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SpriteSheet
This is an example of a C++ port of the C# MonoGame sprite loader and renderer for using sprite sheets created by the CodeAndWeb tool TexturePacker using the built-in MonoGame project type. This makes use of SpriteBatch to render.
You can change this code to work with other sprite sheet creation tools by modifying the metadata reading code in Load.
class SpriteSheet
{
public:
struct SpriteFrame
{
RECT sourceRect;
DirectX::XMFLOAT2 size;
DirectX::XMFLOAT2 origin;
bool rotated;
};
void Load( ID3D11ShaderResourceView* texture, const wchar_t* szFileName )
{
mSprites.clear();
mTexture = texture;
if (szFileName)
{
//
// This code parses the 'MonoGame' project txt file that is produced
// by CodeAndWeb's TexturePacker.
// https://www.codeandweb.com/texturepacker
//
// You can modify it to match whatever sprite-sheet tool you are
// using
//
std::wifstream inFile( szFileName );
if( !inFile )
throw std::exception( "SpriteSheet failed to load .txt data" );
wchar_t strLine[1024];
for(;;)
{
inFile >> strLine;
if( !inFile )
break;
if( 0 == wcscmp( strLine, L"#" ) )
{
// Comment
}
else
{
static const wchar_t* delim = L";\n";
wchar_t* context = nullptr;
wchar_t* name = wcstok_s(strLine, delim, &context);
if ( !name || !*name )
throw std::exception();
if ( mSprites.find( name ) != mSprites.cend() )
throw std::exception();
wchar_t* str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
SpriteFrame frame;
frame.rotated = (_wtoi(str) == 1);
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
frame.sourceRect.left = _wtol(str);
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
frame.sourceRect.top = _wtol(str);
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
LONG dx = _wtol(str);
frame.sourceRect.right = frame.sourceRect.left + dx;
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
LONG dy = + _wtol(str);
frame.sourceRect.bottom = frame.sourceRect.top + dy;
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
frame.size.x = static_cast<float>( _wtof(str) );
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
frame.size.y = static_cast<float>( _wtof(str) );
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
float pivotX = static_cast<float>( _wtof(str) );
str = wcstok_s(nullptr, delim, &context);
if ( !str )
throw std::exception();
float pivotY = static_cast<float>( _wtof(str) );
if (frame.rotated)
{
frame.origin.x = dx * (1.f - pivotY);
frame.origin.y = dy * pivotX;
}
else
{
frame.origin.x = dx * pivotX;
frame.origin.y = dy * pivotY;
}
mSprites.insert( std::pair<std::wstring,SpriteFrame>(
std::wstring(name), frame) );
}
inFile.ignore( 1000, '\n' );
}
}
}
const SpriteFrame* Find(const wchar_t* name) const
{
auto it = mSprites.find(name);
if (it == mSprites.cend())
return nullptr;
return &it->second;
}
void XM_CALLCONV Draw(DirectX::SpriteBatch* batch, const SpriteFrame& frame,
DirectX::XMFLOAT2 const& position,
DirectX::FXMVECTOR color = DirectX::Colors::White, float rotation = 0,
float scale = 1,
DirectX::SpriteEffects effects = DirectX::SpriteEffects_None,
float layerDepth = 0) const
{
assert(batch != 0);
using namespace DirectX;
if (frame.rotated)
{
rotation -= XM_PIDIV2;
switch(effects)
{
case SpriteEffects_FlipHorizontally:
effects = SpriteEffects_FlipVertically;
break;
case SpriteEffects_FlipVertically:
effects = SpriteEffects_FlipHorizontally;
break;
}
}
XMFLOAT2 origin = frame.origin;
switch (effects)
{
case SpriteEffects_FlipHorizontally:
origin.x = frame.sourceRect.right
- frame.sourceRect.left - origin.x;
break;
case SpriteEffects_FlipVertically:
origin.y = frame.sourceRect.bottom
- frame.sourceRect.top - origin.y;
break;
}
batch->Draw(mTexture.Get(), position, &frame.sourceRect,
color, rotation,
origin, scale, effects, layerDepth );
}
void XM_CALLCONV Draw(DirectX::SpriteBatch* batch, const SpriteFrame& frame,
DirectX::XMFLOAT2 const& position,
DirectX::FXMVECTOR color, float rotation, DirectX::XMFLOAT2 const& scale,
DirectX::SpriteEffects effects = DirectX::SpriteEffects_None,
float layerDepth = 0) const
{
...
}
// Draw overloads specifying position and scale via the first two components of
// an XMVECTOR.
void XM_CALLCONV Draw(DirectX::SpriteBatch* batch, const SpriteFrame& frame,
DirectX::FXMVECTOR position,
DirectX::FXMVECTOR color = DirectX::Colors::White, float rotation = 0,
float scale = 1,
DirectX::SpriteEffects effects = DirectX::SpriteEffects_None,
float layerDepth = 0) const
{
...
}
void XM_CALLCONV Draw(DirectX::SpriteBatch* batch, const SpriteFrame& frame,
DirectX::FXMVECTOR position,
DirectX::FXMVECTOR color, float rotation, DirectX::GXMVECTOR scale,
DirectX::SpriteEffects effects = DirectX::SpriteEffects_None,
float layerDepth = 0) const
{
...
}
// Draw overloads specifying position as a RECT.
void XM_CALLCONV Draw(DirectX::SpriteBatch* batch, const SpriteFrame& frame,
RECT const& destinationRectangle,
DirectX::FXMVECTOR color = DirectX::Colors::White, float rotation = 0,
DirectX::SpriteEffects effects = DirectX::SpriteEffects_None,
float layerDepth = 0) const
{
...
}
private:
Microsoft::WRL::ComPtr<ID3D11ShaderResourceView> mTexture;
std::map<std::wstring, SpriteFrame> mSprites;
};
This example uses a sprite sheet created from the content in the original C# XNA Game Studio SpriteSheetSample
sample.
The resulting sprite sheet is SpriteSheetSample.png
and the resulting metadata SpriteSheetSample.txt
#
# Sprite sheet data for MonoGame.
#
# To learn how to import these sprites into your MonoGame project visit:
# http://www.codeandweb.com/texturepacker/monogame
#
# Sprite sheet: SpriteSheetSample.png (204 x 200)
# $TexturePacker:SmartUpdate:0368b25d54aeeee939136b8605cf8eb5:68e5ed36fde793856b1138fb021ac1d9:f18d998871cf5eafdd9feca9b014994a$
#
cat;0;2;2;66;100;100;100;0.5151515151515151;0.5
glow1;0;2;104;64;64;64;64;0.5;0.5
glow2;0;70;2;64;64;64;64;0.5;0.5
glow3;0;136;2;64;64;64;64;0.5;0.5
glow4;0;70;68;64;64;64;64;0.5;0.5
glow5;0;68;134;64;64;64;64;0.5;0.5
glow6;0;134;134;64;64;64;64;0.5;0.5
glow7;0;136;68;64;64;64;64;0.5;0.5
And here is some example code to render using this sprite sheet:
#include "SpriteBatch.h"
#include "SpriteSheet.h"
#include "WICTextureLoader.h"
Microsoft::WRL::ComPtr<ID3D11ShaderResourceView> texture;
std::unique_ptr<DirectX::SpriteBatch> spriteBatch;
std::unique_ptr<SpriteSheet> sprites;
// Create a texture using our sprite sheet
hr = CreateWICTextureFromFile( device, L"SpriteSheetSample.png",
nullptr, texture.GetAddressOf() );
DX::ThrowIfFailed(hr);
...
// Create a SpriteBatch for rendering
spriteBatch = std::make_unique<SpriteBatch>( context );
// Create an SpriteSheet helper class instance
sprites = std::make_unique<SpriteSheet>();
sprites->Load( texture.Get(), L"SpriteSheetSample.txt" );
...
// Render a sprite from the sheet
spriteBatch->Begin();
auto frame = sprites->Find( L"cat" );
assert( frame != 0 );
sprites->Draw( spriteBatch.get(), *frame, screenPos );
// TODO - More sprites or text here
spriteBatch->End();
If you are making use of CodeAndWeb's TexturePacker tool, you will be writing out the sprite sheet texture as a PNG which you will be using at runtime along with the 'data file' .txt that is defined as part of the "MonoGame" project. Note that you will not be making use of the '.cs' file TexturePacker generates as part of the "MonoGame" project type.
If you are using premultiplied alpha for your blending (the default for SpriteBatch), you should under Texture \ show advanced set the Premultiply alpha check box option.
The default Pixel format of RGBA8888 is suitable for all feature levels, and will be loaded at runtime as DXGI_FORMAT_B8G8R8A8_UNORM
. Due to limitations of the built-in Windows PNG codec, using other pixel formats does not reduce video memory usage; only disk space usage. For more flexible control over pixel format at runtime, you should convert to a .DDS
instead (see below).
The default Max size of 2048 x 2048 under Layout is suitable for all feature levels. If your minimum supported feature level is not 9.1 or 9.2, you can set it higher to make use of larger supported texture sizes for more efficient packing.
- Feature Level 9.1, 9.2 -> 2048 x 2048
- Feature Level 9.3 -> 4096 x 4096
- Feature Level 10.0 or 10.1 -> 8192 x 8192
- Feature Level 11.0 or 11.1 -> 16384 x 16384
You can optionally convert the PNG
to a DDS
using DirectXTex's texconv tool or the Visual Studio texture content processor, ideally using BC2 or BC3 for runtime compression. This will result in a larger DDS
file on disk than a PNG
, but will use less video memory when loaded. You would use DDSTextureLoader instead of WICTextureLoader in this case.
If using DDS
rather than PNG
and premultiplied alpha for your blending, you should leave the TexturePacker Premultiply alpha option unchecked and add the -pmalpha option to DirectXTex's texconv to get the premultipled alpha conversion as part of creating the DDS
.
In most cases you won't need mipmap levels generated so specify -m 1 when converting the DDS
. If you do want mipmaps levels and want to support all feature levels (i.e. Feature Levesl 9.x), then in your TexturePacker project under Layout / Size constraints set it to "POW (Power of 2)" and do not use -m 1.
Open a Command Prompt, and change to the directory containing Texconv.exe
Enter the following command-line after changing to the appropriate directory:
texconv.exe SpriteSheetSample.png -f BC3_UNORM -m 1 -pmalpha
The more sprites that can be packed into a single texture, the more efficient the draw operations can be. SpriteBatch
only needs to flush when the source texture is changed, so as long as you draw from the same sprite sheet the performance is very good.
You can extend this further on Direct3D hardware feature level 10.0 or better by packing multiple sprite sheets into a single 2D texture array, but this would require modifying SpriteBatch
and the SpriteBatch.fx
shaders to use a per-vertex texture array index.
All content and source code for this package are subject to the terms of the MIT License.
This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact [email protected] with any additional questions or comments.
- Universal Windows Platform apps
- Windows desktop apps
- Windows 11
- Windows 10
- Windows 8.1
- Xbox One
- x86
- x64
- ARM64
- Visual Studio 2022
- Visual Studio 2019 (16.11)
- clang/LLVM v12 - v18
- MinGW 12.2, 13.2
- CMake 3.20