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FFmpeg/libavcodec/ppc/mpegvideo_altivec.c

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  1. /*

  2.  * Copyright (c) 2002 Dieter Shirley

  3.  *

  4.  * dct_unquantize_h263_altivec:

  5.  * Copyright (c) 2003 Romain Dolbeau <romain@dolbeau.org>

  6.  *

  7.  * This file is part of FFmpeg.

  8.  *

  9.  * FFmpeg is free software; you can redistribute it and/or

  10.  * modify it under the terms of the GNU Lesser General Public

  11.  * License as published by the Free Software Foundation; either

  12.  * version 2.1 of the License, or (at your option) any later version.

  13.  *

  14.  * FFmpeg is distributed in the hope that it will be useful,

  15.  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  16.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  17.  * Lesser General Public License for more details.

  18.  *

  19.  * You should have received a copy of the GNU Lesser General Public

  20.  * License along with FFmpeg; if not, write to the Free Software

  21.  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  22.  */

  23. 

  24. #include <stdlib.h>

  25. #include <stdio.h>

  26. #include "../dsputil.h"

  27. #include "../mpegvideo.h"

  28. 

  29. #include "gcc_fixes.h"

  30. 

  31. #include "dsputil_altivec.h"

  32. 

  33. // Swaps two variables (used for altivec registers)

  34. #define SWAP(a,b) \

  35. do { \

  36.     __typeof__(a) swap_temp=a; \

  37.     a=b; \

  38.     b=swap_temp; \

  39. } while (0)

  40. 

  41. // transposes a matrix consisting of four vectors with four elements each

  42. #define TRANSPOSE4(a,b,c,d) \

  43. do { \

  44.   __typeof__(a) _trans_ach = vec_mergeh(a, c); \

  45.   __typeof__(a) _trans_acl = vec_mergel(a, c); \

  46.   __typeof__(a) _trans_bdh = vec_mergeh(b, d); \

  47.   __typeof__(a) _trans_bdl = vec_mergel(b, d); \

  48.  \

  49.   a = vec_mergeh(_trans_ach, _trans_bdh); \

  50.   b = vec_mergel(_trans_ach, _trans_bdh); \

  51.   c = vec_mergeh(_trans_acl, _trans_bdl); \

  52.   d = vec_mergel(_trans_acl, _trans_bdl); \

  53. } while (0)

  54. 

  55. 

  56. // Loads a four-byte value (int or float) from the target address

  57. // into every element in the target vector.  Only works if the

  58. // target address is four-byte aligned (which should be always).

  59. #define LOAD4(vec, address) \

  60. { \

  61.     __typeof__(vec)* _load_addr = (__typeof__(vec)*)(address); \

  62.     vector unsigned char _perm_vec = vec_lvsl(0,(address)); \

  63.     vec = vec_ld(0, _load_addr); \

  64.     vec = vec_perm(vec, vec, _perm_vec); \

  65.     vec = vec_splat(vec, 0); \

  66. }

  67. 

  68. 

  69. #ifdef CONFIG_DARWIN

  70. #define FOUROF(a) (a)

  71. #else

  72. // slower, for dumb non-apple GCC

  73. #define FOUROF(a) {a,a,a,a}

  74. #endif

  75. int dct_quantize_altivec(MpegEncContext* s,

  76.                         DCTELEM* data, int n,

  77.                         int qscale, int* overflow)

  78. {

  79.     int lastNonZero;

  80.     vector float row0, row1, row2, row3, row4, row5, row6, row7;

  81.     vector float alt0, alt1, alt2, alt3, alt4, alt5, alt6, alt7;

  82.     const_vector float zero = (const_vector float)FOUROF(0.);

  83.     // used after quantise step

  84.     int oldBaseValue = 0;

  85. 

  86.     // Load the data into the row/alt vectors

  87.     {

  88.         vector signed short data0, data1, data2, data3, data4, data5, data6, data7;

  89. 

  90.         data0 = vec_ld(0, data);

  91.         data1 = vec_ld(16, data);

  92.         data2 = vec_ld(32, data);

  93.         data3 = vec_ld(48, data);

  94.         data4 = vec_ld(64, data);

  95.         data5 = vec_ld(80, data);

  96.         data6 = vec_ld(96, data);

  97.         data7 = vec_ld(112, data);

  98. 

  99.         // Transpose the data before we start

  100.         TRANSPOSE8(data0, data1, data2, data3, data4, data5, data6, data7);

  101. 

  102.         // load the data into floating point vectors.  We load

  103.         // the high half of each row into the main row vectors

  104.         // and the low half into the alt vectors.

  105.         row0 = vec_ctf(vec_unpackh(data0), 0);

  106.         alt0 = vec_ctf(vec_unpackl(data0), 0);

  107.         row1 = vec_ctf(vec_unpackh(data1), 0);

  108.         alt1 = vec_ctf(vec_unpackl(data1), 0);

  109.         row2 = vec_ctf(vec_unpackh(data2), 0);

  110.         alt2 = vec_ctf(vec_unpackl(data2), 0);

  111.         row3 = vec_ctf(vec_unpackh(data3), 0);

  112.         alt3 = vec_ctf(vec_unpackl(data3), 0);

  113.         row4 = vec_ctf(vec_unpackh(data4), 0);

  114.         alt4 = vec_ctf(vec_unpackl(data4), 0);

  115.         row5 = vec_ctf(vec_unpackh(data5), 0);

  116.         alt5 = vec_ctf(vec_unpackl(data5), 0);

  117.         row6 = vec_ctf(vec_unpackh(data6), 0);

  118.         alt6 = vec_ctf(vec_unpackl(data6), 0);

  119.         row7 = vec_ctf(vec_unpackh(data7), 0);

  120.         alt7 = vec_ctf(vec_unpackl(data7), 0);

  121.     }

  122. 

  123.     // The following block could exist as a separate an altivec dct

  124.                 // function.  However, if we put it inline, the DCT data can remain

  125.                 // in the vector local variables, as floats, which we'll use during the

  126.                 // quantize step...

  127.     {

  128.         const vector float vec_0_298631336 = (vector float)FOUROF(0.298631336f);

  129.         const vector float vec_0_390180644 = (vector float)FOUROF(-0.390180644f);

  130.         const vector float vec_0_541196100 = (vector float)FOUROF(0.541196100f);

  131.         const vector float vec_0_765366865 = (vector float)FOUROF(0.765366865f);

  132.         const vector float vec_0_899976223 = (vector float)FOUROF(-0.899976223f);

  133.         const vector float vec_1_175875602 = (vector float)FOUROF(1.175875602f);

  134.         const vector float vec_1_501321110 = (vector float)FOUROF(1.501321110f);

  135.         const vector float vec_1_847759065 = (vector float)FOUROF(-1.847759065f);

  136.         const vector float vec_1_961570560 = (vector float)FOUROF(-1.961570560f);

  137.         const vector float vec_2_053119869 = (vector float)FOUROF(2.053119869f);

  138.         const vector float vec_2_562915447 = (vector float)FOUROF(-2.562915447f);

  139.         const vector float vec_3_072711026 = (vector float)FOUROF(3.072711026f);

  140. 

  141. 

  142.         int whichPass, whichHalf;

  143. 

  144.         for(whichPass = 1; whichPass<=2; whichPass++)

  145.         {

  146.             for(whichHalf = 1; whichHalf<=2; whichHalf++)

  147.             {

  148.                 vector float tmp0, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6, tmp7;

  149.                 vector float tmp10, tmp11, tmp12, tmp13;

  150.                 vector float z1, z2, z3, z4, z5;

  151. 

  152.                 tmp0 = vec_add(row0, row7); // tmp0 = dataptr[0] + dataptr[7];

  153.                 tmp7 = vec_sub(row0, row7); // tmp7 = dataptr[0] - dataptr[7];

  154.                 tmp3 = vec_add(row3, row4); // tmp3 = dataptr[3] + dataptr[4];

  155.                 tmp4 = vec_sub(row3, row4); // tmp4 = dataptr[3] - dataptr[4];

  156.                 tmp1 = vec_add(row1, row6); // tmp1 = dataptr[1] + dataptr[6];

  157.                 tmp6 = vec_sub(row1, row6); // tmp6 = dataptr[1] - dataptr[6];

  158.                 tmp2 = vec_add(row2, row5); // tmp2 = dataptr[2] + dataptr[5];

  159.                 tmp5 = vec_sub(row2, row5); // tmp5 = dataptr[2] - dataptr[5];

  160. 

  161.                 tmp10 = vec_add(tmp0, tmp3); // tmp10 = tmp0 + tmp3;

  162.                 tmp13 = vec_sub(tmp0, tmp3); // tmp13 = tmp0 - tmp3;

  163.                 tmp11 = vec_add(tmp1, tmp2); // tmp11 = tmp1 + tmp2;

  164.                 tmp12 = vec_sub(tmp1, tmp2); // tmp12 = tmp1 - tmp2;

  165. 

  166. 

  167.                 // dataptr[0] = (DCTELEM) ((tmp10 + tmp11) << PASS1_BITS);

  168.                 row0 = vec_add(tmp10, tmp11);

  169. 

  170.                 // dataptr[4] = (DCTELEM) ((tmp10 - tmp11) << PASS1_BITS);

  171.                 row4 = vec_sub(tmp10, tmp11);

  172. 

  173. 

  174.                 // z1 = MULTIPLY(tmp12 + tmp13, FIX_0_541196100);

  175.                 z1 = vec_madd(vec_add(tmp12, tmp13), vec_0_541196100, (vector float)zero);

  176. 

  177.                 // dataptr[2] = (DCTELEM) DESCALE(z1 + MULTIPLY(tmp13, FIX_0_765366865),

  178.                 //                                CONST_BITS-PASS1_BITS);

  179.                 row2 = vec_madd(tmp13, vec_0_765366865, z1);

  180. 

  181.                 // dataptr[6] = (DCTELEM) DESCALE(z1 + MULTIPLY(tmp12, - FIX_1_847759065),

  182.                 //                                CONST_BITS-PASS1_BITS);

  183.                 row6 = vec_madd(tmp12, vec_1_847759065, z1);

  184. 

  185.                 z1 = vec_add(tmp4, tmp7); // z1 = tmp4 + tmp7;

  186.                 z2 = vec_add(tmp5, tmp6); // z2 = tmp5 + tmp6;

  187.                 z3 = vec_add(tmp4, tmp6); // z3 = tmp4 + tmp6;

  188.                 z4 = vec_add(tmp5, tmp7); // z4 = tmp5 + tmp7;

  189. 

  190.                 // z5 = MULTIPLY(z3 + z4, FIX_1_175875602); /* sqrt(2) * c3 */

  191.                 z5 = vec_madd(vec_add(z3, z4), vec_1_175875602, (vector float)zero);

  192. 

  193.                 // z3 = MULTIPLY(z3, - FIX_1_961570560); /* sqrt(2) * (-c3-c5) */

  194.                 z3 = vec_madd(z3, vec_1_961570560, z5);

  195. 

  196.                 // z4 = MULTIPLY(z4, - FIX_0_390180644); /* sqrt(2) * (c5-c3) */

  197.                 z4 = vec_madd(z4, vec_0_390180644, z5);

  198. 

  199.                 // The following adds are rolled into the multiplies above

  200.                 // z3 = vec_add(z3, z5);  // z3 += z5;

  201.                 // z4 = vec_add(z4, z5);  // z4 += z5;

  202. 

  203.                 // z2 = MULTIPLY(z2, - FIX_2_562915447); /* sqrt(2) * (-c1-c3) */

  204.                 // Wow!  It's actually more effecient to roll this multiply

  205.                 // into the adds below, even thought the multiply gets done twice!

  206.                 // z2 = vec_madd(z2, vec_2_562915447, (vector float)zero);

  207. 

  208.                 // z1 = MULTIPLY(z1, - FIX_0_899976223); /* sqrt(2) * (c7-c3) */

  209.                 // Same with this one...

  210.                 // z1 = vec_madd(z1, vec_0_899976223, (vector float)zero);

  211. 

  212.                 // tmp4 = MULTIPLY(tmp4, FIX_0_298631336); /* sqrt(2) * (-c1+c3+c5-c7) */

  213.                 // dataptr[7] = (DCTELEM) DESCALE(tmp4 + z1 + z3, CONST_BITS-PASS1_BITS);

  214.                 row7 = vec_madd(tmp4, vec_0_298631336, vec_madd(z1, vec_0_899976223, z3));

  215. 

  216.                 // tmp5 = MULTIPLY(tmp5, FIX_2_053119869); /* sqrt(2) * ( c1+c3-c5+c7) */

  217.                 // dataptr[5] = (DCTELEM) DESCALE(tmp5 + z2 + z4, CONST_BITS-PASS1_BITS);

  218.                 row5 = vec_madd(tmp5, vec_2_053119869, vec_madd(z2, vec_2_562915447, z4));

  219. 

  220.                 // tmp6 = MULTIPLY(tmp6, FIX_3_072711026); /* sqrt(2) * ( c1+c3+c5-c7) */

  221.                 // dataptr[3] = (DCTELEM) DESCALE(tmp6 + z2 + z3, CONST_BITS-PASS1_BITS);

  222.                 row3 = vec_madd(tmp6, vec_3_072711026, vec_madd(z2, vec_2_562915447, z3));

  223. 

  224.                 // tmp7 = MULTIPLY(tmp7, FIX_1_501321110); /* sqrt(2) * ( c1+c3-c5-c7) */

  225.                 // dataptr[1] = (DCTELEM) DESCALE(tmp7 + z1 + z4, CONST_BITS-PASS1_BITS);

  226.                 row1 = vec_madd(z1, vec_0_899976223, vec_madd(tmp7, vec_1_501321110, z4));

  227. 

  228.                 // Swap the row values with the alts.  If this is the first half,

  229.                 // this sets up the low values to be acted on in the second half.

  230.                 // If this is the second half, it puts the high values back in

  231.                 // the row values where they are expected to be when we're done.

  232.                 SWAP(row0, alt0);

  233.                 SWAP(row1, alt1);

  234.                 SWAP(row2, alt2);

  235.                 SWAP(row3, alt3);

  236.                 SWAP(row4, alt4);

  237.                 SWAP(row5, alt5);

  238.                 SWAP(row6, alt6);

  239.                 SWAP(row7, alt7);

  240.             }

  241. 

  242.             if (whichPass == 1)

  243.             {

  244.                 // transpose the data for the second pass

  245. 

  246.                 // First, block transpose the upper right with lower left.

  247.                 SWAP(row4, alt0);

  248.                 SWAP(row5, alt1);

  249.                 SWAP(row6, alt2);

  250.                 SWAP(row7, alt3);

  251. 

  252.                 // Now, transpose each block of four

  253.                 TRANSPOSE4(row0, row1, row2, row3);

  254.                 TRANSPOSE4(row4, row5, row6, row7);

  255.                 TRANSPOSE4(alt0, alt1, alt2, alt3);

  256.                 TRANSPOSE4(alt4, alt5, alt6, alt7);

  257.             }

  258.         }

  259.     }

  260. 

  261.     // perform the quantise step, using the floating point data

  262.     // still in the row/alt registers

  263.     {

  264.         const int* biasAddr;

  265.         const vector signed int* qmat;

  266.         vector float bias, negBias;

  267. 

  268.         if (s->mb_intra)

  269.         {

  270.             vector signed int baseVector;

  271. 

  272.             // We must cache element 0 in the intra case

  273.             // (it needs special handling).

  274.             baseVector = vec_cts(vec_splat(row0, 0), 0);

  275.             vec_ste(baseVector, 0, &oldBaseValue);

  276. 

  277.             qmat = (vector signed int*)s->q_intra_matrix[qscale];

  278.             biasAddr = &(s->intra_quant_bias);

  279.         }

  280.         else

  281.         {

  282.             qmat = (vector signed int*)s->q_inter_matrix[qscale];

  283.             biasAddr = &(s->inter_quant_bias);

  284.         }

  285. 

  286.         // Load the bias vector (We add 0.5 to the bias so that we're

  287.                                 // rounding when we convert to int, instead of flooring.)

  288.         {

  289.             vector signed int biasInt;

  290.             const vector float negOneFloat = (vector float)FOUROF(-1.0f);

  291.             LOAD4(biasInt, biasAddr);

  292.             bias = vec_ctf(biasInt, QUANT_BIAS_SHIFT);

  293.             negBias = vec_madd(bias, negOneFloat, zero);

  294.         }

  295. 

  296.         {

  297.             vector float q0, q1, q2, q3, q4, q5, q6, q7;

  298. 

  299.             q0 = vec_ctf(qmat[0], QMAT_SHIFT);

  300.             q1 = vec_ctf(qmat[2], QMAT_SHIFT);

  301.             q2 = vec_ctf(qmat[4], QMAT_SHIFT);

  302.             q3 = vec_ctf(qmat[6], QMAT_SHIFT);

  303.             q4 = vec_ctf(qmat[8], QMAT_SHIFT);

  304.             q5 = vec_ctf(qmat[10], QMAT_SHIFT);

  305.             q6 = vec_ctf(qmat[12], QMAT_SHIFT);

  306.             q7 = vec_ctf(qmat[14], QMAT_SHIFT);

  307. 

  308.             row0 = vec_sel(vec_madd(row0, q0, negBias), vec_madd(row0, q0, bias),

  309.                     vec_cmpgt(row0, zero));

  310.             row1 = vec_sel(vec_madd(row1, q1, negBias), vec_madd(row1, q1, bias),

  311.                     vec_cmpgt(row1, zero));

  312.             row2 = vec_sel(vec_madd(row2, q2, negBias), vec_madd(row2, q2, bias),

  313.                     vec_cmpgt(row2, zero));

  314.             row3 = vec_sel(vec_madd(row3, q3, negBias), vec_madd(row3, q3, bias),

  315.                     vec_cmpgt(row3, zero));

  316.             row4 = vec_sel(vec_madd(row4, q4, negBias), vec_madd(row4, q4, bias),

  317.                     vec_cmpgt(row4, zero));

  318.             row5 = vec_sel(vec_madd(row5, q5, negBias), vec_madd(row5, q5, bias),

  319.                     vec_cmpgt(row5, zero));

  320.             row6 = vec_sel(vec_madd(row6, q6, negBias), vec_madd(row6, q6, bias),

  321.                     vec_cmpgt(row6, zero));

  322.             row7 = vec_sel(vec_madd(row7, q7, negBias), vec_madd(row7, q7, bias),

  323.                     vec_cmpgt(row7, zero));

  324. 

  325.             q0 = vec_ctf(qmat[1], QMAT_SHIFT);

  326.             q1 = vec_ctf(qmat[3], QMAT_SHIFT);

  327.             q2 = vec_ctf(qmat[5], QMAT_SHIFT);

  328.             q3 = vec_ctf(qmat[7], QMAT_SHIFT);

  329.             q4 = vec_ctf(qmat[9], QMAT_SHIFT);

  330.             q5 = vec_ctf(qmat[11], QMAT_SHIFT);

  331.             q6 = vec_ctf(qmat[13], QMAT_SHIFT);

  332.             q7 = vec_ctf(qmat[15], QMAT_SHIFT);

  333. 

  334.             alt0 = vec_sel(vec_madd(alt0, q0, negBias), vec_madd(alt0, q0, bias),

  335.                     vec_cmpgt(alt0, zero));

  336.             alt1 = vec_sel(vec_madd(alt1, q1, negBias), vec_madd(alt1, q1, bias),

  337.                     vec_cmpgt(alt1, zero));

  338.             alt2 = vec_sel(vec_madd(alt2, q2, negBias), vec_madd(alt2, q2, bias),

  339.                     vec_cmpgt(alt2, zero));

  340.             alt3 = vec_sel(vec_madd(alt3, q3, negBias), vec_madd(alt3, q3, bias),

  341.                     vec_cmpgt(alt3, zero));

  342.             alt4 = vec_sel(vec_madd(alt4, q4, negBias), vec_madd(alt4, q4, bias),

  343.                     vec_cmpgt(alt4, zero));

  344.             alt5 = vec_sel(vec_madd(alt5, q5, negBias), vec_madd(alt5, q5, bias),

  345.                     vec_cmpgt(alt5, zero));

  346.             alt6 = vec_sel(vec_madd(alt6, q6, negBias), vec_madd(alt6, q6, bias),

  347.                     vec_cmpgt(alt6, zero));

  348.             alt7 = vec_sel(vec_madd(alt7, q7, negBias), vec_madd(alt7, q7, bias),

  349.                     vec_cmpgt(alt7, zero));

  350.         }

  351. 

  352. 

  353.     }

  354. 

  355.     // Store the data back into the original block

  356.     {

  357.         vector signed short data0, data1, data2, data3, data4, data5, data6, data7;

  358. 

  359.         data0 = vec_pack(vec_cts(row0, 0), vec_cts(alt0, 0));

  360.         data1 = vec_pack(vec_cts(row1, 0), vec_cts(alt1, 0));

  361.         data2 = vec_pack(vec_cts(row2, 0), vec_cts(alt2, 0));

  362.         data3 = vec_pack(vec_cts(row3, 0), vec_cts(alt3, 0));

  363.         data4 = vec_pack(vec_cts(row4, 0), vec_cts(alt4, 0));

  364.         data5 = vec_pack(vec_cts(row5, 0), vec_cts(alt5, 0));

  365.         data6 = vec_pack(vec_cts(row6, 0), vec_cts(alt6, 0));

  366.         data7 = vec_pack(vec_cts(row7, 0), vec_cts(alt7, 0));

  367. 

  368.         {

  369.             // Clamp for overflow

  370.             vector signed int max_q_int, min_q_int;

  371.             vector signed short max_q, min_q;

  372. 

  373.             LOAD4(max_q_int, &(s->max_qcoeff));

  374.             LOAD4(min_q_int, &(s->min_qcoeff));

  375. 

  376.             max_q = vec_pack(max_q_int, max_q_int);

  377.             min_q = vec_pack(min_q_int, min_q_int);

  378. 

  379.             data0 = vec_max(vec_min(data0, max_q), min_q);

  380.             data1 = vec_max(vec_min(data1, max_q), min_q);

  381.             data2 = vec_max(vec_min(data2, max_q), min_q);

  382.             data4 = vec_max(vec_min(data4, max_q), min_q);

  383.             data5 = vec_max(vec_min(data5, max_q), min_q);

  384.             data6 = vec_max(vec_min(data6, max_q), min_q);

  385.             data7 = vec_max(vec_min(data7, max_q), min_q);

  386.         }

  387. 

  388.         {

  389.         vector bool char zero_01, zero_23, zero_45, zero_67;

  390.         vector signed char scanIndices_01, scanIndices_23, scanIndices_45, scanIndices_67;

  391.         vector signed char negOne = vec_splat_s8(-1);

  392.         vector signed char* scanPtr =

  393.                 (vector signed char*)(s->intra_scantable.inverse);

  394.         signed char lastNonZeroChar;

  395. 

  396.         // Determine the largest non-zero index.

  397.         zero_01 = vec_pack(vec_cmpeq(data0, (vector signed short)zero),

  398.                 vec_cmpeq(data1, (vector signed short)zero));

  399.         zero_23 = vec_pack(vec_cmpeq(data2, (vector signed short)zero),

  400.                 vec_cmpeq(data3, (vector signed short)zero));

  401.         zero_45 = vec_pack(vec_cmpeq(data4, (vector signed short)zero),

  402.                 vec_cmpeq(data5, (vector signed short)zero));

  403.         zero_67 = vec_pack(vec_cmpeq(data6, (vector signed short)zero),

  404.                 vec_cmpeq(data7, (vector signed short)zero));

  405. 

  406.         // 64 biggest values

  407.         scanIndices_01 = vec_sel(scanPtr[0], negOne, zero_01);

  408.         scanIndices_23 = vec_sel(scanPtr[1], negOne, zero_23);

  409.         scanIndices_45 = vec_sel(scanPtr[2], negOne, zero_45);

  410.         scanIndices_67 = vec_sel(scanPtr[3], negOne, zero_67);

  411. 

  412.         // 32 largest values

  413.         scanIndices_01 = vec_max(scanIndices_01, scanIndices_23);

  414.         scanIndices_45 = vec_max(scanIndices_45, scanIndices_67);

  415. 

  416.         // 16 largest values

  417.         scanIndices_01 = vec_max(scanIndices_01, scanIndices_45);

  418. 

  419.         // 8 largest values

  420.         scanIndices_01 = vec_max(vec_mergeh(scanIndices_01, negOne),

  421.                 vec_mergel(scanIndices_01, negOne));

  422. 

  423.         // 4 largest values

  424.         scanIndices_01 = vec_max(vec_mergeh(scanIndices_01, negOne),

  425.                 vec_mergel(scanIndices_01, negOne));

  426. 

  427.         // 2 largest values

  428.         scanIndices_01 = vec_max(vec_mergeh(scanIndices_01, negOne),

  429.                 vec_mergel(scanIndices_01, negOne));

  430. 

  431.         // largest value

  432.         scanIndices_01 = vec_max(vec_mergeh(scanIndices_01, negOne),

  433.                 vec_mergel(scanIndices_01, negOne));

  434. 

  435.         scanIndices_01 = vec_splat(scanIndices_01, 0);

  436. 

  437. 

  438.         vec_ste(scanIndices_01, 0, &lastNonZeroChar);

  439. 

  440.         lastNonZero = lastNonZeroChar;

  441. 

  442.         // While the data is still in vectors we check for the transpose IDCT permute

  443.         // and handle it using the vector unit if we can.  This is the permute used

  444.         // by the altivec idct, so it is common when using the altivec dct.

  445. 

  446.         if ((lastNonZero > 0) && (s->dsp.idct_permutation_type == FF_TRANSPOSE_IDCT_PERM))

  447.         {

  448.             TRANSPOSE8(data0, data1, data2, data3, data4, data5, data6, data7);

  449.         }

  450. 

  451.         vec_st(data0, 0, data);

  452.         vec_st(data1, 16, data);

  453.         vec_st(data2, 32, data);

  454.         vec_st(data3, 48, data);

  455.         vec_st(data4, 64, data);

  456.         vec_st(data5, 80, data);

  457.         vec_st(data6, 96, data);

  458.         vec_st(data7, 112, data);

  459.         }

  460.     }

  461. 

  462.     // special handling of block[0]

  463.     if (s->mb_intra)

  464.     {

  465.         if (!s->h263_aic)

  466.         {

  467.             if (n < 4)

  468.                 oldBaseValue /= s->y_dc_scale;

  469.             else

  470.                 oldBaseValue /= s->c_dc_scale;

  471.         }

  472. 

  473.         // Divide by 8, rounding the result

  474.         data[0] = (oldBaseValue + 4) >> 3;

  475.     }

  476. 

  477.     // We handled the tranpose permutation above and we don't

  478.     // need to permute the "no" permutation case.

  479.     if ((lastNonZero > 0) &&

  480.         (s->dsp.idct_permutation_type != FF_TRANSPOSE_IDCT_PERM) &&

  481.         (s->dsp.idct_permutation_type != FF_NO_IDCT_PERM))

  482.     {

  483.         ff_block_permute(data, s->dsp.idct_permutation,

  484.                 s->intra_scantable.scantable, lastNonZero);

  485.     }

  486. 

  487.     return lastNonZero;

  488. }

  489. #undef FOUROF

  490. 

  491. /*

  492.   AltiVec version of dct_unquantize_h263

  493.   this code assumes `block' is 16 bytes-aligned

  494. */

  495. void dct_unquantize_h263_altivec(MpegEncContext *s,

  496.                                  DCTELEM *block, int n, int qscale)

  497. {

  498. POWERPC_PERF_DECLARE(altivec_dct_unquantize_h263_num, 1);

  499.     int i, level, qmul, qadd;

  500.     int nCoeffs;

  501. 

  502.     assert(s->block_last_index[n]>=0);

  503. 

  504. POWERPC_PERF_START_COUNT(altivec_dct_unquantize_h263_num, 1);

  505. 

  506.     qadd = (qscale - 1) | 1;

  507.     qmul = qscale << 1;

  508. 

  509.     if (s->mb_intra) {

  510.         if (!s->h263_aic) {

  511.             if (n < 4)

  512.                 block[0] = block[0] * s->y_dc_scale;

  513.             else

  514.                 block[0] = block[0] * s->c_dc_scale;

  515.         }else

  516.             qadd = 0;

  517.         i = 1;

  518.         nCoeffs= 63; //does not always use zigzag table

  519.     } else {

  520.         i = 0;

  521.         nCoeffs= s->intra_scantable.raster_end[ s->block_last_index[n] ];

  522.     }

  523. 

  524.     {

  525.       register const_vector signed short vczero = (const_vector signed short)vec_splat_s16(0);

  526.       short __attribute__ ((aligned(16))) qmul8[] =

  527.           {

  528.             qmul, qmul, qmul, qmul,

  529.             qmul, qmul, qmul, qmul

  530.           };

  531.       short __attribute__ ((aligned(16))) qadd8[] =

  532.           {

  533.             qadd, qadd, qadd, qadd,

  534.             qadd, qadd, qadd, qadd

  535.           };

  536.       short __attribute__ ((aligned(16))) nqadd8[] =

  537.           {

  538.             -qadd, -qadd, -qadd, -qadd,

  539.             -qadd, -qadd, -qadd, -qadd

  540.           };

  541.       register vector signed short blockv, qmulv, qaddv, nqaddv, temp1;

  542.       register vector bool short blockv_null, blockv_neg;

  543.       register short backup_0 = block[0];

  544.       register int j = 0;

  545. 

  546.       qmulv = vec_ld(0, qmul8);

  547.       qaddv = vec_ld(0, qadd8);

  548.       nqaddv = vec_ld(0, nqadd8);

  549. 

  550. #if 0 // block *is* 16 bytes-aligned, it seems.

  551.       // first make sure block[j] is 16 bytes-aligned

  552.       for(j = 0; (j <= nCoeffs) && ((((unsigned long)block) + (j << 1)) & 0x0000000F) ; j++) {

  553.         level = block[j];

  554.         if (level) {

  555.           if (level < 0) {

  556.                 level = level * qmul - qadd;

  557.             } else {

  558.                 level = level * qmul + qadd;

  559.             }

  560.             block[j] = level;

  561.         }

  562.       }

  563. #endif

  564. 

  565.       // vectorize all the 16 bytes-aligned blocks

  566.       // of 8 elements

  567.       for(; (j + 7) <= nCoeffs ; j+=8)

  568.       {

  569.         blockv = vec_ld(j << 1, block);

  570.         blockv_neg = vec_cmplt(blockv, vczero);

  571.         blockv_null = vec_cmpeq(blockv, vczero);

  572.         // choose between +qadd or -qadd as the third operand

  573.         temp1 = vec_sel(qaddv, nqaddv, blockv_neg);

  574.         // multiply & add (block{i,i+7} * qmul [+-] qadd)

  575.         temp1 = vec_mladd(blockv, qmulv, temp1);

  576.         // put 0 where block[{i,i+7} used to have 0

  577.         blockv = vec_sel(temp1, blockv, blockv_null);

  578.         vec_st(blockv, j << 1, block);

  579.       }

  580. 

  581.       // if nCoeffs isn't a multiple of 8, finish the job

  582.       // using good old scalar units.

  583.       // (we could do it using a truncated vector,

  584.       // but I'm not sure it's worth the hassle)

  585.       for(; j <= nCoeffs ; j++) {

  586.         level = block[j];

  587.         if (level) {

  588.           if (level < 0) {

  589.                 level = level * qmul - qadd;

  590.             } else {

  591.                 level = level * qmul + qadd;

  592.             }

  593.             block[j] = level;

  594.         }

  595.       }

  596. 

  597.       if (i == 1)

  598.       { // cheat. this avoid special-casing the first iteration

  599.         block[0] = backup_0;

  600.       }

  601.     }

  602. POWERPC_PERF_STOP_COUNT(altivec_dct_unquantize_h263_num, nCoeffs == 63);

  603. }