mutter/common/cogl-primitives.c

/*
 * Cogl
 *
 * An object oriented GL/GLES Abstraction/Utility Layer
 *
 * Copyright (C) 2007,2008,2009 Intel Corporation.
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2 of the License, or (at your option) any later version.
 *
 * This library 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
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include "cogl.h"
#include "cogl-internal.h"
#include "cogl-context.h"
#include "cogl-texture-private.h"
#include "cogl-material-private.h"
#include "cogl-vertex-buffer-private.h"

#include <string.h>
#include <gmodule.h>
#include <math.h>

#define _COGL_MAX_BEZ_RECURSE_DEPTH 16

#ifdef HAVE_COGL_GL

#define glGenBuffers ctx->pf_glGenBuffersARB
#define glBindBuffer ctx->pf_glBindBufferARB
#define glBufferData ctx->pf_glBufferDataARB
#define glBufferSubData ctx->pf_glBufferSubDataARB
#define glDeleteBuffers ctx->pf_glDeleteBuffersARB
#define glClientActiveTexture ctx->pf_glClientActiveTexture

#elif defined (HAVE_COGL_GLES2)

#include "../gles/cogl-gles2-wrapper.h"

#endif


/* XXX NB:
 * Our journal's vertex data is arranged as follows:
 * 4 vertices per quad:
 *    2 or 3 GLfloats per position (3 when doing software transforms)
 *    4 RGBA GLubytes,
 *    2 GLfloats per tex coord * n_layers
 *
 * Where n_layers corresponds to the number of material layers enabled
 *
 * To avoid frequent changes in the stride of our vertex data we always pad
 * n_layers to be >= 2
 *
 * When we are transforming quads in software we need to also track the z
 * coordinate of transformed vertices.
 *
 * So for a given number of layers this gets the stride in 32bit words:
 */
#define SW_TRANSFORM      (!(cogl_debug_flags & \
                             COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM))
#define POS_STRIDE        (SW_TRANSFORM ? 3 : 2) /* number of 32bit words */
#define N_POS_COMPONENTS  POS_STRIDE
#define COLOR_STRIDE      1 /* number of 32bit words */
#define TEX_STRIDE        2 /* number of 32bit words */
#define MIN_LAYER_PADING  2
#define GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS(N_LAYERS) \
  (POS_STRIDE + COLOR_STRIDE + \
   TEX_STRIDE * (N_LAYERS < MIN_LAYER_PADING ? MIN_LAYER_PADING : N_LAYERS))


typedef void (*CoglJournalBatchCallback) (CoglJournalEntry *start,
                                          int n_entries,
                                          void *data);
typedef gboolean (*CoglJournalBatchTest) (CoglJournalEntry *entry0,
                                          CoglJournalEntry *entry1);

typedef struct _CoglJournalFlushState
{
  size_t              stride;
  /* Note: this is a pointer to handle fallbacks. It normally holds a VBO
   * offset, but when the driver doesn't support VBOs then this points into
   * our GArray of logged vertices. */
  char *                   vbo_offset;
  GLuint                   vertex_offset;
#ifndef HAVE_COGL_GL
  CoglJournalIndices *indices;
  size_t              indices_type_size;
#endif
} CoglJournalFlushState;

/* these are defined in the particular backend */
void _cogl_path_add_node    (gboolean new_sub_path,
			     float x,
                             float y);
void _cogl_path_fill_nodes    ();
void _cogl_path_stroke_nodes  ();

void
_cogl_journal_dump_quad_vertices (guint8 *data, int n_layers)
{
  size_t stride = GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS (n_layers);
  int i;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  g_print ("n_layers = %d; stride = %d; pos stride = %d; color stride = %d; "
           "tex stride = %d; stride in bytes = %d\n",
           n_layers, (int)stride, POS_STRIDE, COLOR_STRIDE,
           TEX_STRIDE, (int)stride * 4);

  for (i = 0; i < 4; i++)
    {
      float *v = (float *)data + (i * stride);
      guint8 *c = data + (POS_STRIDE * 4) + (i * stride * 4);
      int j;

      if (cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM)
        g_print ("v%d: x = %f, y = %f, rgba=0x%02X%02X%02X%02X",
                 i, v[0], v[1], c[0], c[1], c[2], c[3]);
      else
        g_print ("v%d: x = %f, y = %f, z = %f, rgba=0x%02X%02X%02X%02X",
                 i, v[0], v[1], v[2], c[0], c[1], c[2], c[3]);
      for (j = 0; j < n_layers; j++)
        {
          float *t = v + POS_STRIDE + COLOR_STRIDE + TEX_STRIDE * j;
          g_print (", tx%d = %f, ty%d = %f", j, t[0], j, t[1]);
        }
      g_print ("\n");
    }
}

void
_cogl_journal_dump_quad_batch (guint8 *data, int n_layers, int n_quads)
{
  size_t byte_stride = GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS (n_layers) * 4;
  int i;

  g_print ("_cogl_journal_dump_quad_batch: n_layers = %d, n_quads = %d\n",
           n_layers, n_quads);
  for (i = 0; i < n_quads; i++)
    _cogl_journal_dump_quad_vertices (data + byte_stride * 4 * i, n_layers);
}

static void
batch_and_call (CoglJournalEntry *entries,
                int n_entries,
                CoglJournalBatchTest can_batch_callback,
                CoglJournalBatchCallback batch_callback,
                void *data)
{
  int i;
  int batch_len = 1;
  CoglJournalEntry *batch_start = entries;

  for (i = 1; i < n_entries; i++)
    {
      CoglJournalEntry *entry0 = &entries[i - 1];
      CoglJournalEntry *entry1 = entry0 + 1;

      if (can_batch_callback (entry0, entry1))
        {
          batch_len++;
          continue;
        }

      batch_callback (batch_start, batch_len, data);

      batch_start = entry1;
      batch_len = 1;
    }

  /* The last batch... */
  batch_callback (batch_start, batch_len, data);
}

static void
_cogl_journal_flush_modelview_and_entries (CoglJournalEntry *batch_start,
                                           int               batch_len,
                                           void             *data)
{
  CoglJournalFlushState *state = data;

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_BATCHING))
    g_print ("BATCHING:    modelview batch len = %d\n", batch_len);

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM))
    GE (glLoadMatrixf ((GLfloat *)&batch_start->model_view));

#ifdef HAVE_COGL_GL

  GE (glDrawArrays (GL_QUADS, state->vertex_offset, batch_len * 4));

#else /* HAVE_COGL_GL */

  if (batch_len > 1)
    {
      int indices_offset = (state->vertex_offset / 4) * 6;
      GE (glDrawElements (GL_TRIANGLES,
                          6 * batch_len,
                          indices->type,
                          indices_offset * state->indices_type_size));
    }
  else
    {
      GE (glDrawArrays (GL_TRIANGLE_FAN,
                        state->vertex_offset, /* first */
                        4)); /* n vertices */
    }
#endif

  /* DEBUGGING CODE XXX:
   * This path will cause all rectangles to be drawn with a red, green
   * or blue outline with no blending. This may e.g. help with debugging
   * texture slicing issues or blending issues, plus it looks quite cool.
   */
  if (cogl_debug_flags & COGL_DEBUG_RECTANGLES)
    {
      static CoglHandle outline = COGL_INVALID_HANDLE;
      static int color = 0;
      int i;
      if (outline == COGL_INVALID_HANDLE)
        outline = cogl_material_new ();

      cogl_enable (COGL_ENABLE_VERTEX_ARRAY);
      for (i = 0; i < batch_len; i++, color = (color + 1) % 3)
        {
          cogl_material_set_color4ub (outline,
                                      color == 0 ? 0xff : 0x00,
                                      color == 1 ? 0xff : 0x00,
                                      color == 2 ? 0xff : 0x00,
                                      0xff);
          _cogl_material_flush_gl_state (outline, NULL);
          GE( glDrawArrays (GL_LINE_LOOP, 4 * i, 4) );
        }
    }

  state->vertex_offset += (4 * batch_len);
}

static gboolean
compare_entry_modelviews (CoglJournalEntry *entry0,
                          CoglJournalEntry *entry1)
{
  /* Batch together quads with the same model view matrix */

  /* FIXME: this is nasty, there are much nicer ways to track this
   * (at the add_quad_vertices level) without resorting to a memcmp!
   *
   * E.g. If the cogl-current-matrix code maintained an "age" for
   * the modelview matrix we could simply check in add_quad_vertices
   * if the age has increased, and if so record the change as a
   * boolean in the journal.
   */

  if (memcmp (&entry0->model_view, &entry1->model_view,
              sizeof (GLfloat) * 16) == 0)
    return TRUE;
  else
    return FALSE;
}

/* At this point we have a run of quads that we know have compatible
 * materials, but they may not all have the same modelview matrix */
static void
_cogl_journal_flush_material_and_entries (CoglJournalEntry *batch_start,
                                          gint              batch_len,
                                          void             *data)
{
  gulong                 enable_flags = 0;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_BATCHING))
    g_print ("BATCHING:   material batch len = %d\n", batch_len);

  _cogl_material_flush_gl_state (batch_start->material,
                                 &batch_start->flush_options);

  /* FIXME: This api is a bit yukky, ideally it will be removed if we
   * re-work the cogl_enable mechanism */
  enable_flags |= _cogl_material_get_cogl_enable_flags (batch_start->material);

  if (ctx->enable_backface_culling)
    enable_flags |= COGL_ENABLE_BACKFACE_CULLING;

  enable_flags |= COGL_ENABLE_VERTEX_ARRAY;
  enable_flags |= COGL_ENABLE_COLOR_ARRAY;
  cogl_enable (enable_flags);

  /* If we haven't transformed the quads in software then we need to also break
   * up batches according to changes in the modelview matrix... */
  if (cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM)
    {
      batch_and_call (batch_start,
                      batch_len,
                      compare_entry_modelviews,
                      _cogl_journal_flush_modelview_and_entries,
                      data);
    }
  else
    _cogl_journal_flush_modelview_and_entries (batch_start, batch_len, data);
}

static gboolean
compare_entry_materials (CoglJournalEntry *entry0, CoglJournalEntry *entry1)
{
  /* batch rectangles using compatible materials */

  /* XXX: _cogl_material_equal may give false negatives since it avoids
   * deep comparisons as an optimization. It aims to compare enough so
   * that we that we are able to batch the 90% common cases, but may not
   * look at less common differences. */
  if (_cogl_material_equal (entry0->material,
                            &entry0->flush_options,
                            entry1->material,
                            &entry1->flush_options))
    return TRUE;
  else
    return FALSE;
}

/* Since the stride may not reflect the number of texture layers in use
 * (due to padding) we deal with texture coordinate offsets separately
 * from vertex and color offsets... */
static void
_cogl_journal_flush_texcoord_vbo_offsets_and_entries (
                                          CoglJournalEntry *batch_start,
                                          gint              batch_len,
                                          void             *data)
{
  CoglJournalFlushState *state = data;
  int                    prev_n_texcoord_arrays_enabled;
  int                    i;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  for (i = 0; i < batch_start->n_layers; i++)
    {
      GE (glClientActiveTexture (GL_TEXTURE0 + i));
      GE (glEnableClientState (GL_TEXTURE_COORD_ARRAY));
      /* XXX NB:
       * Our journal's vertex data is arranged as follows:
       * 4 vertices per quad:
       *    2 or 3 GLfloats per position (3 when doing software transforms)
       *    4 RGBA GLubytes,
       *    2 GLfloats per tex coord * n_layers
       * (though n_layers may be padded; see definition of
       *  GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS for details)
       */
      GE (glTexCoordPointer (2, GL_FLOAT, state->stride,
                             (void *)(state->vbo_offset +
                                      (POS_STRIDE + COLOR_STRIDE) * 4 +
                                      TEX_STRIDE * 4 * i)));
    }
  prev_n_texcoord_arrays_enabled =
    ctx->n_texcoord_arrays_enabled;
  ctx->n_texcoord_arrays_enabled = batch_start->n_layers;
  for (; i < prev_n_texcoord_arrays_enabled; i++)
    {
      GE (glClientActiveTexture (GL_TEXTURE0 + i));
      GE (glDisableClientState (GL_TEXTURE_COORD_ARRAY));
    }

  batch_and_call (batch_start,
                  batch_len,
                  compare_entry_materials,
                  _cogl_journal_flush_material_and_entries,
                  data);
}

static gboolean
compare_entry_n_layers (CoglJournalEntry *entry0, CoglJournalEntry *entry1)
{
  if (entry0->n_layers == entry1->n_layers)
    return TRUE;
  else
    return FALSE;
}

/* At this point we know the stride has changed from the previous batch
 * of journal entries */
static void
_cogl_journal_flush_vbo_offsets_and_entries (CoglJournalEntry *batch_start,
                                             gint              batch_len,
                                             void             *data)
{
  CoglJournalFlushState   *state = data;
  size_t                   stride;
#ifndef HAVE_COGL_GL
  int                      needed_indices = batch_len * 6;
  CoglHandle               indices_handle;
  CoglVertexBufferIndices *indices;
#endif

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_BATCHING))
    g_print ("BATCHING:  vbo offset batch len = %d\n", batch_len);

  /* XXX NB:
   * Our journal's vertex data is arranged as follows:
   * 4 vertices per quad:
   *    2 or 3 GLfloats per position (3 when doing software transforms)
   *    4 RGBA GLubytes,
   *    2 GLfloats per tex coord * n_layers
   * (though n_layers may be padded; see definition of
   *  GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS for details)
   */
  stride = GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS (batch_start->n_layers);
  stride *= sizeof (GLfloat);
  state->stride = stride;

  GE (glVertexPointer (N_POS_COMPONENTS, GL_FLOAT, stride,
                       (void *)state->vbo_offset));
  GE (glColorPointer (4, GL_UNSIGNED_BYTE, stride,
                      (void *)(state->vbo_offset + (POS_STRIDE * 4))));

#ifndef HAVE_COGL_GL
  indices_handle = cogl_vertex_buffer_indices_get_for_quads (needed_indices);
  indices = _cogl_vertex_buffer_indices_pointer_from_handle (indices_handle);
  state->indices = indices;

  if (indices->type == GL_UNSIGNED_BYTE)
    state->indices_type_size = 1;
  else if (indices->type == GL_UNSIGNED_SHORT)
    state->indices_type_size = 2;
  else
    g_critical ("unknown indices type %d", indices->type);

  GE (glBindBuffer (GL_ELEMENT_ARRAY_BUFFER,
                    GPOINTER_TO_UINT (indices->vbo_name)));
#endif

  /* We only call gl{Vertex,Color,Texture}Pointer when the stride within
   * the VBO changes. (due to a change in the number of material layers)
   * While the stride remains constant we walk forward through the above
   * VBO using a vertex offset passed to glDraw{Arrays,Elements} */
  state->vertex_offset = 0;

  if (cogl_debug_flags & COGL_DEBUG_JOURNAL)
    {
      guint8 *verts;

      if (cogl_get_features () & COGL_FEATURE_VBOS)
        verts = ((guint8 *)ctx->logged_vertices->data) +
          (size_t)state->vbo_offset;
      else
        verts = (guint8 *)state->vbo_offset;
      _cogl_journal_dump_quad_batch (verts,
                                     batch_start->n_layers,
                                     batch_len);
    }

  batch_and_call (batch_start,
                  batch_len,
                  compare_entry_n_layers,
                  _cogl_journal_flush_texcoord_vbo_offsets_and_entries,
                  data);

  /* progress forward through the VBO containing all our vertices */
  state->vbo_offset += (stride * 4 * batch_len);
  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_JOURNAL))
    g_print ("new vbo offset = %lu\n", (gulong)state->vbo_offset);
}

static gboolean
compare_entry_strides (CoglJournalEntry *entry0, CoglJournalEntry *entry1)
{
  /* Currently the only thing that affects the stride for our vertex arrays
   * is the number of material layers. We need to update our VBO offsets
   * whenever the stride changes. */
  /* TODO: We should be padding the n_layers == 1 case as if it were
   * n_layers == 2 so we can reduce the need to split batches. */
  if (entry0->n_layers == entry1->n_layers ||
      (entry0->n_layers <= MIN_LAYER_PADING &&
       entry1->n_layers <= MIN_LAYER_PADING))
    return TRUE;
  else
    return FALSE;
}

static void
upload_vertices_to_vbo (GArray *vertices, CoglJournalFlushState *state)
{
  size_t needed_vbo_len;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  needed_vbo_len = vertices->len * sizeof (GLfloat);

  g_assert (ctx->journal_vbo == 0);
  g_assert (needed_vbo_len);
  GE (glGenBuffers (1, &ctx->journal_vbo));
  GE (glBindBuffer (GL_ARRAY_BUFFER, ctx->journal_vbo));
  GE (glBufferData (GL_ARRAY_BUFFER,
                    needed_vbo_len,
                    vertices->data,
                    GL_STATIC_DRAW));

  /* As we flush the journal entries in batches we walk forward through the
   * above VBO starting at offset 0... */
  state->vbo_offset = 0;
}

/* XXX NB: When _cogl_journal_flush() returns all state relating
 * to materials, all glEnable flags and current matrix state
 * is undefined.
 */
void
_cogl_journal_flush (void)
{
  CoglJournalFlushState state;
  int                   i;
  gboolean              vbo_fallback =
    (cogl_get_features () & COGL_FEATURE_VBOS) ? FALSE : TRUE;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  if (ctx->journal->len == 0)
    return;

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_BATCHING))
    g_print ("BATCHING: journal len = %d\n", ctx->journal->len);

  /* Load all the vertex data we have accumulated so far into a single VBO
   * to minimize memory management costs within the GL driver. */
  if (!vbo_fallback)
    upload_vertices_to_vbo (ctx->logged_vertices, &state);
  else
    state.vbo_offset = (char *)ctx->logged_vertices->data;

  /* Since the journal deals with emitting the modelview matrices manually
   * we need to dirty our client side modelview matrix stack cache... */
  _cogl_current_matrix_state_dirty ();

  /* And explicitly flush other matrix stacks... */
  _cogl_set_current_matrix (COGL_MATRIX_PROJECTION);
  _cogl_current_matrix_state_flush ();

  /* If we have transformed all our quads at log time then the whole journal
   * then we ensure no further model transform is applied by loading the
   * identity matrix here...*/
  if (!(cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM))
    {
      GE (glMatrixMode (GL_MODELVIEW));
      glLoadIdentity ();
    }

  /* batch_and_call() batches a list of journal entries according to some
   * given criteria and calls a callback once for each determined batch.
   *
   * The process of flushing the journal is staggered to reduce the amount
   * of driver/GPU state changes necessary:
   * 1) We split the entries according to the stride of the vertices:
   *      Each time the stride of our vertex data changes we need to call
   *      gl{Vertex,Color}Pointer to inform GL of new VBO offsets.
   *      Currently the only thing that affects the stride of our vertex data
   *      is the number of material layers.
   * 2) We split the entries explicitly by the number of material layers:
   *      We pad our vertex data when the number of layers is < 2 so that we
   *      can minimize changes in stride. Each time the number of layers
   *      changes we need to call glTexCoordPointer to inform GL of new VBO
   *      offsets.
   * 3) We then split according to compatible Cogl materials:
   *      This is where we flush material state
   * 4) Finally we split according to modelview matrix changes:
   *      This is when we finally tell GL to draw something.
   *      Note: Splitting by modelview changes is skipped when are doing the
   *      vertex transformation in software at log time.
   */
  batch_and_call ((CoglJournalEntry *)ctx->journal->data, /* first entry */
                  ctx->journal->len, /* max number of entries to consider */
                  compare_entry_strides,
                  _cogl_journal_flush_vbo_offsets_and_entries, /* callback */
                  &state); /* data */

  for (i = 0; i < ctx->journal->len; i++)
    {
      CoglJournalEntry *entry =
        &g_array_index (ctx->journal, CoglJournalEntry, i);
      _cogl_material_journal_unref (entry->material);
    }

  if (!vbo_fallback)
    {
      GE (glDeleteBuffers (1, &ctx->journal_vbo));
      ctx->journal_vbo = 0;
    }

  g_array_set_size (ctx->journal, 0);
  g_array_set_size (ctx->logged_vertices, 0);
}

static void
_cogl_journal_log_quad (float       x_1,
                        float       y_1,
                        float       x_2,
                        float       y_2,
                        CoglHandle  material,
                        int         n_layers,
                        guint32     fallback_layers,
                        GLuint      layer0_override_texture,
                        float      *tex_coords,
                        guint       tex_coords_len)
{
  size_t            stride;
  size_t            byte_stride;
  int               next_vert;
  GLfloat          *v;
  GLubyte          *c;
  GLubyte          *src_c;
  int               i;
  int               next_entry;
  guint32           disable_layers;
  CoglJournalEntry *entry;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  /* The vertex data is logged into a separate array in a layout that can be
   * directly passed to OpenGL
   */

  /* XXX: See definition of GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS for details
   * about how we pack our vertex data */
  stride = GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS (n_layers);
  /* NB: stride is in 32bit words */
  byte_stride = stride * 4;

  next_vert = ctx->logged_vertices->len;
  g_array_set_size (ctx->logged_vertices, next_vert + 4 * stride);
  v = &g_array_index (ctx->logged_vertices, GLfloat, next_vert);
  c = (GLubyte *)(v + POS_STRIDE);

  /* XXX: All the jumping around to fill in this strided buffer doesn't
   * seem ideal. */

  /* XXX: we could defer expanding the vertex data for GL until we come
   * to flushing the journal. */

  /* FIXME: This is a hacky optimization, since it will break if we
   * change the definition of CoglColor: */
  _cogl_material_get_colorubv (material, c);
  src_c = c;
  for (i = 0; i < 3; i++)
    {
      c += byte_stride;
      memcpy (c, src_c, 4);
    }

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM))
    {
      v[0] = x_1; v[1] = y_1;
      v += stride;
      v[0] = x_1; v[1] = y_2;
      v += stride;
      v[0] = x_2; v[1] = y_2;
      v += stride;
      v[0] = x_2; v[1] = y_1;
    }
  else
    {
      CoglMatrix  mv;
      float       x, y, z, w;

      cogl_get_modelview_matrix (&mv);

      x = x_1, y = y_1, z = 0; w = 1;
      cogl_matrix_transform_point (&mv, &x, &y, &z, &w);
      v[0] = x; v[1] = y; v[2] = z;
      v += stride;
      x = x_1, y = y_2, z = 0; w = 1;
      cogl_matrix_transform_point (&mv, &x, &y, &z, &w);
      v[0] = x; v[1] = y; v[2] = z;
      v += stride;
      x = x_2, y = y_2, z = 0; w = 1;
      cogl_matrix_transform_point (&mv, &x, &y, &z, &w);
      v[0] = x; v[1] = y; v[2] = z;
      v += stride;
      x = x_2, y = y_1, z = 0; w = 1;
      cogl_matrix_transform_point (&mv, &x, &y, &z, &w);
      v[0] = x; v[1] = y; v[2] = z;
    }

  for (i = 0; i < n_layers; i++)
    {
      /* XXX: See definition of GET_JOURNAL_VB_STRIDE_FOR_N_LAYERS for details
       * about how we pack our vertex data */
      GLfloat *t = &g_array_index (ctx->logged_vertices, GLfloat,
                                   next_vert +  POS_STRIDE +
                                   COLOR_STRIDE + TEX_STRIDE * i);

      t[0] = tex_coords[0]; t[1] = tex_coords[1];
      t += stride;
      t[0] = tex_coords[0]; t[1] = tex_coords[3];
      t += stride;
      t[0] = tex_coords[2]; t[1] = tex_coords[3];
      t += stride;
      t[0] = tex_coords[2]; t[1] = tex_coords[1];
    }

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_JOURNAL))
    {
      g_print ("Logged new quad:\n");
      v = &g_array_index (ctx->logged_vertices, GLfloat, next_vert);
      _cogl_journal_dump_quad_vertices ((guint8 *)v, n_layers);
    }

  next_entry = ctx->journal->len;
  g_array_set_size (ctx->journal, next_entry + 1);
  entry = &g_array_index (ctx->journal, CoglJournalEntry, next_entry);

  disable_layers = (1 << n_layers) - 1;
  disable_layers = ~disable_layers;

  entry->material = _cogl_material_journal_ref (material);
  entry->n_layers = n_layers;
  entry->flush_options.flags =
    COGL_MATERIAL_FLUSH_FALLBACK_MASK |
    COGL_MATERIAL_FLUSH_DISABLE_MASK |
    COGL_MATERIAL_FLUSH_SKIP_GL_COLOR;
  entry->flush_options.fallback_layers = fallback_layers;
  entry->flush_options.disable_layers = disable_layers;
  if (layer0_override_texture)
    {
      entry->flush_options.flags |= COGL_MATERIAL_FLUSH_LAYER0_OVERRIDE;
      entry->flush_options.layer0_override_texture = layer0_override_texture;
    }
  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_DISABLE_SOFTWARE_TRANSFORM))
    cogl_get_modelview_matrix (&entry->model_view);

  if (G_UNLIKELY (cogl_debug_flags & COGL_DEBUG_DISABLE_BATCHING
                  || cogl_debug_flags & COGL_DEBUG_RECTANGLES))
    _cogl_journal_flush ();
}

static void
_cogl_texture_sliced_quad (CoglTexture *tex,
                           CoglHandle   material,
		           float        x_1,
		           float        y_1,
		           float        x_2,
		           float        y_2,
		           float        tx_1,
		           float        ty_1,
		           float        tx_2,
		           float        ty_2)
{
  CoglSpanIter  iter_x    ,  iter_y;
  float         tw        ,  th;
  float         tqx       ,  tqy;
  float         first_tx  ,  first_ty;
  float         first_qx  ,  first_qy;
  float         slice_tx1 ,  slice_ty1;
  float         slice_tx2 ,  slice_ty2;
  float         slice_qx1 ,  slice_qy1;
  float         slice_qx2 ,  slice_qy2;
  GLuint        gl_handle;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  COGL_NOTE (DRAW, "Drawing Tex Quad (Sliced Mode)");

  /* We can't use hardware repeat so we need to set clamp to edge
     otherwise it might pull in edge pixels from the other side */
  _cogl_texture_set_wrap_mode_parameter (tex, GL_CLAMP_TO_EDGE);

  /* If the texture coordinates are backwards then swap both the
     geometry and texture coordinates so that the texture will be
     flipped but we can still use the same algorithm to iterate the
     slices */
  if (tx_2 < tx_1)
    {
      float temp = x_1;
      x_1 = x_2;
      x_2 = temp;
      temp = tx_1;
      tx_1 = tx_2;
      tx_2 = temp;
    }
  if (ty_2 < ty_1)
    {
      float temp = y_1;
      y_1 = y_2;
      y_2 = temp;
      temp = ty_1;
      ty_1 = ty_2;
      ty_2 = temp;
    }

  /* Scale ratio from texture to quad widths */
  tw = (float)(tex->bitmap.width);
  th = (float)(tex->bitmap.height);

  tqx = (x_2 - x_1) / (tw * (tx_2 - tx_1));
  tqy = (y_2 - y_1) / (th * (ty_2 - ty_1));

  /* Integral texture coordinate for first tile */
  first_tx = (float)(floorf (tx_1));
  first_ty = (float)(floorf (ty_1));

  /* Denormalize texture coordinates */
  first_tx = (first_tx * tw);
  first_ty = (first_ty * th);
  tx_1 = (tx_1 * tw);
  ty_1 = (ty_1 * th);
  tx_2 = (tx_2 * tw);
  ty_2 = (ty_2 * th);

  /* Quad coordinate of the first tile */
  first_qx = x_1 - (tx_1 - first_tx) * tqx;
  first_qy = y_1 - (ty_1 - first_ty) * tqy;


  /* Iterate until whole quad height covered */
  for (_cogl_span_iter_begin (&iter_y, tex->slice_y_spans,
			      first_ty, ty_1, ty_2) ;
       !_cogl_span_iter_end  (&iter_y) ;
       _cogl_span_iter_next  (&iter_y) )
    {
      float tex_coords[4];

      /* Discard slices out of quad early */
      if (!iter_y.intersects) continue;

      /* Span-quad intersection in quad coordinates */
      slice_qy1 = first_qy + (iter_y.intersect_start - first_ty) * tqy;

      slice_qy2 = first_qy + (iter_y.intersect_end - first_ty) * tqy;

      /* Localize slice texture coordinates */
      slice_ty1 = iter_y.intersect_start - iter_y.pos;
      slice_ty2 = iter_y.intersect_end - iter_y.pos;

      /* Normalize texture coordinates to current slice
         (rectangle texture targets take denormalized) */
#if HAVE_COGL_GL
      if (tex->gl_target != CGL_TEXTURE_RECTANGLE_ARB)
#endif
        {
          slice_ty1 /= iter_y.span->size;
          slice_ty2 /= iter_y.span->size;
        }

      /* Iterate until whole quad width covered */
      for (_cogl_span_iter_begin (&iter_x, tex->slice_x_spans,
				  first_tx, tx_1, tx_2) ;
	   !_cogl_span_iter_end  (&iter_x) ;
	   _cogl_span_iter_next  (&iter_x) )
        {
	  /* Discard slices out of quad early */
	  if (!iter_x.intersects) continue;

	  /* Span-quad intersection in quad coordinates */
	  slice_qx1 = first_qx + (iter_x.intersect_start - first_tx) * tqx;

	  slice_qx2 = first_qx + (iter_x.intersect_end - first_tx) * tqx;

	  /* Localize slice texture coordinates */
	  slice_tx1 = iter_x.intersect_start - iter_x.pos;
	  slice_tx2 = iter_x.intersect_end - iter_x.pos;

	  /* Normalize texture coordinates to current slice
             (rectangle texture targets take denormalized) */
#if HAVE_COGL_GL
          if (tex->gl_target != CGL_TEXTURE_RECTANGLE_ARB)
#endif
            {
              slice_tx1 /= iter_x.span->size;
              slice_tx2 /= iter_x.span->size;
            }

          COGL_NOTE (DRAW,
                     "~~~~~ slice (%d, %d)\n"
	             "qx1: %f\t"
	             "qy1: %f\n"
                     "qx2: %f\t"
                     "qy2: %f\n"
                     "tx1: %f\t"
                     "ty1: %f\n"
                     "tx2: %f\t"
                     "ty2: %f\n",
                     iter_x.index, iter_y.index,
                     slice_qx1, slice_qy1,
                     slice_qx2, slice_qy2,
                     slice_tx1, slice_ty1,
                     slice_tx2, slice_ty2);

	  /* Pick and bind opengl texture object */
	  gl_handle = g_array_index (tex->slice_gl_handles, GLuint,
				     iter_y.index * iter_x.array->len +
				     iter_x.index);

          tex_coords[0] = slice_tx1;
          tex_coords[1] = slice_ty1;
          tex_coords[2] = slice_tx2;
          tex_coords[3] = slice_ty2;
          _cogl_journal_log_quad (slice_qx1,
                                  slice_qy1,
                                  slice_qx2,
                                  slice_qy2,
                                  material,
                                  1, /* one layer */
                                  0, /* don't need to use fallbacks */
                                  gl_handle, /* replace the layer0 texture */
                                  tex_coords,
                                  4);
	}
    }
}

static gboolean
_cogl_multitexture_unsliced_quad (float        x_1,
                                  float        y_1,
                                  float        x_2,
                                  float        y_2,
                                  CoglHandle   material,
                                  guint32      fallback_layers,
                                  const float *user_tex_coords,
                                  gint         user_tex_coords_len)
{
  int          n_layers = cogl_material_get_n_layers (material);
  float       *final_tex_coords = alloca (sizeof (float) * 4 * n_layers);
  const GList *layers;
  GList       *tmp;
  int          i;

  _COGL_GET_CONTEXT (ctx, FALSE);

  /*
   * Validate the texture coordinates for this rectangle.
   */
  layers = cogl_material_get_layers (material);
  for (tmp = (GList *)layers, i = 0; tmp != NULL; tmp = tmp->next, i++)
    {
      CoglHandle         layer = (CoglHandle)tmp->data;
      CoglHandle         tex_handle;
      CoglTexture       *tex;
      const float       *in_tex_coords;
      float             *out_tex_coords;
      CoglTexSliceSpan  *x_span;
      CoglTexSliceSpan  *y_span;

      tex_handle = cogl_material_layer_get_texture (layer);

      /* COGL_INVALID_HANDLE textures are handled by
       * _cogl_material_flush_gl_state */
      if (tex_handle == COGL_INVALID_HANDLE)
        continue;

      tex = _cogl_texture_pointer_from_handle (tex_handle);

      in_tex_coords = &user_tex_coords[i * 4];
      out_tex_coords = &final_tex_coords[i * 4];


      /* If the texture has waste or we are using GL_TEXTURE_RECT we
       * can't handle texture repeating so we check that the texture
       * coords lie in the range [0,1].
       *
       * NB: We already know that no texture matrix is being used
       * if the texture has waste since we validated that early on.
       * TODO: check for a texture matrix in the GL_TEXTURE_RECT
       * case.
       */
      if ((
#if HAVE_COGL_GL
           tex->gl_target == GL_TEXTURE_RECTANGLE_ARB ||
#endif
           _cogl_texture_span_has_waste (tex, 0, 0))
          && i < user_tex_coords_len / 4
          && (in_tex_coords[0] < 0 || in_tex_coords[0] > 1.0
              || in_tex_coords[1] < 0 || in_tex_coords[1] > 1.0
              || in_tex_coords[2] < 0 || in_tex_coords[2] > 1.0
              || in_tex_coords[3] < 0 || in_tex_coords[3] > 1.0))
        {
          if (i == 0)
            {
              if (n_layers > 1)
                {
                  static gboolean warning_seen = FALSE;
                  if (!warning_seen)
                    g_warning ("Skipping layers 1..n of your material since "
                               "the first layer has waste and you supplied "
                               "texture coordinates outside the range [0,1]. "
                               "We don't currently support any "
                               "multi-texturing using textures with waste "
                               "when repeating is necissary so we are "
                               "falling back to sliced textures assuming "
                               "layer 0 is the most important one keep");
                  warning_seen = TRUE;
                }
              return FALSE;
            }
          else
            {
              static gboolean warning_seen = FALSE;
              if (!warning_seen)
                g_warning ("Skipping layer %d of your material "
                           "consisting of a texture with waste since "
                           "you have supplied texture coords outside "
                           "the range [0,1] (unsupported when "
                           "multi-texturing)", i);
              warning_seen = TRUE;

              /* NB: marking for fallback will replace the layer with
               * a default transparent texture */
              fallback_layers |= (1 << i);
            }
        }


      /*
       * Setup the texture unit...
       */

      /* NB: The user might not have supplied texture coordinates for all
       * layers... */
      if (i < (user_tex_coords_len / 4))
        {
          GLenum wrap_mode;

          /* If the texture coords are all in the range [0,1] then we want to
             clamp the coords to the edge otherwise it can pull in edge pixels
             from the wrong side when scaled */
          if (in_tex_coords[0] >= 0 && in_tex_coords[0] <= 1.0
              && in_tex_coords[1] >= 0 && in_tex_coords[1] <= 1.0
              && in_tex_coords[2] >= 0 && in_tex_coords[2] <= 1.0
              && in_tex_coords[3] >= 0 && in_tex_coords[3] <= 1.0)
            wrap_mode = GL_CLAMP_TO_EDGE;
          else
            wrap_mode = GL_REPEAT;

          memcpy (out_tex_coords, in_tex_coords, sizeof (GLfloat) * 4);

          _cogl_texture_set_wrap_mode_parameter (tex, wrap_mode);
        }
      else
        {
          out_tex_coords[0] = 0; /* tx_1 */
          out_tex_coords[1] = 0; /* ty_1 */
          out_tex_coords[2] = 1.0; /* tx_2 */
          out_tex_coords[3] = 1.0; /* ty_2 */

          _cogl_texture_set_wrap_mode_parameter (tex, GL_CLAMP_TO_EDGE);
        }

      /* Don't include the waste in the texture coordinates */
      x_span = &g_array_index (tex->slice_x_spans, CoglTexSliceSpan, 0);
      y_span = &g_array_index (tex->slice_y_spans, CoglTexSliceSpan, 0);

      out_tex_coords[0] =
        out_tex_coords[0] * (x_span->size - x_span->waste) / x_span->size;
      out_tex_coords[1] =
        out_tex_coords[1] * (y_span->size - y_span->waste) / y_span->size;
      out_tex_coords[2] =
        out_tex_coords[2] * (x_span->size - x_span->waste) / x_span->size;
      out_tex_coords[3] =
        out_tex_coords[3] * (y_span->size - y_span->waste) / y_span->size;

#if HAVE_COGL_GL
      /* Denormalize texture coordinates for rectangle textures */
      if (tex->gl_target == GL_TEXTURE_RECTANGLE_ARB)
        {
          out_tex_coords[0] *= x_span->size;
          out_tex_coords[1] *= y_span->size;
          out_tex_coords[2] *= x_span->size;
          out_tex_coords[3] *= y_span->size;
        }
#endif
    }

  _cogl_journal_log_quad (x_1,
                          y_1,
                          x_2,
                          y_2,
                          material,
                          n_layers,
                          fallback_layers,
                          0, /* don't replace the layer0 texture */
                          final_tex_coords,
                          n_layers * 4);

  return TRUE;
}

struct _CoglMutiTexturedRect
{
  float        x_1;
  float        y_1;
  float        x_2;
  float        y_2;
  const float *tex_coords;
  gint             tex_coords_len;
};

static void
_cogl_rectangles_with_multitexture_coords (
                                        struct _CoglMutiTexturedRect *rects,
                                        gint                          n_rects)
{
  CoglHandle	 material;
  const GList	*layers;
  int		 n_layers;
  const GList	*tmp;
  guint32        fallback_layers = 0;
  gboolean	 all_use_sliced_quad_fallback = FALSE;
  int		 i;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_clip_ensure ();

  material = ctx->source_material;

  layers = cogl_material_get_layers (material);
  n_layers = cogl_material_get_n_layers (material);

  /*
   * Validate all the layers of the current source material...
   */

  for (tmp = layers, i = 0; tmp != NULL; tmp = tmp->next, i++)
    {
      CoglHandle     layer = tmp->data;
      CoglHandle     tex_handle;
      CoglTexture   *texture = NULL;
      gulong         flags;

      if (cogl_material_layer_get_type (layer)
	  != COGL_MATERIAL_LAYER_TYPE_TEXTURE)
	continue;

      tex_handle = cogl_material_layer_get_texture (layer);

      /* COGL_INVALID_HANDLE textures are handled by
       * _cogl_material_flush_gl_state */
      if (tex_handle == COGL_INVALID_HANDLE)
        continue;

      texture = _cogl_texture_pointer_from_handle (tex_handle);

      /* XXX:
       * For now, if the first layer is sliced then all other layers are
       * ignored since we currently don't support multi-texturing with
       * sliced textures. If the first layer is not sliced then any other
       * layers found to be sliced will be skipped. (with a warning)
       *
       * TODO: Add support for multi-texturing rectangles with sliced
       * textures if no texture matrices are in use.
       */
      if (cogl_texture_is_sliced (tex_handle))
	{
	  if (i == 0)
	    {
              fallback_layers = ~1; /* fallback all except the first layer */
	      all_use_sliced_quad_fallback = TRUE;
              if (tmp->next)
                {
                  static gboolean warning_seen = FALSE;
                  if (!warning_seen)
                    g_warning ("Skipping layers 1..n of your material since "
                               "the first layer is sliced. We don't currently "
                               "support any multi-texturing with sliced "
                               "textures but assume layer 0 is the most "
                               "important to keep");
                  warning_seen = TRUE;
                }
	      break;
	    }
          else
            {
              static gboolean warning_seen = FALSE;
              if (!warning_seen)
                g_warning ("Skipping layer %d of your material consisting of "
                           "a sliced texture (unsuported for multi texturing)",
                           i);
              warning_seen = TRUE;

              /* NB: marking for fallback will replace the layer with
               * a default transparent texture */
              fallback_layers |= (1 << i);
	      continue;
            }
	}

      /* We don't support multi texturing using textures with any waste if the
       * user has supplied a custom texture matrix, since we don't know if
       * the result will end up trying to texture from the waste area. */
      flags = _cogl_material_layer_get_flags (layer);
      if (flags & COGL_MATERIAL_LAYER_FLAG_HAS_USER_MATRIX
          && _cogl_texture_span_has_waste (texture, 0, 0))
        {
          static gboolean warning_seen = FALSE;
          if (!warning_seen)
            g_warning ("Skipping layer %d of your material consisting of a "
                       "texture with waste since you have supplied a custom "
                       "texture matrix and the result may try to sample from "
                       "the waste area of your texture.", i);
          warning_seen = TRUE;

          /* NB: marking for fallback will replace the layer with
           * a default transparent texture */
          fallback_layers |= (1 << i);
          continue;
        }
    }

  /*
   * Emit geometry for each of the rectangles...
   */

  for (i = 0; i < n_rects; i++)
    {
      if (all_use_sliced_quad_fallback
          || !_cogl_multitexture_unsliced_quad (rects[i].x_1, rects[i].y_1,
                                                rects[i].x_2, rects[i].y_2,
                                                material,
                                                fallback_layers,
                                                rects[i].tex_coords,
                                                rects[i].tex_coords_len))
        {
          CoglHandle   first_layer, tex_handle;
          CoglTexture *texture;

          first_layer = layers->data;
          tex_handle = cogl_material_layer_get_texture (first_layer);
          texture = _cogl_texture_pointer_from_handle (tex_handle);
          if (rects[i].tex_coords)
            _cogl_texture_sliced_quad (texture,
                                       material,
                                       rects[i].x_1, rects[i].y_1,
                                       rects[i].x_2, rects[i].y_2,
                                       rects[i].tex_coords[0],
                                       rects[i].tex_coords[1],
                                       rects[i].tex_coords[2],
                                       rects[i].tex_coords[3]);
          else
            _cogl_texture_sliced_quad (texture,
                                       material,
                                       rects[i].x_1, rects[i].y_1,
                                       rects[i].x_2, rects[i].y_2,
                                       0.0f, 0.0f, 1.0f, 1.0f);
        }
    }

#if 0
  /* XXX: The current journal doesn't handle changes to the model view matrix
   * so for now we force a flush at the end of every primitive. */
  _cogl_journal_flush ();
#endif
}

void
cogl_rectangles (const float *verts,
                 guint        n_rects)
{
  struct _CoglMutiTexturedRect *rects;
  int i;

  rects = g_alloca (n_rects * sizeof (struct _CoglMutiTexturedRect));

  for (i = 0; i < n_rects; i++)
    {
      rects[i].x_1 = verts[i * 4];
      rects[i].y_1 = verts[i * 4 + 1];
      rects[i].x_2 = verts[i * 4 + 2];
      rects[i].y_2 = verts[i * 4 + 3];
      rects[i].tex_coords = NULL;
      rects[i].tex_coords_len = 0;
    }

  _cogl_rectangles_with_multitexture_coords (rects, n_rects);
}

void
cogl_rectangles_with_texture_coords (const float *verts,
                                     guint        n_rects)
{
  struct _CoglMutiTexturedRect *rects;
  int i;

  rects = g_alloca (n_rects * sizeof (struct _CoglMutiTexturedRect));

  for (i = 0; i < n_rects; i++)
    {
      rects[i].x_1 = verts[i * 8];
      rects[i].y_1 = verts[i * 8 + 1];
      rects[i].x_2 = verts[i * 8 + 2];
      rects[i].y_2 = verts[i * 8 + 3];
      /* FIXME: rect should be defined to have a const float *geom;
       * instead, to avoid this copy
       * rect[i].geom = &verts[n_rects * 8]; */
      rects[i].tex_coords = &verts[i * 8 + 4];
      rects[i].tex_coords_len = 4;
    }

  _cogl_rectangles_with_multitexture_coords (rects, n_rects);
}

void
cogl_rectangle_with_texture_coords (float x_1,
			            float y_1,
			            float x_2,
			            float y_2,
			            float tx_1,
			            float ty_1,
			            float tx_2,
			            float ty_2)
{
  float verts[8];

  verts[0] = x_1;
  verts[1] = y_1;
  verts[2] = x_2;
  verts[3] = y_2;
  verts[4] = tx_1;
  verts[5] = ty_1;
  verts[6] = tx_2;
  verts[7] = ty_2;

  cogl_rectangles_with_texture_coords (verts, 1);
}

void
cogl_rectangle_with_multitexture_coords (float        x_1,
			                 float        y_1,
			                 float        x_2,
			                 float        y_2,
			                 const float *user_tex_coords,
                                         gint         user_tex_coords_len)
{
  struct _CoglMutiTexturedRect rect;

  rect.x_1 = x_1;
  rect.y_1 = y_1;
  rect.x_2 = x_2;
  rect.y_2 = y_2;
  rect.tex_coords = user_tex_coords;
  rect.tex_coords_len = user_tex_coords_len;

  _cogl_rectangles_with_multitexture_coords (&rect, 1);
}

void
cogl_rectangle (float x_1,
                float y_1,
                float x_2,
                float y_2)
{
  cogl_rectangle_with_multitexture_coords (x_1, y_1,
                                           x_2, y_2,
                                           NULL, 0);
}

static void
_cogl_texture_sliced_polygon (CoglTextureVertex *vertices,
                              guint              n_vertices,
                              guint              stride,
                              gboolean           use_color)
{
  const GList         *layers;
  CoglHandle           layer0;
  CoglHandle           tex_handle;
  CoglTexture         *tex;
  CoglTexSliceSpan    *y_span, *x_span;
  int                  x, y, tex_num, i;
  GLuint               gl_handle;
  GLfloat             *v;
  CoglMaterialFlushOptions options;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  /* We can assume in this case that we have at least one layer in the
   * material that corresponds to a sliced cogl texture */
  layers = cogl_material_get_layers (ctx->source_material);
  layer0 = (CoglHandle)layers->data;
  tex_handle = cogl_material_layer_get_texture (layer0);
  tex = _cogl_texture_pointer_from_handle (tex_handle);

  v = (GLfloat *)ctx->logged_vertices->data;
  for (i = 0; i < n_vertices; i++)
    {
      guint8 *c;

      v[0] = vertices[i].x;
      v[1] = vertices[i].y;
      v[2] = vertices[i].z;

      if (use_color)
        {
          /* NB: [X,Y,Z,TX,TY,R,G,B,A,...] */
          c = (guint8 *) (v + 5);
          c[0] = cogl_color_get_red_byte (&vertices[i].color);
          c[1] = cogl_color_get_green_byte (&vertices[i].color);
          c[2] = cogl_color_get_blue_byte (&vertices[i].color);
          c[3] = cogl_color_get_alpha_byte (&vertices[i].color);
        }

      v += stride;
    }

  /* Render all of the slices with the full geometry but use a
     transparent border color so that any part of the texture not
     covered by the slice will be ignored */
  tex_num = 0;
  for (y = 0; y < tex->slice_y_spans->len; y++)
    {
      y_span = &g_array_index (tex->slice_y_spans, CoglTexSliceSpan, y);

      for (x = 0; x < tex->slice_x_spans->len; x++)
	{
	  x_span = &g_array_index (tex->slice_x_spans, CoglTexSliceSpan, x);

	  gl_handle = g_array_index (tex->slice_gl_handles, GLuint, tex_num++);

	  /* Convert the vertices into an array of GLfloats ready to pass to
	     OpenGL */
          v = (GLfloat *)ctx->logged_vertices->data;
	  for (i = 0; i < n_vertices; i++)
	    {
              GLfloat *t;
              float    tx, ty;

              tx = ((vertices[i].tx
                     - ((float)(x_span->start)
                        / tex->bitmap.width))
                    * tex->bitmap.width / x_span->size);
              ty = ((vertices[i].ty
                     - ((float)(y_span->start)
                        / tex->bitmap.height))
                    * tex->bitmap.height / y_span->size);

#if HAVE_COGL_GL
              /* Scale the coordinates up for rectangle textures */
              if (tex->gl_target == CGL_TEXTURE_RECTANGLE_ARB)
                {
                  tx *= x_span->size;
                  ty *= y_span->size;
                }
#endif

              /* NB: [X,Y,Z,TX,TY,R,G,B,A,...] */
              t = v + 3;
	      t[0] = tx;
	      t[1] = ty;

              v += stride;
	    }

          options.flags =
            COGL_MATERIAL_FLUSH_DISABLE_MASK |
            COGL_MATERIAL_FLUSH_LAYER0_OVERRIDE;
          /* disable all except the first layer */
          options.disable_layers = (guint32)~1;
          options.layer0_override_texture = gl_handle;

          _cogl_material_flush_gl_state (ctx->source_material, &options);
          _cogl_flush_matrix_stacks ();

	  GE( glDrawArrays (GL_TRIANGLE_FAN, 0, n_vertices) );
	}
    }
}

static void
_cogl_multitexture_unsliced_polygon (CoglTextureVertex *vertices,
                                     guint              n_vertices,
                                     guint              n_layers,
                                     guint              stride,
                                     gboolean           use_color,
                                     guint32            fallback_layers)
{
  CoglHandle           material;
  const GList         *layers;
  int                  i;
  GList               *tmp;
  CoglTexSliceSpan    *y_span, *x_span;
  GLfloat             *v;
  CoglMaterialFlushOptions options;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);


  material = ctx->source_material;
  layers = cogl_material_get_layers (material);

  /* Convert the vertices into an array of GLfloats ready to pass to
     OpenGL */
  for (v = (GLfloat *)ctx->logged_vertices->data, i = 0;
       i < n_vertices;
       v += stride, i++)
    {
      guint8 *c;
      int     j;

      /* NB: [X,Y,Z,TX,TY...,R,G,B,A,...] */
      v[0] = vertices[i].x;
      v[1] = vertices[i].y;
      v[2] = vertices[i].z;

      for (tmp = (GList *)layers, j = 0; tmp != NULL; tmp = tmp->next, j++)
        {
          CoglHandle   layer = (CoglHandle)tmp->data;
          CoglHandle   tex_handle;
          CoglTexture *tex;
          GLfloat     *t;
          float        tx, ty;

          tex_handle = cogl_material_layer_get_texture (layer);

          /* COGL_INVALID_HANDLE textures will be handled in
           * _cogl_material_flush_layers_gl_state but there is no need to worry
           * about scaling texture coordinates in this case */
          if (tex_handle == COGL_INVALID_HANDLE)
            continue;

          tex = _cogl_texture_pointer_from_handle (tex_handle);

          y_span = &g_array_index (tex->slice_y_spans, CoglTexSliceSpan, 0);
          x_span = &g_array_index (tex->slice_x_spans, CoglTexSliceSpan, 0);

          tx = ((vertices[i].tx
                 - ((float)(x_span->start)
                    / tex->bitmap.width))
                * tex->bitmap.width / x_span->size);
          ty = ((vertices[i].ty
                 - ((float)(y_span->start)
                    / tex->bitmap.height))
                * tex->bitmap.height / y_span->size);

#if HAVE_COGL_GL
          /* Scale the coordinates up for rectangle textures */
          if (tex->gl_target == CGL_TEXTURE_RECTANGLE_ARB)
            {
              tx *= x_span->size;
              ty *= y_span->size;
            }
#endif

          /* NB: [X,Y,Z,TX,TY...,R,G,B,A,...] */
          t = v + 3 + 2 * j;
          t[0] = tx;
          t[1] = ty;
        }

      if (use_color)
        {
          /* NB: [X,Y,Z,TX,TY...,R,G,B,A,...] */
          c = (guint8 *) (v + 3 + 2 * n_layers);
          c[0] = cogl_color_get_red_byte (&vertices[i].color);
          c[1] = cogl_color_get_green_byte (&vertices[i].color);
          c[2] = cogl_color_get_blue_byte (&vertices[i].color);
          c[3] = cogl_color_get_alpha_byte (&vertices[i].color);
        }
    }

  options.flags = COGL_MATERIAL_FLUSH_FALLBACK_MASK;
  if (use_color)
    options.flags |= COGL_MATERIAL_FLUSH_SKIP_GL_COLOR;
  options.fallback_layers = fallback_layers;
  _cogl_material_flush_gl_state (ctx->source_material, &options);
  _cogl_flush_matrix_stacks ();

  GE (glDrawArrays (GL_TRIANGLE_FAN, 0, n_vertices));
}

void
cogl_polygon (CoglTextureVertex *vertices,
              guint              n_vertices,
	      gboolean           use_color)
{
  CoglHandle           material;
  const GList         *layers;
  int                  n_layers;
  GList               *tmp;
  gboolean	       use_sliced_polygon_fallback = FALSE;
  guint32              fallback_layers = 0;
  int                  i;
  gulong               enable_flags;
  guint                stride;
  gsize                stride_bytes;
  GLfloat             *v;
  int                  prev_n_texcoord_arrays_enabled;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  _cogl_journal_flush ();
  cogl_clip_ensure ();

  material = ctx->source_material;
  layers = cogl_material_get_layers (ctx->source_material);
  n_layers = g_list_length ((GList *)layers);

  for (tmp = (GList *)layers, i = 0; tmp != NULL; tmp = tmp->next, i++)
    {
      CoglHandle   layer = (CoglHandle)tmp->data;
      CoglHandle   tex_handle = cogl_material_layer_get_texture (layer);

      /* COGL_INVALID_HANDLE textures will be handled in
       * _cogl_material_flush_layers_gl_state */
      if (tex_handle == COGL_INVALID_HANDLE)
        continue;

      if (i == 0 && cogl_texture_is_sliced (tex_handle))
        {
#if defined (HAVE_COGL_GLES) || defined (HAVE_COGL_GLES2)
          {
            static gboolean warning_seen = FALSE;
            if (!warning_seen)
              g_warning ("cogl_polygon does not work for sliced textures "
                         "on GL ES");
            warning_seen = TRUE;
            return;
          }
#endif
          if (n_layers > 1)
            {
              static gboolean warning_seen = FALSE;
              if (!warning_seen)
                {
                  g_warning ("Disabling layers 1..n since multi-texturing with "
                             "cogl_polygon isn't supported when using sliced "
                             "textures\n");
                  warning_seen = TRUE;
                }
            }
          use_sliced_polygon_fallback = TRUE;
          n_layers = 1;

          if (cogl_material_layer_get_min_filter (layer) != GL_NEAREST
              || cogl_material_layer_get_mag_filter (layer) != GL_NEAREST)
            {
              static gboolean warning_seen = FALSE;
              if (!warning_seen)
                {
                  g_warning ("cogl_texture_polygon does not work for sliced textures "
                             "when the minification and magnification filters are not "
                             "CGL_NEAREST");
                  warning_seen = TRUE;
                }
              return;
            }

#ifdef HAVE_COGL_GL
          {
            CoglTexture *tex = _cogl_texture_pointer_from_handle (tex_handle);
            /* Temporarily change the wrapping mode on all of the slices to use
             * a transparent border
             * XXX: it's doesn't look like we save/restore this, like
             * the comment implies? */
            _cogl_texture_set_wrap_mode_parameter (tex, GL_CLAMP_TO_BORDER);
          }
#endif
          break;
        }

      if (cogl_texture_is_sliced (tex_handle))
        {
          static gboolean warning_seen = FALSE;
          if (!warning_seen)
            g_warning ("Disabling layer %d of the current source material, "
                       "because texturing with the vertex buffer API is not "
                       "currently supported using sliced textures, or "
                       "textures with waste\n", i);
          warning_seen = TRUE;

          fallback_layers |= (1 << i);
          continue;
        }
    }

  /* Our data is arranged like:
   * [X, Y, Z, TX0, TY0, TX1, TY1..., R, G, B, A,...] */
  stride = 3 + (2 * n_layers) + (use_color ? 1 : 0);
  stride_bytes = stride * sizeof (GLfloat);

  /* Make sure there is enough space in the global vertex
     array. This is used so we can render the polygon with a single
     call to OpenGL but still support any number of vertices */
  g_array_set_size (ctx->logged_vertices, n_vertices * stride);
  v = (GLfloat *)ctx->logged_vertices->data;

  /* Prepare GL state */
  enable_flags = COGL_ENABLE_VERTEX_ARRAY;
  enable_flags |= _cogl_material_get_cogl_enable_flags (ctx->source_material);

  if (ctx->enable_backface_culling)
    enable_flags |= COGL_ENABLE_BACKFACE_CULLING;

  if (use_color)
    {
      enable_flags |= COGL_ENABLE_COLOR_ARRAY;
      GE( glColorPointer (4, GL_UNSIGNED_BYTE,
                          stride_bytes,
                          /* NB: [X,Y,Z,TX,TY...,R,G,B,A,...] */
                          v + 3 + 2 * n_layers) );
    }

  cogl_enable (enable_flags);

  GE (glVertexPointer (3, GL_FLOAT, stride_bytes, v));

  for (i = 0; i < n_layers; i++)
    {
      GE (glClientActiveTexture (GL_TEXTURE0 + i));
      GE (glEnableClientState (GL_TEXTURE_COORD_ARRAY));
      GE (glTexCoordPointer (2, GL_FLOAT,
                             stride_bytes,
                             /* NB: [X,Y,Z,TX,TY...,R,G,B,A,...] */
                             v + 3 + 2 * i));
    }
  prev_n_texcoord_arrays_enabled =
    ctx->n_texcoord_arrays_enabled;
  ctx->n_texcoord_arrays_enabled = n_layers;
  for (; i < prev_n_texcoord_arrays_enabled; i++)
    {
      GE (glClientActiveTexture (GL_TEXTURE0 + i));
      GE (glDisableClientState (GL_TEXTURE_COORD_ARRAY));
    }

  if (use_sliced_polygon_fallback)
    _cogl_texture_sliced_polygon (vertices,
                                  n_vertices,
                                  stride,
                                  use_color);
  else
    _cogl_multitexture_unsliced_polygon (vertices,
                                         n_vertices,
                                         n_layers,
                                         stride,
                                         use_color,
                                         fallback_layers);

  /* Reset the size of the logged vertex array because rendering
     rectangles expects it to start at 0 */
  g_array_set_size (ctx->logged_vertices, 0);
}

void
cogl_path_fill (void)
{
  cogl_path_fill_preserve ();

  cogl_path_new ();
}

void
cogl_path_fill_preserve (void)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  _cogl_journal_flush ();
  cogl_clip_ensure ();

  if (ctx->path_nodes->len == 0)
    return;

  _cogl_path_fill_nodes ();
}

void
cogl_path_stroke (void)
{
  cogl_path_stroke_preserve ();

  cogl_path_new ();
}

void
cogl_path_stroke_preserve (void)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  if (ctx->path_nodes->len == 0)
    return;

  _cogl_journal_flush ();
  cogl_clip_ensure ();

  _cogl_path_stroke_nodes();
}

void
cogl_path_move_to (float x,
                   float y)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  /* FIXME: handle multiple contours maybe? */

  _cogl_path_add_node (TRUE, x, y);

  ctx->path_start.x = x;
  ctx->path_start.y = y;

  ctx->path_pen = ctx->path_start;
}

void
cogl_path_rel_move_to (float x,
                       float y)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_path_move_to (ctx->path_pen.x + x,
                     ctx->path_pen.y + y);
}

void
cogl_path_line_to (float x,
                   float y)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  _cogl_path_add_node (FALSE, x, y);

  ctx->path_pen.x = x;
  ctx->path_pen.y = y;
}

void
cogl_path_rel_line_to (float x,
                       float y)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_path_line_to (ctx->path_pen.x + x,
                     ctx->path_pen.y + y);
}

void
cogl_path_close (void)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  _cogl_path_add_node (FALSE, ctx->path_start.x, ctx->path_start.y);
  ctx->path_pen = ctx->path_start;
}

void
cogl_path_new (void)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  g_array_set_size (ctx->path_nodes, 0);
}

void
cogl_path_line (float x_1,
	        float y_1,
	        float x_2,
	        float y_2)
{
  cogl_path_move_to (x_1, y_1);
  cogl_path_line_to (x_2, y_2);
}

void
cogl_path_polyline (float *coords,
	            gint num_points)
{
  gint c = 0;

  cogl_path_move_to (coords[0], coords[1]);

  for (c = 1; c < num_points; ++c)
    cogl_path_line_to (coords[2*c], coords[2*c+1]);
}

void
cogl_path_polygon (float *coords,
	           gint          num_points)
{
  cogl_path_polyline (coords, num_points);
  cogl_path_close ();
}

void
cogl_path_rectangle (float x_1,
                     float y_1,
                     float x_2,
                     float y_2)
{
  cogl_path_move_to (x_1, y_1);
  cogl_path_line_to (x_2, y_1);
  cogl_path_line_to (x_2, y_2);
  cogl_path_line_to (x_1, y_2);
  cogl_path_close   ();
}

static void
_cogl_path_arc (float center_x,
	        float center_y,
                float radius_x,
                float radius_y,
                float angle_1,
                float angle_2,
                float angle_step,
                guint        move_first)
{
  float a     = 0x0;
  float cosa  = 0x0;
  float sina  = 0x0;
  float px    = 0x0;
  float py    = 0x0;

  /* Fix invalid angles */

  if (angle_1 == angle_2 || angle_step == 0x0)
    return;

  if (angle_step < 0x0)
    angle_step = -angle_step;

  /* Walk the arc by given step */

  a = angle_1;
  while (a != angle_2)
    {
      cosa = cosf (a * (G_PI/180.0));
      sina = sinf (a * (G_PI/180.0));

      px = center_x + (cosa * radius_x);
      py = center_y + (sina * radius_y);

      if (a == angle_1 && move_first)
	cogl_path_move_to (px, py);
      else
	cogl_path_line_to (px, py);

      if (G_LIKELY (angle_2 > angle_1))
        {
          a += angle_step;
          if (a > angle_2)
            a = angle_2;
        }
      else
        {
          a -= angle_step;
          if (a < angle_2)
            a = angle_2;
        }
    }

  /* Make sure the final point is drawn */

  cosa = cosf (angle_2 * (G_PI/180.0));
  sina = sinf (angle_2 * (G_PI/180.0));

  px = center_x + (cosa * radius_x);
  py = center_y + (sina * radius_y);

  cogl_path_line_to (px, py);
}

void
cogl_path_arc (float center_x,
               float center_y,
               float radius_x,
               float radius_y,
               float angle_1,
               float angle_2)
{
  float angle_step = 10;
  /* it is documented that a move to is needed to create a freestanding
   * arc
   */
  _cogl_path_arc (center_x,   center_y,
	          radius_x,   radius_y,
	          angle_1,    angle_2,
	          angle_step, 0 /* no move */);
}


void
cogl_path_arc_rel (float center_x,
		   float center_y,
		   float radius_x,
		   float radius_y,
		   float angle_1,
		   float angle_2,
		   float angle_step)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  _cogl_path_arc (ctx->path_pen.x + center_x,
	          ctx->path_pen.y + center_y,
	          radius_x,   radius_y,
	          angle_1,    angle_2,
	          angle_step, 0 /* no move */);
}

void
cogl_path_ellipse (float center_x,
                   float center_y,
                   float radius_x,
                   float radius_y)
{
  float angle_step = 10;

  /* FIXME: if shows to be slow might be optimized
   * by mirroring just a quarter of it */

  _cogl_path_arc (center_x, center_y,
	          radius_x, radius_y,
	          0, 360,
	          angle_step, 1 /* move first */);

  cogl_path_close();
}

void
cogl_path_round_rectangle (float x_1,
                           float y_1,
                           float x_2,
                           float y_2,
                           float radius,
                           float arc_step)
{
  float inner_width = x_2 - x_1 - radius * 2;
  float inner_height = y_2 - y_1 - radius * 2;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_path_move_to (x_1, y_1 + radius);
  cogl_path_arc_rel (radius, 0,
		     radius, radius,
		     180,
		     270,
		     arc_step);

  cogl_path_line_to       (ctx->path_pen.x + inner_width,
                           ctx->path_pen.y);
  cogl_path_arc_rel       (0, radius,
			   radius, radius,
			   -90,
			   0,
			   arc_step);

  cogl_path_line_to       (ctx->path_pen.x,
                           ctx->path_pen.y + inner_height);

  cogl_path_arc_rel       (-radius, 0,
			   radius, radius,
			   0,
			   90,
			   arc_step);

  cogl_path_line_to       (ctx->path_pen.x - inner_width,
                           ctx->path_pen.y);
  cogl_path_arc_rel       (0, -radius,
			   radius, radius,
			   90,
			   180,
			   arc_step);

  cogl_path_close ();
}


static void
_cogl_path_bezier3_sub (CoglBezCubic *cubic)
{
  CoglBezCubic   cubics[_COGL_MAX_BEZ_RECURSE_DEPTH];
  CoglBezCubic  *cleft;
  CoglBezCubic  *cright;
  CoglBezCubic  *c;
  floatVec2  dif1;
  floatVec2  dif2;
  floatVec2  mm;
  floatVec2  c1;
  floatVec2  c2;
  floatVec2  c3;
  floatVec2  c4;
  floatVec2  c5;
  gint           cindex;

  /* Put first curve on stack */
  cubics[0] = *cubic;
  cindex    =  0;

  while (cindex >= 0)
    {
      c = &cubics[cindex];


      /* Calculate distance of control points from their
       * counterparts on the line between end points */
      dif1.x = (c->p2.x * 3) - (c->p1.x * 2) - c->p4.x;
      dif1.y = (c->p2.y * 3) - (c->p1.y * 2) - c->p4.y;
      dif2.x = (c->p3.x * 3) - (c->p4.x * 2) - c->p1.x;
      dif2.y = (c->p3.y * 3) - (c->p4.y * 2) - c->p1.y;

      if (dif1.x < 0)
        dif1.x = -dif1.x;
      if (dif1.y < 0)
        dif1.y = -dif1.y;
      if (dif2.x < 0)
        dif2.x = -dif2.x;
      if (dif2.y < 0)
        dif2.y = -dif2.y;


      /* Pick the greatest of two distances */
      if (dif1.x < dif2.x) dif1.x = dif2.x;
      if (dif1.y < dif2.y) dif1.y = dif2.y;

      /* Cancel if the curve is flat enough */
      if (dif1.x + dif1.y <= 1.0 ||
	  cindex == _COGL_MAX_BEZ_RECURSE_DEPTH-1)
	{
	  /* Add subdivision point (skip last) */
	  if (cindex == 0)
            return;

	  _cogl_path_add_node (FALSE, c->p4.x, c->p4.y);

	  --cindex;

          continue;
	}

      /* Left recursion goes on top of stack! */
      cright = c; cleft = &cubics[++cindex];

      /* Subdivide into 2 sub-curves */
      c1.x = ((c->p1.x + c->p2.x) / 2);
      c1.y = ((c->p1.y + c->p2.y) / 2);
      mm.x = ((c->p2.x + c->p3.x) / 2);
      mm.y = ((c->p2.y + c->p3.y) / 2);
      c5.x = ((c->p3.x + c->p4.x) / 2);
      c5.y = ((c->p3.y + c->p4.y) / 2);

      c2.x = ((c1.x + mm.x) / 2);
      c2.y = ((c1.y + mm.y) / 2);
      c4.x = ((mm.x + c5.x) / 2);
      c4.y = ((mm.y + c5.y) / 2);

      c3.x = ((c2.x + c4.x) / 2);
      c3.y = ((c2.y + c4.y) / 2);

      /* Add left recursion to stack */
      cleft->p1 = c->p1;
      cleft->p2 = c1;
      cleft->p3 = c2;
      cleft->p4 = c3;

      /* Add right recursion to stack */
      cright->p1 = c3;
      cright->p2 = c4;
      cright->p3 = c5;
      cright->p4 = c->p4;
    }
}

void
cogl_path_curve_to (float x_1,
                    float y_1,
                    float x_2,
                    float y_2,
                    float x_3,
                    float y_3)
{
  CoglBezCubic cubic;

  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  /* Prepare cubic curve */
  cubic.p1 = ctx->path_pen;
  cubic.p2.x = x_1;
  cubic.p2.y = y_1;
  cubic.p3.x = x_2;
  cubic.p3.y = y_2;
  cubic.p4.x = x_3;
  cubic.p4.y = y_3;

  /* Run subdivision */
  _cogl_path_bezier3_sub (&cubic);

  /* Add last point */
  _cogl_path_add_node (FALSE, cubic.p4.x, cubic.p4.y);
  ctx->path_pen = cubic.p4;
}

void
cogl_path_rel_curve_to (float x_1,
                        float y_1,
                        float x_2,
                        float y_2,
                        float x_3,
                        float y_3)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_path_curve_to (ctx->path_pen.x + x_1,
                      ctx->path_pen.y + y_1,
                      ctx->path_pen.x + x_2,
                      ctx->path_pen.y + y_2,
                      ctx->path_pen.x + x_3,
                      ctx->path_pen.y + y_3);
}


/* If second order beziers were needed the following code could
 * be re-enabled:
 */
#if 0

static void
_cogl_path_bezier2_sub (CoglBezQuad *quad)
{
  CoglBezQuad     quads[_COGL_MAX_BEZ_RECURSE_DEPTH];
  CoglBezQuad    *qleft;
  CoglBezQuad    *qright;
  CoglBezQuad    *q;
  floatVec2   mid;
  floatVec2   dif;
  floatVec2   c1;
  floatVec2   c2;
  floatVec2   c3;
  gint            qindex;

  /* Put first curve on stack */
  quads[0] = *quad;
  qindex   =  0;

  /* While stack is not empty */
  while (qindex >= 0)
    {

      q = &quads[qindex];

      /* Calculate distance of control point from its
       * counterpart on the line between end points */
      mid.x = ((q->p1.x + q->p3.x) / 2);
      mid.y = ((q->p1.y + q->p3.y) / 2);
      dif.x = (q->p2.x - mid.x);
      dif.y = (q->p2.y - mid.y);
      if (dif.x < 0) dif.x = -dif.x;
      if (dif.y < 0) dif.y = -dif.y;

      /* Cancel if the curve is flat enough */
      if (dif.x + dif.y <= 1.0 ||
          qindex == _COGL_MAX_BEZ_RECURSE_DEPTH - 1)
	{
	  /* Add subdivision point (skip last) */
	  if (qindex == 0) return;
	  _cogl_path_add_node (FALSE, q->p3.x, q->p3.y);
	  --qindex; continue;
	}

      /* Left recursion goes on top of stack! */
      qright = q; qleft = &quads[++qindex];

      /* Subdivide into 2 sub-curves */
      c1.x = ((q->p1.x + q->p2.x) / 2);
      c1.y = ((q->p1.y + q->p2.y) / 2);
      c3.x = ((q->p2.x + q->p3.x) / 2);
      c3.y = ((q->p2.y + q->p3.y) / 2);
      c2.x = ((c1.x + c3.x) / 2);
      c2.y = ((c1.y + c3.y) / 2);

      /* Add left recursion onto stack */
      qleft->p1 = q->p1;
      qleft->p2 = c1;
      qleft->p3 = c2;

      /* Add right recursion onto stack */
      qright->p1 = c2;
      qright->p2 = c3;
      qright->p3 = q->p3;
    }
}

void
cogl_path_curve2_to (float x_1,
                     float y_1,
                     float x_2,
                     float y_2)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  CoglBezQuad quad;

  /* Prepare quadratic curve */
  quad.p1 = ctx->path_pen;
  quad.p2.x = x_1;
  quad.p2.y = y_1;
  quad.p3.x = x_2;
  quad.p3.y = y_2;

  /* Run subdivision */
  _cogl_path_bezier2_sub (&quad);

  /* Add last point */
  _cogl_path_add_node (FALSE, quad.p3.x, quad.p3.y);
  ctx->path_pen = quad.p3;
}

void
cogl_rel_curve2_to (float x_1,
                    float y_1,
                    float x_2,
                    float y_2)
{
  _COGL_GET_CONTEXT (ctx, NO_RETVAL);

  cogl_path_curve2_to (ctx->path_pen.x + x_1,
                       ctx->path_pen.y + y_1,
                       ctx->path_pen.x + x_2,
                       ctx->path_pen.y + y_2);
}
#endif