/* * 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 #include #include "vpx_mem/vpx_mem.h" #include "vpxscale_arbitrary.h" extern BICUBIC_SCALER_STRUCT g_b_scaler; int bicubic_scale_c64(int in_width, int in_height, int in_stride, int out_width, int out_height, int out_stride, unsigned char *input_image, unsigned char *output_image) { short *restrict l_w, * restrict l_h; short *restrict c_w, * restrict c_h; unsigned char *restrict ip, * restrict op, *restrict op_w; unsigned char *restrict hbuf; int h, w, lw, lh; int phase_offset_w, phase_offset_h; double coeff; int max_phase; c_w = g_b_scaler.c_w; c_h = g_b_scaler.c_h; op = output_image; l_w = g_b_scaler.l_w; l_h = g_b_scaler.l_h; phase_offset_h = 0; for (h = 0; h < out_height; h++) { // select the row to work on lh = l_h[h]; ip = input_image + (in_stride * lh); coeff = _memd8_const(&c_h[phase_offset_h*4]); // vp8_filter the row vertically into an temporary buffer. // If the phase offset == 0 then all the multiplication // is going to result in the output equalling the input. // So instead point the temporary buffer to the input. // Also handle the boundry condition of not being able to // filter that last lines. if (phase_offset_h && (lh < in_height - 2)) { hbuf = g_b_scaler.hbuf; for (w = 0; w < in_width; w += 4) { int ip1, ip2, ip3, ip4; int y13_12, y11_10, y23_22, y21_20, y33_32, y31_30, y43_42, y41_40; int y10_20, y11_21, y12_22, y13_23, y30_40, y31_41, y32_42, y33_43; int s1, s2, s3, s4; ip1 = _mem4_const(&ip[w - in_stride]); ip2 = _mem4_const(&ip[w]); ip3 = _mem4_const(&ip[w + in_stride]); ip4 = _mem4_const(&ip[w + 2*in_stride]); // realignment of data. Unpack the data so that it is in short // format instead of bytes. y13_12 = _unpkhu4(ip1); y11_10 = _unpklu4(ip1); y23_22 = _unpkhu4(ip2); y21_20 = _unpklu4(ip2); y33_32 = _unpkhu4(ip3); y31_30 = _unpklu4(ip3); y43_42 = _unpkhu4(ip4); y41_40 = _unpklu4(ip4); // repack the data so that elements 1 and 2 are together. this // lines up so that a dot product with the coefficients can be // done. y10_20 = _pack2(y11_10, y21_20); y11_21 = _packh2(y11_10, y21_20); y12_22 = _pack2(y13_12, y23_22); y13_23 = _packh2(y13_12, y23_22); s1 = _dotp2(_hi(coeff), y10_20); s2 = _dotp2(_hi(coeff), y11_21); s3 = _dotp2(_hi(coeff), y12_22); s4 = _dotp2(_hi(coeff), y13_23); y30_40 = _pack2(y31_30, y41_40); y31_41 = _packh2(y31_30, y41_40); y32_42 = _pack2(y33_32, y43_42); y33_43 = _packh2(y33_32, y43_42); // now repack elements 3 and 4 together. s1 += _dotp2(_lo(coeff), y30_40); s2 += _dotp2(_lo(coeff), y31_41); s3 += _dotp2(_lo(coeff), y32_42); s4 += _dotp2(_lo(coeff), y33_43); s1 = s1 >> 12; s2 = s2 >> 12; s3 = s3 >> 12; s4 = s4 >> 12; s1 = _pack2(s2, s1); s2 = _pack2(s4, s3); _amem4(&hbuf[w]) = _spacku4(s2, s1); } } else hbuf = ip; // increase the phase offset for the next time around. if (++phase_offset_h >= g_b_scaler.nh) phase_offset_h = 0; op_w = op; // will never be able to interpolate first pixel, so just copy it // over here. phase_offset_w = 1; *op_w++ = hbuf[0]; if (1 >= g_b_scaler.nw) phase_offset_w = 0; max_phase = g_b_scaler.nw; for (w = 1; w < out_width; w++) { double coefficients; int hbuf_high, hbuf_low, hbuf_both; int sum_high, sum_low, sum; // get the index to use to expand the image lw = l_w[w]; coefficients = _amemd8_const(&c_w[phase_offset_w*4]); hbuf_both = _mem4_const(&hbuf[lw-1]); hbuf_high = _unpkhu4(hbuf_both); hbuf_low = _unpklu4(hbuf_both); sum_high = _dotp2(_hi(coefficients), hbuf_high); sum_low = _dotp2(_lo(coefficients), hbuf_low); sum = (sum_high + sum_low) >> 12; if (++phase_offset_w >= max_phase) phase_offset_w = 0; if ((lw + 2) >= in_width) sum = hbuf[lw]; *op_w++ = sum; } op += out_stride; } return 0; } void bicubic_scale_frame_c64(YV12_BUFFER_CONFIG *src, YV12_BUFFER_CONFIG *dst, int new_width, int new_height) { dst->y_width = new_width; dst->y_height = new_height; dst->uv_width = new_width / 2; dst->uv_height = new_height / 2; dst->y_stride = dst->y_width; dst->uv_stride = dst->uv_width; bicubic_scale_c64(src->y_width, src->y_height, src->y_stride, new_width, new_height, dst->y_stride, src->y_buffer, dst->y_buffer); bicubic_scale_c64(src->uv_width, src->uv_height, src->uv_stride, new_width / 2, new_height / 2, dst->uv_stride, src->u_buffer, dst->u_buffer); bicubic_scale_c64(src->uv_width, src->uv_height, src->uv_stride, new_width / 2, new_height / 2, dst->uv_stride, src->v_buffer, dst->v_buffer); }