1] + C*src[stride+0] + D*src[stride+1])); ++ OP(dst[1], (A*src[1] + B*src[2] + C*src[stride+1] + D*src[stride+2])); ++ OP(dst[2], (A*src[2] + B*src[3] + C*src[stride+2] + D*src[stride+3])); ++ OP(dst[3], (A*src[3] + B*src[4] + C*src[stride+3] + D*src[stride+4])); ++ OP(dst[4], (A*src[4] + B*src[5] + C*src[stride+4] + D*src[stride+5])); ++ OP(dst[5], (A*src[5] + B*src[6] + C*src[stride+5] + D*src[stride+6])); ++ OP(dst[6], (A*src[6] + B*src[7] + C*src[stride+6] + D*src[stride+7])); ++ OP(dst[7], (A*src[7] + B*src[8] + C*src[stride+7] + D*src[stride+8])); ++ dst+= stride; ++ src+= stride; ++ */ ++ int src0 = LD32(src); ++ int src1 = (((int)src[4] << 24) | (int)src[stride]); ++ int src2 = LD32(src + stride + 1); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ ++ src0 = LD32(src + 4); ++ src1 = (src[8] << 24) | src[stride + 4]; ++ src2 = LD32(src + stride + 5); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ src += stride; ++ ST32(dst + 4, PICO_GET_W(PICO_OUTPIX0)); ++ ++ dst += stride; ++ } ++} ++ ++ ++static void avg_h264_chroma_mc2_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y); ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ int src0 = LD32(src); ++ int src1 = LD32(src + stride); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 0, 4, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 1, 5, 0); ++ src += stride; ++ ST16(dst, rnd_avg32(LD16(dst), PICO_GET_W(PICO_OUTPIX0))); ++ dst += stride; ++ } ++} ++ ++ ++static void avg_h264_chroma_mc4_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y);\ ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ /* ++ OP(dst[0], (A*src[0] + B*src[1] + C*src[stride+0] + D*src[stride+1])); ++ OP(dst[1], (A*src[1] + B*src[2] + C*src[stride+1] + D*src[stride+2])); ++ OP(dst[2], (A*src[2] + B*src[3] + C*src[stride+2] + D*src[stride+3])); ++ OP(dst[3], (A*src[3] + B*src[4] + C*src[stride+3] + D*src[stride+4])); ++ dst+= stride; ++ src+= stride; ++ */ ++ ++ int src0 = *((int *)src); ++ int src1 = (int)((src[4] << 24) | src[stride]); ++ int src2 = *((int *)(src + stride + 1)); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ src += stride; ++ ST32(dst, rnd_avg32(LD32(dst), PICO_GET_W(PICO_OUTPIX0))); ++ dst += stride; ++ } ++} ++ ++static void avg_h264_chroma_mc8_pico(uint8_t *dst/*align 8*/, uint8_t *src/*align 1*/, int stride, int h, int x, int y){ ++ const int A=(8-x)*(8-y); ++ const int B=( x)*(8-y); ++ const int C=(8-x)*( y); ++ const int D=( x)*( y); ++ int i; ++ ++ PICO_PUT_W(PICO_COEFF0_A, (A << 16) | (B & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF0_B, 32); ++ PICO_PUT_W(PICO_COEFF1_A, (C << 16) | (D & 0xFFFF)); ++ PICO_PUT_W(PICO_COEFF1_B, 0); ++ PICO_PUT_W(PICO_COEFF2_A, 0); ++ PICO_PUT_W(PICO_COEFF2_B, 0); ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_HOR_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(6) ++ | PICO_OFFSET_FRAC_BITS(6)); ++ ++ for(i=0; i<h; i++) ++ { ++ /* ++ OP(dst[0], (A*src[0] + B*src[1] + C*src[stride+0] + D*src[stride+1])); ++ OP(dst[1], (A*src[1] + B*src[2] + C*src[stride+1] + D*src[stride+2])); ++ OP(dst[2], (A*src[2] + B*src[3] + C*src[stride+2] + D*src[stride+3])); ++ OP(dst[3], (A*src[3] + B*src[4] + C*src[stride+3] + D*src[stride+4])); ++ OP(dst[4], (A*src[4] + B*src[5] + C*src[stride+4] + D*src[stride+5])); ++ OP(dst[5], (A*src[5] + B*src[6] + C*src[stride+5] + D*src[stride+6])); ++ OP(dst[6], (A*src[6] + B*src[7] + C*src[stride+6] + D*src[stride+7])); ++ OP(dst[7], (A*src[7] + B*src[8] + C*src[stride+7] + D*src[stride+8])); ++ dst+= stride; ++ src+= stride; ++ */ ++ int src0 = *((int *)src); ++ int src1 = (volatile int)((src[4] << 24) | src[stride]); ++ int src2 = *((int *)(src + stride + 1)); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ ST32(dst, rnd_avg32(LD32(dst), PICO_GET_W(PICO_OUTPIX0))); ++ ++ src0 = *((int *)(src + 4)); ++ src1 = (int)((src[8] << 24) | src[stride + 4]); ++ src2 = *((int *)(src + stride + 5)); ++ ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 7, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 8, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 9, 0); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 10, 0); ++ src += stride; ++ ST32(dst + 4, rnd_avg32(LD32(dst + 4), PICO_GET_W(PICO_OUTPIX0))); ++ dst += stride; ++ } ++} ++ ++static struct pico_config_t h264_qpel4_h_lowpass_config = { ++ .input_mode = PICO_HOR_FILTER_MODE, ++ .output_mode = PICO_PLANAR_MODE, ++ .coeff_frac_bits = 5, ++ .offset_frac_bits = 5, ++ .coeff0_0 = 1, ++ .coeff0_1 = -5, ++ .coeff0_2 = 20, ++ .coeff0_3 = 16, ++ .coeff1_0 = 20, ++ .coeff1_1 = -5, ++ .coeff1_2 = 1, ++ .coeff1_3 = 0, ++ .coeff2_0 = 0, ++ .coeff2_1 = 0, ++ .coeff2_2 = 0, ++ .coeff2_3 = 0 ++}; ++ ++ ++ ++static void put_h264_qpel4_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ const int h=4; ++ int i; ++ ++ set_pico_config(&h264_qpel4_h_lowpass_config); ++ ++ for(i=0; i<h; i++){ ++ ++ /* ++ OP(dst[0], (src[0]+src[1])*20 - (src[-1]+src[2])*5 + (src[-2]+src[3]));\ ++ OP(dst[1], (src[1]+src[2])*20 - (src[0 ]+src[3])*5 + (src[-1]+src[4]));\ ++ OP(dst[2], (src[2]+src[3])*20 - (src[1 ]+src[4])*5 + (src[0 ]+src[5]));\ ++ OP(dst[3], (src[3]+src[4])*20 - (src[2 ]+src[5])*5 + (src[1 ]+src[6]));\ ++ dst+=dstStride;\ ++ src+=srcStride;\ */ ++ PICO_MVRC_W(PICO_INPIX0, LD32(src - 2)); ++ PICO_MVRC_D(PICO_INPIX2, LD64_UNALIGNED(src + 2)); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 3, 6); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 4, 7); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 5, 8); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 6, 9); ++ src += srcStride; ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ dst += dstStride; ++ } ++} ++ ++static void avg_h264_qpel4_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ const int h=4; ++ int i; ++ ++ set_pico_config(&h264_qpel4_h_lowpass_config); ++ ++ for(i=0; i<h; i++){ ++ ++ /* ++ OP(dst[0], (src[0]+src[1])*20 - (src[-1]+src[2])*5 + (src[-2]+src[3]));\ ++ OP(dst[1], (src[1]+src[2])*20 - (src[0 ]+src[3])*5 + (src[-1]+src[4]));\ ++ OP(dst[2], (src[2]+src[3])*20 - (src[1 ]+src[4])*5 + (src[0 ]+src[5]));\ ++ OP(dst[3], (src[3]+src[4])*20 - (src[2 ]+src[5])*5 + (src[1 ]+src[6]));\ ++ dst+=dstStride;\ ++ src+=srcStride;\ */ ++ ++ PICO_MVRC_W(PICO_INPIX0, LD32(src - 2)); ++ PICO_MVRC_D(PICO_INPIX2, LD64_UNALIGNED(src + 2)); ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 3, 6); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 4, 7); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 5, 8); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 6, 9); ++ src += srcStride; ++ ST32(dst, rnd_avg32(LD32(dst), PICO_GET_W(PICO_OUTPIX0))); ++ dst += dstStride; ++ } ++} ++ ++static struct pico_config_t h264_qpel4_v_lowpass_config1 = { ++ .input_mode = PICO_VERT_FILTER_MODE, ++ .output_mode = PICO_PACKED_MODE, ++ .coeff_frac_bits = 5, ++ .offset_frac_bits = 5, ++ .coeff0_0 = 1, ++ .coeff0_1 = -5, ++ .coeff0_2 = 20, ++ .coeff0_3 = 16, ++ .coeff1_0 = 1, ++ .coeff1_1 = -5, ++ .coeff1_2 = 20, ++ .coeff1_3 = 16, ++ .coeff2_0 = 1, ++ .coeff2_1 = -5, ++ .coeff2_2 = 20, ++ .coeff2_3 = 16 ++}; ++ ++ ++ ++static struct pico_config_t h264_qpel4_v_lowpass_config2 = { ++ .input_mode = PICO_VERT_FILTER_MODE, ++ .output_mode = PICO_PLANAR_MODE, ++ .coeff_frac_bits = 5, ++ .offset_frac_bits = 5, ++ .coeff0_0 = 1, ++ .coeff0_1 = -5, ++ .coeff0_2 = 20, ++ .coeff0_3 = 16, ++ .coeff1_0 = 20, ++ .coeff1_1 = -5, ++ .coeff1_2 = 1, ++ .coeff1_3 = 0, ++ .coeff2_0 = 0, ++ .coeff2_1 = 0, ++ .coeff2_2 = 0, ++ .coeff2_3 = 0 ++}; ++ ++static void put_h264_qpel4_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ ++ /* ++ const int w=4; ++ uint8_t *cm = cropTbl + MAX_NEG_CROP; ++ int i; ++ for(i=0; i<w; i++) ++ { ++ const int srcB= src[-2*srcStride];\ ++ const int srcA= src[-1*srcStride];\ ++ const int src0= src[0 *srcStride];\ ++ const int src1= src[1 *srcStride];\ ++ const int src2= src[2 *srcStride];\ ++ const int src3= src[3 *srcStride];\ ++ const int src4= src[4 *srcStride];\ ++ const int src5= src[5 *srcStride];\ ++ const int src6= src[6 *srcStride];\ ++ OP(dst[0*dstStride], (src0+src1)*20 - (srcA+src2)*5 + (srcB+src3));\ ++ OP(dst[1*dstStride], (src1+src2)*20 - (src0+src3)*5 + (srcA+src4));\ ++ OP(dst[2*dstStride], (src2+src3)*20 - (src1+src4)*5 + (src0+src5));\ ++ OP(dst[3*dstStride], (src3+src4)*20 - (src2+src5)*5 + (src1+src6));\ ++ dst++;\ ++ src++;\ ++ */ ++ ++ set_pico_config(&h264_qpel4_v_lowpass_config1); ++ ++ { ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ union wordbytes { ++ int word; ++ struct { ++ unsigned int t:8; ++ unsigned int u:8; ++ unsigned int l:8; ++ unsigned int b:8; ++ } bytes; ++ } tmp1, tmp2, tmp3; ++ ++ /* First compute the leftmost three colums */ ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ dst += dstStride; ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ dst += dstStride; ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ dst += dstStride; ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(dst, PICO_GET_W(PICO_OUTPIX0)); ++ /* Now compute the last column */ ++ ++ tmp1.bytes.t = srcB; ++ tmp1.bytes.u = src1; ++ tmp1.bytes.l = src4; ++ ++ tmp2.bytes.t = srcA; ++ tmp2.bytes.u = src2; ++ tmp2.bytes.l = src5; ++ ++ tmp3.bytes.t = src0; ++ tmp3.bytes.u = src3; ++ tmp3.bytes.l = src6; ++ ++ PICO_MVRC_W(PICO_INPIX0, tmp1.word); ++ PICO_MVRC_W(PICO_INPIX1, tmp2.word); ++ PICO_MVRC_W(PICO_INPIX2, tmp3.word); ++ set_pico_config(&h264_qpel4_v_lowpass_config2); ++ ++ ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 3, 6); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 4, 7); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 5, 8); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 6, 9); ++ ++ PICO_MVCR_W(tmp1.word, PICO_OUTPIX0); ++ dst[3] = (char)(tmp1.bytes.b); ++ dst[3 - dstStride] = (char)(tmp1.bytes.l); ++ dst[3 - 2*dstStride] = (char)(tmp1.bytes.u); ++ dst[3 - 3*dstStride] = (char)(tmp1.bytes.t); ++ ++ } ++ /*} ++ ++ ++ }*/ ++} ++ ++static void avg_h264_qpel4_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ ++ /* ++ const int w=4; ++ uint8_t *cm = cropTbl + MAX_NEG_CROP; ++ int i; ++ for(i=0; i<w; i++) ++ { ++ const int srcB= src[-2*srcStride];\ ++ const int srcA= src[-1*srcStride];\ ++ const int src0= src[0 *srcStride];\ ++ const int src1= src[1 *srcStride];\ ++ const int src2= src[2 *srcStride];\ ++ const int src3= src[3 *srcStride];\ ++ const int src4= src[4 *srcStride];\ ++ const int src5= src[5 *srcStride];\ ++ const int src6= src[6 *srcStride];\ ++ OP(dst[0*dstStride], (src0+src1)*20 - (srcA+src2)*5 + (srcB+src3));\ ++ OP(dst[1*dstStride], (src1+src2)*20 - (src0+src3)*5 + (srcA+src4));\ ++ OP(dst[2*dstStride], (src2+src3)*20 - (src1+src4)*5 + (src0+src5));\ ++ OP(dst[3*dstStride], (src3+src4)*20 - (src2+src5)*5 + (src1+src6));\ ++ dst++;\ ++ src++;\ ++ */ ++ uint8_t tmp_block[4*4]; ++ ++ set_pico_config(&h264_qpel4_v_lowpass_config1); ++ ++ { ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ /* First compute the leftmost three colums */ ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(tmp_block, PICO_GET_W(PICO_OUTPIX0)); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(tmp_block + 4, PICO_GET_W(PICO_OUTPIX0)); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(tmp_block + 8, PICO_GET_W(PICO_OUTPIX0)); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(0, 0, 0, 3, 6); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC, 0, 0, 3, 6); ++ ST32(tmp_block + 12, PICO_GET_W(PICO_OUTPIX0)); ++ /* Now compute the last column */ ++ ++ union wordbytes { ++ int word; ++ struct { ++ unsigned int t:8; ++ unsigned int u:8; ++ unsigned int l:8; ++ unsigned int b:8; ++ } bytes; } tmp1, tmp2, tmp3; ++ ++ ++ tmp1.bytes.t = srcB; ++ tmp1.bytes.u = src1; ++ tmp1.bytes.l = src4; ++ ++ tmp2.bytes.t = srcA; ++ tmp2.bytes.u = src2; ++ tmp2.bytes.l = src5; ++ ++ tmp3.bytes.t = src0; ++ tmp3.bytes.u = src3; ++ tmp3.bytes.l = src6; ++ ++ PICO_MVRC_W(PICO_INPIX0, tmp1.word); ++ PICO_MVRC_W(PICO_INPIX1, tmp2.word); ++ PICO_MVRC_W(PICO_INPIX2, tmp3.word); ++ set_pico_config(&h264_qpel4_v_lowpass_config2); ++ ++ ++ PICO_OP(PICO_SINGLE_VECTOR, 0, 0, 3, 6); ++ PICO_OP(PICO_SINGLE_VECTOR, 1, 1, 4, 7); ++ PICO_OP(PICO_SINGLE_VECTOR, 2, 2, 5, 8); ++ PICO_OP(PICO_SINGLE_VECTOR, 3, 3, 6, 9); ++ ++ PICO_MVCR_W(tmp1.word, PICO_OUTPIX0); ++ tmp_block[3 + 3*4] = (char)(tmp1.bytes.b); ++ tmp_block[3 + 2*4] = (char)(tmp1.bytes.l); ++ tmp_block[3 + 1*4] = (char)(tmp1.bytes.u); ++ tmp_block[3] = (char)(tmp1.bytes.t); ++ ++ /* Compute the average */ ++ srcB= LD32(dst); ++ srcA= LD32(dst + dstStride); ++ src0= LD32(dst + dstStride*2); ++ src1= LD32(dst + dstStride*3); ++ ++ src2= LD32(tmp_block); ++ src3= LD32(tmp_block + 4); ++ src4= LD32(tmp_block + 8); ++ src5= LD32(tmp_block + 12); ++ ++ ST32(dst, rnd_avg32(srcB, src2)); ++ ST32(dst + dstStride, rnd_avg32(srcA, src3)); ++ ST32(dst + 2*dstStride, rnd_avg32(src0, src4)); ++ ST32(dst + 3*dstStride, rnd_avg32(src1, src5)); ++ } ++} ++ ++static struct pico_config_t h264_qpel4_hv_lowpass_config = { ++ .input_mode = PICO_HOR_FILTER_MODE, ++ .output_mode = PICO_PACKED_MODE, ++ .coeff_frac_bits = 10, ++ .offset_frac_bits = 10, ++ .coeff0_0 = 1, ++ .coeff0_1 = -5, ++ .coeff0_2 = 20, ++ .coeff0_3 = 512, ++ .coeff1_0 = -5, ++ .coeff1_1 = 25, ++ .coeff1_2 = -100, ++ .coeff1_3 = 0, ++ .coeff2_0 = 20, ++ .coeff2_1 = -100, ++ .coeff2_2 = 400, ++ .coeff2_3 = 0 ++}; ++ ++static void put_h264_qpel4_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ ++ int32_t tmp_block[48]; ++ int32_t *tmp = tmp_block; ++ int i; ++ ++ set_pico_config(&h264_qpel4_hv_lowpass_config); ++ ++ src -= 2; ++ for ( i = 0; i < 2; i++ ){ ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(0, 0, 0, 4, 8); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src2); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ src += 2; ++ } ++ ++ src -= 1; ++ tmp -= 48; ++ ++ ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_VERT_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(10) ++ | PICO_OFFSET_FRAC_BITS(10)); ++ ++ for ( i = 0; i < 2; i++ ){ ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC, 0, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 0, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 1, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 1, 9, 6, 3); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC, 2, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 2, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 3, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 3, 9, 6, 3); ++ ++ ST16(dst + 0*dstStride, (short)(PICO_GET_W(PICO_OUTPIX0) >> 16)); ++ ST16(dst + 1*dstStride, (short)PICO_GET_W(PICO_OUTPIX0)); ++ ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC, 0, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 0, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 1, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 1, 9, 6, 3); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC, 2, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 2, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 3, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 3, 9, 6, 3); ++ ++ ST16(dst + 2*dstStride, (short)(PICO_GET_W(PICO_OUTPIX0) >> 16)); ++ ST16(dst + 3*dstStride, (short)PICO_GET_W(PICO_OUTPIX0)); ++ ++ dst += 2; ++ src += 2; ++ } ++} ++ ++ ++ ++ ++static void avg_h264_qpel4_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ ++ int32_t tmp_block[48]; ++ int32_t *tmp = tmp_block; ++ int i; ++ ++ set_pico_config(&h264_qpel4_hv_lowpass_config); ++ ++ src -= 2; ++ for ( i = 0; i < 2; i++ ){ ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(0, 0, 0, 4, 8); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src2); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(0, 0, 4, 8, 0); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC, 0, 0, 4, 8); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ ++ PICO_OP(0, 0, 1, 5, 9); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC, 0, 1, 5, 9); ++ PICO_STCM_W(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ tmp += 3; ++ src += 2; ++ } ++ ++ src -= 1; ++ tmp -= 48; ++ ++ ++ PICO_PUT_W(PICO_CONFIG, ++ PICO_OUTPUT_MODE(PICO_PLANAR_MODE) ++ | PICO_INPUT_MODE(PICO_VERT_FILTER_MODE) ++ | PICO_COEFF_FRAC_BITS(10) ++ | PICO_OFFSET_FRAC_BITS(10)); ++ ++ for ( i = 0; i < 2; i++ ){ ++ int srcB= LD32(src - 2*srcStride); ++ int srcA= LD32(src - 1*srcStride); ++ int src0= LD32(src + 0 *srcStride); ++ int src1= LD32(src + 1 *srcStride); ++ int src2= LD32(src + 2 *srcStride); ++ int src3= LD32(src + 3 *srcStride); ++ int src4= LD32(src + 4 *srcStride); ++ int src5= LD32(src + 5 *srcStride); ++ int src6= LD32(src + 6 *srcStride); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC, 0, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX0, src3); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 0, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 1, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, srcB); ++ PICO_MVRC_W(PICO_INPIX1, srcA); ++ PICO_MVRC_W(PICO_INPIX2, src0); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 1, 9, 6, 3); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC, 2, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_MVRC_W(PICO_INPIX1, src3); ++ PICO_MVRC_W(PICO_INPIX0, src4); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 2, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 3, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, srcA); ++ PICO_MVRC_W(PICO_INPIX1, src0); ++ PICO_MVRC_W(PICO_INPIX2, src1); ++ PICO_OP(PICO_USE_ACC | PICO_SINGLE_VECTOR, 3, 9, 6, 3); ++ ++ ST16(dst + 0*dstStride, rnd_avg32(LD16(dst + 0*dstStride), PICO_GET_W(PICO_OUTPIX0) >> 16)); ++ ST16(dst + 1*dstStride, rnd_avg32(LD16(dst + 1*dstStride), PICO_GET_W(PICO_OUTPIX0))); ++ ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC, 0, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_MVRC_W(PICO_INPIX1, src4); ++ PICO_MVRC_W(PICO_INPIX0, src5); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 0, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 1, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, src0); ++ PICO_MVRC_W(PICO_INPIX1, src1); ++ PICO_MVRC_W(PICO_INPIX2, src2); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 1, 9, 6, 3); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC, 2, 6, 3, 0); ++ PICO_MVRC_W(PICO_INPIX2, src4); ++ PICO_MVRC_W(PICO_INPIX1, src5); ++ PICO_MVRC_W(PICO_INPIX0, src6); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 2, 6, 3, 0); ++ ++ PICO_LDCM_W_INC(tmp, ++ PICO_REGVECT_VMU0_OUT, ++ PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT); ++ PICO_OP(PICO_USE_ACC, 3, 9, 6, 3); ++ PICO_MVRC_W(PICO_INPIX0, src1); ++ PICO_MVRC_W(PICO_INPIX1, src2); ++ PICO_MVRC_W(PICO_INPIX2, src3); ++ PICO_OP(PICO_USE_ACC| PICO_SINGLE_VECTOR, 3, 9, 6, 3); ++ ++ ST16(dst + 2*dstStride, rnd_avg32(LD16(dst + 2*dstStride), PICO_GET_W(PICO_OUTPIX0) >> 16)); ++ ST16(dst + 3*dstStride, rnd_avg32(LD16(dst + 3*dstStride), PICO_GET_W(PICO_OUTPIX0))); ++ ++ dst += 2; ++ src += 2; ++ } ++} ++ ++ ++static void put_h264_qpel8_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel4_v_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_v_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ put_h264_qpel4_v_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_v_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel8_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel4_v_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_v_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ avg_h264_qpel4_v_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_v_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void put_h264_qpel8_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel4_h_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_h_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ put_h264_qpel4_h_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_h_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel8_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel4_h_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_h_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ avg_h264_qpel4_h_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_h_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void put_h264_qpel8_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel4_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_hv_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ put_h264_qpel4_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel4_hv_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel8_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel4_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_hv_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++ src += 4*srcStride; ++ dst += 4*dstStride; ++ avg_h264_qpel4_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel4_hv_lowpass_pico(dst+4, src+4, dstStride, srcStride); ++} ++ ++static void put_h264_qpel16_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel8_v_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_v_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ put_h264_qpel8_v_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_v_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel16_v_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel8_v_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_v_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ avg_h264_qpel8_v_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_v_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++static void put_h264_qpel16_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel8_h_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_h_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ put_h264_qpel8_h_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_h_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel16_h_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel8_h_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_h_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ avg_h264_qpel8_h_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_h_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++static void put_h264_qpel16_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ put_h264_qpel8_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_hv_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ put_h264_qpel8_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ put_h264_qpel8_hv_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++static void avg_h264_qpel16_hv_lowpass_pico(uint8_t *dst, uint8_t *src, int dstStride, int srcStride){ ++ avg_h264_qpel8_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_hv_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++ src += 8*srcStride; ++ dst += 8*dstStride; ++ avg_h264_qpel8_hv_lowpass_pico(dst , src , dstStride, srcStride); ++ avg_h264_qpel8_hv_lowpass_pico(dst+8, src+8, dstStride, srcStride); ++} ++ ++ ++#define H264_MC(OPNAME, SIZE) \ ++static void OPNAME ## h264_qpel ## SIZE ## _mc00_pico (uint8_t *dst, uint8_t *src, int stride){\ ++ OPNAME ## pixels ## SIZE ## _c(dst, src, stride, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc10_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t half[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(half, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, src, half, stride, stride, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc20_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ OPNAME ## h264_qpel ## SIZE ## _h_lowpass_pico(dst, src, stride, stride);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc30_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t half[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(half, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, src+1, half, stride, stride, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc01_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t half[SIZE*SIZE];\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(half, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, full_mid, half, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc02_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ OPNAME ## h264_qpel ## SIZE ## _v_lowpass_pico(dst, full_mid, stride, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc03_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t half[SIZE*SIZE];\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(half, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, full_mid+SIZE, half, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc11_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src, SIZE, stride);\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc31_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src, SIZE, stride);\ ++ copy_block ## SIZE (full, src - stride*2 + 1, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc13_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src + stride, SIZE, stride);\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc33_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src + stride, SIZE, stride);\ ++ copy_block ## SIZE (full, src - stride*2 + 1, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc22_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ OPNAME ## h264_qpel ## SIZE ## _hv_lowpass_pico(dst, src, stride, stride);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc21_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfHV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src, SIZE, stride);\ ++ put_h264_qpel ## SIZE ## _hv_lowpass_pico(halfHV, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfHV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc23_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t halfH[SIZE*SIZE];\ ++ uint8_t halfHV[SIZE*SIZE];\ ++ put_h264_qpel ## SIZE ## _h_lowpass_pico(halfH, src + stride, SIZE, stride);\ ++ put_h264_qpel ## SIZE ## _hv_lowpass_pico(halfHV, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfH, halfHV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc12_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfV[SIZE*SIZE];\ ++ uint8_t halfHV[SIZE*SIZE];\ ++ copy_block ## SIZE (full, src - stride*2, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ put_h264_qpel ## SIZE ## _hv_lowpass_pico(halfHV, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfV, halfHV, stride, SIZE, SIZE, SIZE);\ ++}\ ++\ ++static void OPNAME ## h264_qpel ## SIZE ## _mc32_pico(uint8_t *dst, uint8_t *src, int stride){\ ++ uint8_t full[SIZE*(SIZE+5)];\ ++ uint8_t * const full_mid= full + SIZE*2;\ ++ uint8_t halfV[SIZE*SIZE];\ ++ uint8_t halfHV[SIZE*SIZE];\ ++ copy_block ## SIZE (full, src - stride*2 + 1, SIZE, stride, SIZE + 5);\ ++ put_h264_qpel ## SIZE ## _v_lowpass_pico(halfV, full_mid, SIZE, SIZE);\ ++ put_h264_qpel ## SIZE ## _hv_lowpass_pico(halfHV, src, SIZE, stride);\ ++ OPNAME ## pixels ## SIZE ## _l2(dst, halfV, halfHV, stride, SIZE, SIZE, SIZE);\ ++}\ ++ ++H264_MC(put_, 4) ++H264_MC(put_, 8) ++H264_MC(put_, 16) ++H264_MC(avg_, 4) ++H264_MC(avg_, 8) ++H264_MC(avg_, 16) ++ ++ ++ ++#define dspfunc16(PFX) \ ++ void PFX ## _pixels16_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ){ \ ++ PFX ## _pixels8_avr32(dst, pixels, line_size, h);\ ++ PFX ## _pixels8_avr32(dst + 8, pixels + 8, line_size, h);\ ++ }\ ++ void PFX ## _pixels16_h_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ){ \ ++ PFX ## _pixels8_h_avr32(dst, pixels, line_size, h);\ ++ PFX ## _pixels8_h_avr32(dst + 8, pixels + 8, line_size, h);\ ++ }\ ++ void PFX ## _pixels16_v_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ){ \ ++ PFX ## _pixels8_v_avr32(dst, pixels, line_size, h);\ ++ PFX ## _pixels8_v_avr32(dst + 8, pixels + 8, line_size, h);\ ++ }\ ++ void PFX ## _pixels16_hv_avr32(uint8_t *dst, const uint8_t *pixels, int line_size, int h ){ \ ++ PFX ## _pixels8_hv_avr32(dst, pixels, line_size, h);\ ++ PFX ## _pixels8_hv_avr32(dst + 8, pixels + 8, line_size, h);\ ++ }\ ++ ++ ++dspfunc16(put) ++dspfunc16(put_no_rnd) ++dspfunc16(avg) ++dspfunc16(avg_no_rnd) ++#undef dspfunc16 ++ ++static int pix_sum_avr32(uint8_t * pix, int line_size) ++{ ++ int s, i; ++ ++ s = 0; ++ for (i = 0; i < 16; i++) { ++ int tmp1,tmp2,tmp3,tmp4,tmp5; ++ __asm__ volatile ( "ld.w\t%0, %6[0]\n\t" ++ "ld.w\t%1, %6[4]\n\t" ++ "ld.w\t%2, %6[8]\n\t" ++ "ld.w\t%3, %6[12]\n\t" ++ "punpckub.h\t%4, %0:t\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %0:b\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %1:t\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %1:b\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %2:t\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %2:b\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %3:t\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ "punpckub.h\t%4, %3:b\n\t" ++ "padd.h\t%5, %5, %4\n\t" ++ : "=&r"(tmp1),"=&r"(tmp2),"=&r"(tmp3),"=&r"(tmp4),"=&r"(tmp5),"=&r"(s) ++ : "r"(pix)); ++ pix += line_size; ++ } ++ __asm__ volatile ( "addhh.w\t%0, %0:t, %0:b" : "=&r" (s) ); ++ ++ return s; ++} ++ ++ ++//#define op_scale1(x) block[x] = clip_uint8( (block[x]*weight + offset) >> log2_denom ) ++//#define op_scale2(x) dst[x] = clip_uint8( (src[x]*weights + dst[x]*weightd + offset) >> (log2_denom+1)) ++//#define H264_WEIGHT(W,H) \ ++//static void weight_h264_pixels ## W ## x ## H ## _c(uint8_t *block, int stride, int log2_denom, int weight, int offset){ \ ++// int attribute_unused x, y; \ ++// offset <<= log2_denom; \ ++// if(log2_denom) offset += 1<<(log2_denom-1); \ ++// for(y=0; y<H; y++, block += stride){ \ ++// uint32_t tmp0, tmp1; ++// if(W==2) { \ ++// asm volatile ( "ld.ub\t%[tmp0], %[block][0]\n" \ ++// "ld.ub\t%[tmp1], %[block][1]\n" \ ++// "mulhh.w\t%[tmp0], %[tmp0]:b, %[weight]:b\n" \ ++// "mulhh.w\t%[tmp1], %[tmp1]:b, %[weight]:b\n" \ ++// "asr\t%[tmp0], %[log2_denom]\n" \ ++// "asr\t%[tmp1], %[log2_denom]\n" \ ++// "satu\t%[tmp0] >> 0, 8\n" \ ++// "satu\t%[tmp1] >> 0, 8\n" \ ++// "st.b\t%[block][0], %[tmp0]\n" \ ++// "st.b\t%[block][1], %[tmp1]\n" \ ++// : [tmp0] "=&r"(tmp0), [tmp1] "=&r"(tmp1) \ ++// : [block] "r"(block), [weight]"r"(weight), [log2_denom]"r"(log2denom) ); \ ++// } else if ( W==4 ) { \ ++// asm volatile ( "ld.w\t%[tmp0], %[block][0]\n" \ ++// "punpckub.h\t%[tmp1], %[tmp0]:t\n" \ ++// "punpckub.h\t%[tmp0], %[tmp0]:b\n" \ ++// "mulhh.w\t%[tmp2], %[tmp1]:t, %[weight]:b\n" \ ++// "mulhh.w\t%[tmp1], %[tmp1]:b, %[weight]:b\n" \ ++// "asr\t%[tmp0], %[log2_denom]\n" \ ++// "asr\t%[tmp1], %[log2_denom]\n" \ ++// "satu\t%[tmp0] >> 0, 8\n" \ ++// "satu\t%[tmp1] >> 0, 8\n" \ ++// "st.b\t%[block][0], %[tmp0]\n" \ ++// "st.b\t%[block][1], %[tmp1]\n" \ ++// : [tmp0] "=&r"(tmp0), [tmp1] "=&r"(tmp1) \ ++// : [block] "r"(block), [weight]"r"(weight), [log2_denom]"r"(log2denom) ); \ ++// ++// ++// ++// if(W==4) continue; \ ++// op_scale1(4); \ ++// op_scale1(5); \ ++// op_scale1(6); \ ++// op_scale1(7); \ ++// if(W==8) continue; \ ++// op_scale1(8); \ ++// op_scale1(9); \ ++// op_scale1(10); \ ++// op_scale1(11); \ ++// op_scale1(12); \ ++// op_scale1(13); \ ++// op_scale1(14); \ ++// op_scale1(15); \ ++// } \ ++//} \ ++//static void biweight_h264_pixels ## W ## x ## H ## _c(uint8_t *dst, uint8_t *src, int stride, int log2_denom, int weightd, int weights, int offsetd, int offsets){ \ ++// int attribute_unused x, y; \ ++// int offset = (offsets + offsetd + 1) >> 1; \ ++// offset = ((offset << 1) + 1) << log2_denom; \ ++// for(y=0; y<H; y++, dst += stride, src += stride){ \ ++// op_scale2(0); \ ++// op_scale2(1); \ ++// if(W==2) continue; \ ++// op_scale2(2); \ ++// op_scale2(3); \ ++// if(W==4) continue; \ ++// op_scale2(4); \ ++// op_scale2(5); \ ++// op_scale2(6); \ ++// op_scale2(7); \ ++// if(W==8) continue; \ ++// op_scale2(8); \ ++// op_scale2(9); \ ++// op_scale2(10); \ ++// op_scale2(11); \ ++// op_scale2(12); \ ++// op_scale2(13); \ ++// op_scale2(14); \ ++// op_scale2(15); \ ++// } \ ++//} ++ ++ ++ ++/* Returns zero in each byte where the absolute difference between <a> and <b> ++ is not less than <compare> */ ++#define PABS_DIFF_LESS_THAN( a, b, compare) \ ++ ({ uint32_t __tmp__, __tmp2__, __mask__; \ ++ asm ( \ ++ /* Check ABS( a - b ) < compare */ \ ++ "psubs.ub\t%[tmp], %[opa], %[opb]\n" \ ++ "psubs.ub\t%[tmp2], %[opb], %[opa]\n" \ ++ "or\t%[tmp], %[tmp2]\n" /* ABS ( a - b ) */ \ ++ /* This produces 0 for all bytes where the comparison is not true */ \ ++ "psubs.ub\t%[mask], %[cmp], %[tmp]\n" \ ++ : [tmp] "=&r"(__tmp__), [tmp2] "=&r"(__tmp2__), [mask] "=&r"(__mask__) \ ++ : [opa] "r"(a), [opb] "r"(b), [cmp] "r"(compare) ); \ ++ __mask__; }) ++ ++/* ++ Set all bytes containing zero in <value> to 255 and the rest to zero. ++ ++ Add with saturation 254 to all bytes making all bytes different from ++ zero become 255. Then add one without saturation to make all bytes ++ originally containing zero 255 and the rest 0. */ ++#define SET_ALL_BITS_IN_ZERO_BYTES(value) \ ++ ({ uint32_t __tmp__; \ ++ asm ( \ ++ "padds.ub\t%[tmp], %[val], %[max_minus_one]\n" \ ++ "padd.b\t%[tmp], %[tmp], %[all_ones]\n" \ ++ : [tmp] "=r"(__tmp__) \ ++ : [val] "r"(value), [max_minus_one] "r"(0xFEFEFEFE), [all_ones] "r"(0x01010101) ); \ ++ __tmp__; }) ++ ++#define PACKW_SH(upper, lower) \ ++ ({ uint32_t __tmp__; \ ++ asm ( \ ++ "packw.sh\t%[tmp], %[u], %[l]\n" \ ++ : [tmp] "=r"(__tmp__) \ ++ : [u] "r"(upper), [l] "r"(lower) ); \ ++ __tmp__; }) ++ ++#define PACKSH_UB(upper, lower) \ ++ ({ uint32_t __tmp__; \ ++ asm ( \ ++ "packsh.sb\t%[tmp], %[u], %[l]\n" \ ++ : [tmp] "=r"(__tmp__) \ ++ : [u] "r"(upper), [l] "r"(lower) ); \ ++ __tmp__; }) ++ ++static void h264_v_loop_filter_luma_avr32(uint8_t *pix, int stride, int alpha, int beta, int8_t *tc0) ++{ ++ int i; ++ ++ if ( alpha == 0 ) ++ return; ++ ++ alpha = PACKW_SH(alpha, alpha); ++ alpha = PACKSH_UB(alpha, alpha); ++ beta = PACKW_SH(beta, beta); ++ beta = PACKSH_UB(beta, beta); ++ ++ for( i = 0; i < 4; i++ ) { ++ uint32_t p0, p1, p2, q0, q1, q2; ++ uint32_t mask, mask2; ++ uint32_t tmp, tmp2, tmp3, tmp4; ++ ++ if( tc0[i] < 0 ) { ++ pix += 4; ++ continue; ++ } ++ ++/* for( d = 0; d < 4; d++ ) { ++ const int p0 = pix[-1*stride]; ++ const int p1 = pix[-2*stride]; ++ const int p2 = pix[-3*stride]; ++ const int q0 = pix[0]; ++ const int q1 = pix[1*stride]; ++ const int q2 = pix[2*stride]; ++ ++ if( ABS( p0 - q0 ) < alpha && ++ ABS( p1 - p0 ) < beta && ++ ABS( q1 - q0 ) < beta ) { */ ++ ++ p0 = LD32(pix - stride); ++ p1 = LD32(pix - 2*stride); ++ q0 = LD32(pix); ++ q1 = LD32(pix + stride); ++ ++ /* Check which of the columns should be filtered, if any. */ ++ mask = PABS_DIFF_LESS_THAN(p0, q0, alpha); ++ mask |= PABS_DIFF_LESS_THAN(p1, p0, beta); ++ mask |= PABS_DIFF_LESS_THAN(q1, q0, beta); ++ ++ if ( !mask ) ++ continue; ++ ++ mask = SET_ALL_BITS_IN_ZERO_BYTES(mask); ++ ++ ++ int tc = PACKW_SH(tc0[i], tc0[i]); ++ int tc0_p = tc; ++ int tc0_m = PACKW_SH(-tc0[i], -tc0[i]); ++ ++ /* ++ int i_delta; ++ if( ABS( p2 - p0 ) < beta ) { ++ pix[-2*stride] = p1 + clip( (( p2 + ( ( p0 + q0 + 1 ) >> 1 ) ) >> 1) - p1, -tc0[i], tc0[i] ); ++ tc++; ++ }*/ ++ ++ p2 = LD32(pix - 3*stride); ++ mask2 = PABS_DIFF_LESS_THAN(p2, p0, beta) & ~mask; ++ ++ if ( mask2 ){ ++ mask2 = SET_ALL_BITS_IN_ZERO_BYTES(mask2); ++ asm ("pavg.ub\t%[tmp], %[p0], %[q0]\n" ++ "paddh.ub\t%[tmp], %[tmp], %[p2]\n" ++ "punpckub.h\t%[tmp2], %[tmp]:t\n" ++ "punpckub.h\t%[tmp], %[tmp]:b\n" ++ "punpckub.h\t%[tmp3], %[p1]:t\n" ++ "punpckub.h\t%[tmp4], %[p1]:b\n" ++ "psub.h\t%[tmp2], %[tmp2], %[tmp3]\n" ++ "psub.h\t%[tmp], %[tmp], %[tmp4]\n" ++ "pmin.sh\t%[tmp2], %[tmp2], %[tc0_p]\n" ++ "pmin.sh\t%[tmp], %[tmp], %[tc0_p]\n" ++ "pmax.sh\t%[tmp2], %[tmp2], %[tc0_m]\n" ++ "pmax.sh\t%[tmp], %[tmp], %[tc0_m]\n" ++ "padd.h\t%[tmp2], %[tmp2], %[tmp3]\n" ++ "padd.h\t%[tmp], %[tmp], %[tmp4]\n" ++ "packsh.ub\t%[tmp], %[tmp2], %[tmp]\n" ++ "andn\t%[tmp], %[mask2]\n" ++ "and\t%[tmp2], %[q1], %[mask2]\n" ++ "or\t%[tmp], %[tmp2]\n" ++ : [tmp]"=&r"(tmp), [tmp2]"=&r"(tmp2), [tmp3]"=&r"(tmp3), ++ [tmp4]"=&r"(tmp4) ++ : [q0]"r"(q0), [p2]"r"(p2), [p1]"r"(p1), [p0]"r"(p0), [q1]"r"(q1), [tc0_p]"r"(tc0_p), ++ [tc0_m]"r"(tc0_m), [mask2]"r"(mask2)); ++ ST32(pix - 2*stride, tmp); ++ tc += 0x00010001; ++ } ++ ++ ++ q2 = LD32(pix + 2*stride); ++ ++ /* ++ if( ABS( q2 - q0 ) < beta ) { ++ pix[ stride] = q1 + clip( (( q2 + ( ( p0 + q0 + 1 ) >> 1 ) ) >> 1) - q1, -tc0[i], tc0[i] ); ++ tc++; ++ } ++ */ ++ mask2 = PABS_DIFF_LESS_THAN(q2, q0, beta) & ~mask; ++ ++ if ( mask2 ){ ++ mask2 = SET_ALL_BITS_IN_ZERO_BYTES(mask2); ++ asm ("pavg.ub\t%[tmp], %[p0], %[q0]\n" ++ "paddh.ub\t%[tmp], %[tmp], %[q2]\n" ++ "punpckub.h\t%[tmp2], %[tmp]:t\n" ++ "punpckub.h\t%[tmp], %[tmp]:b\n" ++ "punpckub.h\t%[tmp3], %[q1]:t\n" ++ "punpckub.h\t%[tmp4], %[q1]:b\n" ++ "psub.h\t%[tmp2], %[tmp2], %[tmp3]\n" ++ "psub.h\t%[tmp], %[tmp], %[tmp4]\n" ++ "pmin.sh\t%[tmp2], %[tmp2], %[tc0_p]\n" ++ "pmin.sh\t%[tmp], %[tmp], %[tc0_p]\n" ++ "pmax.sh\t%[tmp2], %[tmp2], %[tc0_m]\n" ++ "pmax.sh\t%[tmp], %[tmp], %[tc0_m]\n" ++ "padd.h\t%[tmp2], %[tmp2], %[tmp3]\n" ++ "padd.h\t%[tmp], %[tmp], %[tmp4]\n" ++ "packsh.ub\t%[tmp], %[tmp2], %[tmp]\n" ++ "andn\t%[tmp], %[mask2]\n" ++ "and\t%[tmp2], %[q1], %[mask2]\n" ++ "or\t%[tmp], %[tmp2]\n" ++ : [tmp]"=&r"(tmp), [tmp2]"=&r"(tmp2), [tmp3]"=&r"(tmp3), ++ [tmp4]"=&r"(tmp4) ++ : [q0]"r"(q0), [q2]"r"(q2), [q1]"r"(q1), [p0]"r"(p0), [tc0_p]"r"(tc0_p), ++ [tc0_m]"r"(tc0_m), [mask2]"r"(mask2)); ++ ST32(pix + stride, tmp); ++ tc += 0x00010001; ++ } ++ ++ uint32_t old_p0 = p0; ++ uint32_t old_q0 = q0; ++ ++ /* i_delta = clip( (((q0 - p0 ) << 2) + (p1 - q1) + 4) >> 3, -tc, tc ); ++ pix[-stride] = clip_uint8( p0 + i_delta ); ++ pix[0] = clip_uint8( q0 - i_delta ); */ ++ ++ asm ( ++ /* Check if the two upper pixels should be filtered */ ++ "lsr\t%[tmp], %[inv_mask], 16\n" ++ "breq\t0f\n" ++ ++ "punpckub.h\t%[tmp], %[p1]:t\n" ++ "punpckub.h\t%[tmp2], %[q1]:t\n" ++ ++ /* p1 - q1 */ ++ "psub.h\t%[tmp], %[tmp], %[tmp2]\n" ++ ++ "punpckub.h\t%[tmp3], %[q0]:t\n" ++ "punpckub.h\t%[tmp4], %[p0]:t\n" ++ ++ /* q0 - p0 */ ++ "psub.h\t%[tmp2], %[tmp3], %[tmp4]\n" ++ ++ /* (q0 - p0) << 2 */ ++ "plsl.h\t%[tmp2], %[tmp2], 2\n" ++ ++ /* ((q0 - p0) << 2) + (p1 - q1) */ ++ "padd.h\t%[tmp2], %[tmp2], %[tmp]\n" ++ ++ "mov\t%[tmp], 0x00040004\n" ++ /* ((q0 - p0) << 2) + (p1 - q1) + 4*/ ++ "padd.h\t%[tmp2], %[tmp2], %[tmp]\n" ++ ++ /* (((q0 - p0) << 2) + (p1 - q1) + 4) >> 3*/ ++ "pasr.h\t%[tmp2], %[tmp2], 3\n" ++ ++ "mov\t%[tmp], 0\n" ++ "psub.h\t%[tmp], %[tmp], %[tc]\n" ++ ++ /* i_delta = clip( (((q0 - p0 ) << 2) + (p1 - q1) + 4) >> 3, -tc, tc ); */ ++ "pmin.sh\t%[tmp2], %[tmp2], %[tc]\n" ++ "pmax.sh\t%[tmp2], %[tmp2], %[tmp]\n" ++ ++ ++ /* pix[-stride] = clip_uint8( p0 + i_delta ); */ ++ "padd.h\t%[tmp4], %[tmp4], %[tmp2]\n" ++ ++ ++ /* pix[0] = clip_uint8( q0 - i_delta ); */ ++ "psub.h\t%[tmp3], %[tmp3], %[tmp2]\n" ++ ++ /* Check if the two lower pixels should be filtered */ ++ "lsl\t%[tmp2], %[inv_mask], 16\n" ++ "breq\t1f\n" ++ ++ "0:\n" ++ "punpckub.h\t%[p1], %[p1]:b\n" ++ "punpckub.h\t%[q1], %[q1]:b\n" ++ ++ /* p1 - q1 */ ++ "psub.h\t%[p1], %[p1], %[q1]\n" ++ ++ "punpckub.h\t%[q0], %[q0]:b\n" ++ "punpckub.h\t%[p0], %[p0]:b\n" ++ ++ /* q0 - p0 */ ++ "psub.h\t%[tmp2], %[q0], %[p0]\n" ++ ++ /* (q0 - p0) << 2 */ ++ "plsl.h\t%[tmp2], %[tmp2], 2\n" ++ ++ /* ((q0 - p0) << 2) + (p1 - q1) */ ++ "padd.h\t%[tmp2], %[tmp2], %[p1]\n" ++ ++ "mov\t%[q1], 0x00040004\n" ++ /* ((q0 - p0) << 2) + (p1 - q1) + 4*/ ++ "padd.h\t%[tmp2], %[tmp2], %[q1]\n" ++ ++ /* (((q0 - p0) << 2) + (p1 - q1) + 4) >> 3*/ ++ "pasr.h\t%[tmp2], %[tmp2], 3\n" ++ ++ /* i_delta = clip( (((q0 - p0 ) << 2) + (p1 - q1) + 4) >> 3, -tc, tc ); */ ++ "pmin.sh\t%[tmp2], %[tmp2], %[tc]\n" ++ "pmax.sh\t%[tmp2], %[tmp2], %[tmp]\n" ++ ++ /* pix[-stride] = clip_uint8( p0 + i_delta ); */ ++ "padd.h\t%[p0], %[p0], %[tmp2]\n" ++ ++ /* pix[0] = clip_uint8( q0 - i_delta ); */ ++ "psub.h\t%[q0], %[q0], %[tmp2]\n" ++ ++ "1:\n" ++ "packsh.ub\t%[p0], %[tmp4], %[p0]\n" ++ "packsh.ub\t%[q0], %[tmp3], %[tmp4]\n" ++ ++ : [tmp]"=&r"(tmp), [tmp2]"=&r"(tmp2), [tmp3]"=&r"(tmp3), ++ [tmp4]"=&r"(tmp4), [q0]"=&r"(q0), [q1]"=&r"(q1), [p0]"=&r"(p0), [p1]"=&r"(p1) ++ : [tc]"r"(tc), [inv_mask]"r"(~mask)); ++ ++ ST32(pix - stride, (mask & old_p0) | (p0 & ~mask)); ++ ST32(pix, (mask & old_q0) | (q0 & ~mask)); ++ ++ } ++ pix += 1; ++} ++ ++ ++ ++ ++#ifdef CHECK_DSP_FUNCS_AGAINST_C ++ ++void dump_block8(uint8_t *block, int line_size, int h){ ++ int i, j; ++ ++ for ( i = 0; i < h ; i++ ){ ++ av_log(NULL, AV_LOG_ERROR, "\t"); ++ for ( j = 0; j < 8 ; j++ ){ ++ av_log(NULL, AV_LOG_ERROR, "%d ", block[j + i*line_size]); ++ } ++ av_log(NULL, AV_LOG_ERROR, "\n"); ++ } ++} ++ ++void dump_block4(uint8_t *block, int line_size, int h){ ++ int i, j; ++ ++ for ( i = 0; i < h ; i++ ){ ++ av_log(NULL, AV_LOG_ERROR, "\t"); ++ for ( j = 0; j < 4 ; j++ ){ ++ av_log(NULL, AV_LOG_ERROR, "%d ", block[j + i*line_size]); ++ } ++ av_log(NULL, AV_LOG_ERROR, "\n"); ++ } ++} ++ ++void dump_block(uint8_t *block, int line_size, int h, int w){ ++ int i, j; ++ ++ for ( i = 0; i < h ; i++ ){ ++ av_log(NULL, AV_LOG_ERROR, "\t"); ++ for ( j = 0; j < w ; j++ ){ ++ av_log(NULL, AV_LOG_ERROR, "%d ", block[j + i*line_size]); ++ } ++ av_log(NULL, AV_LOG_ERROR, "\n"); ++ } ++} ++ ++void check_block8(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, char *name, int max_dev){ ++ int i,j; ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < h ; j++ ){ ++ int diff = test[i + line_size_test*j] - correct[i + line_size_correct*j]; ++ diff = diff < 0 ? -diff : diff; ++ if ( diff > max_dev ){ ++ av_log(NULL, AV_LOG_ERROR, "Error pixel x=%i, y=%i differs. Is 0x%x should be 0x%x\n", ++ i, j, test[i + line_size_test*j], correct[i + j*line_size_correct]); ++ av_log(NULL, AV_LOG_ERROR, "Error resulting block from %s is:\n", name); ++ dump_block8(test, line_size_test, h); ++ av_log(NULL, AV_LOG_ERROR, "But should be equal to:\n"); ++ dump_block8(correct, line_size_correct, h); ++ exit(1); ++ } ++ } ++ } ++} ++ ++void check_block4(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, char *name, int max_dev){ ++ int i,j; ++ for ( i = 0; i < 4 ; i++ ){ ++ for ( j = 0; j < h ; j++ ){ ++ int diff = test[i + line_size_test*j] - correct[i + line_size_correct*j]; ++ diff = diff < 0 ? -diff : diff; ++ if ( diff > max_dev ){ ++ av_log(NULL, AV_LOG_ERROR, "Error pixel x=%i, y=%i differs. Is 0x%x should be 0x%x\n", ++ i, j, test[i + line_size_test*j], correct[i + j*line_size_correct]); ++ av_log(NULL, AV_LOG_ERROR, "Error resulting block from %s is:\n", name); ++ dump_block8(test, line_size_test, h); ++ av_log(NULL, AV_LOG_ERROR, "But should be equal to:\n"); ++ dump_block4(correct, line_size_correct, h); ++ exit(1); ++ } ++ } ++ } ++} ++ ++void check_block(uint8_t *test, uint8_t *correct, int line_size_test, int line_size_correct, ++ int h, int width, char *name, int max_dev){ ++ int i,j; ++ for ( i = 0; i < width ; i++ ){ ++ for ( j = 0; j < h ; j++ ){ ++ int diff = test[i + line_size_test*j] - correct[i + line_size_correct*j]; ++ diff = diff < 0 ? -diff : diff; ++ if ( diff > max_dev ){ ++ av_log(NULL, AV_LOG_ERROR, "Error pixel x=%i, y=%i differs. Is 0x%x should be 0x%x\n", ++ i, j, test[i + line_size_test*j], correct[i + j*line_size_correct]); ++ av_log(NULL, AV_LOG_ERROR, "Error resulting block from %s is:\n", name); ++ dump_block(test, line_size_test, h, width); ++ av_log(NULL, AV_LOG_ERROR, "But should be equal to:\n"); ++ dump_block(correct, line_size_correct, h, width); ++ exit(1); ++ } ++ } ++ } ++} ++ ++void dump_dct_block(DCTELEM *block){ ++ int i, j; ++ ++ for ( i = 0; i < 8 ; i++ ){ ++ av_log(NULL, AV_LOG_ERROR, "\t"); ++ for ( j = 0; j < 8 ; j++ ){ ++ av_log(NULL, AV_LOG_ERROR, "0x%x ", block[j + i*8]); ++ } ++ av_log(NULL, AV_LOG_ERROR, "\n"); ++ } ++} ++ ++void test_idct_avr32(DCTELEM *block){ ++ DCTELEM testBlock[64]; ++ int i, j; ++ ++ /* Copy transposed block to testBlock */ ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < 8 ; j++ ){ ++ testBlock[i + 8*j] = block[j + i*8]; ++ } ++ } ++ ++ idct_avr32(block); ++ simple_idct(&testBlock); ++ ++ for ( i = 0; i < 64 ; i++ ){ ++ if ( block[i] != testBlock[i] ){ ++ av_log(NULL, AV_LOG_ERROR, "Error resulting block from idct is:\n"); ++ dump_dct_block(block); ++ av_log(NULL, AV_LOG_ERROR, "But should be equal to the transposed of:\n"); ++ dump_dct_block(testBlock); ++ exit(1); ++ } ++ } ++} ++ ++void test_idct_put_avr32(uint8_t *dest, int line_size, DCTELEM *block){ ++ uint8_t testBlock[64]; ++ DCTELEM blockCopy[64]; ++ int i, j; ++ ++ /* Copy transposed block to blockCopy */ ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < 8 ; j++ ){ ++ blockCopy[i + 8*j] = block[j + i*8]; ++ } ++ } ++ ++ idct_put_avr32(dest, line_size, block); ++ simple_idct_put(&testBlock, 8, blockCopy); ++ ++ check_block8(dest, testBlock, line_size, 8, 8, "idct_put", 1); ++} ++ ++ ++void test_idct_add_avr32(uint8_t *dest, int line_size, DCTELEM *block){ ++ uint8_t testBlock[64]; ++ DCTELEM blockCopy[64]; ++ int i, j; ++ ++ /* Copy dest to testBlock */ ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < 8 ; j++ ){ ++ testBlock[i + 8*j] = dest[i + j*line_size]; ++ } ++ } ++ ++ /* Copy transposed block to blockCopy */ ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < 8 ; j++ ){ ++ blockCopy[i + 8*j] = block[j + i*8]; ++ } ++ } ++ ++ idct_add_avr32(dest, line_size, block); ++ simple_idct_add(&testBlock, 8, blockCopy); ++ ++ check_block8(dest, testBlock, line_size, 8, 8, "idct_add", 1); ++} ++ ++void test_h264_idct_add_avr32(uint8_t *dest, DCTELEM *block, int stride){ ++ uint8_t testBlock[16]; ++ DCTELEM blockCopy[16]; ++ int i, j; ++ ++ /* Copy dest to testBlock */ ++ for ( i = 0; i < 4 ; i++ ){ ++ for ( j = 0; j < 4 ; j++ ){ ++ testBlock[i + 4*j] = dest[i + j*stride]; ++ } ++ } ++ ++ /* Copy transposed block to blockCopy */ ++ for ( i = 0; i < 16 ; i++ ){ ++ blockCopy[i] = block[i]; ++ } ++ ++ ff_h264_idct_add_c(dest, block, stride); ++ ++ h264_idct_add_avr32(testBlock, blockCopy, 4); ++ ++ check_block(dest, testBlock, stride, 4, 4, 4, "h264_idct_add", 0); ++} ++ ++void test_h264_idct8_add_avr32(uint8_t *dest, DCTELEM *block, int stride){ ++ uint8_t testBlock[8*8]; ++ DCTELEM blockCopy[8*8]; ++ int i, j; ++ ++ /* Copy dest to testBlock */ ++ for ( i = 0; i < 8 ; i++ ){ ++ for ( j = 0; j < 8 ; j++ ){ ++ testBlock[i + 8*j] = dest[i + j*stride]; ++ } ++ } ++ ++ /* Copy source block to blockCopy */ ++ for ( i = 0; i < 8*8 ; i++ ){ ++ blockCopy[i] = block[i]; ++ } ++ ++ ff_h264_idct8_add_c(dest, block, stride); ++ h264_idct8_add_avr32(testBlock, blockCopy, 8); ++ ++ check_block(dest, testBlock, stride, 8, 8, 8, "h264_idct8_add", 0); ++} ++ ++void test_put_pixels_funcs8(op_pixels_func test, op_pixels_func correct, uint8_t *block, ++ const uint8_t *pixels, int line_size, int h, char *name, int in_h_size, int in_v_size){ ++ uint8_t *testBlock, *testBlock2; ++ int i, j; ++ int input_v_size = h + in_v_size; ++ int input_h_size = 8 + in_h_size; ++ ++ testBlock = alloca(input_h_size*input_v_size); ++ testBlock2 = alloca(input_h_size*input_v_size); ++ ++ for ( i = 0; i < input_h_size ; i++ ){ ++ for ( j = 0; j < input_v_size ; j++ ){ ++ testBlock[i + input_h_size*j] = pixels[i + j*line_size]; ++ } ++ } ++ ++ test(block, pixels, line_size, h); ++ correct(testBlock2, testBlock, input_h_size, h); ++ ++ check_block8(block, testBlock2, line_size, input_h_size, h, name, 0); ++ ++} ++ ++void test_h264_chroma_mc_funcs(h264_chroma_mc_func test, h264_chroma_mc_func correct, uint8_t *dst, ++ uint8_t *src, int stride, int h, int w, int x, int y, char *name){ ++ uint8_t *testBlock, *testBlock2; ++ int i, j; ++ int input_v_size = h + 1; ++ int input_h_size = ((w + 1) + 3) & ~3; ++ ++ testBlock = alloca(input_h_size*input_v_size); ++ testBlock2 = alloca(input_h_size*input_v_size); ++ ++ for ( i = 0; i < w + 1 ; i++ ){ ++ for ( j = 0; j < h + 1 ; j++ ){ ++ testBlock[i + input_h_size*j] = src[i + j*stride]; ++ } ++ } ++ ++ for ( i = 0; i < w ; i++ ){ ++ for ( j = 0; j < h ; j++ ){ ++ testBlock2[i + input_h_size*j] = dst[i + j*stride]; ++ } ++ } ++ ++ test(dst, src, stride, h, x, y); ++ correct(testBlock2, testBlock, input_h_size, h, x, y); ++ ++ check_block(dst, testBlock2, stride, input_h_size, h, w, name, 0); ++ ++} ++ ++void test_qpel_mc_funcs(qpel_mc_func test, qpel_mc_func correct, uint8_t *dst, ++ uint8_t *src, int stride, int size, char *name){ ++ uint8_t *testBlock, *testBlock2; ++ int i, j; ++ int test_stride = size + 8; ++ ++ testBlock = alloca(test_stride*(size+8)) + 4 + test_stride*4; ++ testBlock2 = alloca(test_stride*size); ++ ++ for ( i = -4; i < size+4 ; i++ ){ ++ for ( j = -4; j < size+4 ; j++ ){ ++ testBlock[i + test_stride*j] = src[i + j*stride]; ++ } ++ } ++ ++ for ( i = 0; i < size ; i++ ){ ++ for ( j = 0; j < size ; j++ ){ ++ testBlock2[i + test_stride*j] = dst[i + j*stride]; ++ } ++ } ++ ++ correct(dst, src, stride); ++ test(testBlock2, testBlock, test_stride); ++ ++ check_block(testBlock2, dst, test_stride, stride, size, size, name, 0); ++ ++} ++ ++ ++#define test_pixels_funcs(PFX, NUM ) \ ++void test_ ## PFX ## _pixels ## NUM ## _avr32( uint8_t *block, const uint8_t *pixels, int line_size, int h){ \ ++ test_put_pixels_funcs8(PFX ## _pixels ## NUM ## _avr32, PFX ## _pixels ## NUM ## _c, \ ++ block, pixels, line_size, h, "test_" #PFX "_pixels", 0, 0); } \ ++void test_ ## PFX ## _pixels ## NUM ## _h_avr32( uint8_t *block, const uint8_t *pixels, int line_size, int h){ \ ++ test_put_pixels_funcs8(PFX ## _pixels ## NUM ## _h_avr32, PFX ## _pixels ## NUM ## _x2_c, \ ++ block, pixels, line_size, h, "test_" #PFX "_pixels_h", 1, 0); } \ ++void test_ ## PFX ## _pixels ## NUM ## _v_avr32( uint8_t *block, const uint8_t *pixels, int line_size, int h){ \ ++ test_put_pixels_funcs8(PFX ## _pixels ## NUM ## _v_avr32, PFX ## _pixels ## NUM ## _y2_c, \ ++ block, pixels, line_size, h, "test_" #PFX "_pixels_v", 0, 1); } \ ++void test_ ## PFX ## _pixels ## NUM ## _hv_avr32( uint8_t *block, const uint8_t *pixels, int line_size, int h){ \ ++ test_put_pixels_funcs8(PFX ## _pixels ## NUM ## _hv_avr32, PFX ## _pixels ## NUM ## _xy2_c, \ ++ block, pixels, line_size, h, "test_" #PFX "_pixels_hv", 1, 1); } ++ ++test_pixels_funcs(put, 8); ++test_pixels_funcs(put_no_rnd, 8); ++test_pixels_funcs(put, 16); ++test_pixels_funcs(put_no_rnd, 16); ++ ++test_pixels_funcs(avg, 8); ++test_pixels_funcs(avg_no_rnd, 8); ++test_pixels_funcs(avg, 16); ++test_pixels_funcs(avg_no_rnd, 16); ++ ++#define test_h264_chroma_mc_funcs(PFX, NUM ) \ ++void test_ ## PFX ## _h264_chroma_mc ## NUM ## _pico( uint8_t *dst, uint8_t *src, int stride, int h, int x, int y){ \ ++ test_h264_chroma_mc_funcs(PFX ## _h264_chroma_mc ## NUM ## _pico, PFX ## _h264_chroma_mc ## NUM ## _c, \ ++ dst, src, stride, h, NUM, x, y, "test_" #PFX "_h264_chroma_mc" #NUM "_pico"); } \ ++ ++test_h264_chroma_mc_funcs(put, 2); ++test_h264_chroma_mc_funcs(put, 4); ++test_h264_chroma_mc_funcs(put, 8); ++test_h264_chroma_mc_funcs(avg, 2); ++test_h264_chroma_mc_funcs(avg, 4); ++test_h264_chroma_mc_funcs(avg, 8); ++ ++#define test_qpel_mc_funcs_type(PFX, NUM, TYPE ) \ ++void test_ ## PFX ## NUM ## _ ## TYPE ## _pico( uint8_t *dst, uint8_t *src, int stride){ \ ++ test_qpel_mc_funcs(PFX ## NUM ## _ ## TYPE ## _pico, PFX ## NUM ## _ ## TYPE ## _c, \ ++ dst, src, stride, NUM, "test_" #PFX #NUM "_" #TYPE "_pico"); } ++ ++#define test_qpel_mc_funcs(PFX, NUM) \ ++ test_qpel_mc_funcs_type(PFX, NUM, mc00);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc10);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc20);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc30);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc01);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc11);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc21);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc31);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc02);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc12);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc22);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc32);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc03);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc13);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc23);\ ++ test_qpel_mc_funcs_type(PFX, NUM, mc33) ++ ++test_qpel_mc_funcs(put_h264_qpel, 4); ++test_qpel_mc_funcs(put_h264_qpel, 8); ++test_qpel_mc_funcs(put_h264_qpel, 16); ++test_qpel_mc_funcs(avg_h264_qpel, 4); ++test_qpel_mc_funcs(avg_h264_qpel, 8); ++test_qpel_mc_funcs(avg_h264_qpel, 16); ++ ++ ++#define dspfunc(PFX, IDX, NUM) \ ++ c->PFX ## _pixels_tab[IDX][ 0] = DSP_FUNC_NAME( PFX ## NUM ## _mc00_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 1] = DSP_FUNC_NAME( PFX ## NUM ## _mc10_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 2] = DSP_FUNC_NAME( PFX ## NUM ## _mc20_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 3] = DSP_FUNC_NAME( PFX ## NUM ## _mc30_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 4] = DSP_FUNC_NAME( PFX ## NUM ## _mc01_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 5] = DSP_FUNC_NAME( PFX ## NUM ## _mc11_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 6] = DSP_FUNC_NAME( PFX ## NUM ## _mc21_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 7] = DSP_FUNC_NAME( PFX ## NUM ## _mc31_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 8] = DSP_FUNC_NAME( PFX ## NUM ## _mc02_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 9] = DSP_FUNC_NAME( PFX ## NUM ## _mc12_pico ); \ ++ c->PFX ## _pixels_tab[IDX][10] = DSP_FUNC_NAME( PFX ## NUM ## _mc22_pico ); \ ++ c->PFX ## _pixels_tab[IDX][11] = DSP_FUNC_NAME( PFX ## NUM ## _mc32_pico ); \ ++ c->PFX ## _pixels_tab[IDX][12] = DSP_FUNC_NAME( PFX ## NUM ## _mc03_pico ); \ ++ c->PFX ## _pixels_tab[IDX][13] = DSP_FUNC_NAME( PFX ## NUM ## _mc13_pico ); \ ++ c->PFX ## _pixels_tab[IDX][14] = DSP_FUNC_NAME( PFX ## NUM ## _mc23_pico ); \ ++ c->PFX ## _pixels_tab[IDX][15] = DSP_FUNC_NAME( PFX ## NUM ## _mc33_pico ) ++ ++#endif ++ ++void dsputil_init_avr32(DSPContext* c, AVCodecContext *avctx) ++{ ++ ++ /* H264 */ ++ ++ if ( 0 /*avr32_use_pico*/ ){ ++ c->put_h264_chroma_pixels_tab[0]= DSP_FUNC_NAME(put_h264_chroma_mc8_pico); ++ c->put_h264_chroma_pixels_tab[1]= DSP_FUNC_NAME(put_h264_chroma_mc4_pico); ++ c->put_h264_chroma_pixels_tab[2]= DSP_FUNC_NAME(put_h264_chroma_mc2_pico); ++ ++ c->avg_h264_chroma_pixels_tab[0]= DSP_FUNC_NAME(avg_h264_chroma_mc8_pico); ++ c->avg_h264_chroma_pixels_tab[1]= DSP_FUNC_NAME(avg_h264_chroma_mc4_pico); ++ c->avg_h264_chroma_pixels_tab[2]= DSP_FUNC_NAME(avg_h264_chroma_mc2_pico); ++ } ++ ++#define dspfunc(PFX, IDX, NUM) \ ++ c->PFX ## _pixels_tab[IDX][ 0] = DSP_FUNC_NAME( PFX ## NUM ## _mc00_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 1] = DSP_FUNC_NAME( PFX ## NUM ## _mc10_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 2] = DSP_FUNC_NAME( PFX ## NUM ## _mc20_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 3] = DSP_FUNC_NAME( PFX ## NUM ## _mc30_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 4] = DSP_FUNC_NAME( PFX ## NUM ## _mc01_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 5] = DSP_FUNC_NAME( PFX ## NUM ## _mc11_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 6] = DSP_FUNC_NAME( PFX ## NUM ## _mc21_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 7] = DSP_FUNC_NAME( PFX ## NUM ## _mc31_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 8] = DSP_FUNC_NAME( PFX ## NUM ## _mc02_pico ); \ ++ c->PFX ## _pixels_tab[IDX][ 9] = DSP_FUNC_NAME( PFX ## NUM ## _mc12_pico ); \ ++ c->PFX ## _pixels_tab[IDX][10] = DSP_FUNC_NAME( PFX ## NUM ## _mc22_pico ); \ ++ c->PFX ## _pixels_tab[IDX][11] = DSP_FUNC_NAME( PFX ## NUM ## _mc32_pico ); \ ++ c->PFX ## _pixels_tab[IDX][12] = DSP_FUNC_NAME( PFX ## NUM ## _mc03_pico ); \ ++ c->PFX ## _pixels_tab[IDX][13] = DSP_FUNC_NAME( PFX ## NUM ## _mc13_pico ); \ ++ c->PFX ## _pixels_tab[IDX][14] = DSP_FUNC_NAME( PFX ## NUM ## _mc23_pico ); \ ++ c->PFX ## _pixels_tab[IDX][15] = DSP_FUNC_NAME( PFX ## NUM ## _mc33_pico ) ++ ++ if ( avr32_use_pico ){ ++ dspfunc(put_h264_qpel, 0, 16); ++ dspfunc(put_h264_qpel, 1, 8); ++ dspfunc(put_h264_qpel, 2, 4); ++ dspfunc(avg_h264_qpel, 0, 16); ++ dspfunc(avg_h264_qpel, 1, 8); ++ dspfunc(avg_h264_qpel, 2, 4); ++ } ++ ++ c->idct_put= DSP_FUNC_NAME(idct_put_avr32); ++ c->idct_add= DSP_FUNC_NAME(idct_add_avr32); ++ c->idct = DSP_FUNC_NAME(idct_avr32); ++ c->h264_idct_add = DSP_FUNC_NAME(h264_idct_add_avr32); ++ c->h264_idct8_add = DSP_FUNC_NAME(h264_idct8_add_avr32); ++ ++ /*c->h264_v_loop_filter_luma= h264_v_loop_filter_luma_avr32;*/ ++ ++ c->idct_permutation_type= FF_TRANSPOSE_IDCT_PERM; ++ ++ c->fdct = fdct_avr32; ++ ++ c->clear_blocks = clear_blocks_avr32; ++ ++#undef dspfunc ++#define dspfunc(PFX, IDX, NUM) \ ++ c->PFX ## _pixels_tab[IDX][0] = DSP_FUNC_NAME( PFX ## _pixels ## NUM ## _avr32 ); \ ++ c->PFX ## _pixels_tab[IDX][1] = DSP_FUNC_NAME( PFX ## _pixels ## NUM ## _h_avr32); \ ++ c->PFX ## _pixels_tab[IDX][2] = DSP_FUNC_NAME( PFX ## _pixels ## NUM ## _v_avr32); \ ++ c->PFX ## _pixels_tab[IDX][3] = DSP_FUNC_NAME( PFX ## _pixels ## NUM ## _hv_avr32) ++ ++ dspfunc(put, 0, 16); ++ dspfunc(put_no_rnd, 0, 16); ++ dspfunc(put, 1, 8); ++ dspfunc(put_no_rnd, 1, 8); ++ ++ dspfunc(avg, 1, 8); ++ dspfunc(avg_no_rnd, 1, 8); ++ dspfunc(avg, 0, 16); ++ dspfunc(avg_no_rnd, 0, 16); ++#undef dspfunc ++ ++} ++ ++ ++ ++#if 0 ++int main(int argc, char *argv[]){ ++ ++ ++} ++#endif ++ +--- /dev/null ++++ b/libavcodec/avr32/fdct.S +@@ -0,0 +1,541 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++ ++//********************************************************** ++//* 2-D fDCT, Based on: * ++//* C. Loeffler, A. Ligtenberg and G. Moschytz, "Practical * ++//* Fast 1-D DCT Algorithms with 11 Multiplications", * ++//* Proc. Int'l. Conf. on Acoustics, Speech, and Signal * ++//* Processing 1989 (ICASSP '89), pp. 988-991. * ++//* * ++//* Fixed point implementation optimized for the AVR-II * ++//* instruction set. If a table is used for the * ++//* coeffisients we can load two and two of them from * ++//* This will give a reduction of ++//* * ++//* * ++//********************************************************** ++ ++ ++/* This routine is a slow-but-accurate integer implementation of the ++ * forward DCT (Discrete Cosine Transform). Taken from the IJG software ++ * ++ * A 2-D DCT can be done by 1-D DCT on each row followed by 1-D DCT ++ * on each column. Direct algorithms are also available, but they are ++ * much more complex and seem not to be any faster when reduced to code. ++ * ++ * This implementation is based on an algorithm described in ++ * C. Loeffler, A. Ligtenberg and G. Moschytz, "Practical Fast 1-D DCT ++ * Algorithms with 11 Multiplications", Proc. Int'l. Conf. on Acoustics, ++ * Speech, and Signal Processing 1989 (ICASSP '89), pp. 988-991. ++ * The primary algorithm described there uses 11 multiplies and 29 adds. ++ * We use their alternate method with 12 multiplies and 32 adds. ++ * The advantage of this method is that no data path contains more than one ++ * multiplication; this allows a very simple and accurate implementation in ++ * scaled fixed-point arithmetic, with a minimal number of shifts. ++ * ++ * The poop on this scaling stuff is as follows: ++ * ++ * Each 1-D DCT step produces outputs which are a factor of sqrt(N) ++ * larger than the true DCT outputs. The final outputs are therefore ++ * a factor of N larger than desired; since N=8 this can be cured by ++ * a simple right shift at the end of the algorithm. The advantage of ++ * this arrangement is that we save two multiplications per 1-D DCT, ++ * because the y0 and y4 outputs need not be divided by sqrt(N). ++ * In the IJG code, this factor of 8 is removed by the quantization step ++ * (in jcdctmgr.c), here it is removed. ++ * ++ * We have to do addition and subtraction of the integer inputs, which ++ * is no problem, and multiplication by fractional constants, which is ++ * a problem to do in integer arithmetic. We multiply all the constants ++ * by CONST_SCALE and convert them to integer constants (thus retaining ++ * CONST_BITS bits of precision in the constants). After doing a ++ * multiplication we have to divide the product by CONST_SCALE, with proper ++ * rounding, to produce the correct output. This division can be done ++ * cheaply as a right shift of CONST_BITS bits. We postpone shifting ++ * as long as possible so that partial sums can be added together with ++ * full fractional precision. ++ * ++ * The outputs of the first pass are scaled up by PASS1_BITS bits so that ++ * they are represented to better-than-integral precision. These outputs ++ * require 8 + PASS1_BITS + 3 bits; this fits in a 16-bit word ++ * with the recommended scaling. (For 12-bit sample data, the intermediate ++ * array is INT32 anyway.) ++ * ++ * To avoid overflow of the 32-bit intermediate results in pass 2, we must ++ * have 8 + CONST_BITS + PASS1_BITS <= 26. Error analysis ++ * shows that the values given below are the most effective. ++ * ++ * We can gain a little more speed, with a further compromise in accuracy, ++ * by omitting the addition in a descaling shift. This yields an incorrectly ++ * rounded result half the time... ++ */ ++ ++ .global fdct_avr32 ++ ++ ++ ++#define CONST_BITS 13 ++#define PASS1_BITS 2 ++ ++#define FIX_0_298631336 2446 /* FIX(0.298631336) */ ++#define FIX_0_390180644 3196 /* FIX(0.390180644) */ ++#define FIX_0_541196100 4433 /* FIX(0.541196100) */ ++#define FIX_0_765366865 6270 /* FIX(0.765366865) */ ++#define FIX_0_899976223 7373 /* FIX(0.899976223) */ ++#define FIX_1_175875602 9633 /* FIX(1.175875602) */ ++#define FIX_1_501321110 12299 /* FIX(1.501321110) */ ++#define FIX_1_847759065 15137 /* FIX(1.847759065) */ ++#define FIX_1_961570560 16069 /* FIX(1.961570560) */ ++#define FIX_2_053119869 16819 /* FIX(2.053119869) */ ++#define FIX_2_562915447 20995 /* FIX(2.562915447) */ ++#define FIX_3_072711026 25172 /* FIX(3.072711026) */ ++ ++ ++/* ++ * Perform an integer forward DCT on one block of samples. ++ */ ++ ++//void ++//fdct_int32(short *const block) ++//{ ++// int tmp0, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6, tmp7; ++// int tmp10, tmp11, tmp12, tmp13; ++// int z1, z2, z3, z4, z5; ++// short *blkptr; ++// int *dataptr; ++// int data[64]; ++// int i; ++// ++// /* Pass 1: process rows. */ ++// /* Note results are scaled up by sqrt(8) compared to a true DCT; */ ++// /* furthermore, we scale the results by 2**PASS1_BITS. */ ++// ++// dataptr = data; ++// blkptr = block; ++ ++ .text ++fdct_avr32: ++ pushm r0-r3, r4-r7, lr ++#define loop_ctr r0 ++#define blkptr r12 ++#define x0 r1 ++#define x1 r2 ++#define x2 r3 ++#define x3 r4 ++#define x4 r5 ++#define x5 r6 ++#define x6 r7 ++#define x7 r8 ++#define tmp0 r5 ++#define tmp7 r2 ++#define tmp1 r3 ++#define tmp6 r4 ++#define tmp2 r9 ++#define tmp5 r8 ++#define tmp3 r7 ++#define tmp4 r6 ++ ++ ++ mov loop_ctr, 8 ++// for (i = 0; i < 8; i++) { ++ROW_LOOP: ++ ++ ldm blkptr, r1, r2, r3, r4 ++ ++// tmp2 = blkptr[2] + blkptr[5]; ++// tmp3 = blkptr[3] + blkptr[4]; ++ paddx.h r5, r3, r2 ++// tmp5 = blkptr[2] - blkptr[5]; ++// tmp4 = blkptr[3] - blkptr[4]; ++ psubx.h r6, r3, r2 ++// tmp0 = blkptr[0] + blkptr[7]; ++// tmp1 = blkptr[1] + blkptr[6]; ++ paddx.h r2, r4, r1 ++// tmp7 = blkptr[0] - blkptr[7]; ++// tmp6 = blkptr[1] - blkptr[6]; ++ psubx.h r3, r4, r1 ++ ++// /* Even part per LL&M figure 1 --- note that published figure is faulty; ++// * rotator "sqrt(2)*c1" should be "sqrt(2)*c6". ++// */ ++ ++#define tmp10 r1 ++#define tmp13 r5 ++#define tmp11 r7 ++#define tmp12 r3 ++#define z1 r9 ++ ++// tmp10 = tmp0 + tmp3; ++// tmp13 = tmp0 - tmp3; ++ paddsub.h r1, r2:t, r5:b ++// tmp11 = tmp1 + tmp2; ++// tmp12 = tmp1 - tmp2; ++ paddsub.h r4, r2:b, r5:t ++ ++ ++// dataptr[0] = (tmp10 + tmp11) << PASS1_BITS; ++// dataptr[4] = (tmp10 - tmp11) << PASS1_BITS; ++ paddsub.h r7, r1:t, r4:t ++ ld.w r10, pc[const_table - .] ++ plsl.h r7, r7, PASS1_BITS ++ ++// z1 = (tmp12 + tmp13) * FIX_0_541196100; ++ addhh.w r8, r4:b, r1:b ++ mulhh.w r8, r8:b, r10:t ++ ++// dataptr[2] = ++// DESCALE(z1 + tmp13 * FIX_0_765366865, CONST_BITS - PASS1_BITS); ++// dataptr[6] = ++// DESCALE(z1 + tmp12 * (-FIX_1_847759065), CONST_BITS - PASS1_BITS); ++ mulhh.w r9, r1:b, r10:b ++ ld.w r10, pc[const_table - . + 4] ++ add r1, r8, r9 ++ satrnds r1 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ mulhh.w r9, r4:b, r10:t ++ add r4, r8, r9 ++ satrnds r4 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ ++// /* Odd part per figure 8 --- note paper omits factor of sqrt(2). ++// * cK represents cos(K*pi/16). ++// * i0..i3 in the paper are tmp4..tmp7 here. ++// */ ++ ++#define z2 r5 ++#define z3 r6 ++#define z4 r7 ++#define z5 r8 ++ ++// z4 = tmp5 + tmp7; ++// z3 = tmp4 + tmp6; ++ padd.h r2, r6, r3 ++// z2 = tmp5 + tmp6; ++// z1 = tmp4 + tmp7; ++ paddx.h r5, r6, r3 ++ ++ lddpc r9, pc[const_table - . + 8] ++// z5 = (z3 + z4) * FIX_1_175875602; /* sqrt(2) * c3 */ ++ addhh.w r8, r2:t, r2:b ++ mulhh.w r8, r8:b, r10:b ++ lddpc r10, pc[const_table - . + 12] ++ ++ ++// tmp4 *= FIX_0_298631336; /* sqrt(2) * (-c1+c3+c5-c7) */ ++ mulhh.w r11, r6:b, r9:t ++ ++// tmp5 *= FIX_2_053119869; /* sqrt(2) * ( c1+c3-c5+c7) */ ++ mulhh.w r6, r6:t, r9:b ++ ++// tmp6 *= FIX_3_072711026; /* sqrt(2) * ( c1+c3+c5-c7) */ ++ lddpc r9, pc[const_table - . + 20] ++ mulhh.w lr, r3:b, r10:t ++ ++// tmp7 *= FIX_1_501321110; /* sqrt(2) * ( c1+c3-c5-c7) */ ++ mulhh.w r3, r3:t, r10:b ++ ++// z3 *= -FIX_1_961570560; /* sqrt(2) * (-c3-c5) */ ++ mulhh.w r10, r2:b, r9:t ++ ++// z4 *= -FIX_0_390180644; /* sqrt(2) * (c5-c3) */ ++ mulhh.w r2, r2:t, r9:b ++ lddpc r9, pc[const_table - . + 16] ++// z3 += z5; ++// z4 += z5; ++ add r10, r8 ++ add r2, r8 ++ ++// z1 *= -FIX_0_899976223; /* sqrt(2) * (c7-c3) */ ++ mulhh.w r8, r5:b, r9:t ++ ++// z2 *= -FIX_2_562915447; /* sqrt(2) * (-c1-c3) */ ++ mulhh.w r5, r5:t, r9:b ++ ++// dataptr[7] = DESCALE(tmp4 + z1 + z3, CONST_BITS - PASS1_BITS); ++ add r11, r8 ++ add r11, r10 ++ satrnds r11 >> (CONST_BITS - PASS1_BITS), 31 ++ ++// dataptr[5] = DESCALE(tmp5 + z2 + z4, CONST_BITS - PASS1_BITS); ++ add r6, r5 ++ ++ sthh.w blkptr[6*2], r4:b, r11:b ++ add r6, r2 ++ satrnds r6 >> (CONST_BITS - PASS1_BITS), 31 ++ ++// dataptr[3] = DESCALE(tmp6 + z2 + z3, CONST_BITS - PASS1_BITS); ++ add lr, r5 ++ sthh.w blkptr[4*2], r7:b, r6:b ++ add lr, r10 ++ satrnds lr >> (CONST_BITS - PASS1_BITS), 31 ++ ++// dataptr[1] = DESCALE(tmp7 + z1 + z4, CONST_BITS - PASS1_BITS); ++ add r3, r8 ++ sthh.w blkptr[2*2], r1:b, lr:b ++ add r3, r2 ++ satrnds r3 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ ++ ++// dataptr += 8; /* advance pointer to next row */ ++// blkptr += 8; ++ sthh.w blkptr[0], r7:t, r3:b ++ sub blkptr, -16 ++ sub loop_ctr, 1 ++ brne ROW_LOOP ++ ++// } ++ ++ /* Pass 2: process columns. ++ * We remove the PASS1_BITS scaling, but leave the results scaled up ++ * by an overall factor of 8. ++ */ ++ ++// dataptr = data; ++ sub blkptr, 128 ++ ++ mov loop_ctr, 4 ++// for (i = 0; i < 8; i++) { ++COLOUMN_LOOP: ++ ld.w r1, blkptr[0] ++ ld.w r2, blkptr[1*8*2] ++ ld.w r3, blkptr[2*8*2] ++ ld.w r4, blkptr[3*8*2] ++ ld.w r5, blkptr[4*8*2] ++ ld.w r6, blkptr[5*8*2] ++ ld.w r7, blkptr[6*8*2] ++ ld.w r8, blkptr[7*8*2] ++ ++// tmp0 = blkptr[0] + blkptr[7*8]; ++ padds.sh r9, r1, r8 ++// tmp7 = blkptr[0] - blkptr[7*8]; ++ psubs.sh r1, r1, r8 ++// tmp1 = blkptr[1*8] + blkptr[6*8]; ++ padds.sh r8, r2, r7 ++// tmp6 = blkptr[1*8] - blkptr[6*8]; ++ psubs.sh r2, r2, r7 ++// tmp2 = blkptr[2*8] + blkptr[5*8]; ++ padds.sh r7, r3, r6 ++// tmp5 = blkptr[2*8] - blkptr[5*8]; ++ psubs.sh r3, r3, r6 ++// tmp3 = blkptr[3*8] + blkptr[4*8]; ++ padds.sh r6, r4, r5 ++// tmp4 = blkptr[3*8] - blkptr[4*8]; ++ psubs.sh r4, r4, r5 ++ ++// /* even part per ll&m figure 1 --- note that published figure is faulty; ++// * rotator "sqrt(2)*c1" should be "sqrt(2)*c6". ++// */ ++// ++// tmp10 = tmp0 + tmp3; ++ padds.sh r5, r9, r6 ++// tmp13 = tmp0 - tmp3; ++ psubs.sh r9, r9, r6 ++// tmp11 = tmp1 + tmp2; ++ padds.sh r6, r8, r7 ++// tmp12 = tmp1 - tmp2; ++ psubs.sh r8, r8, r7 ++ ++// dataptr[0] = DESCALE(tmp10 + tmp11, PASS1_BITS); ++// dataptr[32] = DESCALE(tmp10 - tmp11, PASS1_BITS); ++//Might get an overflow here ++ padds.sh r7, r5, r6 ++ psubs.sh r5, r5, r6 ++ ++ //Rounding ++ mov lr, (1 << (PASS1_BITS + 2)) ++ orh lr, hi(1 << (16 + PASS1_BITS + 2)) ++ padds.sh r7, r7, lr ++ padds.sh r5, r5, lr ++ ++ pasr.h r7, r7, PASS1_BITS + 3 ++ pasr.h r5, r5, PASS1_BITS + 3 ++ st.w r12[0], r7 ++ st.w r12[4*8*2], r5 ++ ++ lddpc r10, const_table2 ++ ++ ++// z1 = (tmp12 + tmp13) * FIX_0_541196100; ++ padds.sh r5, r8, r9 ++ mulhh.w r6, r5:t, r10:t ++ mulhh.w r7, r5:b, r10:t ++ ++// dataptr[16] = ++// DESCALE(z1 + tmp13 * FIX_0_765366865, CONST_BITS + PASS1_BITS); ++ lddpc r11, const_table2 + 4 ++ mulhh.w lr, r9:t, r10:b ++ mulhh.w r9, r9:b, r10:b ++ add lr, r6 ++ add r9, r7 ++ satrnds lr >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r9 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[2*8*2], lr:b, r9:b ++ ++// dataptr[48] = ++// DESCALE(z1 + tmp12 * (-FIX_1_847759065), CONST_BITS + PASS1_BITS); ++ mulhh.w lr, r8:t, r11:t ++ mulhh.w r8, r8:b, r11:t ++ add lr, r6 ++ add r8, r7 ++ satrnds lr >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r8 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[6*8*2], lr:b, r8:b ++ ++// /* Odd part per figure 8 --- note paper omits factor of sqrt(2). ++// * cK represents cos(K*pi/16). ++// * i0..i3 in the paper are tmp4..tmp7 here. ++// */ ++// ++// z2 = tmp5 + tmp6; ++// z3 = tmp4 + tmp6; ++// z4 = tmp5 + tmp7; ++ padds.sh r5, r3, r2 ++ padds.sh r6, r4, r2 ++ padds.sh r7, r3, r1 ++ ++// z5 = (z3 + z4) * FIX_1_175875602; /* sqrt(2) * c3 */ ++ padds.sh r8, r6, r7 ++ mulhh.w r9, r8:t, r11:b ++ mulhh.w r8, r8:b, r11:b ++ ++// z3 *= -FIX_1_961570560; /* sqrt(2) * (-c3-c5) */ ++// z3 += z5; ++ lddpc r11, const_table2 + 8 ++ mulhh.w r10, r6:t, r11:t ++ mulhh.w r6, r6:b, r11:t ++ add r10, r9 ++ add r6, r8 ++ ++// z4 *= -FIX_0_390180644; /* sqrt(2) * (c5-c3) */ ++// z4 += z5; ++ mulhh.w lr, r7:t, r11:b ++ mulhh.w r7, r7:b, r11:b ++ lddpc r11, const_table2 + 12 ++ st.w --sp,r0 ++ add lr, r9 ++ add r7, r8 ++ ++// tmp6 *= FIX_3_072711026; /* sqrt(2) * ( c1+c3+c5-c7) */ ++ mulhh.w r0, r2:t, r11:t ++ machh.w r0, r5:t, r11:b ++ mulhh.w r2, r2:b, r11:t ++ machh.w r2, r5:b, r11:b ++ ++// z2 *= -FIX_2_562915447; /* sqrt(2) * (-c1-c3) */ ++// dataptr[24] = DESCALE(tmp6 + z2 + z3, CONST_BITS + PASS1_BITS); ++ add r0, r10 ++ lddpc r11, const_table2 + 16 ++ add r2, r6 ++ satrnds r0 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r2 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[3*8*2], r0:b, r2:b ++// tmp5 *= FIX_2_053119869; /* sqrt(2) * ( c1+c3-c5+c7) */ ++ mulhh.w r0, r3:t, r11:t ++ machh.w r0, r5:t, r11:b ++ mulhh.w r2, r3:b, r11:t ++ machh.w r2, r5:b, r11:b ++ add r0, lr ++ lddpc r11, const_table2 + 20 ++ add r2, r7 ++ ++// dataptr[40] = DESCALE(tmp5 + z2 + z4, CONST_BITS + PASS1_BITS); ++ satrnds r0 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r2 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[5*8*2], r0:b, r2:b ++ ++ ++// z1 = tmp4 + tmp7; ++ padds.sh r2, r4, r1 ++ ++// tmp4 *= FIX_0_298631336; /* sqrt(2) * (-c1+c3+c5-c7) */ ++ mulhh.w r3, r4:t, r11:t ++ machh.w r3, r2:t, r11:b ++ mulhh.w r4, r4:b, r11:t ++ machh.w r4, r2:b, r11:b ++ add r3, r10 ++ lddpc r11, const_table2 + 24 ++ add r4, r6 ++ ++// z1 *= -FIX_0_899976223; /* sqrt(2) * (c7-c3) */ ++// dataptr[56] = DESCALE(tmp4 + z1 + z3, CONST_BITS + PASS1_BITS); ++ satrnds r3 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r4 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[7*8*2], r3:b, r4:b ++ ++ ++// tmp7 *= FIX_1_501321110; /* sqrt(2) * ( c1+c3-c5-c7) */ ++ mulhh.w r3, r1:t, r11:t ++ machh.w r3, r2:t, r11:b ++ mulhh.w r4, r1:b, r11:t ++ machh.w r4, r2:b, r11:b ++ add r3, lr ++ add r4, r7 ++ ++// dataptr[8] = DESCALE(tmp7 + z1 + z4, CONST_BITS + PASS1_BITS); ++ satrnds r3 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ satrnds r4 >> (CONST_BITS + PASS1_BITS + 3), 31 ++ sthh.w r12[1*8*2], r3:b, r4:b ++ ld.w r0, sp++ ++ ++// dataptr++; /* advance pointer to next column */ ++ sub blkptr, -4 ++ sub loop_ctr, 1 ++ brne COLOUMN_LOOP ++ ++// } ++ ++ popm r0-r3, r4-r7, pc ++ ++// /* descale */ ++// for (i = 0; i < 64; i++) ++// block[i] = (short int) DESCALE(data[i], 3); ++ ++ ++//} ++ ++ ++ .align 2 ++const_table: .short FIX_0_541196100, FIX_0_765366865, -FIX_1_847759065, FIX_1_175875602 ++ .short FIX_0_298631336, FIX_2_053119869, FIX_3_072711026, FIX_1_501321110 ++ .short -FIX_0_899976223,-FIX_2_562915447, -FIX_1_961570560, -FIX_0_390180644 ++ ++const_table2: .short FIX_0_541196100, FIX_0_765366865, -FIX_1_847759065, FIX_1_175875602 ++ .short -FIX_1_961570560, -FIX_0_390180644, FIX_3_072711026, -FIX_2_562915447 ++ .short FIX_2_053119869, -FIX_2_562915447, FIX_0_298631336, -FIX_0_899976223 ++ .short FIX_1_501321110, -FIX_0_899976223 ++ ++ ++ ++ +--- /dev/null ++++ b/libavcodec/avr32/h264idct.S +@@ -0,0 +1,451 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++ ++ .global h264_idct_add_avr32 ++ ++ /* Macro for performing the 1-D transform on one row line. ++ ++ The register 'w01' should contain the first two pixels, ++ and the register 'w23' should contain the last two pixels ++ in the line. The resulting line is placed in p01 and p23 ++ so that { w01, w23 } = { x0, x1, x3, x2 }. ++ 'tmp' and 'tmp2' should be scratchpad registers. */ ++ .macro transform_row w01, w23, tmp, tmp2 ++ add \tmp, \w23, \w01 << 1 /* tmp = { xxxx, 2*w1 + w3 } */ ++ sub \tmp2, \w01, \w23 << 1 /* tmp2 = { xxxx, w1 - 2*w3 } */ ++ bfins \tmp2, \tmp, 16, 16 /* tmp2 = { 2*w1 + w3, w1 - 2*w3 } */ ++ pasr.h \tmp2, \tmp2, 1 /* tmp2 = { w1 + w3/2, w1/2 - w3 } */ ++ paddsub.h \tmp, \w01:t, \w23:t /* tmp = { w0 + w2, w0 - w2 } */ ++ padd.h \w01, \tmp, \tmp2 /* w01 = { w0 + w2 + w1 + w3/2, w0 - w2 + w1/2 - w3 } */ ++ psub.h \w23, \tmp, \tmp2 /* w23 = { w0 + w2 - w1 - w3/2, w0 - w2 - w1/2 + w3 } */ ++ .endm ++ ++ /* Macro for performing the 1-D transform on two columns. ++ ++ The registers w0, w1, w2, w3 should each contain two ++ packed samples from the two colomns to transform. ++ tmp and tmp2 are scratchpad registers. ++ ++ The resulting transformed columns are placed in the ++ same positions as the input columns. ++ */ ++ .macro transform_2columns w0, w1, w2, w3, tmp, tmp2 ++ padd.h \tmp, \w0, \w2 /* tmp = z0 = w0 + w2 */ ++ psub.h \w0, \w0, \w2 /* w0 = z1 = w0 - w2 */ ++ pasr.h \w2, \w1, 1 /* w2 = w1/2 */ ++ pasr.h \tmp2, \w3, 1 /* tmp2 = w3/2 */ ++ psub.h \w3, \w2, \w3 /* w3 = z2 = w1/2 - w3 */ ++ padd.h \tmp2, \w1, \tmp2/* tmp2 = z3 = w1 + w3/2 */ ++ padd.h \w1, \w0, \w3 /* w1 = x1 = z1 + z2 */ ++ psub.h \w2, \w0, \w3 /* w2 = x2 = z1 - z2 */ ++ padd.h \w0, \tmp, \tmp2/* w0 = x0 = z0 + z3 */ ++ psub.h \w3, \tmp, \tmp2/* w3 = x3 = z0 - z3 */ ++ /* Scale down result. */ ++ pasr.h \w0, \w0, 6 ++ pasr.h \w1, \w1, 6 ++ pasr.h \w2, \w2, 6 ++ pasr.h \w3, \w3, 6 ++ .endm ++ ++/*void h264_idct_add_avr32(uint8_t *dst, DCTELEM *block, int stride)*/ ++ ++h264_idct_add_avr32: ++ ++ stm --sp,r0-r3,r4-r7, lr ++ ++ /* Setup rounding factor. */ ++ mov r0, (1 << 5) ++ lsl r0, 16 ++ ++ /* Load block */ ++ ldm r11,r2-r9 ++ /* r9 = { w00, w01 }, ++ r8 = { w02, w03 }, ++ r7 = { w10, w11 }, ++ r6 = { w12, w13 }, ++ r5 = { w20, w21 }, ++ r4 = { w22, w23 }, ++ r3 = { w30, w31 }, ++ r2 = { w32, w33 } */ ++ ++ ++ /* Add the rounding factor to w00. */ ++ add r9, r0 ++ ++ /* Transform rows */ ++ transform_row r9, r8, r0, r1 ++ transform_row r7, r6, r0, r1 ++ transform_row r5, r4, r0, r1 ++ transform_row r3, r2, r0, r1 ++ ++ /* Transform columns */ ++ transform_2columns r9, r7, r5, r3, r0, r1 ++ transform_2columns r8, r6, r4, r2, r0, r1 ++ ++ /* Load predicted pixels.*/ ++ ld.w lr, r12[0] ++ ld.w r11, r12[r10] ++ ++ /* Unpack to halwords. */ ++ punpckub.h r0, lr:t ++ punpckub.h r1, lr:b ++ ++ /* Add with transformed row. */ ++ padd.h r0, r0, r9 ++ paddx.h r1, r1, r8 ++ /* Pack and saturate back to 8-bit pixels. */ ++ packsh.ub r0, r0, r1 ++ ++ /* Unpack to halwords. */ ++ punpckub.h lr, r11:t ++ punpckub.h r11, r11:b ++ ++ /* Add with transformed row. */ ++ padd.h lr, lr, r7 ++ paddx.h r11, r11, r6 ++ /* Pack and saturate back to 8-bit pixels. */ ++ packsh.ub r1, lr, r11 ++ ++ /* Store back to frame. */ ++ st.w r12[0], r0 ++ st.w r12[r10], r1 ++ ++ add r12, r12, r10 << 1 ++ ++ /* Load predicted pixels.*/ ++ ld.w lr, r12[0] ++ ld.w r11, r12[r10] ++ ++ /* Unpack to halwords. */ ++ punpckub.h r0, lr:t ++ punpckub.h r1, lr:b ++ ++ /* Add with transformed row. */ ++ padd.h r0, r0, r5 ++ paddx.h r1, r1, r4 ++ /* Pack and saturate back to 8-bit pixels. */ ++ packsh.ub r0, r0, r1 ++ ++ /* Unpack to halwords. */ ++ punpckub.h lr, r11:t ++ punpckub.h r11, r11:b ++ ++ /* Add with transformed row. */ ++ padd.h lr, lr, r3 ++ paddx.h r11, r11, r2 ++ /* Pack and saturate back to 8-bit pixels. */ ++ packsh.ub r1, lr, r11 ++ ++ /* Store back to frame. */ ++ st.w r12[0], r0 ++ st.w r12[r10], r1 ++ ++ ldm sp++,r0-r3,r4-r7, pc ++ ++ ++ .global h264_idct8_add_avr32 ++//void ff_h264_idct8_add_c(uint8_t *dst, DCTELEM *block, int stride){ ++ ++h264_idct8_add_avr32: ++ stm --sp,r0-r3,r4-r7, lr ++ ++ /* Push dst and stride on stack */ ++ stm --sp,r10,r12 ++ ++// int i; ++// DCTELEM (*src)[8] = (DCTELEM(*)[8])block; ++// uint8_t *cm = cropTbl + MAX_NEG_CROP; ++ ++// block[0] += 32; ++ ++ ++// for( i = 0; i < 8; i++ ) ++// { ++ mov lr, 4 ++0: ++ ld.w r7, r11[0*(8*2)] ++ ld.w r6, r11[1*(8*2)] ++ ld.w r5, r11[2*(8*2)] ++ ld.w r4, r11[3*(8*2)] ++ ld.w r3, r11[4*(8*2)] ++ ld.w r2, r11[5*(8*2)] ++ ld.w r1, r11[6*(8*2)] ++ ld.w r0, r11[7*(8*2)] ++ ++/* ++ ++ const int a0 = src[0][i] + src[4][i]; ++ const int a2 = src[0][i] - src[4][i]; ++ const int a4 = (src[2][i]>>1) - src[6][i]; ++ const int a6 = (src[6][i]>>1) + src[2][i]; ++*/ ++ padd.h r8, r7, r3 /* r8 = a0 */ ++ psub.h r7, r7, r3 /* r7 = a2 */ ++ pasr.h r3, r5, 1 /* r3 = src[2][i] >> 1 */ ++ pasr.h r9, r1, 1 /* r9 = src[6][i] >> 1 */ ++ psub.h r3, r3, r1 /* r3 = a4 */ ++ padd.h r9, r9, r5 /* r9 = a6 */ ++ ++/* ++ const int b0 = a0 + a6; ++ const int b2 = a2 + a4; ++ const int b4 = a2 - a4; ++ const int b6 = a0 - a6; ++*/ ++ padd.h r1, r8, r9 /* r1 = b0 */ ++ psub.h r8, r8, r9 /* r8 = b6 */ ++ padd.h r5, r7, r3 /* r5 = b2 */ ++ psub.h r7, r7, r3 /* r7 = b4 */ ++ ++/* ++ const int a1 = -src[3][i] + src[5][i] - src[7][i] - (src[7][i]>>1); ++ const int a3 = src[1][i] + src[7][i] - src[3][i] - (src[3][i]>>1); ++ const int a5 = -src[1][i] + src[7][i] + src[5][i] + (src[5][i]>>1); ++ const int a7 = src[3][i] + src[5][i] + src[1][i] + (src[1][i]>>1); ++*/ ++ pasr.h r3, r0, 1 ++ padd.h r3, r3, r0 ++ psub.h r3, r2, r3 ++ psub.h r3, r3, r4 /* r3 = a1 */ ++ ++ pasr.h r9, r4, 1 ++ padd.h r9, r9, r4 ++ psub.h r9, r0, r9 ++ padd.h r9, r6, r9 /* r9 = a3 */ ++ ++ pasr.h r10, r2, 1 ++ padd.h r10, r10, r2 ++ padd.h r10, r10, r0 ++ psub.h r10, r10, r6 /* r10 = a5 */ ++ ++ pasr.h r0, r6, 1 ++ padd.h r0, r0, r6 ++ padd.h r0, r0, r2 ++ padd.h r0, r0, r4 /* r0 = a7 */ ++/* ++ const int b1 = (a7>>2) + a1; ++ const int b3 = a3 + (a5>>2); ++ const int b5 = (a3>>2) - a5; ++ const int b7 = a7 - (a1>>2); ++*/ ++ pasr.h r2, r0, 2 ++ padd.h r2, r2, r3 /* r2 = b1 */ ++ pasr.h r3, r3, 2 ++ psub.h r3, r0, r3 /* r3 = b7 */ ++ ++ pasr.h r0, r10, 2 ++ padd.h r0, r0, r9 /* r0 = b3 */ ++ pasr.h r9, r9, 2 ++ psub.h r9, r9, r10 /* r9 = b5 */ ++ ++ ++/* ++ src[0][i] = b0 + b7; ++ src[7][i] = b0 - b7; ++ src[1][i] = b2 + b5; ++ src[6][i] = b2 - b5; ++ src[2][i] = b4 + b3; ++ src[5][i] = b4 - b3; ++ src[3][i] = b6 + b1; ++ src[4][i] = b6 - b1; */ ++ ++ padd.h r4, r1, r3 ++ psub.h r1, r1, r3 ++ st.w r11[0*(8*2)], r4 ++ st.w r11[7*(8*2)], r1 ++ ++ padd.h r3, r5, r9 ++ psub.h r5, r5, r9 ++ st.w r11[1*(8*2)], r3 ++ st.w r11[6*(8*2)], r5 ++ ++ padd.h r9, r7, r0 ++ psub.h r7, r7, r0 ++ st.w r11[2*(8*2)], r9 ++ st.w r11[5*(8*2)], r7 ++ ++ padd.h r0, r8, r2 ++ psub.h r8, r8, r2 ++ st.w r11[3*(8*2)], r0 ++ st.w r11[4*(8*2)], r8 ++ ++ sub r11, -4 ++ sub lr, 1 ++ brne 0b ++ ++// } ++ ++ lddsp r12, sp[0] /* r12 = dst */ ++ sub r11, 4*4 ++ ldm r11++, r4-r7 ++ mov lr, 8 ++ /* Push dst and stride on stack */ ++ ++1: ++// for( i = 0; i < 8; i++ ) ++// { ++ ++ /* r7 = {src[i][0], src[i][1]} ++ r6 = {src[i][2], src[i][3]} ++ r5 = {src[i][4], src[i][5]} ++ r4 = {src[i][6], src[i][7]} */ ++ ++/* ++ const int a0 = src[i][0] + src[i][4]; ++ const int a2 = src[i][0] - src[i][4]; ++ const int a4 = (src[i][2]>>1) - src[i][6]; ++ const int a6 = (src[i][6]>>1) + src[i][2]; ++*/ ++ pasr.h r8, r6, 1 ++ pasr.h r9, r4, 1 ++ addhh.w r0, r7:t, r5:t /* r0 = a0 */ ++ subhh.w r1, r7:t, r5:t /* r1 = a2 */ ++ subhh.w r2, r8:t, r4:t /* r2 = a4 */ ++ addhh.w r3, r9:t, r6:t /* r3 = a6 */ ++ ++/* ++ const int b0 = a0 + a6; ++ const int b2 = a2 + a4; ++ const int b4 = a2 - a4; ++ const int b6 = a0 - a6; ++*/ ++ add r10, r0, r3 /* r10 = b0 */ ++ sub r0, r3 /* r0 = b6 */ ++ add r3, r1, r2 /* r3 = b2 */ ++ sub r1, r2 /* r1 = b4 */ ++/* ++ ++ ++ const int a7 = src[i][5] + src[i][3] + src[i][1] + (src[i][1]>>1); ++ const int a1 = src[i][5] - src[i][3] - src[i][7] - (src[i][7]>>1); ++ const int a3 = src[i][7] + src[i][1] - src[i][3] - (src[i][3]>>1); ++ const int a5 = src[i][7] - src[i][1] + src[i][5] + (src[i][5]>>1); */ ++ addhh.w r8, r8:b, r6:b ++ addhh.w r2, r4:b, r7:b ++ sub r2, r8 /* r2 = a3 */ ++ ++ addhh.w r9, r9:b, r4:b ++ subhh.w r8, r5:b, r6:b ++ sub r8, r9 /* r8 = a1 */ ++ ++ pasr.h r9, r7, 1 ++ addhh.w r9, r9:b, r7:b ++ addhh.w r6, r5:b, r6:b ++ add r6, r9 /* r6 = a7 */ ++ ++ pasr.h r9, r5, 1 ++ addhh.w r9, r9:b, r5:b ++ subhh.w r5, r4:b, r7:b ++ add r5, r9 /* r5 = a5 */ ++ ++/* const int b1 = (a7>>2) + a1; ++ const int b3 = (a5>>2) + a3; ++ const int b5 = (a3>>2) - a5; ++ const int b7 = -(a1>>2) + a7 ; */ ++ asr r4, r6, 2 ++ add r4, r8 /* r4 = b1 */ ++ asr r8, 2 ++ rsub r8, r6 /* r8 = b7 */ ++ ++ asr r6, r5, 2 ++ add r6, r2 /* r6 = b3 */ ++ asr r2, 2 ++ sub r2, r5 /* r2 = b5 */ ++ ++/* ++ dst[i*stride + 0] = cm[ dst[i*stride + 0] + ((b0 + b7) >> 6) ]; ++ dst[i*stride + 1] = cm[ dst[i*stride + 1] + ((b2 + b5) >> 6) ]; ++ dst[i*stride + 2] = cm[ dst[i*stride + 2] + ((b4 + b3) >> 6) ]; ++ dst[i*stride + 3] = cm[ dst[i*stride + 3] + ((b6 + b1) >> 6) ]; ++ dst[i*stride + 4] = cm[ dst[i*stride + 4] + ((b6 - b1) >> 6) ]; ++ dst[i*stride + 5] = cm[ dst[i*stride + 5] + ((b4 - b3) >> 6) ]; ++ dst[i*stride + 6] = cm[ dst[i*stride + 6] + ((b2 - b5) >> 6) ]; ++ dst[i*stride + 7] = cm[ dst[i*stride + 7] + ((b0 - b7) >> 6) ]; ++*/ ++ add r5, r10, r8 ++ satrnds r5 >> 6, 0 /* r5 = (b0 + b7) >> 6 */ ++ sub r10, r8 ++ satrnds r10 >> 6, 0 /* r10 = (b0 - b7) >> 6 */ ++ add r8, r3, r2 ++ satrnds r8 >> 6, 0 /* r8 = (b2 + b5) >> 6 */ ++ sub r3, r2 ++ satrnds r3 >> 6, 0 /* r3 = (b2 - b5) >> 6 */ ++ ++ add r2, r1, r6 ++ satrnds r2 >> 6, 0 /* r2 = (b4 + b3) >> 6 */ ++ sub r1, r6 ++ satrnds r1 >> 6, 0 /* r1 = (b4 - b3) >> 6 */ ++ ++ add r6, r0, r4 ++ satrnds r6 >> 6, 0 /* r6 = (b6 + b1) >> 6 */ ++ sub r0, r4 ++ satrnds r0 >> 6, 0 /* r0 = (b6 - b1) >> 6 */ ++ ++ ld.w r4, r12[0] ++ ++ packw.sh r8, r5, r8 ++ packw.sh r7, r2, r6 ++ ld.w r9, r12[4] ++ packw.sh r6, r0, r1 ++ packw.sh r5, r3, r10 ++ ++ punpckub.h r10, r4:t ++ punpckub.h r4, r4:b ++ punpckub.h r3, r9:t ++ punpckub.h r9, r9:b ++ ++ padd.h r8, r8, r10 ++ padd.h r7, r7, r4 ++ padd.h r6, r6, r3 ++ padd.h r5, r5, r9 ++ ++ lddsp r10, sp[4] /* r10 = stride */ ++ packsh.ub r0, r8, r7 ++ packsh.ub r1, r6, r5 ++ ++ st.w r12[0], r0 ++ st.w r12[4], r1 ++ ++ ldm r11++, r4-r7 ++ add r12, r10 /* dst += stride */ ++ ++ sub lr, 1 ++ brne 1b ++ ++ sub sp, -8 ++ ldm sp++,r0-r3,r4-r7, pc ++ ++ ++ ++// } ++//} +--- /dev/null ++++ b/libavcodec/avr32/idct.S +@@ -0,0 +1,829 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++ ++ .global idct_add_avr32 ++ .global idct_put_avr32 ++ .global idct_avr32 ++ ++ ++#define CONST_BITS 13 ++#define PASS1_BITS 2 ++ ++#define ONE ((INT32) 1) ++ ++#define CONST_SCALE (ONE << CONST_BITS) ++ ++#define LINE_SIZE 32 ++ ++#define FIX_0_298631336 (2446) /* FIX(0.298631336) */ ++#define FIX_0_390180644 (3196) /* FIX(0.390180644) */ ++#define FIX_0_541196100 (4433) /* FIX(0.541196100) */ ++#define FIX_0_765366865 (6270) /* FIX(0.765366865) */ ++#define FIX_0_899976223 (7373) /* FIX(0.899976223) */ ++#define FIX_1_175875602 (9633) /* FIX(1.175875602) */ ++#define FIX_1_501321110 (12299)/* FIX(1.501321110) */ ++#define FIX_1_847759065 (15137)/* FIX(1.847759065) */ ++#define FIX_1_961570560 (16069)/* FIX(1.961570560) */ ++#define FIX_2_053119869 (16819)/* FIX(2.053119869) */ ++#define FIX_2_562915447 (20995)/* FIX(2.562915447) */ ++#define FIX_3_072711026 (25172)/* FIX(3.072711026) */ ++ ++ ++#define loop_cnt r11 ++ ++ .text ++ ++idct_add_avr32: ++ pushm r0-r3, r4-r7, lr //Free up registers to use for local variables ++ ++ // Give room for some variables on the stack ++ sub sp, 8 ++ stdsp SP[0], r12 // rfp ++ stdsp SP[4], r11 // iinc ++ ++ mov loop_cnt, 8 //Initialize loop counter ++ ++FOR_ROW: ++ ++ ldm r10, r0, r1, r2, r3 //Load 8 DCT-coeffisients from the current row in the DCT-block ++ mov r6, 0 ++#ifdef USE_PREFETCH ++ pref r10[LINE_SIZE] //Prefetch next line ++#endif ++ or r4, r2, r3 << 16 ++ or r4, r1 //Check if all DCT-coeffisients except the DC is zero ++ or r4, r0 ++ brne AC_ROW //If there are non-zero AC coeffisients perform row-transform ++ ++ paddsub.h r5, r3:t, r6:b //Extract the DC-coeff from r5 ++ plsl.h r5, r5, PASS1_BITS ++ mov r4, r5 ++ st.d r10++, r4 ++ st.d r10++, r4 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne FOR_ROW //Perform loop one more time if loop_cnt is not zero ++ ++ bral COLOUMN_TRANSFORM //Perform coloumn transform after row transform is computed ++ ++ ++AC_ROW: ++ ++ ++ ld.w r12, pc[coef_table - .] ++ ld.w r9, pc[coef_table - . + 4] ++ ++ padd.h r4, r2, r0 // r4:t = dataptr[2] + dataptr[6],r4:b = dataptr[3] + dataptr[7] ++ mulhh.w r5, r4:t, r12:t ++ mulhh.w r6, r0:t, r12:b ++ ld.w r12, pc[coef_table - . + 8] ++ mulhh.w r7, r2:t, r9:t ++ add r6, r5 // tmp2 ++ satrnds r6 >> (CONST_BITS - PASS1_BITS), 31 ++ add r7, r5 // tmp3 ++ satrnds r7 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r3:t, r1:t ++ plsl.h r5, r5, PASS1_BITS // r5:t = tmp0, r5:b = tmp1 ++ ++ paddsub.h r7, r5:t, r7:b // r7:t = tmp10, r7:b = tmp13 ++ paddsub.h r6, r5:b, r6:b // r6:t = tmp11, r6:b = tmp12 ++ ++ ++ addhh.w lr, r3:b, r1:b // lr = z4 ++ addhh.w r5, r4:b, lr:b ++ mulhh.w r5, r5:b, r9:b // r5 = z5 ++ ++ ld.w r9, pc[coef_table - . + 12] ++ mulhh.w r4, r4:b, r12:t // r4 = z3 ++ mulhh.w lr, lr:b, r12:b // lr = z4 ++ ++ add r4, r5 ++ add lr, r5 ++ ++ addhh.w r5, r2:b, r1:b // r5 = z2 ++ addhh.w r8, r3:b, r0:b // r8 = z1 ++ ++ ++ mulhh.w r0, r0:b, r9:t // r0 = tmp0 ++ ld.w r12, pc[coef_table - . + 16] ++ mulhh.w r1, r1:b, r9:b // r1 = tmp1 ++ ld.w r9, pc[coef_table - . + 20] ++ mulhh.w r2, r2:b, r12:t // r2 = tmp2 ++ mulhh.w r3, r3:b, r12:b // r3 = tmp3 ++ mulhh.w r8, r8:b, r9:t // r8 = z1 ++ mulhh.w r5, r5:b, r9:b // r5 = z2 ++ ++ ++ add r0, r8 ++ add r0, r4 ++ add r1, r5 ++ add r1, lr ++ add r2, r5 ++ add r2, r4 ++ add r3, r8 ++ add r3, lr ++ ++ satrnds r0 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r1 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r2 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r3 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r6:t, r2:b // r5:t = dataptr[1], r5:b = dataptr[6] ++ paddsub.h r4, r7:t, r3:b // r4:t = dataptr[0], r4:b = dataptr[7] ++ paddsub.h r3, r6:b, r1:b // r3:t = dataptr[2], r3:b = dataptr[5] ++ paddsub.h r2, r7:b, r0:b // r2:t = dataptr[3], r2:b = dataptr[4] ++ ++ sthh.w r10[0], r4:t, r5:t ++ sthh.w r10[4], r3:t, r2:t ++ sthh.w r10[8], r2:b, r3:b ++ sthh.w r10[12], r5:b, r4:b ++ ++ ++ ++ sub r10, -16 ++ sub loop_cnt, 1 ++ brne FOR_ROW, e ++ ++COLOUMN_TRANSFORM: ++ ++ sub r10, 128 //Set pointer to start of DCT block ++ ++ ++ mov loop_cnt, 8 ++FOR_COLOUMN: ++ ldins.h r3:t,r10[0] // r3:t = dataptr[0] ++ ldins.h r1:t,r10[1*8*2]// r1:t = dataptr[1] ++ ldins.h r2:t,r10[2*8*2]// r2:t = dataptr[2] ++ ldins.h r0:t,r10[5*8*2]// r0:t = dataptr[5] ++ ldins.h r3:b,r10[4*8*2]// r3:b = dataptr[4] ++ ldins.h r1:b,r10[3*8*2]// r1:b = dataptr[3] ++ ldins.h r2:b,r10[6*8*2]// r2:b = dataptr[6] ++ ldins.h r0:b,r10[7*8*2]// r0:b = dataptr[7] ++ ++ or r4, r1, r3 << 16 ++ or r4, r2 ++ or r4, r0 ++ brne AC_COLOUMN //If there are non-zero AC coeffisients perform row-transform ++ ++ lddsp r12, SP[0] // rfp ++ lddsp r9, SP[4] // iinc ++ satrnds r3 >> ( PASS1_BITS + 3 + 16 ), 9 ++ ld.d r0, r12[0] ++ sub r10, -2 // Increment the dataptr ++ bfins r3, r3, 16, 16 ++ punpckub.h r2, r1:t ++ padd.h r2, r2, r3 ++ punpckub.h r1, r1:b ++ padd.h r1, r1, r3 ++ packsh.ub r1, r2, r1 ++ punpckub.h r2, r0:t ++ padd.h r2, r2, r3 ++ punpckub.h r0, r0:b ++ padd.h r0, r0, r3 ++ packsh.ub r0, r2, r0 ++ st.d r12[0], r0 ++ add r12, r9 // increment rfp ++ stdsp SP[0], r12 ++ ++ sub loop_cnt, 1//Decrement loop counter ++ brne FOR_COLOUMN//Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -8 ++ popm r0-r3, r4-r7, pc//Pop back registers and PC ++ ++AC_COLOUMN: ++ ++ ld.w r12, pc[coef_table - .] ++ ld.w r9, pc[coef_table - . + 4] ++ ++ addhh.w r4, r2:t, r2:b ++ mulhh.w r4, r4:b, r12:t // r4 = z1 ++ mulhh.w r5, r2:b, r12:b ++ ld.w r12, pc[coef_table - . + 8] ++ mulhh.w r6, r2:t, r9:t ++ add r5, r4 // r5 = tmp2 ++ add r6, r4 // r6 = tmp3 ++ ++ addhh.w r7, r3:t, r3:b ++ subhh.w r8, r3:t, r3:b ++ ++ lsl r7, CONST_BITS ++ lsl r8, CONST_BITS ++ ++ add r2, r7, r6 // r2 = tmp10 ++ sub r3, r7, r6 // r3 = tmp13 ++ add r4, r8, r5 // r4 = tmp11 ++ sub r5, r8, r5 // r5 = tmp12 ++ ++ padd.h r6, r0, r1 // r6:t = z4, r6:b = z3 ++ addhh.w r7, r6:t, r6:b ++ mulhh.w r7, r7:b, r9:b // r7 = z5 ++ ++ ld.w r9, pc[coef_table - . + 12] ++ mulhh.w r8, r6:b, r12:t // r8 = z3 ++ mulhh.w r6, r6:t, r12:b // r6 = z4 ++ ++ add r8, r7 ++ add r6, r7 ++ ++ paddx.h r7, r0, r1 // r7:t = z2, r7:b = z1 ++ ++ mulhh.w r12, r0:b, r9:t // r12 = tmp0 ++ mulhh.w r0, r0:t, r9:b // r0 = tmp1 ++ ld.w r9, pc[coef_table - . + 16] ++ add r12, r8 ++ add r0, r6 ++ ++ ld.w lr, pc[coef_table - . + 20] ++ machh.w r8, r1:b, r9:t // r8 = tmp2 ++ machh.w r6, r1:t, r9:b // r6 = tmp3 ++ mulhh.w r9, r7:b, lr:t // r9 = z1 ++ mulhh.w r7, r7:t, lr:b // r7 = z2 ++ ++ ++ add r12, r9 ++ add r0, r7 ++ add r8, r7 ++ add r6, r9 ++ ++ add r1, r2, r6 // r1 = dataptr[DCTSIZE*0] ++ sub r2, r2, r6 // r2 = dataptr[DCTSIZE*7] ++ add r6, r4, r8 // r6 = dataptr[DCTSIZE*1] ++ sub r4, r4, r8 // r4 = dataptr[DCTSIZE*6] ++ add r8, r5, r0 // r8 = dataptr[DCTSIZE*2] ++ sub r5, r5, r0 // r5 = dataptr[DCTSIZE*5] ++ add r0, r3, r12 // r0 = dataptr[DCTSIZE*3] ++ sub r3, r3, r12 // r3 = dataptr[DCTSIZE*4] ++ ++ satrnds r1 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r2 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r6 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r4 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r8 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r5 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r0 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r3 >> (CONST_BITS+PASS1_BITS+3), 9 ++ ++ packw.sh r1, r1, r6 ++ packw.sh r8, r8, r0 ++ packw.sh r3, r3, r5 ++ packw.sh r4, r4, r2 ++ ++ lddsp r12, SP[0] // rfp ++ lddsp r9, SP[4] // iinc ++ ld.d r6, r12[0] ++ sub r10, -2 // Increment the dataptr ++ punpckub.h r0, r7:t ++ padd.h r1, r1, r0 ++ punpckub.h r0, r7:b ++ padd.h r8, r8, r0 ++ packsh.ub r7, r1, r8 ++ punpckub.h r0, r6:t ++ padd.h r3, r3, r0 ++ punpckub.h r0, r6:b ++ padd.h r4, r4, r0 ++ packsh.ub r6, r3, r4 ++ st.d r12[0], r6 ++ add r12, r9 // increment rfp ++ stdsp SP[0], r12 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne FOR_COLOUMN //Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -8 ++ popm r0-r3, r4-r7, pc //Pop back registers and PC ++ ++ ++ ++//Coeffisient Table: ++ .align 2 ++coef_table: ++ .short FIX_0_541196100, -FIX_1_847759065, FIX_0_765366865, FIX_1_175875602 ++ .short - FIX_1_961570560, - FIX_0_390180644, FIX_0_298631336, FIX_2_053119869 ++ .short FIX_3_072711026, FIX_1_501321110, - FIX_0_899976223, - FIX_2_562915447 ++ ++ ++idct_put_avr32: ++ pushm r0-r3, r4-r7, lr //Free up registers to use for local variables ++ ++ //; Give room for some variables on the stack ++ sub sp, 8 ++ stdsp SP[0], r12 // rfp ++ stdsp SP[4], r11 // iinc ++ ++ mov loop_cnt, 8 //Initialize loop counter ++ ++0: ++ ++ ldm r10, r0, r1, r2, r3 //Load 8 DCT-coeffisients from the current row in the DCT-block ++ mov r6, 0 ++#ifdef USE_PREFETCH ++ pref r10[LINE_SIZE] //Prefetch next line ++#endif ++ or r4, r2, r3 << 16 ++ or r4, r1 //Check if all DCT-coeffisients except the DC is zero ++ or r4, r0 ++ brne 1f //If there are non-zero AC coeffisients perform row-transform ++ ++ paddsub.h r5, r3:t, r6:b //Extract the DC-coeff from r5 ++ plsl.h r5, r5, PASS1_BITS ++ mov r4, r5 ++ st.d r10++, r4 ++ st.d r10++, r4 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ bral 2f //Perform coloumn transform after row transform is computed ++ ++1: ++ ++ ld.w r12, pc[coef_table_copy - .] ++ ld.w r9, pc[coef_table_copy - . + 4] ++ ++ padd.h r4, r2, r0 // r4:t = dataptr[2] + dataptr[6],r4:b = dataptr[3] + dataptr[7] ++ mulhh.w r5, r4:t, r12:t ++ mulhh.w r6, r0:t, r12:b ++ ld.w r12, pc[coef_table_copy - . + 8] ++ mulhh.w r7, r2:t, r9:t ++ add r6, r5 // tmp2 ++ satrnds r6 >> (CONST_BITS - PASS1_BITS), 31 ++ add r7, r5 // tmp3 ++ satrnds r7 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r3:t, r1:t ++ plsl.h r5, r5, PASS1_BITS // r5:t = tmp0, r5:b = tmp1 ++ ++ paddsub.h r7, r5:t, r7:b // r7:t = tmp10, r7:b = tmp13 ++ paddsub.h r6, r5:b, r6:b // r6:t = tmp11, r6:b = tmp12 ++ ++ ++ ++ addhh.w lr, r3:b, r1:b // lr = z4 ++ addhh.w r5, r4:b, lr:b ++ mulhh.w r5, r5:b, r9:b // r5 = z5 ++ ++ ld.w r9, pc[coef_table_copy - . + 12] ++ mulhh.w r4, r4:b, r12:t // r4 = z3 ++ mulhh.w lr, lr:b, r12:b // lr = z4 ++ ++ add r4, r5 ++ add lr, r5 ++ ++ addhh.w r5, r2:b, r1:b // r5 = z2 ++ addhh.w r8, r3:b, r0:b // r8 = z1 ++ ++ ++ mulhh.w r0, r0:b, r9:t // r0 = tmp0 ++ ld.w r12, pc[coef_table_copy - . + 16] ++ mulhh.w r1, r1:b, r9:b // r1 = tmp1 ++ ld.w r9, pc[coef_table_copy - . + 20] ++ mulhh.w r2, r2:b, r12:t // r2 = tmp2 ++ mulhh.w r3, r3:b, r12:b // r3 = tmp3 ++ mulhh.w r8, r8:b, r9:t // r8 = z1 ++ mulhh.w r5, r5:b, r9:b // r5 = z2 ++ ++ ++ add r0, r8 ++ add r0, r4 ++ add r1, r5 ++ add r1, lr ++ add r2, r5 ++ add r2, r4 ++ add r3, r8 ++ add r3, lr ++ ++ satrnds r0 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r1 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r2 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r3 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r6:t, r2:b // r5:t = dataptr[1], r5:b = dataptr[6] ++ paddsub.h r4, r7:t, r3:b // r4:t = dataptr[0], r4:b = dataptr[7] ++ paddsub.h r3, r6:b, r1:b // r3:t = dataptr[2], r3:b = dataptr[5] ++ paddsub.h r2, r7:b, r0:b // r2:t = dataptr[3], r2:b = dataptr[4] ++ ++ sthh.w r10[0], r4:t, r5:t ++ sthh.w r10[4], r3:t, r2:t ++ sthh.w r10[8], r2:b, r3:b ++ sthh.w r10[12], r5:b, r4:b ++ ++ ++ ++ sub r10, -16 ++ sub loop_cnt, 1 ++ brne 0b ++ ++2: ++ ++ sub r10, 128 //Set pointer to start of DCT block ++ ++ mov loop_cnt, 8 ++ ++0: ++ ldins.h r3:t,r10[0] // r3:t = dataptr[0] ++ ldins.h r1:t,r10[1*8*2]// r1:t = dataptr[1] ++ ldins.h r2:t,r10[2*8*2]// r2:t = dataptr[2] ++ ldins.h r0:t,r10[5*8*2]// r0:t = dataptr[5] ++ ldins.h r3:b,r10[4*8*2]// r3:b = dataptr[4] ++ ldins.h r1:b,r10[3*8*2]// r1:b = dataptr[3] ++ ldins.h r2:b,r10[6*8*2]// r2:b = dataptr[6] ++ ldins.h r0:b,r10[7*8*2]// r0:b = dataptr[7] ++ ++ or r4, r1, r3 << 16 ++ or r4, r2 ++ or r4, r0 ++ brne 1f //If there are non-zero AC coeffisients perform row-transform ++ ++ lddsp r12, SP[0] // rfp ++ lddsp r9, SP[4] // iinc ++ satrnds r3 >> ( PASS1_BITS + 3 + 16 ), 31 ++ packw.sh r3, r3, r3 ++ packsh.ub r3, r3, r3 ++ mov r2, r3 ++ st.d r12[0], r2 ++ add r12, r9 // increment rfp ++ sub r10, -2 // Increment the dataptr ++ stdsp SP[0], r12 ++ ++ sub loop_cnt, 1//Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -8 ++ popm r0-r3, r4-r7, pc//Pop back registers and PC ++ ++1: ++ ++ ld.w r12, pc[coef_table_copy - .] ++ ld.w r9, pc[coef_table_copy - . + 4] ++ ++ addhh.w r4, r2:t, r2:b ++ mulhh.w r4, r4:b, r12:t // r4 = z1 ++ mulhh.w r5, r2:b, r12:b ++ ld.w r12, pc[coef_table_copy - . + 8] ++ mulhh.w r6, r2:t, r9:t ++ add r5, r4 // r5 = tmp2 ++ add r6, r4 // r6 = tmp3 ++ ++ addhh.w r7, r3:t, r3:b ++ subhh.w r8, r3:t, r3:b ++ ++ lsl r7, CONST_BITS ++ lsl r8, CONST_BITS ++ ++ add r2, r7, r6 // r2 = tmp10 ++ sub r3, r7, r6 // r3 = tmp13 ++ add r4, r8, r5 // r4 = tmp11 ++ sub r5, r8, r5 // r5 = tmp12 ++ ++ ++ padd.h r6, r0, r1 // r6:t = z4, r6:b = z3 ++ addhh.w r7, r6:t, r6:b ++ mulhh.w r7, r7:b, r9:b // r7 = z5 ++ ++ ld.w r9, pc[coef_table_copy - . + 12] ++ mulhh.w r8, r6:b, r12:t // r8 = z3 ++ mulhh.w r6, r6:t, r12:b // r6 = z4 ++ ++ add r8, r7 ++ add r6, r7 ++ ++ paddx.h r7, r0, r1 // r7:t = z2, r7:b = z1 ++ ++ mulhh.w r12, r0:b, r9:t // r12 = tmp0 ++ mulhh.w r0, r0:t, r9:b // r0 = tmp1 ++ ld.w r9, pc[coef_table_copy - . + 16] ++ add r12, r8 ++ add r0, r6 ++ ++ ld.w lr, pc[coef_table_copy - . + 20] ++ machh.w r8, r1:b, r9:t // r8 = tmp2 ++ machh.w r6, r1:t, r9:b // r6 = tmp3 ++ mulhh.w r9, r7:b, lr:t // r9 = z1 ++ mulhh.w r7, r7:t, lr:b // r7 = z2 ++ ++ ++ add r12, r9 ++ add r0, r7 ++ add r8, r7 ++ add r6, r9 ++ ++ add r1, r2, r6 // r1 = dataptr[DCTSIZE*0] ++ sub r2, r2, r6 // r2 = dataptr[DCTSIZE*7] ++ add r6, r4, r8 // r6 = dataptr[DCTSIZE*1] ++ sub r4, r4, r8 // r4 = dataptr[DCTSIZE*6] ++ add r8, r5, r0 // r8 = dataptr[DCTSIZE*2] ++ sub r5, r5, r0 // r5 = dataptr[DCTSIZE*5] ++ add r0, r3, r12 // r0 = dataptr[DCTSIZE*3] ++ sub r3, r3, r12 // r3 = dataptr[DCTSIZE*4] ++ ++ satrnds r1 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r2 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r6 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r4 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r8 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r5 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r0 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r3 >> (CONST_BITS+PASS1_BITS+3), 9 ++ ++ packw.sh r1, r1, r6 ++ packw.sh r8, r8, r0 ++ packw.sh r3, r3, r5 ++ packw.sh r4, r4, r2 ++ ++ packsh.ub r1, r1, r8 ++ packsh.ub r0, r3, r4 ++ lddsp r12, SP[0] // rfp ++ lddsp r9, SP[4] // iinc ++ st.d r12[0], r0 ++ sub r10, -2 // Increment the dataptr ++ add r12, r9 // increment rfp ++ stdsp SP[0], r12 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -8 ++ popm r0-r3, r4-r7, pc //Pop back registers and PC ++ ++ ++ ++ .align 2 ++coef_table_copy: ++ .short FIX_0_541196100, -FIX_1_847759065, FIX_0_765366865, FIX_1_175875602 ++ .short - FIX_1_961570560, - FIX_0_390180644, FIX_0_298631336, FIX_2_053119869 ++ .short FIX_3_072711026, FIX_1_501321110, - FIX_0_899976223, - FIX_2_562915447 ++ ++ ++idct_avr32: ++ pushm r0-r3, r4-r7, lr //Free up registers to use for local variables ++ ++ //; Give room for a temporary block on the stack ++ sub sp, 8*8*2 ++ ++ mov loop_cnt, 8 //Initialize loop counter ++ ++0: ++ ++ ldm r12++, r0, r1, r2, r3 //Load 8 DCT-coeffisients from the current row in the DCT-block ++ mov r6, 0 ++#ifdef USE_PREFETCH ++ pref r12[LINE_SIZE] //Prefetch next line ++#endif ++ or r4, r2, r3 << 16 ++ or r4, r1 //Check if all DCT-coeffisients except the DC is zero ++ or r4, r0 ++ brne 1f //If there are non-zero AC coeffisients perform row-transform ++ ++ paddsub.h r5, r3:t, r6:b //Extract the DC-coeff from r5 ++ plsl.h r5, r5, PASS1_BITS ++ mov r4, r5 ++ st.d sp++, r4 ++ st.d sp++, r4 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ bral 2f //Perform coloumn transform after row transform is computed ++ ++1: ++ ++ ld.w r10, pc[coef_table_idct - .] ++ ld.w r9, pc[coef_table_idct - . + 4] ++ ++ padd.h r4, r2, r0 // r4:t = dataptr[2] + dataptr[6],r4:b = dataptr[3] + dataptr[7] ++ mulhh.w r5, r4:t, r10:t ++ mulhh.w r6, r0:t, r10:b ++ ld.w r10, pc[coef_table_idct - . + 8] ++ mulhh.w r7, r2:t, r9:t ++ add r6, r5 // tmp2 ++ satrnds r6 >> (CONST_BITS - PASS1_BITS), 31 ++ add r7, r5 // tmp3 ++ satrnds r7 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r3:t, r1:t ++ plsl.h r5, r5, PASS1_BITS // r5:t = tmp0, r5:b = tmp1 ++ ++ paddsub.h r7, r5:t, r7:b // r7:t = tmp10, r7:b = tmp13 ++ paddsub.h r6, r5:b, r6:b // r6:t = tmp11, r6:b = tmp12 ++ ++ ++ ++ addhh.w lr, r3:b, r1:b // lr = z4 ++ addhh.w r5, r4:b, lr:b ++ mulhh.w r5, r5:b, r9:b // r5 = z5 ++ ++ ld.w r9, pc[coef_table_idct - . + 12] ++ mulhh.w r4, r4:b, r10:t // r4 = z3 ++ mulhh.w lr, lr:b, r10:b // lr = z4 ++ ++ add r4, r5 ++ add lr, r5 ++ ++ addhh.w r5, r2:b, r1:b // r5 = z2 ++ addhh.w r8, r3:b, r0:b // r8 = z1 ++ ++ ++ mulhh.w r0, r0:b, r9:t // r0 = tmp0 ++ ld.w r10, pc[coef_table_idct - . + 16] ++ mulhh.w r1, r1:b, r9:b // r1 = tmp1 ++ ld.w r9, pc[coef_table_idct - . + 20] ++ mulhh.w r2, r2:b, r10:t // r2 = tmp2 ++ mulhh.w r3, r3:b, r10:b // r3 = tmp3 ++ mulhh.w r8, r8:b, r9:t // r8 = z1 ++ mulhh.w r5, r5:b, r9:b // r5 = z2 ++ ++ ++ add r0, r8 ++ add r0, r4 ++ add r1, r5 ++ add r1, lr ++ add r2, r5 ++ add r2, r4 ++ add r3, r8 ++ add r3, lr ++ ++ satrnds r0 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r1 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r2 >> (CONST_BITS - PASS1_BITS), 31 ++ satrnds r3 >> (CONST_BITS - PASS1_BITS), 31 ++ ++ paddsub.h r5, r6:t, r2:b // r5:t = dataptr[1], r5:b = dataptr[6] ++ paddsub.h r4, r7:t, r3:b // r4:t = dataptr[0], r4:b = dataptr[7] ++ paddsub.h r3, r6:b, r1:b // r3:t = dataptr[2], r3:b = dataptr[5] ++ paddsub.h r2, r7:b, r0:b // r2:t = dataptr[3], r2:b = dataptr[4] ++ ++ sthh.w sp[0], r4:t, r5:t ++ sthh.w sp[4], r3:t, r2:t ++ sthh.w sp[8], r2:b, r3:b ++ sthh.w sp[12], r5:b, r4:b ++ ++ ++ ++ sub sp, -16 ++ sub loop_cnt, 1 ++ brne 0b ++ ++2: ++ ++ sub sp, 8*8*2 //Set pointer to start of DCT block ++ sub r12, 8*8*2 //Set pointer to start of DCT block ++ ++ mov loop_cnt, 8 ++ ++0: ++ ldins.h r3:t,sp[0] // r3:t = dataptr[0] ++ ldins.h r1:t,sp[1*8*2]// r1:t = dataptr[1] ++ ldins.h r2:t,sp[2*8*2]// r2:t = dataptr[2] ++ ldins.h r0:t,sp[5*8*2]// r0:t = dataptr[5] ++ ldins.h r3:b,sp[4*8*2]// r3:b = dataptr[4] ++ ldins.h r1:b,sp[3*8*2]// r1:b = dataptr[3] ++ ldins.h r2:b,sp[6*8*2]// r2:b = dataptr[6] ++ ldins.h r0:b,sp[7*8*2]// r0:b = dataptr[7] ++ ++ or r4, r1, r3 << 16 ++ or r4, r2 ++ or r4, r0 ++ brne 1f //If there are non-zero AC coeffisients perform row-transform ++ ++ satrnds r3 >> ( PASS1_BITS + 3 + 16 ), 31 ++ packw.sh r3, r3, r3 ++ mov r2, r3 ++ st.d r12++, r2 ++ st.d r12++, r2 ++ sub sp, -2 // Increment the dataptr ++ ++ sub loop_cnt, 1//Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -(8*8*2 - 8) ++ popm r0-r3, r4-r7, pc//Pop back registers and PC ++ ++1: ++ ++ ld.w r10, pc[coef_table_idct - .] ++ ld.w r9, pc[coef_table_idct - . + 4] ++ ++ addhh.w r4, r2:t, r2:b ++ mulhh.w r4, r4:b, r10:t // r4 = z1 ++ mulhh.w r5, r2:b, r10:b ++ ld.w r10, pc[coef_table_idct - . + 8] ++ mulhh.w r6, r2:t, r9:t ++ add r5, r4 // r5 = tmp2 ++ add r6, r4 // r6 = tmp3 ++ ++ addhh.w r7, r3:t, r3:b ++ subhh.w r8, r3:t, r3:b ++ ++ lsl r7, CONST_BITS ++ lsl r8, CONST_BITS ++ ++ add r2, r7, r6 // r2 = tmp10 ++ sub r3, r7, r6 // r3 = tmp13 ++ add r4, r8, r5 // r4 = tmp11 ++ sub r5, r8, r5 // r5 = tmp12 ++ ++ ++ padd.h r6, r0, r1 // r6:t = z4, r6:b = z3 ++ addhh.w r7, r6:t, r6:b ++ mulhh.w r7, r7:b, r9:b // r7 = z5 ++ ++ ld.w r9, pc[coef_table_idct - . + 12] ++ mulhh.w r8, r6:b, r10:t // r8 = z3 ++ mulhh.w r6, r6:t, r10:b // r6 = z4 ++ ++ add r8, r7 ++ add r6, r7 ++ ++ paddx.h r7, r0, r1 // r7:t = z2, r7:b = z1 ++ ++ mulhh.w r10, r0:b, r9:t // r10 = tmp0 ++ mulhh.w r0, r0:t, r9:b // r0 = tmp1 ++ ld.w r9, pc[coef_table_idct - . + 16] ++ add r10, r8 ++ add r0, r6 ++ ++ ld.w lr, pc[coef_table_idct - . + 20] ++ machh.w r8, r1:b, r9:t // r8 = tmp2 ++ machh.w r6, r1:t, r9:b // r6 = tmp3 ++ mulhh.w r9, r7:b, lr:t // r9 = z1 ++ mulhh.w r7, r7:t, lr:b // r7 = z2 ++ ++ ++ add r10, r9 ++ add r0, r7 ++ add r8, r7 ++ add r6, r9 ++ ++ add r1, r2, r6 // r1 = dataptr[DCTSIZE*0] ++ sub r2, r2, r6 // r2 = dataptr[DCTSIZE*7] ++ add r6, r4, r8 // r6 = dataptr[DCTSIZE*1] ++ sub r4, r4, r8 // r4 = dataptr[DCTSIZE*6] ++ add r8, r5, r0 // r8 = dataptr[DCTSIZE*2] ++ sub r5, r5, r0 // r5 = dataptr[DCTSIZE*5] ++ add r0, r3, r10 // r0 = dataptr[DCTSIZE*3] ++ sub r3, r3, r10 // r3 = dataptr[DCTSIZE*4] ++ ++ satrnds r1 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r2 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r6 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r4 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r8 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r5 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r0 >> (CONST_BITS+PASS1_BITS+3), 9 ++ satrnds r3 >> (CONST_BITS+PASS1_BITS+3), 9 ++ ++ packw.sh r7, r1, r6 ++ packw.sh r6, r8, r0 ++ packw.sh r5, r3, r5 ++ packw.sh r4, r4, r2 ++ ++ stm r12, r4-r7 ++ sub sp, -2 // Increment the dataptr ++ sub r12, -16 ++ ++ sub loop_cnt, 1 //Decrement loop counter ++ brne 0b //Perform loop one more time if loop_cnt is not zero ++ ++ sub sp, -(8*8*2 - 8) ++ popm r0-r3, r4-r7, pc //Pop back registers and PC ++ ++ ++ ++ .align 2 ++coef_table_idct: ++ .short FIX_0_541196100, -FIX_1_847759065, FIX_0_765366865, FIX_1_175875602 ++ .short - FIX_1_961570560, - FIX_0_390180644, FIX_0_298631336, FIX_2_053119869 ++ .short FIX_3_072711026, FIX_1_501321110, - FIX_0_899976223, - FIX_2_562915447 ++ +--- /dev/null ++++ b/libavcodec/avr32/mc.S +@@ -0,0 +1,434 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++ ++ ++ /* Macro for masking the lowest bit of each byte in a ++ packed word */ ++ .macro packedmask1 reg, round ++ .if \round ++ and \reg, \reg, r8 >> 1 ++ .else ++ and \reg, r8 ++ .endif ++ .endm ++ ++ /* Macro for 8 pixel wide horizontal and vertical interpolation functions */ ++ .macro pixels8_hv round, put ++ ++ ++ pushm r0-r7, lr ++ ++ /* R12 = uint8_t *block, R11 = uint8_t pixels, R10 = int line_size, R9 = int h */ ++ ++ /* Rounding immediate */ ++ .if \round ++ mov r8, lo(0x02020202) ++ orh r8, hi(0x02020202) ++ .else ++ mov r8, lo(0x01010101) ++ orh r8, hi(0x01010101) ++ .endif ++ mov r7, 2 ++ ++ /* Pixel naming convention : ++ ++ |-----------------------------------------------------| ++ | s00 | s01 | s02 | s03 | s04 | s05 | s06 | s07 | s08 | ++ |----d00---d01---d02---d03---d04---d05---d06---d07----| ++ | s10 | s11 | s12 | s13 | s14 | s15 | s16 | s17 | s18 | ++ |-----------------------------------------------------| ++ */ ++1: ++ ld.w r0, r11[0] // r0 = { s00, s01, s02, s03 } ++ ld.w r1, r11[1] // r1 = { s01, s02, s03, s04 } ++ mov lr, r9 ++ eor r2, r0, r1 ++ packedmask1 r2, \round ++ add r2, r8 ++ ++ paddh.ub r0, r0, r1 // r0 = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ ++ add r11, r10 // pixels += line_size ++ ld.w r1, r11[0] // r1 = { s10, s11, s12, s13 } ++ ld.w r3, r11[1] // r3 = { s11, s12, s13, s14 } ++0: ++ eor r5, r1, r3 ++ packedmask1 r5, \round ++ add r2, r5 ++ ++ paddh.ub r1, r1, r3 // r1 = {(s10+s11)/2,(s11+s12)/2,(s12+s13)/2,(s13+s14)/2} ++ eor r6, r0, r1 ++ packedmask1 r6, \round ++ add r2, r2, r6 << 1 ++ ++ ld.w r3, r11[r10] // r3 = { s00, s01, s02, s03 } ++ add r11, r10 // pixels += line_size ++ ld.w r4, r11[1] // r4 = { s01, s02, s03, s04 } ++ ++ paddh.ub r0, r0, r1 ++ plsr.b r2, r2, 2 ++ padd.b r0, r0, r2 // r0 = { d00, d01, d02, d03 } ++ ++ /* Next row */ ++ .if \put ++ eor r2, r3, r4 ++ packedmask1 r2, \round ++ add r2, r8 ++ .else ++ ld.w r6, r12[0] ++ eor r2, r3, r4 ++ packedmask1 r2, \round ++ add r2, r8 ++ pavg.ub r0, r0, r6 ++ .endif ++ st.w r12[0], r0 // Put data into the block ++ ++ add r5, r2 ++ paddh.ub r0, r3, r4 // r0 = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ ++ eor r6, r0, r1 ++ packedmask1 r6, \round ++ add r5, r5, r6 << 1 ++ ++ .if \put ++ paddh.ub r1, r0, r1 ++ plsr.b r5, r5, 2 ++ padd.b r1, r1, r5 // r1 = { d10, d11, d12, d13 } ++ .else ++ ld.w r3, r12[r10] ++ paddh.ub r1, r0, r1 ++ plsr.b r5, r5, 2 ++ padd.b r1, r1, r5 // r1 = { d10, d11, d12, d13 } ++ pavg.ub r1, r1, r3 ++ .endif ++ ++ st.w r12[r10], r1 // Put data into the block ++ ++ ++ ld.w r1, r11[r10] // r1 = { s10, s11, s12, s13 } ++ add r11, r10 // pixels += line_size ++ ld.w r3, r11[1] // r3 = { s11, s12, s13, s14 } ++ add r12, r12, r10 << 1 // block += 2*line_size ++ sub lr, 2 ++ brne 0b ++ ++ mul r0, r10, r9 // r0 = line_size * h ++ rsub r0, r0, 4 // r0 = 4 - (line_size * h) ++ add r11, r0 ++ sub r11, r10 // pixels += 4 - (line_size * (h+1)) ++ add r12, r0 // pixels += 4 - (line_size * (h)) ++ sub r7, 1 ++ brne 1b ++ ++ popm r0-r7, pc ++ .endm ++ ++ ++ /* Macro for 8 pixel wide vertical interpolation functions */ ++ ++ .macro pixels8_v round, put ++ pushm r4-r7,lr ++ /* R12 = uint8_t *block, R11 = uint8_t pixels, R10 = int line_size, R9 = int h */ ++ ++ /* ++ Pixel Naming Convention : ++ |-----------------------------------------------| ++ | s00 | s01 | s02 | s03 | s04 | s05 | s06 | s07 | ++ |-d00---d01---d02---d03---d04---d05---d06---d07-| ++ | s10 | s11 | s12 | s13 | s14 | s15 | s16 | s17 | ++ |-----------------------------------------------| ++ */ ++ ld.w r8, r11[r10] // r8 = { s10, s11, s12, s13 } ++ ld.w lr, r11++ // lr = { s00, s01, s02, s03 }, src += 4 ++ ld.w r7, r11[0] // r7 = { s04, s05, s06, s07 } ++ ld.w r6, r11[r10] // r6 = { s14, s15, s16, s17 } ++ sub r10, 4 // stride -= 4 ++ add r11, r11, r10 << 1 // src += 2*stride ++ sub r11, -4 // src += 4 ++ ++0: ++ .if \round ++ pavg.ub r5, r8, lr // r5 = {(s10+s00)/2,(s11+s01)/2,(s12+s02)/2,(s13+s03)/2} ++ pavg.ub r4, r6, r7 // r4 = {(s14+s04)/2,(s15+s05)/2,(s16+s06)/2,(s17+s07)/2} ++ .else ++ paddh.ub r5, r8, lr // r5 = {(s10+s00)/2,(s11+s01)/2,(s12+s02)/2,(s13+s03)/2} ++ paddh.ub r4, r6, r7 // r4 = {(s14+s04)/2,(s15+s05)/2,(s16+s06)/2,(s17+s07)/2} ++ .endif ++ ++ .if \put ++ st.w r12++, r5 // *dst++ = { d00, d01, d02, d03 } ++ ld.w lr, r11++ // lr = { s10, s11, s12, s13 }, src += 4 ++ st.w r12[0], r4 // *dst = { d04, d05, d06, d07 } ++ ld.w r7, r11[0] // r7 = { s14, s15, s16, s17 } ++ .else ++ ld.w lr, r12[0] ++ ld.w r7, r12[4] ++ pavg.ub r5, r5, lr ++ pavg.ub r4, r4, r7 ++ st.w r12++, r5 // *dst++ = { d00, d01, d02, d03 } ++ ld.w lr, r11++ // lr = { s10, s11, s12, s13 }, src += 4 ++ st.w r12[0], r4 // *dst = { d04, d05, d06, d07 } ++ ld.w r7, r11[0] // r7 = { s14, s15, s16, s17 } ++ .endif ++ add r11, r10 // src += stride ++#ifdef USE_PREFETCH ++ pref r11[0] ++#endif ++ add r12, r10 // dst += stride ++ ++ .if \round ++ pavg.ub r5, r8, lr // r5 = {(s10+s00)/2,(s11+s01)/2,(s12+s02)/2,(s13+s03)/2} ++ pavg.ub r4, r6, r7 // r4 = {(s14+s04)/2,(s15+s05)/2,(s16+s06)/2,(s17+s07)/2} ++ .else ++ paddh.ub r5, r8, lr // r5 = {(s10+s00)/2,(s11+s01)/2,(s12+s02)/2,(s13+s03)/2} ++ paddh.ub r4, r6, r7 // r4 = {(s14+s04)/2,(s15+s05)/2,(s16+s06)/2,(s17+s07)/2} ++ .endif ++ .if \put ++ st.w r12++, r5 // *dst++ = { d00, d01, d02, d03 } ++ ld.w r8, r11++ // r8 = { s10, s11, s12, s13 }, src += 4 ++ st.w r12[0], r4 // *dst = { d04, d05, d06, d07 } ++ ld.w r6, r11[0] // r6 = { s14, s15, s16, s17 } ++ .else ++ ld.w r8, r12[0] ++ ld.w r6, r12[4] ++ pavg.ub r5, r5, r8 ++ pavg.ub r4, r4, r6 ++ st.w r12++, r5 // *dst++ = { d00, d01, d02, d03 } ++ ld.w r8, r11++ // r8 = { s10, s11, s12, s13 }, src += 4 ++ st.w r12[0], r4 // *dst = { d04, d05, d06, d07 } ++ ld.w r6, r11[0] // r6 = { s14, s15, s16, s17 } ++ .endif ++ ++ add r11, r10 // src += stride ++#ifdef USE_PREFETCH ++ pref r11[0] ++#endif ++ add r12, r10 // dst += stride ++ sub r9, 2 ++ brne 0b ++ ++ popm r4-r7,pc ++ .endm ++ ++ /* Macro for 8 pixel wide horizontal interpolation functions */ ++ ++ .macro pixels8_h round, put ++ pushm r4-r7, lr ++ ++ /* R12 = uint8_t *block, R11 = uint8_t pixels, R10 = int line_size, R9 = int h */ ++ /* ++ Pixel Naming Convention: ++ |--------------------------------------------------------------------| ++ | s00 d00 s01 d01 s02 d02 s03 d03 s04 d04 s05 d05 s06 d06 s07 d07 s08| ++ |------|-------|-------|-------|-------|-------|-------|-------|-----| ++ | s10 d10 s11 d11 s12 d12 s13 d13 s14 d14 s15 d15 s16 d16 s17 d17 s18| ++ |--------------------------------------------------------------------| ++ */ ++ ++ ld.w lr, r11[0] // lr = { s00, s01, s02, s03 } ++ ld.w r8, r11[1] // r8 = { s01, s02, s03, s04 } ++ ld.w r7, r11[4] // r7 = { s04, s05, s06, s07 } ++ ld.w r6, r11[5] // r6 = { s05, s06, s07, s08 } ++ add r11, r10 // src += stride ++ ++0: ++ .if \round ++ pavg.ub lr, r8, lr // lr = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ pavg.ub r7, r6, r7 // r7 = {(s04+s05)/2,(s05+s06)/2,(s06+s07)/2,(s07+s08)/2} ++ .else ++ paddh.ub lr, r8, lr // lr = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ paddh.ub r7, r6, r7 // r7 = {(s04+s05)/2,(s05+s06)/2,(s06+s07)/2,(s07+s08)/2} ++ .endif ++ .if \put ++ ld.w r5, r11[0] // r5 = { s00, s01, s02, s03 } ++ ld.w r4, r11[1] // r4 = { s01, s02, s03, s04 } ++ .else ++ ld.w r8, r12[0] ++ ld.w r6, r12[4] ++ ld.w r5, r11[0] // r5 = { s00, s01, s02, s03 } ++ ld.w r4, r11[1] // r4 = { s01, s02, s03, s04 } ++ pavg.ub lr, lr, r8 ++ pavg.ub r7, r7, r6 ++ .endif ++ st.w r12[0], lr // dst = { d00, d01, d02, d03 } ++ st.w r12[4], r7 // dst = { d04, d05, d06, d07 } ++ ld.w r8, r11[4] // r8 = { s04, s05, s06, s07 } ++ ld.w r6, r11[5] // r6 = { s05, s06, s07, s08 } ++ add r11, r10 // src += stride ++#ifdef USE_PREFETCH ++ pref r11[0] ++#endif ++ add r12, r10 // dst += stride ++ ++ .if \round ++ pavg.ub r5, r4, r5 // r5 = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ pavg.ub r4, r6, r8 // r4 = {(s04+s05)/2,(s05+s06)/2,(s06+s07)/2,(s07+s08)/2} ++ .else ++ paddh.ub r5, r4, r5 // r5 = {(s00+s01)/2,(s01+s02)/2,(s02+s03)/2,(s03+s04)/2} ++ paddh.ub r4, r6, r8 // r4 = {(s04+s05)/2,(s05+s06)/2,(s06+s07)/2,(s07+s08)/2} ++ .endif ++ .if \put ++ ld.w lr, r11[0] // lr = { s00, s01, s02, s03 } ++ ld.w r8, r11[1] // r8 = { s01, s02, s03, s04 } ++ .else ++ ld.w r7, r12[0] ++ ld.w r6, r12[4] ++ ld.w lr, r11[0] // lr = { s00, s01, s02, s03 } ++ ld.w r8, r11[1] // r8 = { s01, s02, s03, s04 } ++ pavg.ub r5, r5, r7 ++ pavg.ub r4, r4, r6 ++ .endif ++ st.w r12[0], r5 // dst = { d00, d01, d02, d03 } ++ st.w r12[4], r4 // dst = { d04, d05, d06, d07 } ++ ld.w r7, r11[4] // r7 = { s04, s05, s06, s07 } ++ ld.w r6, r11[5] // r6 = { s05, s06, s07, s08 } ++ add r11, r10 // src += stride ++#ifdef USE_PREFETCH ++ pref r11[0] ++#endif ++ add r12, r10 // dst += stride ++ sub r9, 2 ++ brne 0b ++ ++ popm r4-r7, pc ++ .endm ++ ++ /* Macro for 8 pixel wide copy functions */ ++ .macro pixels8 put ++ stm --sp, r3-r7,lr ++ /* R12 = uint8_t *block, R11 = uint8_t pixels, R10 = int line_size, R9 = int h */ ++ mov lr, r9 ++ sub r3, r10, 2 // stride2 = stride - 2 ++0: ++ .if \put ++ ld.w r9, r11[r10] // r9 = { s10, s11, s12, s13 } ++ ld.w r7, r11++ // r7 = { s00, s01, s02, s03 }, src += 4 ++ ld.w r6, r11[0] // r6 = { s04, s05, s06, s07 } ++ ld.w r8, r11[r10] // r8 = { s14, s15, s16, s17 } ++ .else ++ ld.w r9, r11[r10] // r9 = { s10, s11, s12, s13 } ++ ld.d r4, r12[0] ++ ld.w r7, r11++ // r7 = { s00, s01, s02, s03 }, src += 4 ++ ld.w r6, r11[0] // r6 = { s04, s05, s06, s07 } ++ ld.w r8, r11[r10] // r8 = { s14, s15, s16, s17 } ++ pavg.ub r6, r6, r4 ++ pavg.ub r7, r7, r5 ++ ld.d r4, r12[r10] ++ .endif ++ st.d r12, r6 // *dst = { s00, s01, s02, s03, s04, s05, s06, s07 } ++ add r11, r11, r3 << 1 // src += stride2 * 2 ++ .ifeq \put ++ pavg.ub r8, r8, r4 ++ pavg.ub r9, r9, r5 ++ .endif ++ st.d r12[r10 << 0], r8 // *(dst + stride) = { s10, s11, s12, s13, s14, s15, s16, s17 } ++ add r12, r12, r10 << 1 // dst += 2*stride ++ sub lr, 2 ++ brne 0b ++ ldm sp++, r3-r7,pc ++ ++ .endm ++ ++ .global put_no_rnd_pixels8_hv_avr32 ++ .text ++put_no_rnd_pixels8_hv_avr32: ++ pixels8_hv 0, 1 ++ ++ .global put_pixels8_hv_avr32 ++ .text ++put_pixels8_hv_avr32: ++ pixels8_hv 1, 1 ++ ++ .global avg_no_rnd_pixels8_hv_avr32 ++ .text ++avg_no_rnd_pixels8_hv_avr32: ++ pixels8_hv 0, 0 ++ ++ .global avg_pixels8_hv_avr32 ++ .text ++avg_pixels8_hv_avr32: ++ pixels8_hv 1, 0 ++ ++ .global put_no_rnd_pixels8_v_avr32 ++ .text ++put_no_rnd_pixels8_v_avr32: ++ pixels8_v 0, 1 ++ ++ .global put_pixels8_v_avr32 ++ .text ++put_pixels8_v_avr32: ++ pixels8_v 1, 1 ++ ++ .global avg_no_rnd_pixels8_v_avr32 ++ .text ++avg_no_rnd_pixels8_v_avr32: ++ pixels8_v 0, 0 ++ ++ .global avg_pixels8_v_avr32 ++ .text ++avg_pixels8_v_avr32: ++ pixels8_v 1, 0 ++ ++ .global put_no_rnd_pixels8_h_avr32 ++ .text ++put_no_rnd_pixels8_h_avr32: ++ pixels8_h 0, 1 ++ ++ .global put_pixels8_h_avr32 ++ .text ++put_pixels8_h_avr32: ++ pixels8_h 1, 1 ++ ++ .global avg_no_rnd_pixels8_h_avr32 ++ .text ++avg_no_rnd_pixels8_h_avr32: ++ pixels8_h 0, 0 ++ ++ .global avg_pixels8_h_avr32 ++ .text ++avg_pixels8_h_avr32: ++ pixels8_h 1, 0 ++ ++ .global put_pixels8_avr32 ++ .global put_no_rnd_pixels8_avr32 ++ .text ++put_pixels8_avr32: ++put_no_rnd_pixels8_avr32: ++ pixels8 1 ++ ++ .global avg_no_rnd_pixels8_avr32 ++ .global avg_pixels8_avr32 ++ .text ++avg_pixels8_avr32: ++avg_no_rnd_pixels8_avr32: ++ pixels8 0 +--- /dev/null ++++ b/libavcodec/avr32/pico.h +@@ -0,0 +1,260 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++#ifndef __PICO_H__ ++#define __PICO_H__ ++ ++ ++ ++/* Coprocessor Number */ ++#define PICO_CPNO 1 ++ ++/* Pixel Coprocessor Register file */ ++#define PICO_REGVECT_INPIX2 cr0 ++#define PICO_REGVECT_INPIX1 cr1 ++#define PICO_REGVECT_INPIX0 cr2 ++#define PICO_REGVECT_OUTPIX2 cr3 ++#define PICO_REGVECT_OUTPIX1 cr4 ++#define PICO_REGVECT_OUTPIX0 cr5 ++#define PICO_REGVECT_COEFF0_A cr6 ++#define PICO_REGVECT_COEFF0_B cr7 ++#define PICO_REGVECT_COEFF1_A cr8 ++#define PICO_REGVECT_COEFF1_B cr9 ++#define PICO_REGVECT_COEFF2_A cr10 ++#define PICO_REGVECT_COEFF2_B cr11 ++#define PICO_REGVECT_VMU0_OUT cr12 ++#define PICO_REGVECT_VMU1_OUT cr13 ++#define PICO_REGVECT_VMU2_OUT cr14 ++#define PICO_REGVECT_CONFIG cr15 ++ ++#define PICO_INPIX2 0 ++#define PICO_INPIX1 1 ++#define PICO_INPIX0 2 ++#define PICO_OUTPIX2 3 ++#define PICO_OUTPIX1 4 ++#define PICO_OUTPIX0 5 ++#define PICO_COEFF0_A 6 ++#define PICO_COEFF0_B 7 ++#define PICO_COEFF1_A 8 ++#define PICO_COEFF1_B 9 ++#define PICO_COEFF2_A 10 ++#define PICO_COEFF2_B 11 ++#define PICO_VMU0_OUT 12 ++#define PICO_VMU1_OUT 13 ++#define PICO_VMU2_OUT 14 ++#define PICO_CONFIG 15 ++ ++/* Config Register */ ++#define PICO_COEFF_FRAC_BITS_OFFSET 0 ++#define PICO_COEFF_FRAC_BITS_SIZE 4 ++#define PICO_OFFSET_FRAC_BITS_OFFSET 4 ++#define PICO_OFFSET_FRAC_BITS_SIZE 4 ++#define PICO_INPUT_MODE_OFFSET 8 ++#define PICO_INPUT_MODE_SIZE 2 ++#define PICO_OUTPUT_MODE_OFFSET 10 ++#define PICO_OUTPUT_MODE_SIZE 1 ++ ++struct pico_config_t { ++ unsigned int : 32 - PICO_OUTPUT_MODE_OFFSET - PICO_OUTPUT_MODE_SIZE; ++ unsigned int output_mode : PICO_OUTPUT_MODE_SIZE; ++ unsigned int input_mode : PICO_INPUT_MODE_SIZE; ++ unsigned int offset_frac_bits : PICO_OFFSET_FRAC_BITS_SIZE; ++ unsigned int coeff_frac_bits : PICO_COEFF_FRAC_BITS_SIZE; ++ int vmu2_out; ++ int vmu1_out; ++ int vmu0_out; ++ short coeff2_2; ++ short coeff2_3; ++ short coeff2_0; ++ short coeff2_1; ++ short coeff1_2; ++ short coeff1_3; ++ short coeff1_0; ++ short coeff1_1; ++ short coeff0_2; ++ short coeff0_3; ++ short coeff0_0; ++ short coeff0_1; ++}; ++ ++ ++#define PICO_COEFF_FRAC_BITS(x) (x << PICO_COEFF_FRAC_BITS_OFFSET) ++#define PICO_OFFSET_FRAC_BITS(x) (x << PICO_OFFSET_FRAC_BITS_OFFSET) ++#define PICO_INPUT_MODE(x) (x << PICO_INPUT_MODE_OFFSET) ++#define PICO_OUTPUT_MODE(x) (x << PICO_OUTPUT_MODE_OFFSET) ++ ++#define GET_PICO_COEFF_FRAC_BITS(x) ((x >> PICO_COEFF_FRAC_BITS_OFFSET)&((1 << PICO_COEFF_FRAC_BITS_SIZE)-1)) ++#define GET_PICO_OFFSET_FRAC_BITS(x) ((x >> PICO_OFFSET_FRAC_BITS_OFFSET)&((1 << PICO_OFFSET_FRAC_BITS_SIZE)-1)) ++#define GET_PICO_INPUT_MODE(x) ((x >> PICO_INPUT_MODE_OFFSET)&((1 << PICO_INPUT_MODE_SIZE)-1)) ++#define GET_PICO_OUTPUT_MODE(x) ((x >> PICO_OUTPUT_MODE_OFFSET)&((1 << PICO_OUTPUT_MODE_SIZE)-1)) ++ ++enum pico_input_mode { PICO_TRANSFORMATION_MODE, ++ PICO_HOR_FILTER_MODE, ++ PICO_VERT_FILTER_MODE }; ++ ++enum pico_output_mode { PICO_PACKED_MODE, ++ PICO_PLANAR_MODE }; ++ ++/* Bits in coefficients */ ++#define PICO_COEFF_BITS 12 ++ ++/* Operation bits */ ++#define PICO_MATRIX (0) ++#define PICO_USE_ACC (1 << 2) ++#define PICO_SINGLE_VECTOR (1 << 3) ++ ++ ++#define __str(x...) #x ++#define __xstr(x...) __str(x) ++ ++#define PICO_PUT_W(pico_reg, x) \ ++ __builtin_mvrc_w(PICO_CPNO, pico_reg, x); ++#define PICO_GET_W(pico_reg) \ ++ __builtin_mvcr_w(PICO_CPNO, pico_reg) ++ ++#define PICO_MVCR_W(x, pico_reg) \ ++ asm ("mvcr.w\tcp" __xstr(PICO_CPNO) ", %0, cr" __xstr(pico_reg) : "=r"(x)); ++ ++#define PICO_MVRC_W(pico_reg, x) \ ++ asm ("mvrc.w\tcp" __xstr(PICO_CPNO) ", cr" __xstr(pico_reg) ", %0" :: "r"(x)); ++ ++#define PICO_PUT_D(pico_reg, x) \ ++ __builtin_mvrc_d(PICO_CPNO, pico_reg, x); ++#define PICO_GET_D(pico_reg) \ ++ __builtin_mvcr_d(PICO_CPNO, pico_reg) ++ ++#define PICO_MVCR_D(x, pico_reg) \ ++ asm volatile ("mvcr.d\tcp" __xstr(PICO_CPNO) ", %0, cr" __xstr(pico_reg) : "=r"(x)); ++#define PICO_MVRC_D(pico_reg, x) \ ++ asm volatile ("mvrc.d\tcp" __xstr(PICO_CPNO) ", cr" __xstr(pico_reg) ", %0" :: "r"(x)); ++ ++#define PICO_STCM_W(ptr, pico_regs...) \ ++ asm volatile ("stcm.w\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++#define PICO_STCM_D(ptr, pico_regs...) \ ++ asm volatile ("stcm.d\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++ ++#define PICO_STCM_W_DEC(ptr, pico_regs...) \ ++ asm volatile ("stcm.w\tcp" __xstr(PICO_CPNO) ", --%0," __xstr(pico_regs) : "+r"(ptr)); ++#define PICO_STCM_D_DEC(ptr, pico_regs...) \ ++ asm volatile ("stcm.d\tcp" __xstr(PICO_CPNO) ", --%0," __xstr(pico_regs) : "+r"(ptr)); ++ ++#define PICO_LDCM_W(ptr, pico_regs...) \ ++ asm volatile ("ldcm.w\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++#define PICO_LDCM_D(ptr, pico_regs...) \ ++ asm volatile ("ldcm.d\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++ ++#define PICO_LDCM_W_INC(ptr, pico_regs...) \ ++ asm volatile ("ldcm.w\tcp" __xstr(PICO_CPNO) ", %0++," __xstr(pico_regs) : "+r"(ptr)); ++#define PICO_LDCM_D_INC(ptr, pico_regs...) \ ++ asm volatile ("ldcm.d\tcp" __xstr(PICO_CPNO) ", %0++," __xstr(pico_regs) : "+r"(ptr)); ++ ++#define PICO_OP(op, dst_addr, addr0, addr1, addr2) \ ++ __builtin_cop(PICO_CPNO, addr0, addr1, addr2, op | dst_addr); ++ ++static inline void set_pico_config(struct pico_config_t *config){ ++ PICO_LDCM_D(config, ++ PICO_REGVECT_COEFF0_A, PICO_REGVECT_COEFF0_B, ++ PICO_REGVECT_COEFF1_A, PICO_REGVECT_COEFF1_B, ++ PICO_REGVECT_COEFF2_A, PICO_REGVECT_COEFF2_B, ++ PICO_REGVECT_VMU0_OUT, PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT, PICO_REGVECT_CONFIG); ++} ++ ++static inline void get_pico_config(struct pico_config_t *config){ ++ PICO_STCM_D(config, ++ PICO_REGVECT_COEFF0_A, PICO_REGVECT_COEFF0_B, ++ PICO_REGVECT_COEFF1_A, PICO_REGVECT_COEFF1_B, ++ PICO_REGVECT_COEFF2_A, PICO_REGVECT_COEFF2_B, ++ PICO_REGVECT_VMU0_OUT, PICO_REGVECT_VMU1_OUT, ++ PICO_REGVECT_VMU2_OUT, PICO_REGVECT_CONFIG); ++} ++ ++static inline void dump_pico_config(){ ++ struct pico_config_t pico_config; ++ char *input_mode, *output_mode; ++ get_pico_config(&pico_config); ++ ++ ++ av_log(NULL, AV_LOG_INFO, "Dumping pico configuration:\n\n"); ++ av_log(NULL, AV_LOG_INFO, "\tcoeff_frac_bits = %d\n", pico_config.coeff_frac_bits); ++ av_log(NULL, AV_LOG_INFO, "\toffset_frac_bits = %d\n", pico_config.offset_frac_bits); ++ ++ switch ( pico_config.input_mode ){ ++ case PICO_TRANSFORMATION_MODE: ++ input_mode = "Transformation Mode"; ++ break; ++ case PICO_HOR_FILTER_MODE: ++ input_mode = "Horisontal Filter Mode"; ++ break; ++ case PICO_VERT_FILTER_MODE: ++ input_mode = "Vertical Filter Mode"; ++ break; ++ default: ++ input_mode = "Unknown Mode!!"; ++ break; ++ } ++ av_log(NULL, AV_LOG_INFO, "\tinput_mode = %s\n", input_mode); ++ ++ switch ( pico_config.output_mode ){ ++ case PICO_PLANAR_MODE: ++ output_mode = "Planar Mode"; ++ break; ++ case PICO_PACKED_MODE: ++ output_mode = "Packed Mode"; ++ break; ++ default: ++ output_mode = "Unknown Mode!!"; ++ break; ++ } ++ ++ av_log(NULL, AV_LOG_INFO, "\toutput_mode = %s\n", output_mode); ++ ++ av_log(NULL, AV_LOG_INFO, "\tCoeff0_0 = %f\n", (float)pico_config.coeff0_0/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff0_1 = %f\n", (float)pico_config.coeff0_1/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff0_2 = %f\n", (float)pico_config.coeff0_2/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff0_3 = %f\n", (float)pico_config.coeff0_3/(float)(1 << pico_config.offset_frac_bits)); ++ ++ av_log(NULL, AV_LOG_INFO, "\tCoeff1_0 = %f\n", (float)pico_config.coeff1_0/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff1_1 = %f\n", (float)pico_config.coeff1_1/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff1_2 = %f\n", (float)pico_config.coeff1_2/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff1_3 = %f\n", (float)pico_config.coeff1_3/(float)(1 << pico_config.offset_frac_bits)); ++ ++ av_log(NULL, AV_LOG_INFO, "\tCoeff2_0 = %f\n", (float)pico_config.coeff2_0/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff2_1 = %f\n", (float)pico_config.coeff2_1/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff2_2 = %f\n", (float)pico_config.coeff2_2/(float)(1 << pico_config.coeff_frac_bits)); ++ av_log(NULL, AV_LOG_INFO, "\tCoeff2_3 = %f\n", (float)pico_config.coeff2_3/(float)(1 << pico_config.offset_frac_bits)); ++} ++ ++ ++ ++#endif ++ +--- a/libavcodec/bitstream.h ++++ b/libavcodec/bitstream.h +@@ -178,7 +178,7 @@ typedef struct RL_VLC_ELEM { + #endif + + /* used to avoid misaligned exceptions on some archs (alpha, ...) */ +-#if defined(ARCH_X86) ++#if defined(ARCH_X86) || defined(ARCH_AVR32) + # define unaligned16(a) (*(const uint16_t*)(a)) + # define unaligned32(a) (*(const uint32_t*)(a)) + # define unaligned64(a) (*(const uint64_t*)(a)) +@@ -810,6 +810,44 @@ void free_vlc(VLC *vlc); + * if the vlc code is invalid and max_depth>1 than the number of bits removed + * is undefined + */ ++ ++#if defined(ARCH_AVR32) ++#define GET_VLC(code, name, gb, table, bits, max_depth)\ ++{\ ++ int n, index, nb_bits;\ ++ union { VLC_TYPE vlc[2];\ ++ uint32_t u32; } table_elem;\ ++\ ++ index= SHOW_UBITS(name, gb, bits);\ ++ table_elem.u32 = unaligned32(&table[index]); \ ++ code = table_elem.vlc[0];\ ++ n = table_elem.vlc[1];\ ++\ ++ if(max_depth > 1 && n < 0 ){\ ++ LAST_SKIP_BITS(name, gb, bits)\ ++ UPDATE_CACHE(name, gb)\ ++\ ++ nb_bits = -n;\ ++\ ++ index= SHOW_UBITS(name, gb, nb_bits) + code;\ ++ table_elem.u32 = unaligned32(&table[index]); \ ++ code = table_elem.vlc[0];\ ++ n = table_elem.vlc[1];\ ++ if(max_depth > 2 && n < 0){\ ++ LAST_SKIP_BITS(name, gb, nb_bits)\ ++ UPDATE_CACHE(name, gb)\ ++\ ++ nb_bits = -n;\ ++\ ++ index= SHOW_UBITS(name, gb, nb_bits) + code;\ ++ code = table[index][0];\ ++ n = table[index][1];\ ++ }\ ++ }\ ++ SKIP_BITS(name, gb, n)\ ++} ++ ++#else + #define GET_VLC(code, name, gb, table, bits, max_depth)\ + {\ + int n, index, nb_bits;\ +@@ -818,7 +856,7 @@ void free_vlc(VLC *vlc); + code = table[index][0];\ + n = table[index][1];\ + \ +- if(max_depth > 1 && n < 0){\ ++ if(max_depth > 1 && n < 0 ){\ + LAST_SKIP_BITS(name, gb, bits)\ + UPDATE_CACHE(name, gb)\ + \ +@@ -840,7 +878,38 @@ void free_vlc(VLC *vlc); + }\ + SKIP_BITS(name, gb, n)\ + } ++#endif + ++#if defined(ARCH_AVR32) ++#define GET_RL_VLC(level, run, name, gb, table, bits, max_depth, need_update)\ ++{\ ++ int n, index, nb_bits;\ ++ union { RL_VLC_ELEM vlc;\ ++ uint32_t u32; } table_elem;\ ++\ ++ index= SHOW_UBITS(name, gb, bits);\ ++ table_elem.u32 = unaligned32(&table[index]); \ ++ level = table_elem.vlc.level;\ ++ n = table_elem.vlc.len;\ ++\ ++ if(max_depth > 1 && n < 0 ){\ ++ SKIP_BITS(name, gb, bits)\ ++ if(need_update){\ ++ UPDATE_CACHE(name, gb)\ ++ }\ ++\ ++ nb_bits = -n;\ ++\ ++ index= SHOW_UBITS(name, gb, nb_bits) + level;\ ++ table_elem.u32 = unaligned32(&table[index]); \ ++ level = table_elem.vlc.level;\ ++ n = table_elem.vlc.len;\ ++ }\ ++ run= table_elem.vlc.run;\ ++ SKIP_BITS(name, gb, n)\ ++} ++ ++#else + #define GET_RL_VLC(level, run, name, gb, table, bits, max_depth, need_update)\ + {\ + int n, index, nb_bits;\ +@@ -849,7 +918,7 @@ void free_vlc(VLC *vlc); + level = table[index].level;\ + n = table[index].len;\ + \ +- if(max_depth > 1 && n < 0){\ ++ if(max_depth > 1 && n < 0 ){\ + SKIP_BITS(name, gb, bits)\ + if(need_update){\ + UPDATE_CACHE(name, gb)\ +@@ -864,7 +933,7 @@ void free_vlc(VLC *vlc); + run= table[index].run;\ + SKIP_BITS(name, gb, n)\ + } +- ++#endif + + /** + * parses a vlc code, faster then get_vlc() +--- a/libavcodec/dsputil.c ++++ b/libavcodec/dsputil.c +@@ -4155,6 +4155,7 @@ void dsputil_init(DSPContext* c, AVCodec + + if (ENABLE_MMX) dsputil_init_mmx (c, avctx); + if (ENABLE_ARMV4L) dsputil_init_armv4l(c, avctx); ++ if (ENABLE_AVR32) dsputil_init_avr32 (c, avctx); + if (ENABLE_MLIB) dsputil_init_mlib (c, avctx); + if (ENABLE_VIS) dsputil_init_vis (c, avctx); + if (ENABLE_ALPHA) dsputil_init_alpha (c, avctx); +--- a/libavcodec/h264.c ++++ b/libavcodec/h264.c +@@ -2043,7 +2043,12 @@ static void free_tables(H264Context *h){ + + static void init_dequant8_coeff_table(H264Context *h){ + int i,q,x; ++#ifdef ARCH_AVR32 ++ const int transpose = 0; ++#else + const int transpose = (h->s.dsp.h264_idct8_add != ff_h264_idct8_add_c); //FIXME ugly ++#endif ++ + h->dequant8_coeff[0] = h->dequant8_buffer[0]; + h->dequant8_coeff[1] = h->dequant8_buffer[1]; + +@@ -2066,7 +2071,13 @@ static void init_dequant8_coeff_table(H2 + + static void init_dequant4_coeff_table(H264Context *h){ + int i,j,q,x; ++ // Yes this is ugly as hell.... ++#ifdef ARCH_AVR32 ++ const int transpose = 0; ++#else + const int transpose = (h->s.dsp.h264_idct_add != ff_h264_idct_add_c); //FIXME ugly ++#endif ++ + for(i=0; i<6; i++ ){ + h->dequant4_coeff[i] = h->dequant4_buffer[i]; + for(j=0; j<i; j++){ +@@ -3710,7 +3721,11 @@ static int init_poc(H264Context *h){ + static void init_scan_tables(H264Context *h){ + MpegEncContext * const s = &h->s; + int i; ++#ifdef ARCH_AVR32 ++ if(1){ ++#else + if(s->dsp.h264_idct_add == ff_h264_idct_add_c){ //FIXME little ugly ++#endif + memcpy(h->zigzag_scan, zigzag_scan, 16*sizeof(uint8_t)); + memcpy(h-> field_scan, field_scan, 16*sizeof(uint8_t)); + }else{ +--- a/libavutil/common.h ++++ b/libavutil/common.h +@@ -174,23 +174,39 @@ static inline int mid_pred(int a, int b, + * @param amax maximum value of the clip range + * @return clipped value + */ ++#if defined(ARCH_AVR32) ++#define av_clip(a, amin, amax) \ ++ ({ int __tmp__; \ ++ asm ("min\t%0, %1, %2\n" \ ++ "max\t%0, %0, %3\n" \ ++ : "=&r"(__tmp__) : "r"(a), "r"(amax), "r"(amin)); \ ++ __tmp__; }) ++#else + static inline int av_clip(int a, int amin, int amax) + { + if (a < amin) return amin; + else if (a > amax) return amax; + else return a; + } ++#endif + + /** + * clip a signed integer value into the 0-255 range + * @param a value to clip + * @return clipped value + */ ++#if defined(ARCH_AVR32) ++#define av_clip_uint8(a) \ ++ ({ int __tmp__ = a; \ ++ asm ("satu\t%0 >> 0, 8" : "+r"(__tmp__)); \ ++ __tmp__; }) ++#else + static inline uint8_t av_clip_uint8(int a) + { + if (a&(~255)) return (-a)>>31; + else return a; + } ++#endif + + /** + * clip a signed integer value into the -32768,32767 range +--- a/libfaad2/common.h ++++ b/libfaad2/common.h +@@ -69,7 +69,7 @@ extern "C" { + /* Use if target platform has address generators with autoincrement */ + //#define PREFER_POINTERS + +-#if defined(_WIN32_WCE) || defined(__arm__) ++#if defined(_WIN32_WCE) || defined(__arm__) || defined(__avr32__) + #define FIXED_POINT + #endif + +--- a/libmpcodecs/ad_libmad.c ++++ b/libmpcodecs/ad_libmad.c +@@ -86,6 +86,11 @@ static int init(sh_audio_t *sh){ + sh->channels=(this->frame.header.mode == MAD_MODE_SINGLE_CHANNEL) ? 1 : 2; + sh->samplerate=this->frame.header.samplerate; + sh->i_bps=this->frame.header.bitrate/8; ++#ifdef WORDS_BIGENDIAN ++ sh->sample_format = AF_FORMAT_S16_BE; ++#else ++ sh->sample_format = AF_FORMAT_S16_LE; ++#endif + sh->samplesize=2; + + return 1; +--- /dev/null ++++ b/libswscale/pico-avr32.h +@@ -0,0 +1,137 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++#ifndef __PICO_H__ ++#define __PICO_H__ ++ ++/* Coprocessor Number */ ++#define PICO_CPNO 1 ++ ++/* Pixel Coprocessor Register file */ ++#define PICO_REGVECT_INPIX2 cr0 ++#define PICO_REGVECT_INPIX1 cr1 ++#define PICO_REGVECT_INPIX0 cr2 ++#define PICO_REGVECT_OUTPIX2 cr3 ++#define PICO_REGVECT_OUTPIX1 cr4 ++#define PICO_REGVECT_OUTPIX0 cr5 ++#define PICO_REGVECT_COEFF0_A cr6 ++#define PICO_REGVECT_COEFF0_B cr7 ++#define PICO_REGVECT_COEFF1_A cr8 ++#define PICO_REGVECT_COEFF1_B cr9 ++#define PICO_REGVECT_COEFF2_A cr10 ++#define PICO_REGVECT_COEFF2_B cr11 ++#define PICO_REGVECT_VMU0_OUT cr12 ++#define PICO_REGVECT_VMU1_OUT cr13 ++#define PICO_REGVECT_VMU2_OUT cr14 ++#define PICO_REGVECT_CONFIG cr15 ++ ++#define PICO_INPIX2 0 ++#define PICO_INPIX1 1 ++#define PICO_INPIX0 2 ++#define PICO_OUTPIX2 3 ++#define PICO_OUTPIX1 4 ++#define PICO_OUTPIX0 5 ++#define PICO_COEFF0_A 6 ++#define PICO_COEFF0_B 7 ++#define PICO_COEFF1_A 8 ++#define PICO_COEFF1_B 9 ++#define PICO_COEFF2_A 10 ++#define PICO_COEFF2_B 11 ++#define PICO_VMU0_OUT 12 ++#define PICO_VMU1_OUT 13 ++#define PICO_VMU2_OUT 14 ++#define PICO_CONFIG 15 ++ ++/* Config Register */ ++#define PICO_COEFF_FRAC_BITS 0 ++#define PICO_COEFF_FRAC_BITS_WIDTH 4 ++#define PICO_OFFSET_FRAC_BITS 4 ++#define PICO_OFFSET_FRAC_BITS_WIDTH 4 ++#define PICO_INPUT_MODE 8 ++#define PICO_INPUT_MODE_WIDTH 2 ++#define PICO_OUTPUT_MODE 10 ++ ++#define PICO_TRANSFORMATION_MODE 0 ++#define PICO_HOR_FILTER_MODE 1 ++#define PICO_VERT_FILTER_MODE 2 ++ ++#define PICO_PLANAR_MODE 1 ++#define PICO_PACKED_MODE 0 ++ ++/* Bits in coefficients */ ++#define PICO_COEFF_BITS 12 ++ ++/* Operation bits */ ++#define PICO_USE_ACC (1 << 2) ++#define PICO_SINGLE_VECTOR (1 << 3) ++ ++ ++#define __str(x...) #x ++#define __xstr(x...) __str(x) ++ ++#define PICO_PUT_W(pico_reg, x) \ ++ __builtin_mvrc_w(PICO_CPNO, pico_reg, x); ++#define PICO_GET_W(pico_reg) \ ++ __builtin_mvcr_w(PICO_CPNO, pico_reg) ++ ++#define PICO_PUT_D(pico_reg, x) \ ++ __builtin_mvrc_d(PICO_CPNO, pico_reg, x); ++#define PICO_GET_D(pico_reg) \ ++ __builtin_mvcr_d(PICO_CPNO, pico_reg) ++ ++ ++#define PICO_STCM_W(ptr, pico_regs...) \ ++ asm volatile ("stcm.w\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++#define PICO_STCM_D(ptr, pico_regs...) \ ++ asm volatile ("stcm.d\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++ ++#define PICO_STCM_W_DEC(ptr, pico_regs...) \ ++ asm volatile ("stcm.w\tcp" __xstr(PICO_CPNO) ", --%0," __xstr(pico_regs) : "+r"(ptr)); ++#define PICO_STCM_D_DEC(ptr, pico_regs...) \ ++ asm volatile ("stcm.d\tcp" __xstr(PICO_CPNO) ", --%0," __xstr(pico_regs) : "+r"(ptr)); ++ ++#define PICO_LDCM_W(ptr, pico_regs...) \ ++ asm volatile ("ldcm.w\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++#define PICO_LDCM_D(ptr, pico_regs...) \ ++ asm volatile ("ldcm.d\tcp" __xstr(PICO_CPNO) ", %0," __xstr(pico_regs) :: "r"(ptr)); ++ ++#define PICO_LDCM_W_INC(ptr, pico_regs...) \ ++ asm volatile ("ldcm.w\tcp" __xstr(PICO_CPNO) ", %0++," __xstr(pico_regs) : "+r"(ptr)); ++#define PICO_LDCM_D_INC(ptr, pico_regs...) \ ++ asm volatile ("ldcm.d\tcp" __xstr(PICO_CPNO) ", %0++," __xstr(pico_regs) : "+r"(ptr)); ++ ++#define PICO_OP(op, dst_addr, addr0, addr1, addr2) \ ++ __builtin_cop(PICO_CPNO, addr0, addr1, addr2, op | dst_addr); ++ ++ ++#endif ++ +--- a/libswscale/swscale_internal.h ++++ b/libswscale/swscale_internal.h +@@ -181,7 +181,7 @@ typedef struct SwsContext{ + SwsFunc yuv2rgb_get_func_ptr (SwsContext *c); + int yuv2rgb_c_init_tables (SwsContext *c, const int inv_table[4], int fullRange, int brightness, int contrast, int saturation); + +-char *sws_format_name(int format); ++char *sws_format_name(enum PixelFormat format); + + //FIXME replace this with something faster + #define isPlanarYUV(x) ( \ +--- a/libswscale/yuv2rgb.c ++++ b/libswscale/yuv2rgb.c +@@ -47,6 +47,10 @@ + #include "yuv2rgb_mlib.c" + #endif + ++#ifdef ARCH_AVR32 ++#include "yuv2rgb_avr32.c" ++#endif ++ + #define DITHER1XBPP // only for mmx + + const uint8_t __attribute__((aligned(8))) dither_2x2_4[2][8]={ +@@ -646,6 +650,12 @@ SwsFunc yuv2rgb_get_func_ptr (SwsContext + if (t) return t; + } + #endif ++#ifdef ARCH_AVR32 ++ { ++ SwsFunc t= yuv2rgb_init_avr32(c); ++ if(t) return t; ++ } ++#endif + #ifdef HAVE_ALTIVEC + if (c->flags & SWS_CPU_CAPS_ALTIVEC) + { +@@ -736,6 +746,10 @@ int yuv2rgb_c_init_tables (SwsContext *c + //printf("%lld %lld %lld %lld %lld\n", cy, crv, cbu, cgu, cgv); + oy -= 256*brightness; + ++#ifdef ARCH_AVR32 ++ yuv2rgb_c_init_tables_avr32 (c, inv_table, fullRange, brightness, contrast, saturation); ++#endif ++ + for (i = 0; i < 1024; i++) { + int j; + +--- /dev/null ++++ b/libswscale/yuv2rgb_avr32.c +@@ -0,0 +1,411 @@ ++/* ++ * Copyright (c) 2007 Atmel Corporation. All rights reserved. ++ * ++ * Redistribution and use in source and binary forms, with or without ++ * modification, are permitted provided that the following conditions ++ * are met: ++ * ++ * 1. Redistributions of source code must retain the above copyright ++ * notice, this list of conditions and the following disclaimer. ++ * ++ * 2. Redistributions in binary form must reproduce the above ++ * copyright notice, this list of conditions and the following ++ * disclaimer in the documentation and/or other materials provided ++ * with the distribution. ++ * ++ * 3. The name of ATMEL may not be used to endorse or promote products ++ * derived from this software without specific prior written ++ * permission. ++ * ++ * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR ++ * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ++ * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ++ * ARE EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL ++ * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, ++ * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, ++ * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR ++ * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY ++ * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ++ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE ++ * USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH ++ * DAMAGE. ++ */ ++#include "pico-avr32.h" ++#include "log.h" ++ ++#define RGB(uv_part) \ ++ __asm__ volatile ( \ ++ "ld.w\t%0, %3[%7:" uv_part " << 2]\n\t" /* tmp = c->table_gV[V] */ \ ++ "ld.w\t%1, %4[%8:" uv_part " << 2]\n\t" /* g = c->table_gU[U] */ \ ++ "ld.w\t%2, %5[%8:" uv_part " << 2]\n\t" /* b = c->table_bU[U] */ \ ++ "add\t%1, %0\n\t" /* g += tmp */\ ++ "ld.w\t%0, %6[%7:" uv_part " << 2]" /* r = c->table_rV[V] */ \ ++ : "=&r" (r), "=&r" (g), "=&r" (b) \ ++ : "r" (&c->table_gV[0]), "r" (&c->table_gU[0]),"r" (&c->table_bU[0]), \ ++ "r" (&c->table_rV[0]), "r" (V), "r" (U)); ++ ++#undef YUV2RGB1 ++#define YUV2RGB1(dst, src, y, idx) \ ++ { int tmp2; __asm__ volatile ( \ ++ "ld.ub\t%0, %3[2*%8]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 24) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 0], %1\n\t" /* dst_1[2] = tmp; */ \ ++ "st.b\t%7[6*%8 + 1], %2\n\t" /* dst_1[1] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%0, %3[2*%8 + 1]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "st.b\t%7[6*%8 + 2], %1\n\t" /* dst_1[0] = tmp; */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 16) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 3], %1\n\t" /* dst_1[5] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 4], %2\n\t" /* dst_1[4] = tmp; */ \ ++ "st.b\t%7[6*%8 + 5], %1" /* dst_1[3] = tmp; */ \ ++ : "=&r" (y), "=&r" (tmp), "=&r" (tmp2) \ ++ : "r" (src), "r" (r), "r" (g), "r" (b), "r" (dst), "i" (idx)); } ++ ++#undef YUV2RGB2 ++#define YUV2RGB2(dst, src, y, idx) \ ++ { int tmp2; __asm__ volatile ( \ ++ "ld.ub\t%0, %3[2*%8]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 24) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 0], %1\n\t" /* dst_1[2] = tmp; */ \ ++ "st.b\t%7[6*%8 + 1], %2\n\t" /* dst_1[1] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%0, %3[2*%8 + 1]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "st.b\t%7[6*%8 + 2], %1\n\t" /* dst_1[0] = tmp; */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 16) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 3], %1\n\t" /* dst_1[5] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 4], %2\n\t" /* dst_1[4] = tmp; */ \ ++ "st.b\t%7[6*%8 + 5], %1" /* dst_1[3] = tmp; */ \ ++ : "=&r" (y), "=&r" (tmp), "=&r" (tmp2) \ ++ : "r" (src), "r" (r), "r" (g), "r" (b), "r" (dst), "i" (idx)); } ++ ++ ++#undef YUV2BGR1 ++#define YUV2BGR1(dst, src, y, idx) \ ++ { int tmp2; __asm__ volatile ( \ ++ "ld.ub\t%0, %3[2*%8]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 24) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 2], %1\n\t" /* dst_1[2] = tmp; */ \ ++ "st.b\t%7[6*%8 + 1], %2\n\t" /* dst_1[1] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%0, %3[2*%8 + 1]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "st.b\t%7[6*%8 + 0], %1\n\t" /* dst_1[0] = tmp; */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 16) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 5], %1\n\t" /* dst_1[5] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 4], %2\n\t" /* dst_1[4] = tmp; */ \ ++ "st.b\t%7[6*%8 + 3], %1" /* dst_1[3] = tmp; */ \ ++ : "=&r" (y), "=&r" (tmp), "=&r" (tmp2) \ ++ : "r" (src), "r" (r), "r" (g), "r" (b), "r" (dst), "i" (idx)); } ++ ++#undef YUV2BGR2 ++#define YUV2BGR2(dst, src, y, idx) \ ++ { int tmp2; __asm__ volatile ( \ ++ "ld.ub\t%0, %3[2*%8]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 24) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 2], %1\n\t" /* dst_1[2] = tmp; */ \ ++ "st.b\t%7[6*%8 + 1], %2\n\t" /* dst_1[1] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 24) & 0xFF] */ \ ++ "ld.ub\t%0, %3[2*%8 + 1]\n\t" /* Y = ((uint32_t*)py_1)[0] */ \ ++ "st.b\t%7[6*%8 + 0], %1\n\t" /* dst_1[0] = tmp; */ \ ++ "ld.ub\t%1, %4[%0]\n\t" /* tmp = r[(Y >> 16) & 0xFF] */ \ ++ "ld.ub\t%2, %5[%0]\n\t" /* tmp = g[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 5], %1\n\t" /* dst_1[5] = tmp; */ \ ++ "ld.ub\t%1, %6[%0]\n\t" /* tmp = b[(Y >> 16) & 0xFF] */ \ ++ "st.b\t%7[6*%8 + 4], %2\n\t" /* dst_1[4] = tmp; */ \ ++ "st.b\t%7[6*%8 + 3], %1" /* dst_1[3] = tmp; */ \ ++ : "=&r" (y), "=&r" (tmp), "=&r" (tmp2) \ ++ : "r" (src), "r" (r), "r" (g), "r" (b), "r" (dst), "i" (idx)); } ++ ++int yuv2bgr24_avr32(SwsContext *c, uint8_t* src[], int srcStride[], int srcSliceY, ++ int srcSliceH, uint8_t* dst[], int dstStride[]){ ++ int y; ++ ++ if(c->srcFormat == PIX_FMT_YUV422P){ ++ srcStride[1] *= 2; ++ srcStride[2] *= 2; ++ } ++ ++ ++ for(y=0; y<srcSliceH; y+=2){ ++ uint8_t *dst_1= (uint8_t*)(dst[0] + (y+srcSliceY )*dstStride[0]); ++ uint8_t *dst_2= (uint8_t*)(dst[0] + (y+srcSliceY+1)*dstStride[0]); ++ uint32_t *r, *g, *b; ++ uint8_t *py_1= src[0] + y*srcStride[0]; ++ uint8_t *py_2= py_1 + srcStride[0]; ++ uint8_t *pu= src[1] + (y>>1)*srcStride[1]; ++ uint8_t *pv= src[2] + (y>>1)*srcStride[2]; ++ unsigned int h_size= c->dstW>>3; ++ while (h_size--) { ++ uint32_t U, V, Y1, Y2, tmp; ++ U = ((uint32_t*)pu)[0]; ++ V = ((uint32_t*)pv)[0]; ++ ++ RGB("t") ++ YUV2BGR1(dst_1, py_1, Y1, 0) ++ YUV2BGR1(dst_2, py_2, Y2, 0) ++ ++ RGB("u") ++ YUV2BGR2(dst_1, py_1, Y1, 1) ++ YUV2BGR2(dst_2, py_2, Y2, 1) ++ ++ RGB("l") ++ YUV2BGR1(dst_1, py_1, Y1, 2) ++ YUV2BGR1(dst_2, py_2, Y2, 2) ++ ++ RGB("b") ++ YUV2BGR2(dst_1, py_1, Y1, 3) ++ YUV2BGR2(dst_2, py_2, Y2, 3) ++ ++ pu += 4; ++ pv += 4; ++ py_1 += 8; ++ py_2 += 8; ++ dst_1 += 24; ++ dst_2 += 24; ++ } ++ } ++ return srcSliceH; ++} ++ ++ ++ ++static int yuv2rgb24_avr32(SwsContext *c, uint8_t* src[], int srcStride[], int srcSliceY, ++ int srcSliceH, uint8_t* dst[], int dstStride[]){ ++ int y; ++ ++ if(c->srcFormat == PIX_FMT_YUV422P){ ++ srcStride[1] *= 2; ++ srcStride[2] *= 2; ++ } ++ for(y=0; y<srcSliceH; y+=2){ ++ uint8_t *dst_1= (uint8_t*)(dst[0] + (y+srcSliceY )*dstStride[0]); ++ uint8_t *dst_2= (uint8_t*)(dst[0] + (y+srcSliceY+1)*dstStride[0]); ++ uint8_t *r, *g, *b; ++ uint8_t *py_1= src[0] + y*srcStride[0]; ++ uint8_t *py_2= py_1 + srcStride[0]; ++ uint8_t *pu= src[1] + (y>>1)*srcStride[1]; ++ uint8_t *pv= src[2] + (y>>1)*srcStride[2]; ++ unsigned int h_size= c->dstW>>3; ++ while (h_size--) { ++ uint32_t U, V, Y1, Y2, tmp; ++ U = ((uint32_t*)pu)[0]; ++ V = ((uint32_t*)pv)[0]; ++ ++ RGB("t") ++ YUV2RGB1(dst_1, py_1, Y1, 0) ++ YUV2RGB1(dst_2, py_2, Y2, 0) ++ ++ RGB("u") ++ YUV2RGB2(dst_1, py_1, Y1, 1) ++ YUV2RGB2(dst_2, py_2, Y2, 1) ++ ++ RGB("l") ++ YUV2RGB1(dst_1, py_1, Y1, 2) ++ YUV2RGB1(dst_2, py_2, Y2, 2) ++ ++ RGB("b") ++ YUV2RGB2(dst_1, py_1, Y1, 3) ++ YUV2RGB2(dst_2, py_2, Y2, 3) ++ ++ pu += 4; ++ pv += 4; ++ py_1 += 8; ++ py_2 += 8; ++ dst_1 += 24; ++ dst_2 += 24; ++ } ++ } ++ return srcSliceH; ++} ++ ++#define SCALE(x, bits) (((x) + ( 1 << (bits - 1))) >> bits) ++#define COEFF_FRAC_BITS 9 ++#define OFFSET_FRAC_BITS 2 ++ ++/* Coefficients used in the pico */ ++static struct { ++ short coeff2_2; ++ short coeff2_3; ++ short coeff2_0; ++ short coeff2_1; ++ short coeff1_2; ++ short coeff1_3; ++ short coeff1_0; ++ short coeff1_1; ++ short coeff0_2; ++ short coeff0_3; ++ short coeff0_0; ++ short coeff0_1; ++} pico_coeff; ++ ++ ++static int yuv2bgr24_avr32_pico(SwsContext *c, uint8_t* src[], int srcStride[], int srcSliceY, ++ int srcSliceH, uint8_t* dst[], int dstStride[]){ ++ int y; ++ static int first_time = 1; ++ ++ /* Initialize pico */ ++ PICO_LDCM_D(&pico_coeff, ++ PICO_REGVECT_COEFF0_A, PICO_REGVECT_COEFF0_B, ++ PICO_REGVECT_COEFF1_A, PICO_REGVECT_COEFF1_B, ++ PICO_REGVECT_COEFF2_A, PICO_REGVECT_COEFF2_B); ++ ++ PICO_PUT_W(PICO_CONFIG, ++ (PICO_PACKED_MODE << PICO_OUTPUT_MODE ++ | PICO_TRANSFORMATION_MODE << PICO_INPUT_MODE ++ | OFFSET_FRAC_BITS << PICO_OFFSET_FRAC_BITS ++ | COEFF_FRAC_BITS << PICO_COEFF_FRAC_BITS)); ++ ++ ++ if(c->srcFormat == PIX_FMT_YUV422P){ ++ srcStride[1] *= 2; ++ srcStride[2] *= 2; ++ } ++ ++ for(y=0; y<srcSliceH; y+=2){ ++ uint8_t *dst_1= (uint8_t*)(dst[0] + (y+srcSliceY )*dstStride[0]); ++ uint8_t *dst_2= (uint8_t*)(dst[0] + (y+srcSliceY+1)*dstStride[0]); ++ uint8_t *r, *g, *b; ++ uint8_t *py_1= src[0] + y*srcStride[0]; ++ uint8_t *py_2= py_1 + srcStride[0]; ++ uint8_t *pu= src[1] + (y>>1)*srcStride[1]; ++ uint8_t *pv= src[2] + (y>>1)*srcStride[2]; ++ unsigned int h_size= c->dstW>>3; ++ int *py_1_int = (int *)py_1; ++ int *py_2_int = (int *)py_2; ++ int *pu_int = (int *)pu; ++ int *pv_int = (int *)pv; ++ while (h_size--) { ++ PICO_PUT_W(PICO_INPIX0, *py_1_int++); ++ PICO_PUT_W(PICO_INPIX1, *pu_int++); ++ PICO_PUT_W(PICO_INPIX2, *pv_int++); ++ PICO_OP(0, 0, 0, 4, 8); ++ PICO_OP(0, 1, 1, 4, 8); ++ PICO_OP(0, 2, 2, 5, 9); ++ PICO_OP(0, 3, 3, 5, 9); ++ PICO_PUT_W(PICO_INPIX0, *py_1_int++); ++ PICO_STCM_W(dst_1, PICO_REGVECT_OUTPIX2, PICO_REGVECT_OUTPIX1, PICO_REGVECT_OUTPIX0); ++ PICO_OP(0, 0, 0, 6, 10); ++ PICO_OP(0, 1, 1, 6, 10); ++ PICO_OP(0, 2, 2, 7, 11); ++ PICO_OP(0, 3, 3, 7, 11); ++ PICO_PUT_W(PICO_INPIX0, *py_2_int++); ++ PICO_STCM_W(dst_1 + 12, PICO_REGVECT_OUTPIX2, PICO_REGVECT_OUTPIX1, PICO_REGVECT_OUTPIX0); ++ ++ PICO_OP(0, 0, 0, 4, 8); ++ PICO_OP(0, 1, 1, 4, 8); ++ PICO_OP(0, 2, 2, 5, 9); ++ PICO_OP(0, 3, 3, 5, 9); ++ PICO_PUT_W(PICO_INPIX0, *py_2_int++); ++ PICO_STCM_W(dst_2, PICO_REGVECT_OUTPIX2, PICO_REGVECT_OUTPIX1, PICO_REGVECT_OUTPIX0); ++ PICO_OP(0, 0, 0, 6, 10); ++ PICO_OP(0, 1, 1, 6, 10); ++ PICO_OP(0, 2, 2, 7, 11); ++ PICO_OP(0, 3, 3, 7, 11); ++ PICO_STCM_W(dst_2 + 12, PICO_REGVECT_OUTPIX2, PICO_REGVECT_OUTPIX1, PICO_REGVECT_OUTPIX0); ++ ++ dst_1 += 24; ++ dst_2 += 24; ++ } ++ } ++ return srcSliceH; ++} ++ ++extern int avr32_use_pico; ++ ++SwsFunc yuv2rgb_init_avr32 (SwsContext *c){ ++ switch(c->dstFormat){ ++ case PIX_FMT_BGR24: ++ { ++ if ( avr32_use_pico ){ ++ av_log(c, AV_LOG_INFO, "AVR32 BGR24: Using PICO for color space conversion\n"); ++ return yuv2bgr24_avr32_pico; ++ } else { ++ av_log(c, AV_LOG_INFO, "AVR32 BGR24: Using optimized color space conversion\n"); ++ return yuv2bgr24_avr32; ++ } ++ } ++ break; ++ case PIX_FMT_RGB24: ++ { ++ if ( avr32_use_pico ){ ++ av_log(c, AV_LOG_INFO, "AVR32 RGB24: Using PICO for color space conversion\n"); ++ return yuv2bgr24_avr32_pico; ++ } else { ++ av_log(c, AV_LOG_INFO, "AVR32 RGB24: Using optimized color space conversion\n"); ++ return yuv2rgb24_avr32; ++ } ++ } ++ } ++ return NULL; ++} ++ ++ ++int yuv2rgb_c_init_tables_avr32 (SwsContext *c, const int inv_table[4], int fullRange, int brightness, int contrast, int saturation){ ++ const int isRgb = (c->dstFormat == PIX_FMT_RGB24); ++ ++ int64_t crv = inv_table[0]; ++ int64_t cbu = inv_table[1]; ++ int64_t cgu = -inv_table[2]; ++ int64_t cgv = -inv_table[3]; ++ int64_t cy = 1<<16; ++ int64_t oy = 0; ++ ++ if(!fullRange){ ++ cy= (cy*255) / 219; ++ oy= 16<<16; ++ } ++ ++ cy = (cy *contrast )>>16; ++ crv= (crv*contrast * saturation)>>32; ++ cbu= (cbu*contrast * saturation)>>32; ++ cgu= (cgu*contrast * saturation)>>32; ++ cgv= (cgv*contrast * saturation)>>32; ++ ++ oy -= 256*brightness; ++ ++ pico_coeff.coeff1_0 = SCALE(cy, 16 - COEFF_FRAC_BITS); /* G <- Y */ ++ pico_coeff.coeff1_1 = SCALE(cgu, 16 - COEFF_FRAC_BITS); /* G <- U */ ++ pico_coeff.coeff1_2 = SCALE(cgv, 16 - COEFF_FRAC_BITS); /* G <- V */ ++ pico_coeff.coeff1_3 = (SCALE(-128*cgu - 128*cgv - 16*cy, 16 - OFFSET_FRAC_BITS) ++ + /*0.5*/(1 << (OFFSET_FRAC_BITS-1))); /* G offset */ ++ ++ if ( isRgb ){ ++ pico_coeff.coeff0_0 = SCALE(cy, 16 - COEFF_FRAC_BITS); /* R <- Y */ ++ pico_coeff.coeff0_1 = 0; /* R <- U */ ++ pico_coeff.coeff0_2 = SCALE(crv, 16 - COEFF_FRAC_BITS); /* R <- V */ ++ pico_coeff.coeff0_3 = (SCALE(-128*crv - 16*cy, 16 - OFFSET_FRAC_BITS) ++ + /*0.5*/(1 << (OFFSET_FRAC_BITS-1))); /* R offset */ ++ ++ pico_coeff.coeff2_0 = SCALE(cy, 16 - COEFF_FRAC_BITS); /* B <- Y */ ++ pico_coeff.coeff2_1 = SCALE(cbu, 16 - COEFF_FRAC_BITS); /* B <- U */ ++ pico_coeff.coeff2_2 = 0; /* B <- V */ ++ pico_coeff.coeff2_3 = (SCALE(-128*cbu - 16*cy, 16 - OFFSET_FRAC_BITS) ++ + /*0.5*/(1 << (OFFSET_FRAC_BITS-1)));/* B offset */ ++ } else { ++ pico_coeff.coeff2_0 = SCALE(cy, 16 - COEFF_FRAC_BITS); /* R <- Y */ ++ pico_coeff.coeff2_1 = 0; /* R <- U */ ++ pico_coeff.coeff2_2 = SCALE(crv, 16 - COEFF_FRAC_BITS); /* R <- V */ ++ pico_coeff.coeff2_3 = (SCALE(-128*crv - 16*cy, 16 - OFFSET_FRAC_BITS) ++ + /*0.5*/(1 << (OFFSET_FRAC_BITS-1))); /* R offset */ ++ ++ pico_coeff.coeff0_0 = SCALE(cy, 16 - COEFF_FRAC_BITS); /* B <- Y */ ++ pico_coeff.coeff0_1 = SCALE(cbu, 16 - COEFF_FRAC_BITS); /* B <- U */ ++ pico_coeff.coeff0_2 = 0; /* B <- V */ ++ pico_coeff.coeff0_3 = (SCALE(-128*cbu - 16*cy, 16 - OFFSET_FRAC_BITS) ++ + /*0.5*/(1 << (OFFSET_FRAC_BITS-1))); /* B offset */ ++ } ++ ++} ++ ++ ++#undef RGB +--- a/libvo/vo_fbdev2.c ++++ b/libvo/vo_fbdev2.c +@@ -22,6 +22,9 @@ + #include "sub.h" + #include "mp_msg.h" + ++/* Draw directly to framebuffer */ ++#define USE_CONVERT2FB ++ + static vo_info_t info = { + "Framebuffer Device", + "fbdev2", +@@ -178,6 +181,15 @@ static int fb_preinit(int reset) + } + fb_orig_vinfo = fb_vinfo; + ++ /* Reset panning offset */ ++ fb_vinfo.yoffset = 0; ++ if (ioctl(fb_dev_fd, FBIOPAN_DISPLAY, &fb_vinfo)) { ++ mp_msg(MSGT_VO, MSGL_ERR, ++ "[fbdev2] FBIOPAN_DISPLAY failed: %s\n", ++ strerror(errno)); ++ return 0; ++ } ++ + fb_bpp = fb_vinfo.bits_per_pixel; + + /* 16 and 15 bpp is reported as 16 bpp */ +@@ -289,6 +301,10 @@ static int config(uint32_t width, uint32 + mp_msg(MSGT_VO, MSGL_ERR, "[fbdev2] Can't malloc next_frame: %s\n", strerror(errno)); + return 1; + } ++#else ++ if ((fb_line_len * fb_vinfo.yres) <= (fb_finfo.smem_len / 2) ++ && fb_vinfo.yoffset == 0) ++ center += fb_line_len * fb_vinfo.yres; + #endif + if (fs) memset(frame_buffer, '\0', fb_line_len * fb_vinfo.yres); + +@@ -299,14 +315,22 @@ static int query_format(uint32_t format) + { + // open the device, etc. + if (fb_preinit(0)) return 0; +- if ((format & IMGFMT_BGR_MASK) == IMGFMT_BGR) { ++ if ((format & IMGFMT_RGB_MASK) == IMGFMT_RGB) { + int fb_target_bpp = format & 0xff; + set_bpp(&fb_vinfo, fb_target_bpp); + fb_vinfo.xres_virtual = fb_vinfo.xres; +- fb_vinfo.yres_virtual = fb_vinfo.yres; ++ fb_vinfo.yres_virtual = fb_vinfo.yres * 2; + if (ioctl(fb_dev_fd, FBIOPUT_VSCREENINFO, &fb_vinfo)) { +- mp_msg(MSGT_VO, MSGL_ERR, "[fbdev2] Can't put VSCREENINFO: %s\n", strerror(errno)); +- return 0; ++ mp_msg(MSGT_VO, MSGL_WARN, ++ "[fbdev2] Can't double virtual y resolution: %s\n", ++ strerror(errno)); ++ fb_vinfo.yres_virtual = fb_vinfo.yres; ++ if (ioctl(fb_dev_fd, FBIOPUT_VSCREENINFO, &fb_vinfo)) { ++ mp_msg(MSGT_VO, MSGL_ERR, ++ "[fbdev2] Can't put VSCREENINFO: %s\n", ++ strerror(errno)); ++ return -1; ++ } + } + fb_pixel_size = fb_vinfo.bits_per_pixel / 8; + fb_bpp = fb_vinfo.red.length + fb_vinfo.green.length + +@@ -367,16 +391,67 @@ static void check_events(void) + + static void flip_page(void) + { +-#ifndef USE_CONVERT2FB + int i, out_offset = 0, in_offset = 0; + +- for (i = 0; i < in_height; i++) { +- fast_memcpy(center + out_offset, next_frame + in_offset, +- in_width * fb_pixel_size); +- out_offset += fb_line_len; +- in_offset += in_width * fb_pixel_size; +- } ++#ifndef USE_CONVERT2FB ++ if (1) { ++#else ++ if (fb_vinfo.yres_virtual == fb_vinfo.yres) { + #endif ++ for (i = 0; i < in_height; i++) { ++ fast_memcpy(center + out_offset, next_frame + in_offset, ++ in_width * fb_pixel_size); ++ out_offset += fb_line_len; ++ in_offset += in_width * fb_pixel_size; ++ } ++ } else { ++ if (fb_vinfo.yoffset == 0) { ++ fb_vinfo.yoffset += fb_vinfo.yres; ++ center -= fb_line_len * fb_vinfo.yres; ++ } else { ++ fb_vinfo.yoffset = 0; ++ center += fb_line_len * fb_vinfo.yres; ++ } ++ ++ if (ioctl(fb_dev_fd, FBIOPAN_DISPLAY, &fb_vinfo)) { ++ mp_msg(MSGT_VO, MSGL_ERR, ++ "[fbdev2] Can't FBIOPAN_DISPLAY: %s\n", ++ strerror(errno)); ++ } ++ } ++} ++ ++static uint32_t get_image(mp_image_t *mpi) ++{ ++ if(mpi->flags&MP_IMGFLAG_READABLE) ++ return VO_FALSE; // slow video ram ++ if(mpi->type==MP_IMGTYPE_STATIC) ++ return VO_FALSE; // it is not static ++ ++ if (mpi->flags & (MP_IMGFLAG_ACCEPT_STRIDE | MP_IMGFLAG_ACCEPT_WIDTH)) { ++ // we're lucky or codec accepts stride => ok, let's go! ++ ++ //YUY2 and RGB formats ++ mpi->planes[0] = center; ++ mpi->width = in_width; ++ mpi->stride[0] = fb_line_len; ++ ++ // center image ++ ++ mpi->flags |= MP_IMGFLAG_DIRECT; ++ ++ return VO_TRUE; ++ } ++ ++ return VO_FALSE; ++} ++ ++static uint32_t put_image(mp_image_t *mpi) ++{ ++ // already out? ++ if ((mpi->flags & (MP_IMGFLAG_DIRECT | MP_IMGFLAG_DRAW_CALLBACK))) ++ return VO_TRUE; ++ return VO_FALSE; + } + + static void uninit(void) +@@ -403,6 +478,10 @@ static int control(uint32_t request, voi + switch (request) { + case VOCTRL_QUERY_FORMAT: + return query_format(*((uint32_t*)data)); ++ case VOCTRL_GET_IMAGE: ++ return get_image(data); ++ case VOCTRL_DRAW_IMAGE: ++ return put_image(data); + } + return VO_NOTIMPL; + } +--- a/version.sh ++++ b/version.sh +@@ -1,3 +1,3 @@ + #!/bin/sh +-echo "#define VERSION \"1.0rc2-$1\"" > version.h +-echo "#define MP_TITLE \"MPlayer 1.0rc2-$1 (C) 2000-2007 MPlayer Team\"" >> version.h ++echo "#define VERSION \"1.0rc2.atmel.1-$1\"" > version.h ++echo "#define MP_TITLE \"MPlayer 1.0rc2.atmel.1-$1 (C) 2000-2007 MPlayer Team\"" >> version.h |