Merge "Make MeasureCallback signature .NET friendly" into devel/master

[platform/core/uifw/dali-toolkit.git] / dali-toolkit / internal / visuals / visual-factory-cache.cpp

 /*
 * Copyright (c) 2020 Samsung Electronics Co., Ltd.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

// CLASS HEADER
#include "visual-factory-cache.h"

// EXTERNAL INCLUDES
#include <dali/devel-api/common/hash.h>
#include <dali/devel-api/adaptor-framework/image-loading.h>

// INTERNAL INCLUDES
#include <dali-toolkit/internal/visuals/color/color-visual.h>
#include <dali-toolkit/internal/visuals/svg/svg-visual.h>
#include <dali-toolkit/internal/visuals/image-atlas-manager.h>
#include <dali-toolkit/internal/visuals/animated-vector-image/vector-animation-manager.h>

namespace Dali
{

namespace Toolkit
{

namespace Internal
{

VisualFactoryCache::VisualFactoryCache( bool preMultiplyOnLoad )
: mSvgRasterizeThread( NULL ),
  mVectorAnimationManager(),
  mBrokenImageUrl(""),
  mPreMultiplyOnLoad( preMultiplyOnLoad )
{
}

VisualFactoryCache::~VisualFactoryCache()
{
  SvgRasterizeThread::TerminateThread( mSvgRasterizeThread );
}

Geometry VisualFactoryCache::GetGeometry( GeometryType type )
{
  if( !mGeometry[type] && type == QUAD_GEOMETRY )
  {
    mGeometry[type] = CreateQuadGeometry();
  }

  return mGeometry[type];
}

void VisualFactoryCache::SaveGeometry( GeometryType type, Geometry geometry )
{
  mGeometry[type] = geometry;
}

Shader VisualFactoryCache::GetShader( ShaderType type )
{
  return mShader[type];
}

void VisualFactoryCache::SaveShader( ShaderType type, Shader shader )
{
  mShader[type] = shader;
}

Geometry VisualFactoryCache::CreateQuadGeometry()
{
  const float halfWidth = 0.5f;
  const float halfHeight = 0.5f;
  struct QuadVertex { Vector2 position;};
  QuadVertex quadVertexData[4] =
  {
      { Vector2(-halfWidth, -halfHeight) },
      { Vector2(-halfWidth, halfHeight)  },
      { Vector2( halfWidth, -halfHeight) },
      { Vector2( halfWidth, halfHeight)  }
  };

  Property::Map quadVertexFormat;
  quadVertexFormat["aPosition"] = Property::VECTOR2;
  VertexBuffer quadVertices = VertexBuffer::New( quadVertexFormat );
  quadVertices.SetData( quadVertexData, 4 );

  // Create the geometry object
  Geometry geometry = Geometry::New();
  geometry.AddVertexBuffer( quadVertices );
  geometry.SetType( Geometry::TRIANGLE_STRIP );

  return geometry;
}

ImageAtlasManagerPtr VisualFactoryCache::GetAtlasManager()
{
  if( !mAtlasManager )
  {
    mAtlasManager = new ImageAtlasManager();
    mAtlasManager->SetBrokenImage( mBrokenImageUrl );
  }

  return mAtlasManager;
}

TextureManager& VisualFactoryCache::GetTextureManager()
{
  return mTextureManager;
}

NPatchLoader& VisualFactoryCache::GetNPatchLoader()
{
  return mNPatchLoader;
}

SvgRasterizeThread* VisualFactoryCache::GetSVGRasterizationThread()
{
  if( !mSvgRasterizeThread )
  {
    mSvgRasterizeThread = new SvgRasterizeThread( new EventThreadCallback( MakeCallback( this, &VisualFactoryCache::ApplyRasterizedSVGToSampler ) ) );
    mSvgRasterizeThread->Start();
  }
  return mSvgRasterizeThread;
}

VectorAnimationManager& VisualFactoryCache::GetVectorAnimationManager()
{
  if( !mVectorAnimationManager )
  {
    mVectorAnimationManager = std::unique_ptr< VectorAnimationManager >( new VectorAnimationManager() );
  }
  return *mVectorAnimationManager;
}

void VisualFactoryCache::ApplyRasterizedSVGToSampler()
{
  while( RasterizingTaskPtr task = mSvgRasterizeThread->NextCompletedTask() )
  {
#ifdef NO_THORVG
    task->GetSvgVisual()->ApplyRasterizedImage( task->GetParsedImage(), task->GetPixelData() );
#else /* NO_THORVG */
    task->GetSvgVisual()->ApplyRasterizedImage( task->GetVectorRenderer(), task->GetPixelData(), task->IsLoaded() );
#endif /* NO_THORVG */
  }
}

Geometry VisualFactoryCache::CreateGridGeometry( Uint16Pair gridSize )
{
  uint16_t gridWidth = gridSize.GetWidth();
  uint16_t gridHeight = gridSize.GetHeight();

  // Create vertices
  Vector< Vector2 > vertices;
  vertices.Reserve( ( gridWidth + 1 ) * ( gridHeight + 1 ) );

  for( int y = 0; y < gridHeight + 1; ++y )
  {
    for( int x = 0; x < gridWidth + 1; ++x )
    {
      vertices.PushBack( Vector2( (float)x/gridWidth - 0.5f, (float)y/gridHeight  - 0.5f) );
    }
  }

  // Create indices
  Vector< unsigned short > indices;
  indices.Reserve( (gridWidth+2)*gridHeight*2 - 2);

  for( unsigned int row = 0u; row < gridHeight; ++row )
  {
    unsigned int rowStartIndex = row*(gridWidth+1u);
    unsigned int nextRowStartIndex = rowStartIndex + gridWidth +1u;

    if( row != 0u ) // degenerate index on non-first row
    {
      indices.PushBack( rowStartIndex );
    }

    for( unsigned int column = 0u; column < gridWidth+1u; column++) // main strip
    {
      indices.PushBack( rowStartIndex + column);
      indices.PushBack( nextRowStartIndex + column);
    }

    if( row != gridHeight-1u ) // degenerate index on non-last row
    {
      indices.PushBack( nextRowStartIndex + gridWidth );
    }
  }

  Property::Map vertexFormat;
  vertexFormat[ "aPosition" ] = Property::VECTOR2;
  VertexBuffer vertexBuffer = VertexBuffer::New( vertexFormat );
  if( vertices.Size() > 0 )
  {
    vertexBuffer.SetData( &vertices[ 0 ], vertices.Size() );
  }

  Property::Map indexFormat;
  indexFormat[ "indices" ] = Property::INTEGER;
  VertexBuffer indexVertexBuffer = VertexBuffer::New( indexFormat );


  // Create the geometry object
  Geometry geometry = Geometry::New();
  geometry.AddVertexBuffer( vertexBuffer );
  if( indices.Size() > 0 )
  {
    geometry.SetIndexBuffer( &indices[ 0 ], indices.Size() );
  }

  geometry.SetType( Geometry::TRIANGLE_STRIP );

  return geometry;
}

Texture VisualFactoryCache::GetBrokenVisualImage()
{
  if(!mBrokenImageTexture && mBrokenImageUrl.size())
  {
    PixelData data;
    Devel::PixelBuffer pixelBuffer = LoadImageFromFile( mBrokenImageUrl );
    if( pixelBuffer )
    {
      data = Devel::PixelBuffer::Convert(pixelBuffer); // takes ownership of buffer
      mBrokenImageTexture = Texture::New( Dali::TextureType::TEXTURE_2D, data.GetPixelFormat(),
                                      data.GetWidth(), data.GetHeight() );
      mBrokenImageTexture.Upload( data );
    }
  }
  return mBrokenImageTexture;
}

void VisualFactoryCache::SetPreMultiplyOnLoad( bool preMultiply )
{
  mPreMultiplyOnLoad = preMultiply;
}

bool VisualFactoryCache::GetPreMultiplyOnLoad()
{
  return mPreMultiplyOnLoad;
}

void VisualFactoryCache::SetBrokenImageUrl(const std::string& brokenImageUrl)
{
  mBrokenImageUrl = brokenImageUrl;

  if( !mAtlasManager )
  {
    mAtlasManager = new ImageAtlasManager();
  }

  mAtlasManager->SetBrokenImage( mBrokenImageUrl );
  mTextureManager.SetBrokenImageUrl( mBrokenImageUrl );
}

} // namespace Internal

} // namespace Toolkit

} // namespace Dali