;****************************************************************************** ;* MMX/SSE2-optimized functions for the VP3 decoder ;* Copyright (c) 2007 Aurelien Jacobs ;* ;* 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 ;* 51, Inc., Foundation Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA ;****************************************************************************** %include "x86inc.asm" %include "x86util.asm" ; MMX-optimized functions cribbed from the original VP3 source code. SECTION_RODATA vp3_idct_data: times 8 dw 64277 times 8 dw 60547 times 8 dw 54491 times 8 dw 46341 times 8 dw 36410 times 8 dw 25080 times 8 dw 12785 cextern pb_1 cextern pb_3 cextern pb_7 cextern pb_1F cextern pb_81 cextern pw_8 cextern put_signed_pixels_clamped_mmx cextern add_pixels_clamped_mmx SECTION .text ; this is off by one or two for some cases when filter_limit is greater than 63 ; in: p0 in mm6, p1 in mm4, p2 in mm2, p3 in mm1 ; out: p1 in mm4, p2 in mm3 %macro VP3_LOOP_FILTER 0 movq m7, m6 pand m6, [pb_7] ; p0&7 psrlw m7, 3 pand m7, [pb_1F] ; p0>>3 movq m3, m2 ; p2 pxor m2, m4 pand m2, [pb_1] ; (p2^p1)&1 movq m5, m2 paddb m2, m2 paddb m2, m5 ; 3*(p2^p1)&1 paddb m2, m6 ; extra bits lost in shifts pcmpeqb m0, m0 pxor m1, m0 ; 255 - p3 pavgb m1, m2 ; (256 - p3 + extrabits) >> 1 pxor m0, m4 ; 255 - p1 pavgb m0, m3 ; (256 + p2-p1) >> 1 paddb m1, [pb_3] pavgb m1, m0 ; 128+2+( p2-p1 - p3) >> 2 pavgb m1, m0 ; 128+1+(3*(p2-p1) - p3) >> 3 paddusb m7, m1 ; d+128+1 movq m6, [pb_81] psubusb m6, m7 psubusb m7, [pb_81] movq m5, [r2+516] ; flim pminub m6, m5 pminub m7, m5 movq m0, m6 movq m1, m7 paddb m6, m6 paddb m7, m7 pminub m6, m5 pminub m7, m5 psubb m6, m0 psubb m7, m1 paddusb m4, m7 psubusb m4, m6 psubusb m3, m7 paddusb m3, m6 %endmacro %macro STORE_4_WORDS 1 movd r2d, %1 mov [r0 -1], r2w psrlq %1, 32 shr r2, 16 mov [r0+r1 -1], r2w movd r2d, %1 mov [r0+r1*2-1], r2w shr r2, 16 mov [r0+r3 -1], r2w %endmacro INIT_MMX cglobal vp3_v_loop_filter_mmx2, 3, 4 %ifdef ARCH_X86_64 movsxd r1, r1d %endif mov r3, r1 neg r1 movq m6, [r0+r1*2] movq m4, [r0+r1 ] movq m2, [r0 ] movq m1, [r0+r3 ] VP3_LOOP_FILTER movq [r0+r1], m4 movq [r0 ], m3 RET cglobal vp3_h_loop_filter_mmx2, 3, 4 %ifdef ARCH_X86_64 movsxd r1, r1d %endif lea r3, [r1*3] movd m6, [r0 -2] movd m4, [r0+r1 -2] movd m2, [r0+r1*2-2] movd m1, [r0+r3 -2] lea r0, [r0+r1*4 ] punpcklbw m6, [r0 -2] punpcklbw m4, [r0+r1 -2] punpcklbw m2, [r0+r1*2-2] punpcklbw m1, [r0+r3 -2] sub r0, r3 sub r0, r1 TRANSPOSE4x4B 6, 4, 2, 1, 0 VP3_LOOP_FILTER SBUTTERFLY bw, 4, 3, 5 STORE_4_WORDS m4 lea r0, [r0+r1*4 ] STORE_4_WORDS m3 RET ; from original comments: The Macro does IDct on 4 1-D Dcts %macro BeginIDCT 0 movq m2, I(3) movq m6, C(3) movq m4, m2 movq m7, J(5) pmulhw m4, m6 ; r4 = c3*i3 - i3 movq m1, C(5) pmulhw m6, m7 ; r6 = c3*i5 - i5 movq m5, m1 pmulhw m1, m2 ; r1 = c5*i3 - i3 movq m3, I(1) pmulhw m5, m7 ; r5 = c5*i5 - i5 movq m0, C(1) paddw m4, m2 ; r4 = c3*i3 paddw m6, m7 ; r6 = c3*i5 paddw m2, m1 ; r2 = c5*i3 movq m1, J(7) paddw m7, m5 ; r7 = c5*i5 movq m5, m0 ; r5 = c1 pmulhw m0, m3 ; r0 = c1*i1 - i1 paddsw m4, m7 ; r4 = C = c3*i3 + c5*i5 pmulhw m5, m1 ; r5 = c1*i7 - i7 movq m7, C(7) psubsw m6, m2 ; r6 = D = c3*i5 - c5*i3 paddw m0, m3 ; r0 = c1*i1 pmulhw m3, m7 ; r3 = c7*i1 movq m2, I(2) pmulhw m7, m1 ; r7 = c7*i7 paddw m5, m1 ; r5 = c1*i7 movq m1, m2 ; r1 = i2 pmulhw m2, C(2) ; r2 = c2*i2 - i2 psubsw m3, m5 ; r3 = B = c7*i1 - c1*i7 movq m5, J(6) paddsw m0, m7 ; r0 = A = c1*i1 + c7*i7 movq m7, m5 ; r7 = i6 psubsw m0, m4 ; r0 = A - C pmulhw m5, C(2) ; r5 = c2*i6 - i6 paddw m2, m1 ; r2 = c2*i2 pmulhw m1, C(6) ; r1 = c6*i2 paddsw m4, m4 ; r4 = C + C paddsw m4, m0 ; r4 = C. = A + C psubsw m3, m6 ; r3 = B - D paddw m5, m7 ; r5 = c2*i6 paddsw m6, m6 ; r6 = D + D pmulhw m7, C(6) ; r7 = c6*i6 paddsw m6, m3 ; r6 = D. = B + D movq I(1), m4 ; save C. at I(1) psubsw m1, m5 ; r1 = H = c6*i2 - c2*i6 movq m4, C(4) movq m5, m3 ; r5 = B - D pmulhw m3, m4 ; r3 = (c4 - 1) * (B - D) paddsw m7, m2 ; r3 = (c4 - 1) * (B - D) movq I(2), m6 ; save D. at I(2) movq m2, m0 ; r2 = A - C movq m6, I(0) pmulhw m0, m4 ; r0 = (c4 - 1) * (A - C) paddw m5, m3 ; r5 = B. = c4 * (B - D) movq m3, J(4) psubsw m5, m1 ; r5 = B.. = B. - H paddw m2, m0 ; r0 = A. = c4 * (A - C) psubsw m6, m3 ; r6 = i0 - i4 movq m0, m6 pmulhw m6, m4 ; r6 = (c4 - 1) * (i0 - i4) paddsw m3, m3 ; r3 = i4 + i4 paddsw m1, m1 ; r1 = H + H paddsw m3, m0 ; r3 = i0 + i4 paddsw m1, m5 ; r1 = H. = B + H pmulhw m4, m3 ; r4 = (c4 - 1) * (i0 + i4) paddsw m6, m0 ; r6 = F = c4 * (i0 - i4) psubsw m6, m2 ; r6 = F. = F - A. paddsw m2, m2 ; r2 = A. + A. movq m0, I(1) ; r0 = C. paddsw m2, m6 ; r2 = A.. = F + A. paddw m4, m3 ; r4 = E = c4 * (i0 + i4) psubsw m2, m1 ; r2 = R2 = A.. - H. %endmacro ; RowIDCT gets ready to transpose %macro RowIDCT 0 BeginIDCT movq m3, I(2) ; r3 = D. psubsw m4, m7 ; r4 = E. = E - G paddsw m1, m1 ; r1 = H. + H. paddsw m7, m7 ; r7 = G + G paddsw m1, m2 ; r1 = R1 = A.. + H. paddsw m7, m4 ; r1 = R1 = A.. + H. psubsw m4, m3 ; r4 = R4 = E. - D. paddsw m3, m3 psubsw m6, m5 ; r6 = R6 = F. - B.. paddsw m5, m5 paddsw m3, m4 ; r3 = R3 = E. + D. paddsw m5, m6 ; r5 = R5 = F. + B.. psubsw m7, m0 ; r7 = R7 = G. - C. paddsw m0, m0 movq I(1), m1 ; save R1 paddsw m0, m7 ; r0 = R0 = G. + C. %endmacro ; Column IDCT normalizes and stores final results %macro ColumnIDCT 0 BeginIDCT paddsw m2, OC_8 ; adjust R2 (and R1) for shift paddsw m1, m1 ; r1 = H. + H. paddsw m1, m2 ; r1 = R1 = A.. + H. psraw m2, 4 ; r2 = NR2 psubsw m4, m7 ; r4 = E. = E - G psraw m1, 4 ; r1 = NR2 movq m3, I(2) ; r3 = D. paddsw m7, m7 ; r7 = G + G movq I(2), m2 ; store NR2 at I2 paddsw m7, m4 ; r7 = G. = E + G movq I(1), m1 ; store NR1 at I1 psubsw m4, m3 ; r4 = R4 = E. - D. paddsw m4, OC_8 ; adjust R4 (and R3) for shift paddsw m3, m3 ; r3 = D. + D. paddsw m3, m4 ; r3 = R3 = E. + D. psraw m4, 4 ; r4 = NR4 psubsw m6, m5 ; r6 = R6 = F. - B.. psraw m3, 4 ; r3 = NR3 paddsw m6, OC_8 ; adjust R6 (and R5) for shift paddsw m5, m5 ; r5 = B.. + B.. paddsw m5, m6 ; r5 = R5 = F. + B.. psraw m6, 4 ; r6 = NR6 movq J(4), m4 ; store NR4 at J4 psraw m5, 4 ; r5 = NR5 movq I(3), m3 ; store NR3 at I3 psubsw m7, m0 ; r7 = R7 = G. - C. paddsw m7, OC_8 ; adjust R7 (and R0) for shift paddsw m0, m0 ; r0 = C. + C. paddsw m0, m7 ; r0 = R0 = G. + C. psraw m7, 4 ; r7 = NR7 movq J(6), m6 ; store NR6 at J6 psraw m0, 4 ; r0 = NR0 movq J(5), m5 ; store NR5 at J5 movq J(7), m7 ; store NR7 at J7 movq I(0), m0 ; store NR0 at I0 %endmacro ; Following macro does two 4x4 transposes in place. ; ; At entry (we assume): ; ; r0 = a3 a2 a1 a0 ; I(1) = b3 b2 b1 b0 ; r2 = c3 c2 c1 c0 ; r3 = d3 d2 d1 d0 ; ; r4 = e3 e2 e1 e0 ; r5 = f3 f2 f1 f0 ; r6 = g3 g2 g1 g0 ; r7 = h3 h2 h1 h0 ; ; At exit, we have: ; ; I(0) = d0 c0 b0 a0 ; I(1) = d1 c1 b1 a1 ; I(2) = d2 c2 b2 a2 ; I(3) = d3 c3 b3 a3 ; ; J(4) = h0 g0 f0 e0 ; J(5) = h1 g1 f1 e1 ; J(6) = h2 g2 f2 e2 ; J(7) = h3 g3 f3 e3 ; ; I(0) I(1) I(2) I(3) is the transpose of r0 I(1) r2 r3. ; J(4) J(5) J(6) J(7) is the transpose of r4 r5 r6 r7. ; ; Since r1 is free at entry, we calculate the Js first. %macro Transpose 0 movq m1, m4 ; r1 = e3 e2 e1 e0 punpcklwd m4, m5 ; r4 = f1 e1 f0 e0 movq I(0), m0 ; save a3 a2 a1 a0 punpckhwd m1, m5 ; r1 = f3 e3 f2 e2 movq m0, m6 ; r0 = g3 g2 g1 g0 punpcklwd m6, m7 ; r6 = h1 g1 h0 g0 movq m5, m4 ; r5 = f1 e1 f0 e0 punpckldq m4, m6 ; r4 = h0 g0 f0 e0 = R4 punpckhdq m5, m6 ; r5 = h1 g1 f1 e1 = R5 movq m6, m1 ; r6 = f3 e3 f2 e2 movq J(4), m4 punpckhwd m0, m7 ; r0 = h3 g3 h2 g2 movq J(5), m5 punpckhdq m6, m0 ; r6 = h3 g3 f3 e3 = R7 movq m4, I(0) ; r4 = a3 a2 a1 a0 punpckldq m1, m0 ; r1 = h2 g2 f2 e2 = R6 movq m5, I(1) ; r5 = b3 b2 b1 b0 movq m0, m4 ; r0 = a3 a2 a1 a0 movq J(7), m6 punpcklwd m0, m5 ; r0 = b1 a1 b0 a0 movq J(6), m1 punpckhwd m4, m5 ; r4 = b3 a3 b2 a2 movq m5, m2 ; r5 = c3 c2 c1 c0 punpcklwd m2, m3 ; r2 = d1 c1 d0 c0 movq m1, m0 ; r1 = b1 a1 b0 a0 punpckldq m0, m2 ; r0 = d0 c0 b0 a0 = R0 punpckhdq m1, m2 ; r1 = d1 c1 b1 a1 = R1 movq m2, m4 ; r2 = b3 a3 b2 a2 movq I(0), m0 punpckhwd m5, m3 ; r5 = d3 c3 d2 c2 movq I(1), m1 punpckhdq m4, m5 ; r4 = d3 c3 b3 a3 = R3 punpckldq m2, m5 ; r2 = d2 c2 b2 a2 = R2 movq I(3), m4 movq I(2), m2 %endmacro %macro VP3_IDCT_mmx 1 ; eax = quantized input ; ebx = dequantizer matrix ; ecx = IDCT constants ; M(I) = ecx + MaskOffset(0) + I * 8 ; C(I) = ecx + CosineOffset(32) + (I-1) * 8 ; edx = output ; r0..r7 = mm0..mm7 %define OC_8 [pw_8] %define C(x) [vp3_idct_data+16*(x-1)] ; at this point, function has completed dequantization + dezigzag + ; partial transposition; now do the idct itself %define I(x) [%1+16* x ] %define J(x) [%1+16*(x-4)+8] RowIDCT Transpose %define I(x) [%1+16* x +64] %define J(x) [%1+16*(x-4)+72] RowIDCT Transpose %define I(x) [%1+16*x] %define J(x) [%1+16*x] ColumnIDCT %define I(x) [%1+16*x+8] %define J(x) [%1+16*x+8] ColumnIDCT %endmacro %macro VP3_1D_IDCT_SSE2 0 movdqa m2, I(3) ; xmm2 = i3 movdqa m6, C(3) ; xmm6 = c3 movdqa m4, m2 ; xmm4 = i3 movdqa m7, I(5) ; xmm7 = i5 pmulhw m4, m6 ; xmm4 = c3 * i3 - i3 movdqa m1, C(5) ; xmm1 = c5 pmulhw m6, m7 ; xmm6 = c3 * i5 - i5 movdqa m5, m1 ; xmm5 = c5 pmulhw m1, m2 ; xmm1 = c5 * i3 - i3 movdqa m3, I(1) ; xmm3 = i1 pmulhw m5, m7 ; xmm5 = c5 * i5 - i5 movdqa m0, C(1) ; xmm0 = c1 paddw m4, m2 ; xmm4 = c3 * i3 paddw m6, m7 ; xmm6 = c3 * i5 paddw m2, m1 ; xmm2 = c5 * i3 movdqa m1, I(7) ; xmm1 = i7 paddw m7, m5 ; xmm7 = c5 * i5 movdqa m5, m0 ; xmm5 = c1 pmulhw m0, m3 ; xmm0 = c1 * i1 - i1 paddsw m4, m7 ; xmm4 = c3 * i3 + c5 * i5 = C pmulhw m5, m1 ; xmm5 = c1 * i7 - i7 movdqa m7, C(7) ; xmm7 = c7 psubsw m6, m2 ; xmm6 = c3 * i5 - c5 * i3 = D paddw m0, m3 ; xmm0 = c1 * i1 pmulhw m3, m7 ; xmm3 = c7 * i1 movdqa m2, I(2) ; xmm2 = i2 pmulhw m7, m1 ; xmm7 = c7 * i7 paddw m5, m1 ; xmm5 = c1 * i7 movdqa m1, m2 ; xmm1 = i2 pmulhw m2, C(2) ; xmm2 = i2 * c2 -i2 psubsw m3, m5 ; xmm3 = c7 * i1 - c1 * i7 = B movdqa m5, I(6) ; xmm5 = i6 paddsw m0, m7 ; xmm0 = c1 * i1 + c7 * i7 = A movdqa m7, m5 ; xmm7 = i6 psubsw m0, m4 ; xmm0 = A - C pmulhw m5, C(2) ; xmm5 = c2 * i6 - i6 paddw m2, m1 ; xmm2 = i2 * c2 pmulhw m1, C(6) ; xmm1 = c6 * i2 paddsw m4, m4 ; xmm4 = C + C paddsw m4, m0 ; xmm4 = A + C = C. psubsw m3, m6 ; xmm3 = B - D paddw m5, m7 ; xmm5 = c2 * i6 paddsw m6, m6 ; xmm6 = D + D pmulhw m7, C(6) ; xmm7 = c6 * i6 paddsw m6, m3 ; xmm6 = B + D = D. movdqa I(1), m4 ; Save C. at I(1) psubsw m1, m5 ; xmm1 = c6 * i2 - c2 * i6 = H movdqa m4, C(4) ; xmm4 = C4 movdqa m5, m3 ; xmm5 = B - D pmulhw m3, m4 ; xmm3 = ( c4 -1 ) * ( B - D ) paddsw m7, m2 ; xmm7 = c2 * i2 + c6 * i6 = G movdqa I(2), m6 ; save D. at I(2) movdqa m2, m0 ; xmm2 = A - C movdqa m6, I(0) ; xmm6 = i0 pmulhw m0, m4 ; xmm0 = ( c4 - 1 ) * ( A - C ) = A. paddw m5, m3 ; xmm5 = c4 * ( B - D ) = B. movdqa m3, I(4) ; xmm3 = i4 psubsw m5, m1 ; xmm5 = B. - H = B.. paddw m2, m0 ; xmm2 = c4 * ( A - C) = A. psubsw m6, m3 ; xmm6 = i0 - i4 movdqa m0, m6 ; xmm0 = i0 - i4 pmulhw m6, m4 ; xmm6 = (c4 - 1) * (i0 - i4) = F paddsw m3, m3 ; xmm3 = i4 + i4 paddsw m1, m1 ; xmm1 = H + H paddsw m3, m0 ; xmm3 = i0 + i4 paddsw m1, m5 ; xmm1 = B. + H = H. pmulhw m4, m3 ; xmm4 = ( c4 - 1 ) * ( i0 + i4 ) paddw m6, m0 ; xmm6 = c4 * ( i0 - i4 ) psubsw m6, m2 ; xmm6 = F - A. = F. paddsw m2, m2 ; xmm2 = A. + A. movdqa m0, I(1) ; Load C. from I(1) paddsw m2, m6 ; xmm2 = F + A. = A.. paddw m4, m3 ; xmm4 = c4 * ( i0 + i4 ) = 3 psubsw m2, m1 ; xmm2 = A.. - H. = R2 ADD(m2) ; Adjust R2 and R1 before shifting paddsw m1, m1 ; xmm1 = H. + H. paddsw m1, m2 ; xmm1 = A.. + H. = R1 SHIFT(m2) ; xmm2 = op2 psubsw m4, m7 ; xmm4 = E - G = E. SHIFT(m1) ; xmm1 = op1 movdqa m3, I(2) ; Load D. from I(2) paddsw m7, m7 ; xmm7 = G + G paddsw m7, m4 ; xmm7 = E + G = G. psubsw m4, m3 ; xmm4 = E. - D. = R4 ADD(m4) ; Adjust R4 and R3 before shifting paddsw m3, m3 ; xmm3 = D. + D. paddsw m3, m4 ; xmm3 = E. + D. = R3 SHIFT(m4) ; xmm4 = op4 psubsw m6, m5 ; xmm6 = F. - B..= R6 SHIFT(m3) ; xmm3 = op3 ADD(m6) ; Adjust R6 and R5 before shifting paddsw m5, m5 ; xmm5 = B.. + B.. paddsw m5, m6 ; xmm5 = F. + B.. = R5 SHIFT(m6) ; xmm6 = op6 SHIFT(m5) ; xmm5 = op5 psubsw m7, m0 ; xmm7 = G. - C. = R7 ADD(m7) ; Adjust R7 and R0 before shifting paddsw m0, m0 ; xmm0 = C. + C. paddsw m0, m7 ; xmm0 = G. + C. SHIFT(m7) ; xmm7 = op7 SHIFT(m0) ; xmm0 = op0 %endmacro %macro PUT_BLOCK 8 movdqa O(0), m%1 movdqa O(1), m%2 movdqa O(2), m%3 movdqa O(3), m%4 movdqa O(4), m%5 movdqa O(5), m%6 movdqa O(6), m%7 movdqa O(7), m%8 %endmacro %macro VP3_IDCT_sse2 1 %define I(x) [%1+16*x] %define O(x) [%1+16*x] %define C(x) [vp3_idct_data+16*(x-1)] %define SHIFT(x) %define ADD(x) VP3_1D_IDCT_SSE2 %ifdef ARCH_X86_64 TRANSPOSE8x8W 0, 1, 2, 3, 4, 5, 6, 7, 8 %else TRANSPOSE8x8W 0, 1, 2, 3, 4, 5, 6, 7, [%1], [%1+16] %endif PUT_BLOCK 0, 1, 2, 3, 4, 5, 6, 7 %define SHIFT(x) psraw x, 4 %define ADD(x) paddsw x, [pw_8] VP3_1D_IDCT_SSE2 PUT_BLOCK 0, 1, 2, 3, 4, 5, 6, 7 %endmacro %macro vp3_idct_funcs 3 cglobal vp3_idct_%1, 1, 1, %2 VP3_IDCT_%1 r0 RET cglobal vp3_idct_put_%1, 3, %3, %2 VP3_IDCT_%1 r2 %ifdef ARCH_X86_64 mov r3, r2 mov r2, r1 mov r1, r0 mov r0, r3 %else mov r0m, r2 mov r1m, r0 mov r2m, r1 %endif %ifdef WIN64 call put_signed_pixels_clamped_mmx RET %else jmp put_signed_pixels_clamped_mmx %endif cglobal vp3_idct_add_%1, 3, %3, %2 VP3_IDCT_%1 r2 %ifdef ARCH_X86_64 mov r3, r2 mov r2, r1 mov r1, r0 mov r0, r3 %else mov r0m, r2 mov r1m, r0 mov r2m, r1 %endif %ifdef WIN64 call add_pixels_clamped_mmx RET %else jmp add_pixels_clamped_mmx %endif %endmacro %ifdef ARCH_X86_64 %define REGS 4 %else %define REGS 3 %endif INIT_MMX vp3_idct_funcs mmx, 0, REGS INIT_XMM vp3_idct_funcs sse2, 9, REGS %undef REGS %macro DC_ADD 0 movq m2, [r0 ] movq m3, [r0+r1 ] paddusb m2, m0 movq m4, [r0+r1*2] paddusb m3, m0 movq m5, [r0+r3 ] paddusb m4, m0 paddusb m5, m0 psubusb m2, m1 psubusb m3, m1 movq [r0 ], m2 psubusb m4, m1 movq [r0+r1 ], m3 psubusb m5, m1 movq [r0+r1*2], m4 movq [r0+r3 ], m5 %endmacro INIT_MMX cglobal vp3_idct_dc_add_mmx2, 3, 4 %ifdef ARCH_X86_64 movsxd r1, r1d %endif lea r3, [r1*3] movsx r2, word [r2] add r2, 15 sar r2, 5 movd m0, r2d pshufw m0, m0, 0x0 pxor m1, m1 psubw m1, m0 packuswb m0, m0 packuswb m1, m1 DC_ADD lea r0, [r0+r1*4] DC_ADD RET