src/dec/io.c - platform/external/webp - Git at Google

 // Copyright 2011 Google Inc. All Rights Reserved.
 //
 // This code is licensed under the same terms as WebM:
 //  Software License Agreement:  http://www.webmproject.org/license/software/
 //  Additional IP Rights Grant:  http://www.webmproject.org/license/additional/
 // -----------------------------------------------------------------------------
 //
 // functions for sample output.
 //
 // Author: Skal (pascal.massimino@gmail.com)

 #include <assert.h>
 #include <stdlib.h>
 #include "../dec/vp8i.h"
 #include "./webpi.h"
 #include "../dsp/dsp.h"
 #include "../dsp/yuv.h"

 #if defined(__cplusplus) || defined(c_plusplus)
 extern "C" {
 #endif

 //------------------------------------------------------------------------------
 // Main YUV<->RGB conversion functions

 static int EmitYUV(const VP8Io* const io, WebPDecParams* const p) {
   WebPDecBuffer* output = p->output;
   const WebPYUVABuffer* const buf = &output->u.YUVA;
   uint8_t* const y_dst = buf->y + io->mb_y * buf->y_stride;
   uint8_t* const u_dst = buf->u + (io->mb_y >> 1) * buf->u_stride;
   uint8_t* const v_dst = buf->v + (io->mb_y >> 1) * buf->v_stride;
   const int mb_w = io->mb_w;
   const int mb_h = io->mb_h;
   const int uv_w = (mb_w + 1) / 2;
   const int uv_h = (mb_h + 1) / 2;
   int j;
   for (j = 0; j < mb_h; ++j) {
     memcpy(y_dst + j * buf->y_stride, io->y + j * io->y_stride, mb_w);
   }
   for (j = 0; j < uv_h; ++j) {
     memcpy(u_dst + j * buf->u_stride, io->u + j * io->uv_stride, uv_w);
     memcpy(v_dst + j * buf->v_stride, io->v + j * io->uv_stride, uv_w);
   }
   return io->mb_h;
 }

 // Point-sampling U/V sampler.
 static int EmitSampledRGB(const VP8Io* const io, WebPDecParams* const p) {
   WebPDecBuffer* output = p->output;
   const WebPRGBABuffer* const buf = &output->u.RGBA;
   uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
   const uint8_t* y_src = io->y;
   const uint8_t* u_src = io->u;
   const uint8_t* v_src = io->v;
   const WebPSampleLinePairFunc sample = WebPSamplers[output->colorspace];
   const int mb_w = io->mb_w;
   const int last = io->mb_h - 1;
   int j;
   for (j = 0; j < last; j += 2) {
     sample(y_src, y_src + io->y_stride, u_src, v_src,
            dst, dst + buf->stride, mb_w);
     y_src += 2 * io->y_stride;
     u_src += io->uv_stride;
     v_src += io->uv_stride;
     dst += 2 * buf->stride;
   }
   if (j == last) {  // Just do the last line twice
     sample(y_src, y_src, u_src, v_src, dst, dst, mb_w);
   }
   return io->mb_h;
 }

 //------------------------------------------------------------------------------
 // YUV444 -> RGB conversion

 #if 0   // TODO(skal): this is for future rescaling.
 static int EmitRGB(const VP8Io* const io, WebPDecParams* const p) {
   WebPDecBuffer* output = p->output;
   const WebPRGBABuffer* const buf = &output->u.RGBA;
   uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
   const uint8_t* y_src = io->y;
   const uint8_t* u_src = io->u;
   const uint8_t* v_src = io->v;
   const WebPYUV444Converter convert = WebPYUV444Converters[output->colorspace];
   const int mb_w = io->mb_w;
   const int last = io->mb_h;
   int j;
   for (j = 0; j < last; ++j) {
     convert(y_src, u_src, v_src, dst, mb_w);
     y_src += io->y_stride;
     u_src += io->uv_stride;
     v_src += io->uv_stride;
     dst += buf->stride;
   }
   return io->mb_h;
 }
 #endif

 //------------------------------------------------------------------------------
 // Fancy upsampling

 #ifdef FANCY_UPSAMPLING
 static int EmitFancyRGB(const VP8Io* const io, WebPDecParams* const p) {
   int num_lines_out = io->mb_h;   // a priori guess
   const WebPRGBABuffer* const buf = &p->output->u.RGBA;
   uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
   WebPUpsampleLinePairFunc upsample = WebPUpsamplers[p->output->colorspace];
   const uint8_t* cur_y = io->y;
   const uint8_t* cur_u = io->u;
   const uint8_t* cur_v = io->v;
   const uint8_t* top_u = p->tmp_u;
   const uint8_t* top_v = p->tmp_v;
   int y = io->mb_y;
   int y_end = io->mb_y + io->mb_h;
   const int mb_w = io->mb_w;
   const int uv_w = (mb_w + 1) / 2;

   if (y == 0) {
     // First line is special cased. We mirror the u/v samples at boundary.
     upsample(NULL, cur_y, cur_u, cur_v, cur_u, cur_v, NULL, dst, mb_w);
   } else {
     // We can finish the left-over line from previous call.
     upsample(p->tmp_y, cur_y, top_u, top_v, cur_u, cur_v,
              dst - buf->stride, dst, mb_w);
     ++num_lines_out;
   }
   // Loop over each output pairs of row.
   for (; y + 2 < y_end; y += 2) {
     top_u = cur_u;
     top_v = cur_v;
     cur_u += io->uv_stride;
     cur_v += io->uv_stride;
     dst += 2 * buf->stride;
     cur_y += 2 * io->y_stride;
     upsample(cur_y - io->y_stride, cur_y,
              top_u, top_v, cur_u, cur_v,
              dst - buf->stride, dst, mb_w);
   }
   // move to last row
   cur_y += io->y_stride;
   if (io->crop_top + y_end < io->crop_bottom) {
     // Save the unfinished samples for next call (as we're not done yet).
     memcpy(p->tmp_y, cur_y, mb_w * sizeof(*p->tmp_y));
     memcpy(p->tmp_u, cur_u, uv_w * sizeof(*p->tmp_u));
     memcpy(p->tmp_v, cur_v, uv_w * sizeof(*p->tmp_v));
     // The fancy upsampler leaves a row unfinished behind
     // (except for the very last row)
     num_lines_out--;
   } else {
     // Process the very last row of even-sized picture
     if (!(y_end & 1)) {
       upsample(cur_y, NULL, cur_u, cur_v, cur_u, cur_v,
               dst + buf->stride, NULL, mb_w);
     }
   }
   return num_lines_out;
 }

 #endif    /* FANCY_UPSAMPLING */

 //------------------------------------------------------------------------------

 static int EmitAlphaYUV(const VP8Io* const io, WebPDecParams* const p) {
   const uint8_t* alpha = io->a;
   const WebPYUVABuffer* const buf = &p->output->u.YUVA;
   const int mb_w = io->mb_w;
   const int mb_h = io->mb_h;
   uint8_t* dst = buf->a + io->mb_y * buf->a_stride;
   int j;

   if (alpha != NULL) {
     for (j = 0; j < mb_h; ++j) {
       memcpy(dst, alpha, mb_w * sizeof(*dst));
       alpha += io->width;
       dst += buf->a_stride;
     }
   } else if (buf->a != NULL) {
     // the user requested alpha, but there is none, set it to opaque.
     for (j = 0; j < mb_h; ++j) {
       memset(dst, 0xff, mb_w * sizeof(*dst));
       dst += buf->a_stride;
     }
   }
   return 0;
 }

 static int GetAlphaSourceRow(const VP8Io* const io,
                              const uint8_t** alpha, int* const num_rows) {
   int start_y = io->mb_y;
   *num_rows = io->mb_h;

   // Compensate for the 1-line delay of the fancy upscaler.
   // This is similar to EmitFancyRGB().
   if (io->fancy_upsampling) {
     if (start_y == 0) {
       // We don't process the last row yet. It'll be done during the next call.
       --*num_rows;
     } else {
       --start_y;
       // Fortunately, *alpha data is persistent, so we can go back
       // one row and finish alpha blending, now that the fancy upscaler
       // completed the YUV->RGB interpolation.
       *alpha -= io->width;
     }
     if (io->crop_top + io->mb_y + io->mb_h == io->crop_bottom) {
       // If it's the very last call, we process all the remaing rows!
       *num_rows = io->crop_bottom - io->crop_top - start_y;
     }
   }
   return start_y;
 }

 static int EmitAlphaRGB(const VP8Io* const io, WebPDecParams* const p) {
   const uint8_t* alpha = io->a;
   if (alpha != NULL) {
     const int mb_w = io->mb_w;
     int i, j;
     const WEBP_CSP_MODE colorspace = p->output->colorspace;
     const int alpha_first =
         (colorspace == MODE_ARGB || colorspace == MODE_Argb);
     const WebPRGBABuffer* const buf = &p->output->u.RGBA;
     int num_rows;
     const int start_y = GetAlphaSourceRow(io, &alpha, &num_rows);
     uint32_t alpha_mask = 0xff;

     {
       uint8_t* const base_rgba = buf->rgba + start_y * buf->stride;
       uint8_t* dst = base_rgba + (alpha_first ? 0 : 3);
       for (j = 0; j < num_rows; ++j) {
         for (i = 0; i < mb_w; ++i) {
           const uint32_t alpha_value = alpha[i];
           dst[4 * i] = alpha_value;
           alpha_mask &= alpha_value;
         }
         alpha += io->width;
         dst += buf->stride;
       }
       // alpha_mask is < 0xff if there's non-trivial alpha to premultiply with.
       if (alpha_mask != 0xff && WebPIsPremultipliedMode(colorspace)) {
         WebPApplyAlphaMultiply(base_rgba, alpha_first,
                                mb_w, num_rows, buf->stride);
       }
     }
   }
   return 0;
 }

 static int EmitAlphaRGBA4444(const VP8Io* const io, WebPDecParams* const p) {
   const uint8_t* alpha = io->a;
   if (alpha != NULL) {
     const int mb_w = io->mb_w;
     int i, j;
     const WebPRGBABuffer* const buf = &p->output->u.RGBA;
     int num_rows;
     const int start_y = GetAlphaSourceRow(io, &alpha, &num_rows);
     uint32_t alpha_mask = 0x0f;

     {
       uint8_t* const base_rgba = buf->rgba + start_y * buf->stride;
       uint8_t* alpha_dst = base_rgba + 1;
       for (j = 0; j < num_rows; ++j) {
         for (i = 0; i < mb_w; ++i) {
           // Fill in the alpha value (converted to 4 bits).
           const uint32_t alpha_value = alpha[i] >> 4;
           alpha_dst[2 * i] = (alpha_dst[2 * i] & 0xf0) | alpha_value;
           alpha_mask &= alpha_value;
         }
         alpha += io->width;
         alpha_dst += buf->stride;
       }
       if (alpha_mask != 0x0f && p->output->colorspace == MODE_rgbA_4444) {
         WebPApplyAlphaMultiply4444(base_rgba, mb_w, num_rows, buf->stride);
       }
     }
   }
   return 0;
 }

 //------------------------------------------------------------------------------
 // YUV rescaling (no final RGB conversion needed)

 static int Rescale(const uint8_t* src, int src_stride,
                    int new_lines, WebPRescaler* const wrk) {
   int num_lines_out = 0;
   while (new_lines > 0) {    // import new contributions of source rows.
     const int lines_in = WebPRescalerImport(wrk, new_lines, src, src_stride);
     src += lines_in * src_stride;
     new_lines -= lines_in;
     num_lines_out += WebPRescalerExport(wrk);    // emit output row(s)
   }
   return num_lines_out;
 }

 static int EmitRescaledYUV(const VP8Io* const io, WebPDecParams* const p) {
   const int mb_h = io->mb_h;
   const int uv_mb_h = (mb_h + 1) >> 1;
   const int num_lines_out = Rescale(io->y, io->y_stride, mb_h, &p->scaler_y);
   Rescale(io->u, io->uv_stride, uv_mb_h, &p->scaler_u);
   Rescale(io->v, io->uv_stride, uv_mb_h, &p->scaler_v);
   return num_lines_out;
 }

 static int EmitRescaledAlphaYUV(const VP8Io* const io, WebPDecParams* const p) {
   if (io->a != NULL) {
     Rescale(io->a, io->width, io->mb_h, &p->scaler_a);
   }
   return 0;
 }

 static int InitYUVRescaler(const VP8Io* const io, WebPDecParams* const p) {
   const int has_alpha = WebPIsAlphaMode(p->output->colorspace);
   const WebPYUVABuffer* const buf = &p->output->u.YUVA;
   const int out_width  = io->scaled_width;
   const int out_height = io->scaled_height;
   const int uv_out_width  = (out_width + 1) >> 1;
   const int uv_out_height = (out_height + 1) >> 1;
   const int uv_in_width  = (io->mb_w + 1) >> 1;
   const int uv_in_height = (io->mb_h + 1) >> 1;
   const size_t work_size = 2 * out_width;   // scratch memory for luma rescaler
   const size_t uv_work_size = 2 * uv_out_width;  // and for each u/v ones
   size_t tmp_size;
   int32_t* work;

   tmp_size = work_size + 2 * uv_work_size;
   if (has_alpha) {
     tmp_size += work_size;
   }
   p->memory = calloc(1, tmp_size * sizeof(*work));
   if (p->memory == NULL) {
     return 0;   // memory error
   }
   work = (int32_t*)p->memory;
   WebPRescalerInit(&p->scaler_y, io->mb_w, io->mb_h,
                    buf->y, out_width, out_height, buf->y_stride, 1,
                    io->mb_w, out_width, io->mb_h, out_height,
                    work);
   WebPRescalerInit(&p->scaler_u, uv_in_width, uv_in_height,
                    buf->u, uv_out_width, uv_out_height, buf->u_stride, 1,
                    uv_in_width, uv_out_width,
                    uv_in_height, uv_out_height,
                    work + work_size);
   WebPRescalerInit(&p->scaler_v, uv_in_width, uv_in_height,
                    buf->v, uv_out_width, uv_out_height, buf->v_stride, 1,
                    uv_in_width, uv_out_width,
                    uv_in_height, uv_out_height,
                    work + work_size + uv_work_size);
   p->emit = EmitRescaledYUV;

   if (has_alpha) {
     WebPRescalerInit(&p->scaler_a, io->mb_w, io->mb_h,
                      buf->a, out_width, out_height, buf->a_stride, 1,
                      io->mb_w, out_width, io->mb_h, out_height,
                      work + work_size + 2 * uv_work_size);
     p->emit_alpha = EmitRescaledAlphaYUV;
   }
   return 1;
 }

 //------------------------------------------------------------------------------
 // RGBA rescaling

 static int ExportRGB(WebPDecParams* const p, int y_pos) {
   const WebPYUV444Converter convert =
       WebPYUV444Converters[p->output->colorspace];
   const WebPRGBABuffer* const buf = &p->output->u.RGBA;
   uint8_t* dst = buf->rgba + (p->last_y + y_pos) * buf->stride;
   int num_lines_out = 0;
   // For RGB rescaling, because of the YUV420, current scan position
   // U/V can be +1/-1 line from the Y one.  Hence the double test.
   while (WebPRescalerHasPendingOutput(&p->scaler_y) &&
          WebPRescalerHasPendingOutput(&p->scaler_u)) {
     assert(p->last_y + y_pos + num_lines_out < p->output->height);
     assert(p->scaler_u.y_accum == p->scaler_v.y_accum);
     WebPRescalerExportRow(&p->scaler_y);
     WebPRescalerExportRow(&p->scaler_u);
     WebPRescalerExportRow(&p->scaler_v);
     convert(p->scaler_y.dst, p->scaler_u.dst, p->scaler_v.dst,
             dst, p->scaler_y.dst_width);
     dst += buf->stride;
     ++num_lines_out;
   }
   return num_lines_out;
 }

 static int EmitRescaledRGB(const VP8Io* const io, WebPDecParams* const p) {
   const int mb_h = io->mb_h;
   const int uv_mb_h = (mb_h + 1) >> 1;
   int j = 0, uv_j = 0;
   int num_lines_out = 0;
   while (j < mb_h) {
     const int y_lines_in =
         WebPRescalerImport(&p->scaler_y, mb_h - j,
                            io->y + j * io->y_stride, io->y_stride);
     const int u_lines_in =
         WebPRescalerImport(&p->scaler_u, uv_mb_h - uv_j,
                            io->u + uv_j * io->uv_stride, io->uv_stride);
     const int v_lines_in =
         WebPRescalerImport(&p->scaler_v, uv_mb_h - uv_j,
                            io->v + uv_j * io->uv_stride, io->uv_stride);
     (void)v_lines_in;   // remove a gcc warning
     assert(u_lines_in == v_lines_in);
     j += y_lines_in;
     uv_j += u_lines_in;
     num_lines_out += ExportRGB(p, num_lines_out);
   }
   return num_lines_out;
 }

 static int ExportAlpha(WebPDecParams* const p, int y_pos) {
   const WebPRGBABuffer* const buf = &p->output->u.RGBA;
   uint8_t* const base_rgba = buf->rgba + (p->last_y + y_pos) * buf->stride;
   const WEBP_CSP_MODE colorspace = p->output->colorspace;
   const int alpha_first =
       (colorspace == MODE_ARGB || colorspace == MODE_Argb);
   uint8_t* dst = base_rgba + (alpha_first ? 0 : 3);
   int num_lines_out = 0;
   const int is_premult_alpha = WebPIsPremultipliedMode(colorspace);
   uint32_t alpha_mask = 0xff;
   const int width = p->scaler_a.dst_width;

   while (WebPRescalerHasPendingOutput(&p->scaler_a)) {
     int i;
     assert(p->last_y + y_pos + num_lines_out < p->output->height);
     WebPRescalerExportRow(&p->scaler_a);
     for (i = 0; i < width; ++i) {
       const uint32_t alpha_value = p->scaler_a.dst[i];
       dst[4 * i] = alpha_value;
       alpha_mask &= alpha_value;
     }
     dst += buf->stride;
     ++num_lines_out;
   }
   if (is_premult_alpha && alpha_mask != 0xff) {
     WebPApplyAlphaMultiply(base_rgba, alpha_first,
                            width, num_lines_out, buf->stride);
   }
   return num_lines_out;
 }

 static int ExportAlphaRGBA4444(WebPDecParams* const p, int y_pos) {
   const WebPRGBABuffer* const buf = &p->output->u.RGBA;
   uint8_t* const base_rgba = buf->rgba + (p->last_y + y_pos) * buf->stride;
   uint8_t* alpha_dst = base_rgba + 1;
   int num_lines_out = 0;
   const WEBP_CSP_MODE colorspace = p->output->colorspace;
   const int width = p->scaler_a.dst_width;
   const int is_premult_alpha = WebPIsPremultipliedMode(colorspace);
   uint32_t alpha_mask = 0x0f;

   while (WebPRescalerHasPendingOutput(&p->scaler_a)) {
     int i;
     assert(p->last_y + y_pos + num_lines_out < p->output->height);
     WebPRescalerExportRow(&p->scaler_a);
     for (i = 0; i < width; ++i) {
       // Fill in the alpha value (converted to 4 bits).
       const uint32_t alpha_value = p->scaler_a.dst[i] >> 4;
       alpha_dst[2 * i] = (alpha_dst[2 * i] & 0xf0) | alpha_value;
       alpha_mask &= alpha_value;
     }
     alpha_dst += buf->stride;
     ++num_lines_out;
   }
   if (is_premult_alpha && alpha_mask != 0x0f) {
     WebPApplyAlphaMultiply4444(base_rgba, width, num_lines_out, buf->stride);
   }
   return num_lines_out;
 }

 static int EmitRescaledAlphaRGB(const VP8Io* const io, WebPDecParams* const p) {
   if (io->a != NULL) {
     WebPRescaler* const scaler = &p->scaler_a;
     int j = 0;
     int pos = 0;
     while (j < io->mb_h) {
       j += WebPRescalerImport(scaler, io->mb_h - j,
                               io->a + j * io->width, io->width);
       pos += p->emit_alpha_row(p, pos);
     }
   }
   return 0;
 }

 static int InitRGBRescaler(const VP8Io* const io, WebPDecParams* const p) {
   const int has_alpha = WebPIsAlphaMode(p->output->colorspace);
   const int out_width  = io->scaled_width;
   const int out_height = io->scaled_height;
   const int uv_in_width  = (io->mb_w + 1) >> 1;
   const int uv_in_height = (io->mb_h + 1) >> 1;
   const size_t work_size = 2 * out_width;   // scratch memory for one rescaler
   int32_t* work;  // rescalers work area
   uint8_t* tmp;   // tmp storage for scaled YUV444 samples before RGB conversion
   size_t tmp_size1, tmp_size2;

   tmp_size1 = 3 * work_size;
   tmp_size2 = 3 * out_width;
   if (has_alpha) {
     tmp_size1 += work_size;
     tmp_size2 += out_width;
   }
   p->memory =
       calloc(1, tmp_size1 * sizeof(*work) + tmp_size2 * sizeof(*tmp));
   if (p->memory == NULL) {
     return 0;   // memory error
   }
   work = (int32_t*)p->memory;
   tmp = (uint8_t*)(work + tmp_size1);
   WebPRescalerInit(&p->scaler_y, io->mb_w, io->mb_h,
                    tmp + 0 * out_width, out_width, out_height, 0, 1,
                    io->mb_w, out_width, io->mb_h, out_height,
                    work + 0 * work_size);
   WebPRescalerInit(&p->scaler_u, uv_in_width, uv_in_height,
                    tmp + 1 * out_width, out_width, out_height, 0, 1,
                    io->mb_w, 2 * out_width, io->mb_h, 2 * out_height,
                    work + 1 * work_size);
   WebPRescalerInit(&p->scaler_v, uv_in_width, uv_in_height,
                    tmp + 2 * out_width, out_width, out_height, 0, 1,
                    io->mb_w, 2 * out_width, io->mb_h, 2 * out_height,
                    work + 2 * work_size);
   p->emit = EmitRescaledRGB;

   if (has_alpha) {
     WebPRescalerInit(&p->scaler_a, io->mb_w, io->mb_h,
                      tmp + 3 * out_width, out_width, out_height, 0, 1,
                      io->mb_w, out_width, io->mb_h, out_height,
                      work + 3 * work_size);
     p->emit_alpha = EmitRescaledAlphaRGB;
     if (p->output->colorspace == MODE_RGBA_4444 ||
         p->output->colorspace == MODE_rgbA_4444) {
       p->emit_alpha_row = ExportAlphaRGBA4444;
     } else {
       p->emit_alpha_row = ExportAlpha;
     }
   }
   return 1;
 }

 //------------------------------------------------------------------------------
 // Default custom functions

 static int CustomSetup(VP8Io* io) {
   WebPDecParams* const p = (WebPDecParams*)io->opaque;
   const WEBP_CSP_MODE colorspace = p->output->colorspace;
   const int is_rgb = WebPIsRGBMode(colorspace);
   const int is_alpha = WebPIsAlphaMode(colorspace);

   p->memory = NULL;
   p->emit = NULL;
   p->emit_alpha = NULL;
   p->emit_alpha_row = NULL;
   if (!WebPIoInitFromOptions(p->options, io, is_alpha ? MODE_YUV : MODE_YUVA)) {
     return 0;
   }

   if (io->use_scaling) {
     const int ok = is_rgb ? InitRGBRescaler(io, p) : InitYUVRescaler(io, p);
     if (!ok) {
       return 0;    // memory error
     }
   } else {
     if (is_rgb) {
       p->emit = EmitSampledRGB;   // default
 #ifdef FANCY_UPSAMPLING
       if (io->fancy_upsampling) {
         const int uv_width = (io->mb_w + 1) >> 1;
         p->memory = malloc(io->mb_w + 2 * uv_width);
         if (p->memory == NULL) {
           return 0;   // memory error.
         }
         p->tmp_y = (uint8_t*)p->memory;
         p->tmp_u = p->tmp_y + io->mb_w;
         p->tmp_v = p->tmp_u + uv_width;
         p->emit = EmitFancyRGB;
         WebPInitUpsamplers();
       }
 #endif
     } else {
       p->emit = EmitYUV;
     }
     if (is_alpha) {  // need transparency output
       if (WebPIsPremultipliedMode(colorspace)) WebPInitPremultiply();
       p->emit_alpha =
           (colorspace == MODE_RGBA_4444 || colorspace == MODE_rgbA_4444) ?
               EmitAlphaRGBA4444
           : is_rgb ? EmitAlphaRGB
           : EmitAlphaYUV;
     }
   }

   if (is_rgb) {
     VP8YUVInit();
   }
   return 1;
 }

 //------------------------------------------------------------------------------

 static int CustomPut(const VP8Io* io) {
   WebPDecParams* p = (WebPDecParams*)io->opaque;
   const int mb_w = io->mb_w;
   const int mb_h = io->mb_h;
   int num_lines_out;
   assert(!(io->mb_y & 1));

   if (mb_w <= 0 || mb_h <= 0) {
     return 0;
   }
   num_lines_out = p->emit(io, p);
   if (p->emit_alpha) {
     p->emit_alpha(io, p);
   }
   p->last_y += num_lines_out;
   return 1;
 }

 //------------------------------------------------------------------------------

 static void CustomTeardown(const VP8Io* io) {
   WebPDecParams* const p = (WebPDecParams*)io->opaque;
   free(p->memory);
   p->memory = NULL;
 }

 //------------------------------------------------------------------------------
 // Main entry point

 void WebPInitCustomIo(WebPDecParams* const params, VP8Io* const io) {
   io->put      = CustomPut;
   io->setup    = CustomSetup;
   io->teardown = CustomTeardown;
   io->opaque   = params;
 }

 //------------------------------------------------------------------------------

 #if defined(__cplusplus) || defined(c_plusplus)
 }    // extern "C"
 #endif
	// Copyright 2011 Google Inc. All Rights Reserved.
	//
	// This code is licensed under the same terms as WebM:
	// Software License Agreement: http://www.webmproject.org/license/software/
	// Additional IP Rights Grant: http://www.webmproject.org/license/additional/
	// -----------------------------------------------------------------------------
	//
	// functions for sample output.
	//
	// Author: Skal (pascal.massimino@gmail.com)

	#include <assert.h>
	#include <stdlib.h>
	#include "../dec/vp8i.h"
	#include "./webpi.h"
	#include "../dsp/dsp.h"
	#include "../dsp/yuv.h"

	#if defined(__cplusplus) \|\| defined(c_plusplus)
	extern "C" {
	#endif

	//------------------------------------------------------------------------------
	// Main YUV<->RGB conversion functions

	static int EmitYUV(const VP8Io* const io, WebPDecParams* const p) {
	WebPDecBuffer* output = p->output;
	const WebPYUVABuffer* const buf = &output->u.YUVA;
	uint8_t* const y_dst = buf->y + io->mb_y * buf->y_stride;
	uint8_t* const u_dst = buf->u + (io->mb_y >> 1) * buf->u_stride;
	uint8_t* const v_dst = buf->v + (io->mb_y >> 1) * buf->v_stride;
	const int mb_w = io->mb_w;
	const int mb_h = io->mb_h;
	const int uv_w = (mb_w + 1) / 2;
	const int uv_h = (mb_h + 1) / 2;
	int j;
	for (j = 0; j < mb_h; ++j) {
	memcpy(y_dst + j * buf->y_stride, io->y + j * io->y_stride, mb_w);
	}
	for (j = 0; j < uv_h; ++j) {
	memcpy(u_dst + j * buf->u_stride, io->u + j * io->uv_stride, uv_w);
	memcpy(v_dst + j * buf->v_stride, io->v + j * io->uv_stride, uv_w);
	}
	return io->mb_h;
	}

	// Point-sampling U/V sampler.
	static int EmitSampledRGB(const VP8Io* const io, WebPDecParams* const p) {
	WebPDecBuffer* output = p->output;
	const WebPRGBABuffer* const buf = &output->u.RGBA;
	uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
	const uint8_t* y_src = io->y;
	const uint8_t* u_src = io->u;
	const uint8_t* v_src = io->v;
	const WebPSampleLinePairFunc sample = WebPSamplers[output->colorspace];
	const int mb_w = io->mb_w;
	const int last = io->mb_h - 1;
	int j;
	for (j = 0; j < last; j += 2) {
	sample(y_src, y_src + io->y_stride, u_src, v_src,
	dst, dst + buf->stride, mb_w);
	y_src += 2 * io->y_stride;
	u_src += io->uv_stride;
	v_src += io->uv_stride;
	dst += 2 * buf->stride;
	}
	if (j == last) { // Just do the last line twice
	sample(y_src, y_src, u_src, v_src, dst, dst, mb_w);
	}
	return io->mb_h;
	}

	//------------------------------------------------------------------------------
	// YUV444 -> RGB conversion

	#if 0 // TODO(skal): this is for future rescaling.
	static int EmitRGB(const VP8Io* const io, WebPDecParams* const p) {
	WebPDecBuffer* output = p->output;
	const WebPRGBABuffer* const buf = &output->u.RGBA;
	uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
	const uint8_t* y_src = io->y;
	const uint8_t* u_src = io->u;
	const uint8_t* v_src = io->v;
	const WebPYUV444Converter convert = WebPYUV444Converters[output->colorspace];
	const int mb_w = io->mb_w;
	const int last = io->mb_h;
	int j;
	for (j = 0; j < last; ++j) {
	convert(y_src, u_src, v_src, dst, mb_w);
	y_src += io->y_stride;
	u_src += io->uv_stride;
	v_src += io->uv_stride;
	dst += buf->stride;
	}
	return io->mb_h;
	}
	#endif

	//------------------------------------------------------------------------------
	// Fancy upsampling

	#ifdef FANCY_UPSAMPLING
	static int EmitFancyRGB(const VP8Io* const io, WebPDecParams* const p) {
	int num_lines_out = io->mb_h; // a priori guess
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	uint8_t* dst = buf->rgba + io->mb_y * buf->stride;
	WebPUpsampleLinePairFunc upsample = WebPUpsamplers[p->output->colorspace];
	const uint8_t* cur_y = io->y;
	const uint8_t* cur_u = io->u;
	const uint8_t* cur_v = io->v;
	const uint8_t* top_u = p->tmp_u;
	const uint8_t* top_v = p->tmp_v;
	int y = io->mb_y;
	int y_end = io->mb_y + io->mb_h;
	const int mb_w = io->mb_w;
	const int uv_w = (mb_w + 1) / 2;

	if (y == 0) {
	// First line is special cased. We mirror the u/v samples at boundary.
	upsample(NULL, cur_y, cur_u, cur_v, cur_u, cur_v, NULL, dst, mb_w);
	} else {
	// We can finish the left-over line from previous call.
	upsample(p->tmp_y, cur_y, top_u, top_v, cur_u, cur_v,
	dst - buf->stride, dst, mb_w);
	++num_lines_out;
	}
	// Loop over each output pairs of row.
	for (; y + 2 < y_end; y += 2) {
	top_u = cur_u;
	top_v = cur_v;
	cur_u += io->uv_stride;
	cur_v += io->uv_stride;
	dst += 2 * buf->stride;
	cur_y += 2 * io->y_stride;
	upsample(cur_y - io->y_stride, cur_y,
	top_u, top_v, cur_u, cur_v,
	dst - buf->stride, dst, mb_w);
	}
	// move to last row
	cur_y += io->y_stride;
	if (io->crop_top + y_end < io->crop_bottom) {
	// Save the unfinished samples for next call (as we're not done yet).
	memcpy(p->tmp_y, cur_y, mb_w * sizeof(*p->tmp_y));
	memcpy(p->tmp_u, cur_u, uv_w * sizeof(*p->tmp_u));
	memcpy(p->tmp_v, cur_v, uv_w * sizeof(*p->tmp_v));
	// The fancy upsampler leaves a row unfinished behind
	// (except for the very last row)
	num_lines_out--;
	} else {
	// Process the very last row of even-sized picture
	if (!(y_end & 1)) {
	upsample(cur_y, NULL, cur_u, cur_v, cur_u, cur_v,
	dst + buf->stride, NULL, mb_w);
	}
	}
	return num_lines_out;
	}

	#endif /* FANCY_UPSAMPLING */

	//------------------------------------------------------------------------------

	static int EmitAlphaYUV(const VP8Io* const io, WebPDecParams* const p) {
	const uint8_t* alpha = io->a;
	const WebPYUVABuffer* const buf = &p->output->u.YUVA;
	const int mb_w = io->mb_w;
	const int mb_h = io->mb_h;
	uint8_t* dst = buf->a + io->mb_y * buf->a_stride;
	int j;

	if (alpha != NULL) {
	for (j = 0; j < mb_h; ++j) {
	memcpy(dst, alpha, mb_w * sizeof(*dst));
	alpha += io->width;
	dst += buf->a_stride;
	}
	} else if (buf->a != NULL) {
	// the user requested alpha, but there is none, set it to opaque.
	for (j = 0; j < mb_h; ++j) {
	memset(dst, 0xff, mb_w * sizeof(*dst));
	dst += buf->a_stride;
	}
	}
	return 0;
	}

	static int GetAlphaSourceRow(const VP8Io* const io,
	const uint8_t** alpha, int* const num_rows) {
	int start_y = io->mb_y;
	*num_rows = io->mb_h;

	// Compensate for the 1-line delay of the fancy upscaler.
	// This is similar to EmitFancyRGB().
	if (io->fancy_upsampling) {
	if (start_y == 0) {
	// We don't process the last row yet. It'll be done during the next call.
	--*num_rows;
	} else {
	--start_y;
	// Fortunately, *alpha data is persistent, so we can go back
	// one row and finish alpha blending, now that the fancy upscaler
	// completed the YUV->RGB interpolation.
	*alpha -= io->width;
	}
	if (io->crop_top + io->mb_y + io->mb_h == io->crop_bottom) {
	// If it's the very last call, we process all the remaing rows!
	*num_rows = io->crop_bottom - io->crop_top - start_y;
	}
	}
	return start_y;
	}

	static int EmitAlphaRGB(const VP8Io* const io, WebPDecParams* const p) {
	const uint8_t* alpha = io->a;
	if (alpha != NULL) {
	const int mb_w = io->mb_w;
	int i, j;
	const WEBP_CSP_MODE colorspace = p->output->colorspace;
	const int alpha_first =
	(colorspace == MODE_ARGB \|\| colorspace == MODE_Argb);
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	int num_rows;
	const int start_y = GetAlphaSourceRow(io, &alpha, &num_rows);
	uint32_t alpha_mask = 0xff;

	{
	uint8_t* const base_rgba = buf->rgba + start_y * buf->stride;
	uint8_t* dst = base_rgba + (alpha_first ? 0 : 3);
	for (j = 0; j < num_rows; ++j) {
	for (i = 0; i < mb_w; ++i) {
	const uint32_t alpha_value = alpha[i];
	dst[4 * i] = alpha_value;
	alpha_mask &= alpha_value;
	}
	alpha += io->width;
	dst += buf->stride;
	}
	// alpha_mask is < 0xff if there's non-trivial alpha to premultiply with.
	if (alpha_mask != 0xff && WebPIsPremultipliedMode(colorspace)) {
	WebPApplyAlphaMultiply(base_rgba, alpha_first,
	mb_w, num_rows, buf->stride);
	}
	}
	}
	return 0;
	}

	static int EmitAlphaRGBA4444(const VP8Io* const io, WebPDecParams* const p) {
	const uint8_t* alpha = io->a;
	if (alpha != NULL) {
	const int mb_w = io->mb_w;
	int i, j;
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	int num_rows;
	const int start_y = GetAlphaSourceRow(io, &alpha, &num_rows);
	uint32_t alpha_mask = 0x0f;

	{
	uint8_t* const base_rgba = buf->rgba + start_y * buf->stride;
	uint8_t* alpha_dst = base_rgba + 1;
	for (j = 0; j < num_rows; ++j) {
	for (i = 0; i < mb_w; ++i) {
	// Fill in the alpha value (converted to 4 bits).
	const uint32_t alpha_value = alpha[i] >> 4;
	alpha_dst[2 * i] = (alpha_dst[2 * i] & 0xf0) \| alpha_value;
	alpha_mask &= alpha_value;
	}
	alpha += io->width;
	alpha_dst += buf->stride;
	}
	if (alpha_mask != 0x0f && p->output->colorspace == MODE_rgbA_4444) {
	WebPApplyAlphaMultiply4444(base_rgba, mb_w, num_rows, buf->stride);
	}
	}
	}
	return 0;
	}

	//------------------------------------------------------------------------------
	// YUV rescaling (no final RGB conversion needed)

	static int Rescale(const uint8_t* src, int src_stride,
	int new_lines, WebPRescaler* const wrk) {
	int num_lines_out = 0;
	while (new_lines > 0) { // import new contributions of source rows.
	const int lines_in = WebPRescalerImport(wrk, new_lines, src, src_stride);
	src += lines_in * src_stride;
	new_lines -= lines_in;
	num_lines_out += WebPRescalerExport(wrk); // emit output row(s)
	}
	return num_lines_out;
	}

	static int EmitRescaledYUV(const VP8Io* const io, WebPDecParams* const p) {
	const int mb_h = io->mb_h;
	const int uv_mb_h = (mb_h + 1) >> 1;
	const int num_lines_out = Rescale(io->y, io->y_stride, mb_h, &p->scaler_y);
	Rescale(io->u, io->uv_stride, uv_mb_h, &p->scaler_u);
	Rescale(io->v, io->uv_stride, uv_mb_h, &p->scaler_v);
	return num_lines_out;
	}

	static int EmitRescaledAlphaYUV(const VP8Io* const io, WebPDecParams* const p) {
	if (io->a != NULL) {
	Rescale(io->a, io->width, io->mb_h, &p->scaler_a);
	}
	return 0;
	}

	static int InitYUVRescaler(const VP8Io* const io, WebPDecParams* const p) {
	const int has_alpha = WebPIsAlphaMode(p->output->colorspace);
	const WebPYUVABuffer* const buf = &p->output->u.YUVA;
	const int out_width = io->scaled_width;
	const int out_height = io->scaled_height;
	const int uv_out_width = (out_width + 1) >> 1;
	const int uv_out_height = (out_height + 1) >> 1;
	const int uv_in_width = (io->mb_w + 1) >> 1;
	const int uv_in_height = (io->mb_h + 1) >> 1;
	const size_t work_size = 2 * out_width; // scratch memory for luma rescaler
	const size_t uv_work_size = 2 * uv_out_width; // and for each u/v ones
	size_t tmp_size;
	int32_t* work;

	tmp_size = work_size + 2 * uv_work_size;
	if (has_alpha) {
	tmp_size += work_size;
	}
	p->memory = calloc(1, tmp_size * sizeof(*work));
	if (p->memory == NULL) {
	return 0; // memory error
	}
	work = (int32_t*)p->memory;
	WebPRescalerInit(&p->scaler_y, io->mb_w, io->mb_h,
	buf->y, out_width, out_height, buf->y_stride, 1,
	io->mb_w, out_width, io->mb_h, out_height,
	work);
	WebPRescalerInit(&p->scaler_u, uv_in_width, uv_in_height,
	buf->u, uv_out_width, uv_out_height, buf->u_stride, 1,
	uv_in_width, uv_out_width,
	uv_in_height, uv_out_height,
	work + work_size);
	WebPRescalerInit(&p->scaler_v, uv_in_width, uv_in_height,
	buf->v, uv_out_width, uv_out_height, buf->v_stride, 1,
	uv_in_width, uv_out_width,
	uv_in_height, uv_out_height,
	work + work_size + uv_work_size);
	p->emit = EmitRescaledYUV;

	if (has_alpha) {
	WebPRescalerInit(&p->scaler_a, io->mb_w, io->mb_h,
	buf->a, out_width, out_height, buf->a_stride, 1,
	io->mb_w, out_width, io->mb_h, out_height,
	work + work_size + 2 * uv_work_size);
	p->emit_alpha = EmitRescaledAlphaYUV;
	}
	return 1;
	}

	//------------------------------------------------------------------------------
	// RGBA rescaling

	static int ExportRGB(WebPDecParams* const p, int y_pos) {
	const WebPYUV444Converter convert =
	WebPYUV444Converters[p->output->colorspace];
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	uint8_t* dst = buf->rgba + (p->last_y + y_pos) * buf->stride;
	int num_lines_out = 0;
	// For RGB rescaling, because of the YUV420, current scan position
	// U/V can be +1/-1 line from the Y one. Hence the double test.
	while (WebPRescalerHasPendingOutput(&p->scaler_y) &&
	WebPRescalerHasPendingOutput(&p->scaler_u)) {
	assert(p->last_y + y_pos + num_lines_out < p->output->height);
	assert(p->scaler_u.y_accum == p->scaler_v.y_accum);
	WebPRescalerExportRow(&p->scaler_y);
	WebPRescalerExportRow(&p->scaler_u);
	WebPRescalerExportRow(&p->scaler_v);
	convert(p->scaler_y.dst, p->scaler_u.dst, p->scaler_v.dst,
	dst, p->scaler_y.dst_width);
	dst += buf->stride;
	++num_lines_out;
	}
	return num_lines_out;
	}

	static int EmitRescaledRGB(const VP8Io* const io, WebPDecParams* const p) {
	const int mb_h = io->mb_h;
	const int uv_mb_h = (mb_h + 1) >> 1;
	int j = 0, uv_j = 0;
	int num_lines_out = 0;
	while (j < mb_h) {
	const int y_lines_in =
	WebPRescalerImport(&p->scaler_y, mb_h - j,
	io->y + j * io->y_stride, io->y_stride);
	const int u_lines_in =
	WebPRescalerImport(&p->scaler_u, uv_mb_h - uv_j,
	io->u + uv_j * io->uv_stride, io->uv_stride);
	const int v_lines_in =
	WebPRescalerImport(&p->scaler_v, uv_mb_h - uv_j,
	io->v + uv_j * io->uv_stride, io->uv_stride);
	(void)v_lines_in; // remove a gcc warning
	assert(u_lines_in == v_lines_in);
	j += y_lines_in;
	uv_j += u_lines_in;
	num_lines_out += ExportRGB(p, num_lines_out);
	}
	return num_lines_out;
	}

	static int ExportAlpha(WebPDecParams* const p, int y_pos) {
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	uint8_t* const base_rgba = buf->rgba + (p->last_y + y_pos) * buf->stride;
	const WEBP_CSP_MODE colorspace = p->output->colorspace;
	const int alpha_first =
	(colorspace == MODE_ARGB \|\| colorspace == MODE_Argb);
	uint8_t* dst = base_rgba + (alpha_first ? 0 : 3);
	int num_lines_out = 0;
	const int is_premult_alpha = WebPIsPremultipliedMode(colorspace);
	uint32_t alpha_mask = 0xff;
	const int width = p->scaler_a.dst_width;

	while (WebPRescalerHasPendingOutput(&p->scaler_a)) {
	int i;
	assert(p->last_y + y_pos + num_lines_out < p->output->height);
	WebPRescalerExportRow(&p->scaler_a);
	for (i = 0; i < width; ++i) {
	const uint32_t alpha_value = p->scaler_a.dst[i];
	dst[4 * i] = alpha_value;
	alpha_mask &= alpha_value;
	}
	dst += buf->stride;
	++num_lines_out;
	}
	if (is_premult_alpha && alpha_mask != 0xff) {
	WebPApplyAlphaMultiply(base_rgba, alpha_first,
	width, num_lines_out, buf->stride);
	}
	return num_lines_out;
	}

	static int ExportAlphaRGBA4444(WebPDecParams* const p, int y_pos) {
	const WebPRGBABuffer* const buf = &p->output->u.RGBA;
	uint8_t* const base_rgba = buf->rgba + (p->last_y + y_pos) * buf->stride;
	uint8_t* alpha_dst = base_rgba + 1;
	int num_lines_out = 0;
	const WEBP_CSP_MODE colorspace = p->output->colorspace;
	const int width = p->scaler_a.dst_width;
	const int is_premult_alpha = WebPIsPremultipliedMode(colorspace);
	uint32_t alpha_mask = 0x0f;

	while (WebPRescalerHasPendingOutput(&p->scaler_a)) {
	int i;
	assert(p->last_y + y_pos + num_lines_out < p->output->height);
	WebPRescalerExportRow(&p->scaler_a);
	for (i = 0; i < width; ++i) {
	// Fill in the alpha value (converted to 4 bits).
	const uint32_t alpha_value = p->scaler_a.dst[i] >> 4;
	alpha_dst[2 * i] = (alpha_dst[2 * i] & 0xf0) \| alpha_value;
	alpha_mask &= alpha_value;
	}
	alpha_dst += buf->stride;
	++num_lines_out;
	}
	if (is_premult_alpha && alpha_mask != 0x0f) {
	WebPApplyAlphaMultiply4444(base_rgba, width, num_lines_out, buf->stride);
	}
	return num_lines_out;
	}

	static int EmitRescaledAlphaRGB(const VP8Io* const io, WebPDecParams* const p) {
	if (io->a != NULL) {
	WebPRescaler* const scaler = &p->scaler_a;
	int j = 0;
	int pos = 0;
	while (j < io->mb_h) {
	j += WebPRescalerImport(scaler, io->mb_h - j,
	io->a + j * io->width, io->width);
	pos += p->emit_alpha_row(p, pos);
	}
	}
	return 0;
	}

	static int InitRGBRescaler(const VP8Io* const io, WebPDecParams* const p) {
	const int has_alpha = WebPIsAlphaMode(p->output->colorspace);
	const int out_width = io->scaled_width;
	const int out_height = io->scaled_height;
	const int uv_in_width = (io->mb_w + 1) >> 1;
	const int uv_in_height = (io->mb_h + 1) >> 1;
	const size_t work_size = 2 * out_width; // scratch memory for one rescaler
	int32_t* work; // rescalers work area
	uint8_t* tmp; // tmp storage for scaled YUV444 samples before RGB conversion
	size_t tmp_size1, tmp_size2;

	tmp_size1 = 3 * work_size;
	tmp_size2 = 3 * out_width;
	if (has_alpha) {
	tmp_size1 += work_size;
	tmp_size2 += out_width;
	}
	p->memory =
	calloc(1, tmp_size1 * sizeof(work) + tmp_size2 sizeof(*tmp));
	if (p->memory == NULL) {
	return 0; // memory error
	}
	work = (int32_t*)p->memory;
	tmp = (uint8_t*)(work + tmp_size1);
	WebPRescalerInit(&p->scaler_y, io->mb_w, io->mb_h,
	tmp + 0 * out_width, out_width, out_height, 0, 1,
	io->mb_w, out_width, io->mb_h, out_height,
	work + 0 * work_size);
	WebPRescalerInit(&p->scaler_u, uv_in_width, uv_in_height,
	tmp + 1 * out_width, out_width, out_height, 0, 1,
	io->mb_w, 2 * out_width, io->mb_h, 2 * out_height,
	work + 1 * work_size);
	WebPRescalerInit(&p->scaler_v, uv_in_width, uv_in_height,
	tmp + 2 * out_width, out_width, out_height, 0, 1,
	io->mb_w, 2 * out_width, io->mb_h, 2 * out_height,
	work + 2 * work_size);
	p->emit = EmitRescaledRGB;

	if (has_alpha) {
	WebPRescalerInit(&p->scaler_a, io->mb_w, io->mb_h,
	tmp + 3 * out_width, out_width, out_height, 0, 1,
	io->mb_w, out_width, io->mb_h, out_height,
	work + 3 * work_size);
	p->emit_alpha = EmitRescaledAlphaRGB;
	if (p->output->colorspace == MODE_RGBA_4444 \|\|
	p->output->colorspace == MODE_rgbA_4444) {
	p->emit_alpha_row = ExportAlphaRGBA4444;
	} else {
	p->emit_alpha_row = ExportAlpha;
	}
	}
	return 1;
	}

	//------------------------------------------------------------------------------
	// Default custom functions

	static int CustomSetup(VP8Io* io) {
	WebPDecParams* const p = (WebPDecParams*)io->opaque;
	const WEBP_CSP_MODE colorspace = p->output->colorspace;
	const int is_rgb = WebPIsRGBMode(colorspace);
	const int is_alpha = WebPIsAlphaMode(colorspace);

	p->memory = NULL;
	p->emit = NULL;
	p->emit_alpha = NULL;
	p->emit_alpha_row = NULL;
	if (!WebPIoInitFromOptions(p->options, io, is_alpha ? MODE_YUV : MODE_YUVA)) {
	return 0;
	}

	if (io->use_scaling) {
	const int ok = is_rgb ? InitRGBRescaler(io, p) : InitYUVRescaler(io, p);
	if (!ok) {
	return 0; // memory error
	}
	} else {
	if (is_rgb) {
	p->emit = EmitSampledRGB; // default
	#ifdef FANCY_UPSAMPLING
	if (io->fancy_upsampling) {
	const int uv_width = (io->mb_w + 1) >> 1;
	p->memory = malloc(io->mb_w + 2 * uv_width);
	if (p->memory == NULL) {
	return 0; // memory error.
	}
	p->tmp_y = (uint8_t*)p->memory;
	p->tmp_u = p->tmp_y + io->mb_w;
	p->tmp_v = p->tmp_u + uv_width;
	p->emit = EmitFancyRGB;
	WebPInitUpsamplers();
	}
	#endif
	} else {
	p->emit = EmitYUV;
	}
	if (is_alpha) { // need transparency output
	if (WebPIsPremultipliedMode(colorspace)) WebPInitPremultiply();
	p->emit_alpha =
	(colorspace == MODE_RGBA_4444 \|\| colorspace == MODE_rgbA_4444) ?
	EmitAlphaRGBA4444
	: is_rgb ? EmitAlphaRGB
	: EmitAlphaYUV;
	}
	}

	if (is_rgb) {
	VP8YUVInit();
	}
	return 1;
	}

	//------------------------------------------------------------------------------

	static int CustomPut(const VP8Io* io) {
	WebPDecParams* p = (WebPDecParams*)io->opaque;
	const int mb_w = io->mb_w;
	const int mb_h = io->mb_h;
	int num_lines_out;
	assert(!(io->mb_y & 1));

	if (mb_w <= 0 \|\| mb_h <= 0) {
	return 0;
	}
	num_lines_out = p->emit(io, p);
	if (p->emit_alpha) {
	p->emit_alpha(io, p);
	}
	p->last_y += num_lines_out;
	return 1;
	}

	//------------------------------------------------------------------------------

	static void CustomTeardown(const VP8Io* io) {
	WebPDecParams* const p = (WebPDecParams*)io->opaque;
	free(p->memory);
	p->memory = NULL;
	}

	//------------------------------------------------------------------------------
	// Main entry point

	void WebPInitCustomIo(WebPDecParams* const params, VP8Io* const io) {
	io->put = CustomPut;
	io->setup = CustomSetup;
	io->teardown = CustomTeardown;
	io->opaque = params;
	}

	//------------------------------------------------------------------------------

	#if defined(__cplusplus) \|\| defined(c_plusplus)
	} // extern "C"
	#endif