/* * Copyright (c) 2010 The WebM project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include #include "vpx_ports/config.h" #include "vp8/common/idct.h" #include "vp8/common/systemdependent.h" #if CONFIG_HYBRIDTRANSFORM || CONFIG_HYBRIDTRANSFORM8X8 || CONFIG_HYBRIDTRANSFORM16X16 #include "vp8/common/blockd.h" // TODO: these transforms can be converted into integer forms to reduce // the complexity float dct_4[16] = { 0.500000000000000, 0.500000000000000, 0.500000000000000, 0.500000000000000, 0.653281482438188, 0.270598050073099, -0.270598050073099, -0.653281482438188, 0.500000000000000, -0.500000000000000, -0.500000000000000, 0.500000000000000, 0.270598050073099, -0.653281482438188, 0.653281482438188, -0.270598050073099 }; float adst_4[16] = { 0.228013428883779, 0.428525073124360, 0.577350269189626, 0.656538502008139, 0.577350269189626, 0.577350269189626, 0.000000000000000, -0.577350269189626, 0.656538502008139, -0.228013428883779, -0.577350269189626, 0.428525073124359, 0.428525073124360, -0.656538502008139, 0.577350269189626, -0.228013428883779 }; float dct_8[64] = { 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.353553390593274, 0.490392640201615, 0.415734806151273, 0.277785116509801, 0.097545161008064, -0.097545161008064, -0.277785116509801, -0.415734806151273, -0.490392640201615, 0.461939766255643, 0.191341716182545, -0.191341716182545, -0.461939766255643, -0.461939766255643, -0.191341716182545, 0.191341716182545, 0.461939766255643, 0.415734806151273, -0.097545161008064, -0.490392640201615, -0.277785116509801, 0.277785116509801, 0.490392640201615, 0.097545161008064, -0.415734806151273, 0.353553390593274, -0.353553390593274, -0.353553390593274, 0.353553390593274, 0.353553390593274, -0.353553390593274, -0.353553390593274, 0.353553390593274, 0.277785116509801, -0.490392640201615, 0.097545161008064, 0.415734806151273, -0.415734806151273, -0.097545161008064, 0.490392640201615, -0.277785116509801, 0.191341716182545, -0.461939766255643, 0.461939766255643, -0.191341716182545, -0.191341716182545, 0.461939766255643, -0.461939766255643, 0.191341716182545, 0.097545161008064, -0.277785116509801, 0.415734806151273, -0.490392640201615, 0.490392640201615, -0.415734806151273, 0.277785116509801, -0.097545161008064 }; float adst_8[64] = { 0.089131608307533, 0.175227946595735, 0.255357107325376, 0.326790388032145, 0.387095214016349, 0.434217976756762, 0.466553967085785, 0.483002021635509, 0.255357107325376, 0.434217976756762, 0.483002021635509, 0.387095214016349, 0.175227946595735, -0.089131608307533, -0.326790388032145, -0.466553967085785, 0.387095214016349, 0.466553967085785, 0.175227946595735, -0.255357107325376, -0.483002021635509, -0.326790388032145, 0.089131608307533, 0.434217976756762, 0.466553967085785, 0.255357107325376, -0.326790388032145, -0.434217976756762, 0.089131608307533, 0.483002021635509, 0.175227946595735, -0.387095214016348, 0.483002021635509, -0.089131608307533, -0.466553967085785, 0.175227946595735, 0.434217976756762, -0.255357107325376, -0.387095214016348, 0.326790388032145, 0.434217976756762, -0.387095214016348, -0.089131608307533, 0.466553967085786, -0.326790388032145, -0.175227946595735, 0.483002021635509, -0.255357107325375, 0.326790388032145, -0.483002021635509, 0.387095214016349, -0.089131608307534, -0.255357107325377, 0.466553967085785, -0.434217976756762, 0.175227946595736, 0.175227946595735, -0.326790388032145, 0.434217976756762, -0.483002021635509, 0.466553967085785, -0.387095214016348, 0.255357107325376, -0.089131608307532 }; #endif #if CONFIG_HYBRIDTRANSFORM16X16 || CONFIG_HYBRIDTRANSFORM || CONFIG_HYBRIDTRANSFORM8X8 float dct_16[256] = { 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.250000, 0.351851, 0.338330, 0.311806, 0.273300, 0.224292, 0.166664, 0.102631, 0.034654, -0.034654, -0.102631, -0.166664, -0.224292, -0.273300, -0.311806, -0.338330, -0.351851, 0.346760, 0.293969, 0.196424, 0.068975, -0.068975, -0.196424, -0.293969, -0.346760, -0.346760, -0.293969, -0.196424, -0.068975, 0.068975, 0.196424, 0.293969, 0.346760, 0.338330, 0.224292, 0.034654, -0.166664, -0.311806, -0.351851, -0.273300, -0.102631, 0.102631, 0.273300, 0.351851, 0.311806, 0.166664, -0.034654, -0.224292, -0.338330, 0.326641, 0.135299, -0.135299, -0.326641, -0.326641, -0.135299, 0.135299, 0.326641, 0.326641, 0.135299, -0.135299, -0.326641, -0.326641, -0.135299, 0.135299, 0.326641, 0.311806, 0.034654, -0.273300, -0.338330, -0.102631, 0.224292, 0.351851, 0.166664, -0.166664, -0.351851, -0.224292, 0.102631, 0.338330, 0.273300, -0.034654, -0.311806, 0.293969, -0.068975, -0.346760, -0.196424, 0.196424, 0.346760, 0.068975, -0.293969, -0.293969, 0.068975, 0.346760, 0.196424, -0.196424, -0.346760, -0.068975, 0.293969, 0.273300, -0.166664, -0.338330, 0.034654, 0.351851, 0.102631, -0.311806, -0.224292, 0.224292, 0.311806, -0.102631, -0.351851, -0.034654, 0.338330, 0.166664, -0.273300, 0.250000, -0.250000, -0.250000, 0.250000, 0.250000, -0.250000, -0.250000, 0.250000, 0.250000, -0.250000, -0.250000, 0.250000, 0.250000, -0.250000, -0.250000, 0.250000, 0.224292, -0.311806, -0.102631, 0.351851, -0.034654, -0.338330, 0.166664, 0.273300, -0.273300, -0.166664, 0.338330, 0.034654, -0.351851, 0.102631, 0.311806, -0.224292, 0.196424, -0.346760, 0.068975, 0.293969, -0.293969, -0.068975, 0.346760, -0.196424, -0.196424, 0.346760, -0.068975, -0.293969, 0.293969, 0.068975, -0.346760, 0.196424, 0.166664, -0.351851, 0.224292, 0.102631, -0.338330, 0.273300, 0.034654, -0.311806, 0.311806, -0.034654, -0.273300, 0.338330, -0.102631, -0.224292, 0.351851, -0.166664, 0.135299, -0.326641, 0.326641, -0.135299, -0.135299, 0.326641, -0.326641, 0.135299, 0.135299, -0.326641, 0.326641, -0.135299, -0.135299, 0.326641, -0.326641, 0.135299, 0.102631, -0.273300, 0.351851, -0.311806, 0.166664, 0.034654, -0.224292, 0.338330, -0.338330, 0.224292, -0.034654, -0.166664, 0.311806, -0.351851, 0.273300, -0.102631, 0.068975, -0.196424, 0.293969, -0.346760, 0.346760, -0.293969, 0.196424, -0.068975, -0.068975, 0.196424, -0.293969, 0.346760, -0.346760, 0.293969, -0.196424, 0.068975, 0.034654, -0.102631, 0.166664, -0.224292, 0.273300, -0.311806, 0.338330, -0.351851, 0.351851, -0.338330, 0.311806, -0.273300, 0.224292, -0.166664, 0.102631, -0.034654 }; float adst_16[256] = { 0.033094, 0.065889, 0.098087, 0.129396, 0.159534, 0.188227, 0.215215, 0.240255, 0.263118, 0.283599, 0.301511, 0.316693, 0.329007, 0.338341, 0.344612, 0.347761, 0.098087, 0.188227, 0.263118, 0.316693, 0.344612, 0.344612, 0.316693, 0.263118, 0.188227, 0.098087, 0.000000, -0.098087, -0.188227, -0.263118, -0.316693, -0.344612, 0.159534, 0.283599, 0.344612, 0.329007, 0.240255, 0.098087, -0.065889, -0.215215, -0.316693, -0.347761, -0.301511, -0.188227, -0.033094, 0.129396, 0.263118, 0.338341, 0.215215, 0.338341, 0.316693, 0.159534, -0.065889, -0.263118, -0.347761, -0.283599, -0.098087, 0.129396, 0.301511, 0.344612, 0.240255, 0.033094, -0.188227, -0.329007, 0.263118, 0.344612, 0.188227, -0.098087, -0.316693, -0.316693, -0.098087, 0.188227, 0.344612, 0.263118, 0.000000, -0.263118, -0.344612, -0.188227, 0.098087, 0.316693, 0.301511, 0.301511, 0.000000, -0.301511, -0.301511, -0.000000, 0.301511, 0.301511, 0.000000, -0.301511, -0.301511, -0.000000, 0.301511, 0.301511, 0.000000, -0.301511, 0.329007, 0.215215, -0.188227, -0.338341, -0.033094, 0.316693, 0.240255, -0.159534, -0.344612, -0.065889, 0.301511, 0.263118, -0.129396, -0.347761, -0.098087, 0.283599, 0.344612, 0.098087, -0.316693, -0.188227, 0.263118, 0.263118, -0.188227, -0.316693, 0.098087, 0.344612, 0.000000, -0.344612, -0.098087, 0.316693, 0.188227, -0.263118, 0.347761, -0.033094, -0.344612, 0.065889, 0.338341, -0.098087, -0.329007, 0.129396, 0.316693, -0.159534, -0.301511, 0.188227, 0.283599, -0.215215, -0.263118, 0.240255, 0.338341, -0.159534, -0.263118, 0.283599, 0.129396, -0.344612, 0.033094, 0.329007, -0.188227, -0.240255, 0.301511, 0.098087, -0.347761, 0.065889, 0.316693, -0.215215, 0.316693, -0.263118, -0.098087, 0.344612, -0.188227, -0.188227, 0.344612, -0.098087, -0.263118, 0.316693, 0.000000, -0.316693, 0.263118, 0.098087, -0.344612, 0.188227, 0.283599, -0.329007, 0.098087, 0.215215, -0.347761, 0.188227, 0.129396, -0.338341, 0.263118, 0.033094, -0.301511, 0.316693, -0.065889, -0.240255, 0.344612, -0.159534, 0.240255, -0.347761, 0.263118, -0.033094, -0.215215, 0.344612, -0.283599, 0.065889, 0.188227, -0.338341, 0.301511, -0.098087, -0.159534, 0.329007, -0.316693, 0.129396, 0.188227, -0.316693, 0.344612, -0.263118, 0.098087, 0.098087, -0.263118, 0.344612, -0.316693, 0.188227, 0.000000, -0.188227, 0.316693, -0.344612, 0.263118, -0.098087, 0.129396, -0.240255, 0.316693, -0.347761, 0.329007, -0.263118, 0.159534, -0.033094, -0.098087, 0.215215, -0.301511, 0.344612, -0.338341, 0.283599, -0.188227, 0.065889, 0.065889, -0.129396, 0.188227, -0.240255, 0.283599, -0.316693, 0.338341, -0.347761, 0.344612, -0.329007, 0.301511, -0.263118, 0.215215, -0.159534, 0.098087, -0.033094 }; #endif static const int xC1S7 = 16069; static const int xC2S6 = 15137; static const int xC3S5 = 13623; static const int xC4S4 = 11585; static const int xC5S3 = 9102; static const int xC6S2 = 6270; static const int xC7S1 = 3196; #define SHIFT_BITS 14 #define DOROUND(X) X += (1<<(SHIFT_BITS-1)); #define FINAL_SHIFT 3 #define FINAL_ROUNDING (1<<(FINAL_SHIFT -1)) #define IN_SHIFT (FINAL_SHIFT+1) void vp8_short_fdct8x8_c(short *InputData, short *OutputData, int pitch) { int loop; int short_pitch = pitch >> 1; int is07, is12, is34, is56; int is0734, is1256; int id07, id12, id34, id56; int irot_input_x, irot_input_y; int icommon_product1; // Re-used product (c4s4 * (s12 - s56)) int icommon_product2; // Re-used product (c4s4 * (d12 + d56)) int temp1, temp2; // intermediate variable for computation int InterData[64]; int *ip = InterData; short *op = OutputData; for (loop = 0; loop < 8; loop++) { // Pre calculate some common sums and differences. is07 = (InputData[0] + InputData[7]) << IN_SHIFT; is12 = (InputData[1] + InputData[2]) << IN_SHIFT; is34 = (InputData[3] + InputData[4]) << IN_SHIFT; is56 = (InputData[5] + InputData[6]) << IN_SHIFT; id07 = (InputData[0] - InputData[7]) << IN_SHIFT; id12 = (InputData[1] - InputData[2]) << IN_SHIFT; id34 = (InputData[3] - InputData[4]) << IN_SHIFT; id56 = (InputData[5] - InputData[6]) << IN_SHIFT; is0734 = is07 + is34; is1256 = is12 + is56; // Pre-Calculate some common product terms. icommon_product1 = xC4S4 * (is12 - is56); DOROUND(icommon_product1) icommon_product1 >>= SHIFT_BITS; icommon_product2 = xC4S4 * (id12 + id56); DOROUND(icommon_product2) icommon_product2 >>= SHIFT_BITS; ip[0] = (xC4S4 * (is0734 + is1256)); DOROUND(ip[0]); ip[0] >>= SHIFT_BITS; ip[4] = (xC4S4 * (is0734 - is1256)); DOROUND(ip[4]); ip[4] >>= SHIFT_BITS; // Define inputs to rotation for outputs 2 and 6 irot_input_x = id12 - id56; irot_input_y = is07 - is34; // Apply rotation for outputs 2 and 6. temp1 = xC6S2 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC2S6 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[2] = temp1 + temp2; temp1 = xC6S2 * irot_input_y; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC2S6 * irot_input_x; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[6] = temp1 - temp2; // Define inputs to rotation for outputs 1 and 7 irot_input_x = icommon_product1 + id07; irot_input_y = -(id34 + icommon_product2); // Apply rotation for outputs 1 and 7. temp1 = xC1S7 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC7S1 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[1] = temp1 - temp2; temp1 = xC7S1 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC1S7 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[7] = temp1 + temp2; // Define inputs to rotation for outputs 3 and 5 irot_input_x = id07 - icommon_product1; irot_input_y = id34 - icommon_product2; // Apply rotation for outputs 3 and 5. temp1 = xC3S5 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC5S3 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[3] = temp1 - temp2; temp1 = xC5S3 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC3S5 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; ip[5] = temp1 + temp2; // Increment data pointer for next row InputData += short_pitch; ip += 8; } // Performed DCT on rows, now transform the columns ip = InterData; for (loop = 0; loop < 8; loop++) { // Pre calculate some common sums and differences. is07 = ip[0 * 8] + ip[7 * 8]; is12 = ip[1 * 8] + ip[2 * 8]; is34 = ip[3 * 8] + ip[4 * 8]; is56 = ip[5 * 8] + ip[6 * 8]; id07 = ip[0 * 8] - ip[7 * 8]; id12 = ip[1 * 8] - ip[2 * 8]; id34 = ip[3 * 8] - ip[4 * 8]; id56 = ip[5 * 8] - ip[6 * 8]; is0734 = is07 + is34; is1256 = is12 + is56; // Pre-Calculate some common product terms icommon_product1 = xC4S4 * (is12 - is56); icommon_product2 = xC4S4 * (id12 + id56); DOROUND(icommon_product1) DOROUND(icommon_product2) icommon_product1 >>= SHIFT_BITS; icommon_product2 >>= SHIFT_BITS; temp1 = xC4S4 * (is0734 + is1256); temp2 = xC4S4 * (is0734 - is1256); DOROUND(temp1); DOROUND(temp2); temp1 >>= SHIFT_BITS; temp2 >>= SHIFT_BITS; op[0 * 8] = (temp1 + FINAL_ROUNDING) >> FINAL_SHIFT; op[4 * 8] = (temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; // Define inputs to rotation for outputs 2 and 6 irot_input_x = id12 - id56; irot_input_y = is07 - is34; // Apply rotation for outputs 2 and 6. temp1 = xC6S2 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC2S6 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[2 * 8] = (temp1 + temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; temp1 = xC6S2 * irot_input_y; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC2S6 * irot_input_x; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[6 * 8] = (temp1 - temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; // Define inputs to rotation for outputs 1 and 7 irot_input_x = icommon_product1 + id07; irot_input_y = -(id34 + icommon_product2); // Apply rotation for outputs 1 and 7. temp1 = xC1S7 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC7S1 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[1 * 8] = (temp1 - temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; temp1 = xC7S1 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC1S7 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[7 * 8] = (temp1 + temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; // Define inputs to rotation for outputs 3 and 5 irot_input_x = id07 - icommon_product1; irot_input_y = id34 - icommon_product2; // Apply rotation for outputs 3 and 5. temp1 = xC3S5 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC5S3 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[3 * 8] = (temp1 - temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; temp1 = xC5S3 * irot_input_x; DOROUND(temp1); temp1 >>= SHIFT_BITS; temp2 = xC3S5 * irot_input_y; DOROUND(temp2); temp2 >>= SHIFT_BITS; op[5 * 8] = (temp1 + temp2 + FINAL_ROUNDING) >> FINAL_SHIFT; // Increment data pointer for next column. ip++; op++; } } void vp8_short_fhaar2x2_c(short *input, short *output, int pitch) { // pitch = 8 /* [1 1; 1 -1] orthogonal transform */ /* use position: 0,1, 4, 8 */ int i; short *ip1 = input; short *op1 = output; for (i = 0; i < 16; i++) { op1[i] = 0; } op1[0] = (ip1[0] + ip1[1] + ip1[4] + ip1[8] + 1) >> 1; op1[1] = (ip1[0] - ip1[1] + ip1[4] - ip1[8]) >> 1; op1[4] = (ip1[0] + ip1[1] - ip1[4] - ip1[8]) >> 1; op1[8] = (ip1[0] - ip1[1] - ip1[4] + ip1[8]) >> 1; } #if CONFIG_HYBRIDTRANSFORM8X8 || CONFIG_HYBRIDTRANSFORM || CONFIG_HYBRIDTRANSFORM16X16 void vp8_fht_c(short *input, short *output, int pitch, TX_TYPE tx_type, int tx_dim) { vp8_clear_system_state(); // Make it simd safe : __asm emms; { int i, j, k; float bufa[256], bufb[256]; // buffers are for floating-point test purpose // the implementation could be simplified in // conjunction with integer transform short *ip = input; short *op = output; float *pfa = &bufa[0]; float *pfb = &bufb[0]; // pointers to vertical and horizontal transforms float *ptv, *pth; assert(tx_type != DCT_DCT); // load and convert residual array into floating-point for(j = 0; j < tx_dim; j++) { for(i = 0; i < tx_dim; i++) { pfa[i] = (float)ip[i]; } pfa += tx_dim; ip += pitch / 2; } // vertical transformation pfa = &bufa[0]; pfb = &bufb[0]; switch(tx_type) { case ADST_ADST : case ADST_DCT : ptv = (tx_dim == 4) ? &adst_4[0] : ((tx_dim == 8) ? &adst_8[0] : &adst_16[0]); break; default : ptv = (tx_dim == 4) ? &dct_4[0] : ((tx_dim == 8) ? &dct_8[0] : &dct_16[0]); break; } for(j = 0; j < tx_dim; j++) { for(i = 0; i < tx_dim; i++) { pfb[i] = 0; for(k = 0; k < tx_dim; k++) { pfb[i] += ptv[k] * pfa[(k * tx_dim)]; } pfa += 1; } pfb += tx_dim; ptv += tx_dim; pfa = &bufa[0]; } // horizontal transformation pfa = &bufa[0]; pfb = &bufb[0]; switch(tx_type) { case ADST_ADST : case DCT_ADST : pth = (tx_dim == 4) ? &adst_4[0] : ((tx_dim == 8) ? &adst_8[0] : &adst_16[0]); break; default : pth = (tx_dim == 4) ? &dct_4[0] : ((tx_dim == 8) ? &dct_8[0] : &dct_16[0]); break; } for(j = 0; j < tx_dim; j++) { for(i = 0; i < tx_dim; i++) { pfa[i] = 0; for(k = 0; k < tx_dim; k++) { pfa[i] += pfb[k] * pth[k]; } pth += tx_dim; } pfa += tx_dim; pfb += tx_dim; // pth -= tx_dim * tx_dim; switch(tx_type) { case ADST_ADST : case DCT_ADST : pth = (tx_dim == 4) ? &adst_4[0] : ((tx_dim == 8) ? &adst_8[0] : &adst_16[0]); break; default : pth = (tx_dim == 4) ? &dct_4[0] : ((tx_dim == 8) ? &dct_8[0] : &dct_16[0]); break; } } // convert to short integer format and load BLOCKD buffer op = output ; pfa = &bufa[0] ; for(j = 0; j < tx_dim; j++) { for(i = 0; i < tx_dim; i++) { op[i] = (pfa[i] > 0 ) ? (short)( 8 * pfa[i] + 0.49) : -(short)(- 8 * pfa[i] + 0.49); } op += tx_dim; pfa += tx_dim; } } vp8_clear_system_state(); // Make it simd safe : __asm emms; } #endif void vp8_short_fdct4x4_c(short *input, short *output, int pitch) { int i; int a1, b1, c1, d1; short *ip = input; short *op = output; for (i = 0; i < 4; i++) { a1 = ((ip[0] + ip[3]) << 5); b1 = ((ip[1] + ip[2]) << 5); c1 = ((ip[1] - ip[2]) << 5); d1 = ((ip[0] - ip[3]) << 5); op[0] = a1 + b1; op[2] = a1 - b1; op[1] = (c1 * 2217 + d1 * 5352 + 14500) >> 12; op[3] = (d1 * 2217 - c1 * 5352 + 7500) >> 12; ip += pitch / 2; op += 4; } ip = output; op = output; for (i = 0; i < 4; i++) { a1 = ip[0] + ip[12]; b1 = ip[4] + ip[8]; c1 = ip[4] - ip[8]; d1 = ip[0] - ip[12]; op[0] = (a1 + b1 + 7) >> 4; op[8] = (a1 - b1 + 7) >> 4; op[4] = ((c1 * 2217 + d1 * 5352 + 12000) >> 16) + (d1 != 0); op[12] = (d1 * 2217 - c1 * 5352 + 51000) >> 16; ip++; op++; } } void vp8_short_fdct8x4_c(short *input, short *output, int pitch) { vp8_short_fdct4x4_c(input, output, pitch); vp8_short_fdct4x4_c(input + 4, output + 16, pitch); } void vp8_short_walsh4x4_c(short *input, short *output, int pitch) { int i; int a1, b1, c1, d1; short *ip = input; short *op = output; int pitch_short = pitch >> 1; for (i = 0; i < 4; i++) { a1 = ip[0 * pitch_short] + ip[3 * pitch_short]; b1 = ip[1 * pitch_short] + ip[2 * pitch_short]; c1 = ip[1 * pitch_short] - ip[2 * pitch_short]; d1 = ip[0 * pitch_short] - ip[3 * pitch_short]; op[0] = (a1 + b1 + 1) >> 1; op[4] = (c1 + d1) >> 1; op[8] = (a1 - b1) >> 1; op[12] = (d1 - c1) >> 1; ip++; op++; } ip = output; op = output; for (i = 0; i < 4; i++) { a1 = ip[0] + ip[3]; b1 = ip[1] + ip[2]; c1 = ip[1] - ip[2]; d1 = ip[0] - ip[3]; op[0] = (a1 + b1 + 1) >> 1; op[1] = (c1 + d1) >> 1; op[2] = (a1 - b1) >> 1; op[3] = (d1 - c1) >> 1; ip += 4; op += 4; } } #if CONFIG_LOSSLESS void vp8_short_walsh4x4_lossless_c(short *input, short *output, int pitch) { int i; int a1, b1, c1, d1; short *ip = input; short *op = output; int pitch_short = pitch >> 1; for (i = 0; i < 4; i++) { a1 = (ip[0 * pitch_short] + ip[3 * pitch_short]) >> Y2_WHT_UPSCALE_FACTOR; b1 = (ip[1 * pitch_short] + ip[2 * pitch_short]) >> Y2_WHT_UPSCALE_FACTOR; c1 = (ip[1 * pitch_short] - ip[2 * pitch_short]) >> Y2_WHT_UPSCALE_FACTOR; d1 = (ip[0 * pitch_short] - ip[3 * pitch_short]) >> Y2_WHT_UPSCALE_FACTOR; op[0] = (a1 + b1 + 1) >> 1; op[4] = (c1 + d1) >> 1; op[8] = (a1 - b1) >> 1; op[12] = (d1 - c1) >> 1; ip++; op++; } ip = output; op = output; for (i = 0; i < 4; i++) { a1 = ip[0] + ip[3]; b1 = ip[1] + ip[2]; c1 = ip[1] - ip[2]; d1 = ip[0] - ip[3]; op[0] = ((a1 + b1 + 1) >> 1) << Y2_WHT_UPSCALE_FACTOR; op[1] = ((c1 + d1) >> 1) << Y2_WHT_UPSCALE_FACTOR; op[2] = ((a1 - b1) >> 1) << Y2_WHT_UPSCALE_FACTOR; op[3] = ((d1 - c1) >> 1) << Y2_WHT_UPSCALE_FACTOR; ip += 4; op += 4; } } void vp8_short_walsh4x4_x8_c(short *input, short *output, int pitch) { int i; int a1, b1, c1, d1; short *ip = input; short *op = output; int pitch_short = pitch >> 1; for (i = 0; i < 4; i++) { a1 = ip[0 * pitch_short] + ip[3 * pitch_short]; b1 = ip[1 * pitch_short] + ip[2 * pitch_short]; c1 = ip[1 * pitch_short] - ip[2 * pitch_short]; d1 = ip[0 * pitch_short] - ip[3 * pitch_short]; op[0] = (a1 + b1 + 1) >> 1; op[4] = (c1 + d1) >> 1; op[8] = (a1 - b1) >> 1; op[12] = (d1 - c1) >> 1; ip++; op++; } ip = output; op = output; for (i = 0; i < 4; i++) { a1 = ip[0] + ip[3]; b1 = ip[1] + ip[2]; c1 = ip[1] - ip[2]; d1 = ip[0] - ip[3]; op[0] = ((a1 + b1 + 1) >> 1) << WHT_UPSCALE_FACTOR; op[1] = ((c1 + d1) >> 1) << WHT_UPSCALE_FACTOR; op[2] = ((a1 - b1) >> 1) << WHT_UPSCALE_FACTOR; op[3] = ((d1 - c1) >> 1) << WHT_UPSCALE_FACTOR; ip += 4; op += 4; } } void vp8_short_walsh8x4_x8_c(short *input, short *output, int pitch) { vp8_short_walsh4x4_x8_c(input, output, pitch); vp8_short_walsh4x4_x8_c(input + 4, output + 16, pitch); } #endif static const double C1 = 0.995184726672197; static const double C2 = 0.98078528040323; static const double C3 = 0.956940335732209; static const double C4 = 0.923879532511287; static const double C5 = 0.881921264348355; static const double C6 = 0.831469612302545; static const double C7 = 0.773010453362737; static const double C8 = 0.707106781186548; static const double C9 = 0.634393284163646; static const double C10 = 0.555570233019602; static const double C11 = 0.471396736825998; static const double C12 = 0.38268343236509; static const double C13 = 0.290284677254462; static const double C14 = 0.195090322016128; static const double C15 = 0.098017140329561; static void dct16x16_1d(double input[16], double output[16]) { vp8_clear_system_state(); // Make it simd safe : __asm emms; { double step[16]; double intermediate[16]; double temp1, temp2; // step 1 step[ 0] = input[0] + input[15]; step[ 1] = input[1] + input[14]; step[ 2] = input[2] + input[13]; step[ 3] = input[3] + input[12]; step[ 4] = input[4] + input[11]; step[ 5] = input[5] + input[10]; step[ 6] = input[6] + input[ 9]; step[ 7] = input[7] + input[ 8]; step[ 8] = input[7] - input[ 8]; step[ 9] = input[6] - input[ 9]; step[10] = input[5] - input[10]; step[11] = input[4] - input[11]; step[12] = input[3] - input[12]; step[13] = input[2] - input[13]; step[14] = input[1] - input[14]; step[15] = input[0] - input[15]; // step 2 output[0] = step[0] + step[7]; output[1] = step[1] + step[6]; output[2] = step[2] + step[5]; output[3] = step[3] + step[4]; output[4] = step[3] - step[4]; output[5] = step[2] - step[5]; output[6] = step[1] - step[6]; output[7] = step[0] - step[7]; temp1 = step[ 8]*C7; temp2 = step[15]*C9; output[ 8] = temp1 + temp2; temp1 = step[ 9]*C11; temp2 = step[14]*C5; output[ 9] = temp1 - temp2; temp1 = step[10]*C3; temp2 = step[13]*C13; output[10] = temp1 + temp2; temp1 = step[11]*C15; temp2 = step[12]*C1; output[11] = temp1 - temp2; temp1 = step[11]*C1; temp2 = step[12]*C15; output[12] = temp2 + temp1; temp1 = step[10]*C13; temp2 = step[13]*C3; output[13] = temp2 - temp1; temp1 = step[ 9]*C5; temp2 = step[14]*C11; output[14] = temp2 + temp1; temp1 = step[ 8]*C9; temp2 = step[15]*C7; output[15] = temp2 - temp1; // step 3 step[ 0] = output[0] + output[3]; step[ 1] = output[1] + output[2]; step[ 2] = output[1] - output[2]; step[ 3] = output[0] - output[3]; temp1 = output[4]*C14; temp2 = output[7]*C2; step[ 4] = temp1 + temp2; temp1 = output[5]*C10; temp2 = output[6]*C6; step[ 5] = temp1 + temp2; temp1 = output[5]*C6; temp2 = output[6]*C10; step[ 6] = temp2 - temp1; temp1 = output[4]*C2; temp2 = output[7]*C14; step[ 7] = temp2 - temp1; step[ 8] = output[ 8] + output[11]; step[ 9] = output[ 9] + output[10]; step[10] = output[ 9] - output[10]; step[11] = output[ 8] - output[11]; step[12] = output[12] + output[15]; step[13] = output[13] + output[14]; step[14] = output[13] - output[14]; step[15] = output[12] - output[15]; // step 4 output[ 0] = (step[ 0] + step[ 1]); output[ 8] = (step[ 0] - step[ 1]); temp1 = step[2]*C12; temp2 = step[3]*C4; temp1 = temp1 + temp2; output[ 4] = 2*(temp1*C8); temp1 = step[2]*C4; temp2 = step[3]*C12; temp1 = temp2 - temp1; output[12] = 2*(temp1*C8); output[ 2] = 2*((step[4] + step[ 5])*C8); output[14] = 2*((step[7] - step[ 6])*C8); temp1 = step[4] - step[5]; temp2 = step[6] + step[7]; output[ 6] = (temp1 + temp2); output[10] = (temp1 - temp2); intermediate[8] = step[8] + step[14]; intermediate[9] = step[9] + step[15]; temp1 = intermediate[8]*C12; temp2 = intermediate[9]*C4; temp1 = temp1 - temp2; output[3] = 2*(temp1*C8); temp1 = intermediate[8]*C4; temp2 = intermediate[9]*C12; temp1 = temp2 + temp1; output[13] = 2*(temp1*C8); output[ 9] = 2*((step[10] + step[11])*C8); intermediate[11] = step[10] - step[11]; intermediate[12] = step[12] + step[13]; intermediate[13] = step[12] - step[13]; intermediate[14] = step[ 8] - step[14]; intermediate[15] = step[ 9] - step[15]; output[15] = (intermediate[11] + intermediate[12]); output[ 1] = -(intermediate[11] - intermediate[12]); output[ 7] = 2*(intermediate[13]*C8); temp1 = intermediate[14]*C12; temp2 = intermediate[15]*C4; temp1 = temp1 - temp2; output[11] = -2*(temp1*C8); temp1 = intermediate[14]*C4; temp2 = intermediate[15]*C12; temp1 = temp2 + temp1; output[ 5] = 2*(temp1*C8); } vp8_clear_system_state(); // Make it simd safe : __asm emms; } void vp8_short_fdct16x16_c(short *input, short *out, int pitch) { vp8_clear_system_state(); // Make it simd safe : __asm emms; { int shortpitch = pitch >> 1; int i, j; double output[256]; // First transform columns for (i = 0; i < 16; i++) { double temp_in[16], temp_out[16]; for (j = 0; j < 16; j++) temp_in[j] = input[j*shortpitch + i]; dct16x16_1d(temp_in, temp_out); for (j = 0; j < 16; j++) output[j*16 + i] = temp_out[j]; } // Then transform rows for (i = 0; i < 16; ++i) { double temp_in[16], temp_out[16]; for (j = 0; j < 16; ++j) temp_in[j] = output[j + i*16]; dct16x16_1d(temp_in, temp_out); for (j = 0; j < 16; ++j) output[j + i*16] = temp_out[j]; } // Scale by some magic number for (i = 0; i < 256; i++) out[i] = (short)round(output[i]/2); } vp8_clear_system_state(); // Make it simd safe : __asm emms; }