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Java example source code file (mlib_ImageScanPoly.c)

This example Java source code file (mlib_ImageScanPoly.c) is included in the alvinalexander.com "Java Source Code Warehouse" project. The intent of this project is to help you "Learn Java by Example" TM.

Learn more about this Java project at its project page.

Java - Java tags/keywords

mlib_edge_src_padded, mlib_failure, mlib_nearest, mlib_s32_max, mlib_success, null, sat32, store_param

The mlib_ImageScanPoly.c Java example source code

/*
 * Copyright (c) 1997, 2003, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
 */


/*
 *  DESCRIPTION
 *    Calculates cliping boundary for Affine functions.
 *
 */

#include "mlib_image.h"
#include "mlib_SysMath.h"
#include "mlib_ImageAffine.h"

/***************************************************************/
mlib_status mlib_AffineEdges(mlib_affine_param *param,
                             const mlib_image  *dst,
                             const mlib_image  *src,
                             void              *buff_lcl,
                             mlib_s32          buff_size,
                             mlib_s32          kw,
                             mlib_s32          kh,
                             mlib_s32          kw1,
                             mlib_s32          kh1,
                             mlib_edge         edge,
                             const mlib_d64    *mtx,
                             mlib_s32          shiftx,
                             mlib_s32          shifty)
{
  mlib_u8 *buff = buff_lcl;
  mlib_u8 **lineAddr = param->lineAddr;
  mlib_s32 srcWidth, dstWidth, srcHeight, dstHeight, srcYStride, dstYStride;
  mlib_s32 *leftEdges, *rightEdges, *xStarts, *yStarts, bsize0, bsize1 = 0;
  mlib_u8 *srcData, *dstData;
  mlib_u8 *paddings;
  void *warp_tbl = NULL;
  mlib_s32 yStart = 0, yFinish = -1, dX, dY;

  mlib_d64 xClip, yClip, wClip, hClip;
  mlib_d64 delta = 0.;
  mlib_d64 minX, minY, maxX, maxY;

  mlib_d64 coords[4][2];
  mlib_d64 a = mtx[0], b = mtx[1], tx = mtx[2], c = mtx[3], d = mtx[4], ty = mtx[5];
  mlib_d64 a2, b2, tx2, c2, d2, ty2;
  mlib_d64 dx, dy, div;
  mlib_s32 sdx, sdy;
  mlib_d64 dTop;
  mlib_d64 val0;
  mlib_s32 top, bot;
  mlib_s32 topIdx, max_xsize = 0;
  mlib_s32 i, j, t;

  srcData = mlib_ImageGetData(src);
  dstData = mlib_ImageGetData(dst);
  srcWidth = mlib_ImageGetWidth(src);
  srcHeight = mlib_ImageGetHeight(src);
  dstWidth = mlib_ImageGetWidth(dst);
  dstHeight = mlib_ImageGetHeight(dst);
  srcYStride = mlib_ImageGetStride(src);
  dstYStride = mlib_ImageGetStride(dst);
  paddings = mlib_ImageGetPaddings(src);

  if (srcWidth >= (1 << 15) || srcHeight >= (1 << 15)) {
    return MLIB_FAILURE;
  }

  div = a * d - b * c;

  if (div == 0.0) {
    return MLIB_FAILURE;
  }

  bsize0 = (dstHeight * sizeof(mlib_s32) + 7) & ~7;

  if (lineAddr == NULL) {
    bsize1 = ((srcHeight + 4 * kh) * sizeof(mlib_u8 *) + 7) & ~7;
  }

  param->buff_malloc = NULL;

  if ((4 * bsize0 + bsize1) > buff_size) {
    buff = param->buff_malloc = mlib_malloc(4 * bsize0 + bsize1);

    if (buff == NULL)
      return MLIB_FAILURE;
  }

  leftEdges = (mlib_s32 *) (buff);
  rightEdges = (mlib_s32 *) (buff += bsize0);
  xStarts = (mlib_s32 *) (buff += bsize0);
  yStarts = (mlib_s32 *) (buff += bsize0);

  if (lineAddr == NULL) {
    mlib_u8 *srcLinePtr = srcData;
    lineAddr = (mlib_u8 **) (buff += bsize0);
    for (i = 0; i < 2 * kh; i++)
      lineAddr[i] = srcLinePtr;
    lineAddr += 2 * kh;
    for (i = 0; i < srcHeight - 1; i++) {
      lineAddr[i] = srcLinePtr;
      srcLinePtr += srcYStride;
    }

    for (i = srcHeight - 1; i < srcHeight + 2 * kh; i++)
      lineAddr[i] = srcLinePtr;
  }

  if ((mlib_s32) edge < 0) {                               /* process edges */
    minX = 0;
    minY = 0;
    maxX = srcWidth;
    maxY = srcHeight;
  }
  else {

    if (kw > 1)
      delta = -0.5;                                        /* for MLIB_NEAREST filter delta = 0. */

    minX = (kw1 - delta);
    minY = (kh1 - delta);
    maxX = srcWidth - ((kw - 1) - (kw1 - delta));
    maxY = srcHeight - ((kh - 1) - (kh1 - delta));

    if (edge == MLIB_EDGE_SRC_PADDED) {
      if (minX < paddings[0])
        minX = paddings[0];

      if (minY < paddings[1])
        minY = paddings[1];

      if (maxX > (srcWidth - paddings[2]))
        maxX = srcWidth - paddings[2];

      if (maxY > (srcHeight - paddings[3]))
        maxY = srcHeight - paddings[3];
    }
  }

  xClip = minX;
  yClip = minY;
  wClip = maxX;
  hClip = maxY;

/*
 *   STORE_PARAM(param, src);
 *   STORE_PARAM(param, dst);
 */
  param->src = (void *)src;
  param->dst = (void *)dst;
  STORE_PARAM(param, lineAddr);
  STORE_PARAM(param, dstData);
  STORE_PARAM(param, srcYStride);
  STORE_PARAM(param, dstYStride);
  STORE_PARAM(param, leftEdges);
  STORE_PARAM(param, rightEdges);
  STORE_PARAM(param, xStarts);
  STORE_PARAM(param, yStarts);
  STORE_PARAM(param, max_xsize);
  STORE_PARAM(param, yStart);
  STORE_PARAM(param, yFinish);
  STORE_PARAM(param, warp_tbl);

  if ((xClip >= wClip) || (yClip >= hClip)) {
    return MLIB_SUCCESS;
  }

  a2 = d;
  b2 = -b;
  tx2 = (-d * tx + b * ty);
  c2 = -c;
  d2 = a;
  ty2 = (c * tx - a * ty);

  dx = a2;
  dy = c2;

  tx -= 0.5;
  ty -= 0.5;

  coords[0][0] = xClip * a + yClip * b + tx;
  coords[0][1] = xClip * c + yClip * d + ty;

  coords[2][0] = wClip * a + hClip * b + tx;
  coords[2][1] = wClip * c + hClip * d + ty;

  if (div > 0) {
    coords[1][0] = wClip * a + yClip * b + tx;
    coords[1][1] = wClip * c + yClip * d + ty;

    coords[3][0] = xClip * a + hClip * b + tx;
    coords[3][1] = xClip * c + hClip * d + ty;
  }
  else {
    coords[3][0] = wClip * a + yClip * b + tx;
    coords[3][1] = wClip * c + yClip * d + ty;

    coords[1][0] = xClip * a + hClip * b + tx;
    coords[1][1] = xClip * c + hClip * d + ty;
  }

  topIdx = 0;
  for (i = 1; i < 4; i++) {

    if (coords[i][1] < coords[topIdx][1])
      topIdx = i;
  }

  dTop = coords[topIdx][1];
  val0 = dTop;
  SAT32(top);
  bot = -1;

  if (top >= dstHeight) {
    return MLIB_SUCCESS;
  }

  if (dTop >= 0.0) {
    mlib_d64 xLeft, xRight, x;
    mlib_s32 nextIdx;

    if (dTop == top) {
      xLeft = coords[topIdx][0];
      xRight = coords[topIdx][0];
      nextIdx = (topIdx + 1) & 0x3;

      if (dTop == coords[nextIdx][1]) {
        x = coords[nextIdx][0];
        xLeft = (xLeft <= x) ? xLeft : x;
        xRight = (xRight >= x) ? xRight : x;
      }

      nextIdx = (topIdx - 1) & 0x3;

      if (dTop == coords[nextIdx][1]) {
        x = coords[nextIdx][0];
        xLeft = (xLeft <= x) ? xLeft : x;
        xRight = (xRight >= x) ? xRight : x;
      }

      val0 = xLeft;
      SAT32(t);
      leftEdges[top] = (t >= xLeft) ? t : ++t;

      if (xLeft >= MLIB_S32_MAX)
        leftEdges[top] = MLIB_S32_MAX;

      val0 = xRight;
      SAT32(rightEdges[top]);
    }
    else
      top++;
  }
  else
    top = 0;

  for (i = 0; i < 2; i++) {
    mlib_d64 dY1 = coords[(topIdx - i) & 0x3][1];
    mlib_d64 dX1 = coords[(topIdx - i) & 0x3][0];
    mlib_d64 dY2 = coords[(topIdx - i - 1) & 0x3][1];
    mlib_d64 dX2 = coords[(topIdx - i - 1) & 0x3][0];
    mlib_d64 x = dX1, slope = (dX2 - dX1) / (dY2 - dY1);
    mlib_s32 y1;
    mlib_s32 y2;

    if (dY1 == dY2)
      continue;

    if (dY1 < 0.0)
      y1 = 0;
    else {
      val0 = dY1 + 1;
      SAT32(y1);
    }

    val0 = dY2;
    SAT32(y2);

    if (y2 >= dstHeight)
      y2 = (mlib_s32) (dstHeight - 1);

    x += slope * (y1 - dY1);
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (j = y1; j <= y2; j++) {
      val0 = x;
      SAT32(t);
      leftEdges[j] = (t >= x) ? t : ++t;

      if (x >= MLIB_S32_MAX)
        leftEdges[j] = MLIB_S32_MAX;
      x += slope;
    }
  }

  for (i = 0; i < 2; i++) {
    mlib_d64 dY1 = coords[(topIdx + i) & 0x3][1];
    mlib_d64 dX1 = coords[(topIdx + i) & 0x3][0];
    mlib_d64 dY2 = coords[(topIdx + i + 1) & 0x3][1];
    mlib_d64 dX2 = coords[(topIdx + i + 1) & 0x3][0];
    mlib_d64 x = dX1, slope = (dX2 - dX1) / (dY2 - dY1);
    mlib_s32 y1;
    mlib_s32 y2;

    if (dY1 == dY2)
      continue;

    if (dY1 < 0.0)
      y1 = 0;
    else {
      val0 = dY1 + 1;
      SAT32(y1);
    }

    val0 = dY2;
    SAT32(y2);

    if (y2 >= dstHeight)
      y2 = (mlib_s32) (dstHeight - 1);

    x += slope * (y1 - dY1);
#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
    for (j = y1; j <= y2; j++) {
      val0 = x;
      SAT32(rightEdges[j]);
      x += slope;
    }

    bot = y2;
  }

  {
    mlib_d64 dxCl = xClip * div;
    mlib_d64 dyCl = yClip * div;
    mlib_d64 dwCl = wClip * div;
    mlib_d64 dhCl = hClip * div;

    mlib_s32 xCl = (mlib_s32) (xClip + delta);
    mlib_s32 yCl = (mlib_s32) (yClip + delta);
    mlib_s32 wCl = (mlib_s32) (wClip + delta);
    mlib_s32 hCl = (mlib_s32) (hClip + delta);

    /*
     * mlib_s32 xCl = (mlib_s32)(xClip + delta);
     * mlib_s32 yCl = (mlib_s32)(yClip + delta);
     * mlib_s32 wCl = (mlib_s32)(wClip);
     * mlib_s32 hCl = (mlib_s32)(hClip);
     */

    if (edge == MLIB_EDGE_SRC_PADDED) {
      xCl = kw1;
      yCl = kh1;
      wCl = (mlib_s32) (srcWidth - ((kw - 1) - kw1));
      hCl = (mlib_s32) (srcHeight - ((kh - 1) - kh1));
    }

    div = 1.0 / div;

    sdx = (mlib_s32) (a2 * div * (1 << shiftx));
    sdy = (mlib_s32) (c2 * div * (1 << shifty));

    if (div > 0) {

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = top; i <= bot; i++) {
        mlib_s32 xLeft = leftEdges[i];
        mlib_s32 xRight = rightEdges[i];
        mlib_s32 xs, ys, x_e, y_e, x_s, y_s;
        mlib_d64 dxs, dys, dxe, dye;
        mlib_d64 xl, ii, xr;

        xLeft = (xLeft < 0) ? 0 : xLeft;
        xRight = (xRight >= dstWidth) ? (mlib_s32) (dstWidth - 1) : xRight;

        xl = xLeft + 0.5;
        ii = i + 0.5;
        xr = xRight + 0.5;
        dxs = xl * a2 + ii * b2 + tx2;
        dys = xl * c2 + ii * d2 + ty2;

        if ((dxs < dxCl) || (dxs >= dwCl) || (dys < dyCl) || (dys >= dhCl)) {
          dxs += dx;
          dys += dy;
          xLeft++;

          if ((dxs < dxCl) || (dxs >= dwCl) || (dys < dyCl) || (dys >= dhCl))
            xRight = -1;
        }

        dxe = xr * a2 + ii * b2 + tx2;
        dye = xr * c2 + ii * d2 + ty2;

        if ((dxe < dxCl) || (dxe >= dwCl) || (dye < dyCl) || (dye >= dhCl)) {
          dxe -= dx;
          dye -= dy;
          xRight--;

          if ((dxe < dxCl) || (dxe >= dwCl) || (dye < dyCl) || (dye >= dhCl))
            xRight = -1;
        }

        xs = (mlib_s32) ((dxs * div + delta) * (1 << shiftx));
        x_s = xs >> shiftx;

        ys = (mlib_s32) ((dys * div + delta) * (1 << shifty));
        y_s = ys >> shifty;

        if (x_s < xCl)
          xs = (xCl << shiftx);
        else if (x_s >= wCl)
          xs = ((wCl << shiftx) - 1);

        if (y_s < yCl)
          ys = (yCl << shifty);
        else if (y_s >= hCl)
          ys = ((hCl << shifty) - 1);

        if (xRight >= xLeft) {
          x_e = ((xRight - xLeft) * sdx + xs) >> shiftx;
          y_e = ((xRight - xLeft) * sdy + ys) >> shifty;

          if ((x_e < xCl) || (x_e >= wCl)) {
            if (sdx > 0)
              sdx -= 1;
            else
              sdx += 1;
          }

          if ((y_e < yCl) || (y_e >= hCl)) {
            if (sdy > 0)
              sdy -= 1;
            else
              sdy += 1;
          }
        }

        leftEdges[i] = xLeft;
        rightEdges[i] = xRight;
        xStarts[i] = xs;
        yStarts[i] = ys;

        if ((xRight - xLeft + 1) > max_xsize)
          max_xsize = (xRight - xLeft + 1);
      }
    }
    else {

#ifdef __SUNPRO_C
#pragma pipeloop(0)
#endif /* __SUNPRO_C */
      for (i = top; i <= bot; i++) {
        mlib_s32 xLeft = leftEdges[i];
        mlib_s32 xRight = rightEdges[i];
        mlib_s32 xs, ys, x_e, y_e, x_s, y_s;
        mlib_d64 dxs, dys, dxe, dye;
        mlib_d64 xl, ii, xr;

        xLeft = (xLeft < 0) ? 0 : xLeft;
        xRight = (xRight >= dstWidth) ? (mlib_s32) (dstWidth - 1) : xRight;

        xl = xLeft + 0.5;
        ii = i + 0.5;
        xr = xRight + 0.5;
        dxs = xl * a2 + ii * b2 + tx2;
        dys = xl * c2 + ii * d2 + ty2;

        if ((dxs > dxCl) || (dxs <= dwCl) || (dys > dyCl) || (dys <= dhCl)) {
          dxs += dx;
          dys += dy;
          xLeft++;

          if ((dxs > dxCl) || (dxs <= dwCl) || (dys > dyCl) || (dys <= dhCl))
            xRight = -1;
        }

        dxe = xr * a2 + ii * b2 + tx2;
        dye = xr * c2 + ii * d2 + ty2;

        if ((dxe > dxCl) || (dxe <= dwCl) || (dye > dyCl) || (dye <= dhCl)) {
          dxe -= dx;
          dye -= dy;
          xRight--;

          if ((dxe > dxCl) || (dxe <= dwCl) || (dye > dyCl) || (dye <= dhCl))
            xRight = -1;
        }

        xs = (mlib_s32) ((dxs * div + delta) * (1 << shiftx));
        x_s = xs >> shiftx;

        if (x_s < xCl)
          xs = (xCl << shiftx);
        else if (x_s >= wCl)
          xs = ((wCl << shiftx) - 1);

        ys = (mlib_s32) ((dys * div + delta) * (1 << shifty));
        y_s = ys >> shifty;

        if (y_s < yCl)
          ys = (yCl << shifty);
        else if (y_s >= hCl)
          ys = ((hCl << shifty) - 1);

        if (xRight >= xLeft) {
          x_e = ((xRight - xLeft) * sdx + xs) >> shiftx;
          y_e = ((xRight - xLeft) * sdy + ys) >> shifty;

          if ((x_e < xCl) || (x_e >= wCl)) {
            if (sdx > 0)
              sdx -= 1;
            else
              sdx += 1;
          }

          if ((y_e < yCl) || (y_e >= hCl)) {
            if (sdy > 0)
              sdy -= 1;
            else
              sdy += 1;
          }
        }

        leftEdges[i] = xLeft;
        rightEdges[i] = xRight;
        xStarts[i] = xs;
        yStarts[i] = ys;

        if ((xRight - xLeft + 1) > max_xsize)
          max_xsize = (xRight - xLeft + 1);
      }
    }
  }

  while (leftEdges[top] > rightEdges[top] && top <= bot)
    top++;

  if (top < bot)
    while (leftEdges[bot] > rightEdges[bot])
      bot--;

  yStart = top;
  yFinish = bot;
  dX = sdx;
  dY = sdy;

  dstData += (yStart - 1) * dstYStride;

  STORE_PARAM(param, dstData);
  STORE_PARAM(param, yStart);
  STORE_PARAM(param, yFinish);
  STORE_PARAM(param, max_xsize);
  STORE_PARAM(param, dX);
  STORE_PARAM(param, dY);

  return MLIB_SUCCESS;
}

/***************************************************************/

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