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#include "pins.h"
#include "tfxparam.h"
#include "trop.h"
#include "tmathutil.h"
#include "tofflinegl.h"

#include <cmath>

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

namespace {

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

bool lineIntersection(const TPointD &P, const TPointD &R, const TPointD &Q,
                      const TPointD &S, TPointD &ret);

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

bool lineIntersection(const TPointD &P, const TPointD &R, const TPointD &Q,
                      const TPointD &S, TPointD &ret) {
  TPointD u = R - P;
  TPointD v = S - Q;
  double r;
  if (u.y * v.x - u.x * v.y != 0) {
    r = (P.x * u.y - Q.x * u.y + u.x * (Q.y - P.y)) / (u.y * v.x - u.x * v.y);
    assert(!std::isnan(r));
    ret = Q + v * r;
    assert(!std::isnan(ret.x) && !std::isnan(ret.y));
    return true;
  } else {
    ret = P;
    assert(!std::isnan(ret.x) && !std::isnan(ret.y));
    return false;
  }
}

//----------------------------------------------------------------------------
};

#ifndef checkErrorsByGL
#define checkErrorsByGL                                                        \
  {                                                                            \
    GLenum err = glGetError();                                                 \
    assert(err != GL_INVALID_ENUM);                                            \
    assert(err != GL_INVALID_VALUE);                                           \
    assert(err != GL_INVALID_OPERATION);                                       \
    assert(err != GL_STACK_OVERFLOW);                                          \
    assert(err != GL_STACK_UNDERFLOW);                                         \
    assert(err != GL_OUT_OF_MEMORY);                                           \
    assert(err == GL_NO_ERROR);                                                \
  }
#endif

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

void subCompute(TRasterFxPort &m_input, TTile &tile, double frame,
                const TRenderSettings &ri, TPointD p00, TPointD p01,
                TPointD p11, TPointD p10, int details, bool wireframe,
                TDimension m_offScreenSize, bool isCast) {
  TPixel32 bgColor;
  TRectD outBBox, inBBox;
  outBBox = inBBox = TRectD(tile.m_pos, TDimensionD(tile.getRaster()->getLx(),
                                                    tile.getRaster()->getLy()));
  m_input->getBBox(frame, inBBox, ri);
  if (inBBox == TConsts::infiniteRectD)  // e' uno zerario
    inBBox = outBBox;

  int inBBoxLx = (int)inBBox.getLx() / ri.m_shrinkX;
  int inBBoxLy = (int)inBBox.getLy() / ri.m_shrinkY;

  if (inBBox.isEmpty()) return;

  if (p00 == p01 && p00 == p10 && p00 == p11 &&
      !isCast)  // significa che non c'e' deformazione
  {
    m_input->compute(tile, frame, ri);
    return;
  }

  TRaster32P rasIn;
  TPointD rasInPos;

  if (!wireframe) {
    if (ri.m_bpp == 64 || ri.m_bpp == 48) {
      TRaster64P aux = TRaster64P(inBBoxLx, inBBoxLy);
      rasInPos = TPointD(inBBox.x0 / ri.m_shrinkX, inBBox.y0 / ri.m_shrinkY);
      TTile tmp(aux, rasInPos);
      m_input->compute(tmp, frame, ri);
      rasIn = TRaster32P(inBBoxLx, inBBoxLy);
      TRop::convert(rasIn, aux);
    } else {
      rasInPos = TPointD(inBBox.x0 / ri.m_shrinkX, inBBox.y0 / ri.m_shrinkY);
      TTile tmp(TRaster32P(inBBoxLx, inBBoxLy), rasInPos);
      m_input->allocateAndCompute(tmp, rasInPos, TDimension(inBBoxLx, inBBoxLy),
                                  TRaster32P(), frame, ri);
      rasIn = tmp.getRaster();
    }
  }

  unsigned int texWidth  = 2;
  unsigned int texHeight = 2;

  while (texWidth < (unsigned int)inBBoxLx) texWidth = texWidth << 1;

  while (texHeight < (unsigned int)inBBoxLy) texHeight = texHeight << 1;

  while (texWidth > 1024 || texHeight > 1024)  // avevo usato la costante
                                               // GL_MAX_TEXTURE_SIZE invece di
                                               // 1024, ma non funzionava!
  {
    inBBoxLx  = inBBoxLx >> 1;
    inBBoxLy  = inBBoxLy >> 1;
    texWidth  = texWidth >> 1;
    texHeight = texHeight >> 1;
  }

  if (rasIn->getLx() != inBBoxLx || rasIn->getLy() != inBBoxLy) {
    TRaster32P rasOut = TRaster32P(inBBoxLx, inBBoxLy);
    TRop::resample(rasOut, rasIn,
                   TScale((double)rasOut->getLx() / rasIn->getLx(),
                          (double)rasOut->getLy() / rasIn->getLy()));
    rasIn = rasOut;
  }

  int rasterWidth  = tile.getRaster()->getLx() + 2;
  int rasterHeight = tile.getRaster()->getLy() + 2;
  assert(rasterWidth > 0);
  assert(rasterHeight > 0);

  TRectD clippingRect =
      TRectD(tile.m_pos,
             TDimensionD(tile.getRaster()->getLx(), tile.getRaster()->getLy()));
#ifdef CREATE_GL_CONTEXT_ONE_TIME
  int ret = wglMakeCurrent(m_offScreenGL.m_offDC, m_offScreenGL.m_hglRC);
  assert(ret == TRUE);
#else
  TOfflineGL offScreenRendering(TDimension(rasterWidth, rasterHeight));
  //#ifdef _WIN32
  offScreenRendering.makeCurrent();
//#else
//#if defined(LINUX) || defined(MACOSX)
// offScreenRendering.m_offlineGL->makeCurrent();
//#endif
#endif

  checkErrorsByGL
      // disabilito quello che non mi serve per le texture
      glHint(GL_PERSPECTIVE_CORRECTION_HINT, GL_FASTEST);
  glDisable(GL_DITHER);
  glDisable(GL_DEPTH_TEST);
  glCullFace(GL_FRONT);
  glDisable(GL_STENCIL_TEST);
  glDisable(GL_LOGIC_OP);

  // creo la texture in base all'immagine originale
  glTexParameterf(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP);
  glTexParameterf(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP);
  glTexParameterf(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
  glTexParameterf(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
  glTexEnvf(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE);

  checkErrorsByGL
#ifndef CREATE_GL_CONTEXT_ONE_TIME
      TRaster32P rasaux;
  if (!wireframe) {
    TRaster32P texture(texWidth, texHeight);
    texture->clear();
    rasaux = texture;
    rasaux->lock();
    texture->copy(rasIn);

    glPixelStorei(GL_UNPACK_ROW_LENGTH, 0);
    glTexImage2D(GL_TEXTURE_2D, 0, 4, texWidth, texHeight, 0, GL_RGBA,
                 GL_UNSIGNED_BYTE, texture->getRawData());
  }
#else

      unsigned int texWidth = 1024;
  unsigned int texHeight    = 1024;
  rasaux                    = rasIn;
  rasaux->lock();

  glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, rasIn->getLx(), rasIn->getLy(),
                  GL_RGBA, GL_UNSIGNED_BYTE, rasIn->getRawData());

#endif
  checkErrorsByGL

      glEnable(GL_TEXTURE_2D);

  // cfr. help: OpenGL/Programming tip/OpenGL Correctness Tips
  glMatrixMode(GL_PROJECTION);
  glLoadIdentity();
  glOrtho(-rasterWidth * 0.5, rasterWidth * 0.5, -rasterHeight * 0.5,
          rasterHeight * 0.5, -1, 1);
  glViewport(0, 0, rasterWidth, rasterHeight);

  glMatrixMode(GL_MODELVIEW);
  glLoadIdentity();

  glClearColor(0.0f, 0.0f, 0.0f, 0.0f);
  glClear(GL_COLOR_BUFFER_BIT);

  // do OpenGL draw

  double lwTex = (double)(inBBoxLx - 1) / (double)(texWidth - 1);
  double lhTex = (double)(inBBoxLy - 1) / (double)(texHeight - 1);

  TPointD tex00 = TPointD(0.0, 0.0);
  TPointD tex10 = TPointD(lwTex, 0.0);
  TPointD tex11 = TPointD(lwTex, lhTex);
  TPointD tex01 = TPointD(0.0, lhTex);

  GLenum polygonStyle;
  if (wireframe) {
    polygonStyle = GL_LINE;
    glDisable(GL_TEXTURE_2D);
  } else
    polygonStyle = GL_FILL;
  checkErrorsByGL p00.x /= ri.m_shrinkX;
  p00.y /= ri.m_shrinkY;

  p10.x /= ri.m_shrinkX;
  p10.y /= ri.m_shrinkY;

  p11.x /= ri.m_shrinkX;
  p11.y /= ri.m_shrinkY;

  p01.x /= ri.m_shrinkX;
  p01.y /= ri.m_shrinkY;

  TPointD translate = TPointD(tile.m_pos.x + tile.getRaster()->getLx() * 0.5,
                              tile.m_pos.y + tile.getRaster()->getLy() * 0.5);
  glTranslated(-translate.x, -translate.y, 0.0);

  // disegno il poligono
  double dist_p00_p01                 = tdistance2(p00, p01);
  double dist_p10_p11                 = tdistance2(p10, p11);
  double dist_p01_p11                 = tdistance2(p01, p11);
  double dist_p00_p10                 = tdistance2(p00, p10);
  bool vertical                       = (dist_p00_p01 == dist_p10_p11);
  bool horizontal                     = (dist_p00_p10 == dist_p01_p11);
  if (vertical && horizontal) details = 1;
  glPolygonMode(GL_FRONT_AND_BACK, polygonStyle);
  subdivision(p00, p10, p11, p01, tex00, tex10, tex11, tex01, clippingRect,
              details);

  if (!wireframe) {
    // abilito l'antialiasing delle linee
    glEnable(GL_LINE_SMOOTH);
    glEnable(GL_BLEND);
    glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
    glHint(GL_LINE_SMOOTH_HINT, GL_NICEST);

    // disegno il bordo del poligono
    glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
    glBegin(GL_QUADS);
    glTexCoord2d(tex00.x, tex00.y);
    tglVertex(p00);
    glTexCoord2d(tex10.x, tex10.y);
    tglVertex(p10);
    glTexCoord2d(tex11.x, tex11.y);
    tglVertex(p11);
    glTexCoord2d(tex01.x, tex01.y);
    tglVertex(p01);
    glEnd();

    // disabilito l'antialiasing per le linee
    glDisable(GL_LINE_SMOOTH);
    glDisable(GL_BLEND);
    glDisableClientState(GL_VERTEX_ARRAY);
    glDisableClientState(GL_TEXTURE_COORD_ARRAY);
    glDisable(GL_TEXTURE_2D);
  }

  // force to finish
  glFlush();

  // rimetto il disegno dei poligoni a GL_FILL
  glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);

  // metto il frame buffer nel raster del tile
  glPixelStorei(GL_UNPACK_ROW_LENGTH, rasterWidth);
  glPixelStorei(GL_UNPACK_ALIGNMENT, 4);

  TRaster32P newRas(tile.getRaster()->getLx(), tile.getRaster()->getLy());
  newRas->lock();
  glReadPixels(1, 1, newRas->getLx(), newRas->getLy(), GL_RGBA,
               GL_UNSIGNED_BYTE, (void *)newRas->getRawData());
  newRas->unlock();
  checkErrorsByGL

      rasaux->unlock();

  tile.getRaster()->copy(newRas);
}

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

void subdivision(const TPointD &p00, const TPointD &p10, const TPointD &p11,
                 const TPointD &p01, const TPointD &tex00, const TPointD &tex10,
                 const TPointD &tex11, const TPointD &tex01,
                 const TRectD &clippingRect, int details) {
  if (details == 1) {
    glBegin(GL_QUADS);

    glTexCoord2d(tex00.x, tex00.y);
    tglVertex(p00);

    glTexCoord2d(tex10.x, tex10.y);
    tglVertex(p10);

    glTexCoord2d(tex11.x, tex11.y);
    tglVertex(p11);

    glTexCoord2d(tex01.x, tex01.y);
    tglVertex(p01);

    glEnd();
  } else {
    TPointD A = p00;
    TPointD B = p10;
    TPointD C = p11;
    TPointD D = p01;

    /*
*     D                L2               C
*     +----------------+----------------+
*     |                |                |
*     |                |                |
*     |                |                |
*     |                |                |
*     |                |                |
*  H1 +----------------+----------------+ H2
*     |                | M              |
*     |                |                |
*     |                |                |
*     |                |                |
*     |                |                |
*     +----------------+----------------+
*     A                L1               B
*
*/

    TPointD M, L1, L2, H1, H2, P1, P2;
    bool intersection;

    // M
    intersection = lineIntersection(A, C, B, D, M);
    assert(intersection);

    // P1 (punto di fuga)
    intersection = lineIntersection(D, C, A, B, P1);
    if (!intersection) {
      P1.x = 0.5 * (A.x + D.x);
      P1.y = 0.5 * (A.y + D.y);
    }
    // H1
    intersection = lineIntersection(A, D, P1, M, H1);
    assert(intersection);

    // H2
    intersection = lineIntersection(B, C, P1, M, H2);
    assert(intersection);

    // P2 (punto di fuga)
    intersection = lineIntersection(A, D, B, C, P2);
    if (!intersection) {
      P2.x = 0.5 * (A.x + B.x);
      P2.y = 0.5 * (A.y + B.y);
    }
    // L1
    intersection = lineIntersection(A, B, P2, M, L1);
    assert(intersection);

    // L2
    intersection = lineIntersection(D, C, P2, M, L2);
    assert(intersection);

    TPointD texA = (tex00 + tex10) * 0.5;
    TPointD texB = (tex10 + tex11) * 0.5;
    TPointD texC = (tex11 + tex01) * 0.5;
    TPointD texD = (tex01 + tex00) * 0.5;
    TPointD texM = (texA + texC) * 0.5;

    details--;

    TRectD r1 = TRectD(
        std::min({A.x, L1.x, M.x, H1.x}), std::min({A.y, L1.y, M.y, H1.y}),
        std::max({A.x, L1.x, M.x, H1.x}), std::max({A.y, L1.y, M.y, H1.y}));

    TRectD r2 = TRectD(
        std::min({L1.x, B.x, H2.x, M.x}), std::min({L1.y, B.y, H2.y, M.y}),
        std::max({L1.x, B.x, H2.x, M.x}), std::max({L1.y, B.y, H2.y, M.y}));

    TRectD r3 = TRectD(
        std::min({M.x, H2.x, C.x, L2.x}), std::min({M.y, H2.y, C.y, L2.y}),
        std::max({M.x, H2.x, C.x, L2.x}), std::max({M.y, H2.y, C.y, L2.y}));

    TRectD r4 = TRectD(
        std::min({H1.x, M.x, L2.x, D.x}), std::min({H1.y, M.y, L2.y, D.y}),
        std::max({H1.x, M.x, L2.x, D.x}), std::max({H1.y, M.y, L2.y, D.y}));

    if (r1.overlaps(clippingRect))
      subdivision(A, L1, M, H1, tex00, texA, texM, texD, clippingRect, details);

    if (r2.overlaps(clippingRect))
      subdivision(L1, B, H2, M, texA, tex10, texB, texM, clippingRect, details);

    if (r3.overlaps(clippingRect))
      subdivision(M, H2, C, L2, texM, texB, tex11, texC, clippingRect, details);

    if (r4.overlaps(clippingRect))
      subdivision(H1, M, L2, D, texD, texM, texC, tex01, clippingRect, details);
  }
}

// ------------------------------------------------------------------------
// ------------------------------------------------------------------------
// ------------------------------------------------------------------------
#define TINY 1.0e-20

static int splitMatrix(double **a, int n, int *index) {
  int i, imax = 0, j, k;
  double big, dum, sum, temp;
  double *vv, d;

  vv = new double[n];

  d = 1.00;
  for (i = 0; i < n; i++) {
    big = 0.0;
    for (j = 0; j < n; j++)
      if ((temp = fabs(a[i][j])) > big) big = temp;
    if (big == 0.0) {
      /*printf("aho, sta matrice e 'vota!!\n");*/
      return 0;
      // exit(0);
    }
    vv[i] = 1.0 / big;
  }
  for (j = 0; j < n; j++) {
    for (i = 0; i < j; i++) {
      sum = a[i][j];
      for (k  = 0; k < i; k++) sum -= a[i][k] * a[k][j];
      a[i][j] = sum;
    }
    big = 0.0;
    for (i = j; i < n; i++) {
      sum = a[i][j];
      for (k  = 0; k < j; k++) sum -= a[i][k] * a[k][j];
      a[i][j] = sum;
      if ((dum = vv[i] * fabs(sum)) >= big) {
        big  = dum;
        imax = i;
      }
    }
    if (j != imax) {
      for (k = 0; k < n; k++) {
        dum        = a[imax][k];
        a[imax][k] = a[j][k];
        a[j][k]    = dum;
      }
      d        = -d;
      vv[imax] = vv[j];
    }
    index[j] = imax;
    if (fabsf(a[j][j]) <= TINY && (j != n - 1)) {
      /*printf("Cazzo, E' singolare %f!\n", a[j][j] );*/
      return imax + 1;
    }
    if (j != n - 1) {
      dum = 1.0 / a[j][j];
      for (i = j + 1; i < n; i++) a[i][j] *= dum;
    }
  }
  delete[] vv;
  return 0;
}

/*-----------------------------------------------------------------*/

static void buildMatrixes(const FourPoints &ss, const FourPoints &dd,
                          double **a, double *b) {
  int i;
  TPointD s[4], d[4];

  s[0] = ss.m_p00, s[1] = ss.m_p01, s[2] = ss.m_p10, s[3] = ss.m_p11;
  d[0] = dd.m_p00, d[1] = dd.m_p01, d[2] = dd.m_p10, d[3] = dd.m_p11;

  for (i = 0; i < 4; i++) {
    a[i][0] = a[i + 4][3] = s[i].x;
    a[i][1] = a[i + 4][4] = s[i].y;
    a[i][2] = a[i + 4][5] = 1;
    a[i][3] = a[i + 4][0] = 0;
    a[i][4] = a[i + 4][1] = 0;
    a[i][5] = a[i + 4][2] = 0;
    a[i][6]               = -s[i].x * d[i].x;
    a[i + 4][6]           = -s[i].x * d[i].y;
    a[i][7]               = -s[i].y * d[i].x;
    a[i + 4][7]           = -s[i].y * d[i].y;

    b[i]     = d[i].x;
    b[i + 4] = d[i].y;
  }
}

/*-----------------------------------------------------------------*/

static void computeSolutions(double **a, int *index, double *b) {
  int i, ii = 0, ip, j;
  double sum;

  for (i = 0; i < 8; i++) {
    ip    = index[i];
    sum   = b[ip];
    b[ip] = b[i];
    if (ii)
      for (j = ii - 1; j <= i - 1; j++) sum -= a[i][j] * b[j];
    else if (sum)
      ii = i + 1;
    b[i] = sum;
  }
  for (i = 7; i >= 0; i--) {
    sum = b[i];
    for (j = i + 1; j < 8; j++) sum -= a[i][j] * b[j];
    b[i]   = sum / a[i][i];
  }
}

/*-----------------------------------------------------------------*/

static void solveSystems(double **a, double *bx) {
  int index[255], i, count = 0, bad_line;
  double **atmp;
  int n = 8;

  atmp = new double *[n];

  for (i = 0; i < n; i++) {
    atmp[i] = new double[n];
    memcpy(atmp[i], a[i], n * sizeof(double));
  }

  while ((bad_line = splitMatrix(atmp, n, index)) != 0 && n > 0) {
    /*printf("la riga %d fa schifo!\n", bad_line);*/
    /*bad_lines[count] = bad_line;*/
    for (i = bad_line - 1; i < n - 1; i++)
      memcpy(atmp[i], a[i + 1], n * sizeof(a[i + 1]));
    n--;
    count++;
  }

  if (count == 0) computeSolutions(atmp, index, bx);

  for (i = 0; i < n; i++) delete atmp[i];

  delete atmp;
}

/*-----------------------------------------------------------------*/

static void computeTransformation(const FourPoints &s, const FourPoints &d,
                                  TAffine &aff, TPointD &perspectDen) {
  double **a, *b;

  int i;
  a = new double *[8];
  for (i = 0; i < 8; i++) a[i] = new double[8];
  b                            = new double[8];

  buildMatrixes(s, d, a, b);

  solveSystems(a, b);

  aff.a11       = b[0];
  aff.a12       = b[1];
  aff.a13       = b[2];
  aff.a21       = b[3];
  aff.a22       = b[4];
  aff.a23       = b[5];
  perspectDen.x = b[6];
  perspectDen.y = b[7];

  for (i = 0; i < 8; i++) delete a[i];
  delete b;
  delete a;
}

/*-----------------------------------------------------------------*/

FourPoints computeTransformed(const FourPoints &pointsFrom,
                              const FourPoints &pointsTo,
                              const FourPoints &from) {
  TAffine aff;
  TPointD perspectiveDen;

  computeTransformation(pointsFrom, pointsTo, aff, perspectiveDen);

  double den;
  FourPoints fp;

  den = perspectiveDen.x * from.m_p00.x + perspectiveDen.y * from.m_p00.y + 1;
  assert(den != 0);
  fp.m_p00 = (1.0 / den) * (aff * from.m_p00);
  den = perspectiveDen.x * from.m_p01.x + perspectiveDen.y * from.m_p01.y + 1;
  assert(den != 0);
  fp.m_p01 = (1.0 / den) * (aff * from.m_p01);
  den = perspectiveDen.x * from.m_p10.x + perspectiveDen.y * from.m_p10.y + 1;
  assert(den != 0);
  fp.m_p10 = (1.0 / den) * (aff * from.m_p10);
  den = perspectiveDen.x * from.m_p11.x + perspectiveDen.y * from.m_p11.y + 1;
  assert(den != 0);
  fp.m_p11 = (1.0 / den) * (aff * from.m_p11);

  return fp;
}