ffmpeg/libavcodec/bfin/fdct_bfin.S

326 lines
11 KiB
ArmAsm

/*
* fdct BlackFin
*
* Copyright (C) 2007 Marc Hoffman <marc.hoffman@analog.com>
*
* This file is part of Libav.
*
* Libav is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* Libav is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with Libav; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
void ff_bfin_fdct (int16_t *buf);
This implementation works only for 8x8 input. The range of input
must be -256 to 255 i.e. 8bit input represented in a 16bit data
word. The original data must be sign extended into the 16bit data
words.
Chen factorization of
8
X(m) = sum (x(n) * cos ((2n+1)*m*pi/16))
n=0
C4
0 --*-------------*0+7---*-----*0+3-------*-*-------------------> 0
\ / \ / X S4,S4
1 --*-\---------/-*1+6---*-\-/-*1+2-------*-*-------------------> 4
\ / \ -C4 C3
2 --*---\-----/---*2+5---*-/-\-*1-2---------------*-*-----------> 2
\ / / \ X S3,-S3
3 --*-----\-/-----*3+4---*-----*0-3---------------*-*-----------> 6
/ C7 C3
4 --*-----/-\-----*3-4------------*-*4+5--*-----*---------------> 1
/ \ -C4 X \ /S7 C3
5 --*---/-----\---*2-5---*-*------*=*4-5----\-/------*-*--------> 5
/ \ X S4,S4 / X S3,-S3
6 --*-/---------\-*1-6---*-*------*=*7-6----/-\------*-*--------> 3
/ \ C4 X / \-S7 C3
--*-------------*0-7------------*-*7+6--*-----*---------------> 7
C7
Notation
Cn = cos(n*pi/8) used throughout the code.
Registers used:
R0, R1, R2, R3, R4, R5, R6,R7, P0, P1, P2, P3, P4, P5, A0, A1.
Other registers used:
I0, I1, I2, I3, B0, B2, B3, M0, M1, L3 registers and LC0.
Input - r0 - pointer to start of int16_t *block
Output - The DCT output coefficients in the int16_t *block
Register constraint:
This code is called from jpeg_encode.
R6, R5, R4 if modified should be stored and restored.
Performance: (Timer version 0.6.33)
Code Size : 240 Bytes.
Memory Required :
Input Matrix : 8 * 8 * 2 Bytes.
Coefficients : 16 Bytes
Temporary matrix: 8 * 8 * 2 Bytes.
Cycle Count :26+{18+8*(14+2S)}*2 where S -> Stalls
(7.45 c/pel)
-----------------------------------------
| Size | Forward DCT | Inverse DCT |
-----------------------------------------
| 8x8 | 284 Cycles | 311 Cycles |
-----------------------------------------
Ck = int16(cos(k/16*pi)*32767+.5)/2
#define C4 23170
#define C3 13623
#define C6 6270
#define C7 3196
Sk = int16(sin(k/16*pi)*32767+.5)/2
#define S4 11585
#define S3 9102
#define S6 15137
#define S7 16069
the coefficients are ordered as follows:
short dct_coef[]
C4,S4,
C6,S6,
C7,S7,
S3,C3,
-----------------------------------------------------------
Libav conformance testing results
-----------------------------------------------------------
dct-test: modified with the following
dct_error("BFINfdct", 0, ff_bfin_fdct, fdct, test);
produces the following output:
libavcodec> ./dct-test
Libav DCT/IDCT test
2 -131 -6 -48 -36 33 -83 24
34 52 -24 -15 5 92 57 143
-67 -43 -1 74 -16 5 -71 32
-78 106 92 -34 -38 81 20 -18
7 -62 40 2 -15 90 -62 -83
-83 1 -104 -13 43 -19 7 11
-63 31 12 -29 83 72 21 10
-17 -63 -15 73 50 -91 159 -14
DCT BFINfdct: err_inf=2 err2=0.16425938 syserr=0.00795000 maxout=2098 blockSumErr=27
DCT BFINfdct: 92.1 kdct/s
*/
#include "libavutil/bfin/asm.h"
SECTION_L1_DATA_B
.align 4;
dct_coeff:
.short 0x5a82, 0x2d41, 0x187e, 0x3b21, 0x0c7c, 0x3ec5, 0x238e, 0x3537;
SECTION_L1_DATA_A
.align 4
vtmp: .space 128
.text
DEFUN(fdct,mL1,
(int16_t *block)):
[--SP] = (R7:4, P5:3); // Push the registers onto the stack.
b0 = r0;
RELOC(r0, P3, dct_coeff);
b3 = r0;
RELOC(r0, P3, vtmp);
b2 = r0;
L3 = 16; // L3 is set to 16 to make the coefficient
// array Circular.
//----------------------------------------------------------------------------
/*
* I0, I1, and I2 registers are used to read the input data. I3 register is used
* to read the coefficients. P0 and P1 registers are used for writing the output
* data.
*/
M0 = 12 (X); // All these initializations are used in the
M1 = 16 (X); // modification of address offsets.
M2 = 128 (X);
P2 = 16;
P3 = 32 (X);
P4 = -110 (X);
P5 = -62 (X);
P0 = 2(X);
// Prescale the input to get the correct precision.
i0=b0;
i1=b0;
lsetup (.0, .1) LC0 = P3;
r0=[i0++];
.0: r1=r0<<3 (v) || r0=[i0++] ;
.1: [i1++]=r1;
/*
* B0 points to the "in" buffer.
* B2 points to "temp" buffer in the first iteration.
*/
lsetup (.2, .3) LC0 = P0;
.2:
I0 = B0; // I0 points to Input Element (0, 0).
I1 = B0; // Element 1 and 0 is read in R0.
I1 += M0 || R0 = [I0++]; // I1 points to Input Element (0, 6).
I2 = I1; // Element 6 is read into R3.H.
I2 -= 4 || R3.H = W[I1++]; // I2 points to Input Element (0, 4).
I3 = B3; // I3 points to Coefficients.
P0 = B2; // P0 points to temporary array Element
// (0, 0).
P1 = B2; // P1 points to temporary array.
R7 = [P1++P2] || R2 = [I2++]; // P1 points to temporary array
// Element (1, 0).
// R7 is a dummy read. X4,X5
// are read into R2.
R3.L = W[I1--]; // X7 is read into R3.L.
R1.H = W[I0++]; // X2 is read into R1.H.
/*
* X0 = (X0 + X7) / 2.
* X1 = (X1 + X6) / 2.
* X6 = (X1 - X6) / 2.
* X7 = (X0 - X7) / 2.
* It reads the data 3 in R1.L.
*/
R0 = R0 +|+ R3, R3 = R0 -|- R3 || R1.L = W[I0++] || NOP;
/*
* X2 = (X2 + X5) / 2.
* X3 = (X3 + X4) / 2.
* X4 = (X3 - X4) / 2.
* X5 = (X2 - X5) / 2.
* R7 = C4 = cos(4*pi/16)
*/
R1 = R1 +|+ R2, R2 = R1 -|- R2 (CO) || NOP || R7 = [I3++];
/*
* At the end of stage 1 R0 has (1,0), R1 has (2,3), R2 has (4, 5) and
* R3 has (6,7).
* Where the notation (x, y) represents uper/lower half pairs.
*/
/*
* X0 = X0 + X3.
* X1 = X1 + X2.
* X2 = X1 - X2.
* X3 = X0 - X3.
*/
R0 = R0 +|+ R1, R1 = R0 -|- R1;
lsetup (.row0, .row1) LC1 = P2 >> 1; // 1d dct, loops 8x
.row0:
/*
* This is part 2 computation continued.....
* A1 = X6 * cos(pi/4)
* A0 = X6 * cos(pi/4)
* A1 = A1 - X5 * cos(pi/4)
* A0 = A0 + X5 * cos(pi/4).
* The instruction W[I0] = R3.L is used for packing it to R2.L.
*/
A1=R3.H*R7.l, A0=R3.H*R7.l || I1+=M1 || W[I0] = R3.L;
R4.H=(A1-=R2.L*R7.l), R4.L=(A0+=R2.L*R7.l) || I2+=M0 || NOP;
/* R0 = (X1,X0) R1 = (X2,X3) R4 = (X5, X6). */
/*
* A1 = X0 * cos(pi/4)
* A0 = X0 * cos(pi/4)
* A1 = A1 - X1 * cos(pi/4)
* A0 = A0 + X1 * cos(pi/4)
* R7 = (C2,C6)
*/
A1=R0.L*R7.h, A0=R0.L*R7.h || NOP || R3.H=W[I1++];
R5.H=(A1-=R0.H*R7.h),R5.L=(A0+=R0.H*R7.h) || R7=[I3++] || NOP;
/*
* A1 = X2 * cos(3pi/8)
* A0 = X3 * cos(3pi/8)
* A1 = A1 + X3 * cos(pi/8)
* A0 = A0 - X2 * cos(pi/8)
* R3 = cos(pi/4)
* R7 = (cos(7pi/8),cos(pi/8))
* X4 = X4 + X5.
* X5 = X4 - X5.
* X6 = X7 - X6.
* X7 = X7 + X6.
*/
A1=R1.H*R7.L, A0=R1.L*R7.L || W[P0++P3]=R5.L || R2.L=W[I0];
R2=R2+|+R4, R4=R2-|-R4 || I0+=4 || R3.L=W[I1--];
R6.H=(A1+=R1.L*R7.H),R6.L=(A0 -= R1.H * R7.H) || I0+=4 || R7=[I3++];
/* R2 = (X4, X7) R4 = (X5,X6) R5 = (X1, X0) R6 = (X2,X3). */
/*
* A1 = X4 * cos(7pi/16)
* A0 = X7 * cos(7pi/16)
* A1 = A1 + X7 * cos(pi/16)
* A0 = A0 - X4 * cos(pi/16)
*/
A1=R2.H*R7.L, A0=R2.L*R7.L || W[P0++P3]=R6.H || R0=[I0++];
R2.H=(A1+=R2.L*R7.H),R2.L=(A0-=R2.H*R7.H) || W[P0++P3]=R5.H || R7=[I3++];
/*
* A1 = X5 * cos(3pi/16)
* A0 = X6 * cos(3pi/16)
* A1 = A1 + X6 * cos(5pi/16)
* A0 = A0 - X5 * cos(5pi/16)
* The output values are written.
*/
A1=R4.H*R7.H, A0=R4.L*R7.H || W[P0++P2]=R6.L || R1.H=W[I0++];
R4.H=(A1+=R4.L*R7.L),R4.L=(A0-=R4.H*R7.L) || W[P0++P4]=R2.L || R1.L=W[I0++];
/* Beginning of next stage, **pipelined** + drain and store the
rest of the column store. */
R0=R0+|+R3,R3=R0-|-R3 || W[P1++P3]=R2.H || R2=[I2++];
R1=R1+|+R2,R2=R1-|-R2 (CO) || W[P1++P3]=R4.L || R7=[I3++];
.row1: R0=R0+|+R1,R1=R0-|-R1 || W[P1++P5]=R4.H || NOP;
// Exchange input with output.
B1 = B0;
B0 = B2;
.3: B2 = B1;
L3=0;
(r7:4,p5:3) = [sp++];
RTS;
DEFUN_END(fdct)