I am trying to teach myself C# and have heard from a variety of sources that the functions get and setpixel can be horribly slow. What are some of the alternatives and is the performance improvement really that significant?

A chunk of my code for reference:

public static Bitmap Paint(Bitmap _b, Color f)
  Bitmap b = new Bitmap(_b);
  for (int x = 0; x < b.Width; x++) 
    for (int y = 0; y < b.Height; y++) 
      Color c = b.GetPixel(x, y);
      b.SetPixel(x, y, Color.FromArgb(c.A, f.R, f.G, f.B));
  return b;
  • 1
    All of the answers here support a specific pixel format only. If both fast and simple solution is required you can use this library (disclaimer: written by me). Commented Apr 19, 2021 at 17:44

5 Answers 5


The immediately usable code

public class DirectBitmap : IDisposable
    public Bitmap Bitmap { get; private set; }
    public Int32[] Bits { get; private set; }
    public bool Disposed { get; private set; }
    public int Height { get; private set; }
    public int Width { get; private set; }

    protected GCHandle BitsHandle { get; private set; }

    public DirectBitmap(int width, int height)
        Width = width;
        Height = height;
        Bits = new Int32[width * height];
        BitsHandle = GCHandle.Alloc(Bits, GCHandleType.Pinned);
        Bitmap = new Bitmap(width, height, width * 4, PixelFormat.Format32bppPArgb, BitsHandle.AddrOfPinnedObject());

    public void SetPixel(int x, int y, Color colour)
        int index = x + (y * Width);
        int col = colour.ToArgb();

        Bits[index] = col;

    public Color GetPixel(int x, int y)
        int index = x + (y * Width);
        int col = Bits[index];
        Color result = Color.FromArgb(col);

        return result;

    public void Dispose()
        if (Disposed) return;
        Disposed = true;

There's no need for LockBits or SetPixel. Use the above class for direct access to bitmap data.

With this class, it is possible to set raw bitmap data as 32-bit data. Notice that it is PARGB, which is premultiplied alpha. See Alpha Compositing on Wikipedia for more information on how this works and examples on the MSDN article for BLENDFUNCTION to find out how to calculate the alpha properly.

If premultiplication might overcomplicate things, use PixelFormat.Format32bppArgb instead. A performance hit occurs when it's drawn, because it's internally being converted to PixelFormat.Format32bppPArgb. If the image doesn't have to change prior to being drawn, the work can be done before premultiplication, drawn to a PixelFormat.Format32bppArgb buffer, and further used from there.

Access to standard Bitmap members is exposed via the Bitmap property. Bitmap data is directly accessed using the Bits property.

Using byte instead of int for raw pixel data

Change both instances of Int32 to byte, and then change this line:

Bits = new Int32[width * height];

To this:

Bits = new byte[width * height * 4];

When bytes are used, the format is Alpha/Red/Green/Blue in that order. Each pixel takes 4 bytes of data, one for each channel. The GetPixel and SetPixel functions will need to be reworked accordingly or removed.

Benefits to using the above class

  • Memory allocation for merely manipulating the data is unnecessary; changes made to the raw data are immediately applied to the bitmap.
  • There are no additional objects to manage. This implements IDisposable just like Bitmap.
  • It does not require an unsafe block.


  • Pinned memory cannot be moved. It's a required side effect in order for this kind of memory access to work. This reduces the efficiency of the garbage collector (MSDN Article). Do it only with bitmaps where performance is required, and be sure to Dispose them when you're done so the memory can be unpinned.

Access via the Graphics object

Because the Bitmap property is actually a .NET Bitmap object, it's straightforward to perform operations using the Graphics class.

var dbm = new DirectBitmap(200, 200);
using (var g = Graphics.FromImage(dbm.Bitmap))
    g.DrawRectangle(Pens.Black, new Rectangle(50, 50, 100, 100));

Performance comparison

The question asks about performance, so here's a table that should show the relative performance between the three different methods proposed in the answers. This was done using a .NET Standard 2 based application and NUnit.

* Time to fill the entire bitmap with red pixels *
- Not including the time to create and dispose the bitmap
- Best out of 100 runs taken
- Lower is better
- Time is measured in Stopwatch ticks to emphasize magnitude rather than actual time elapsed
- Tests were performed on an Intel Core i7-4790 based workstation

              Bitmap size
Method        4x4   16x16   64x64   256x256   1024x1024   4096x4096
DirectBitmap  <1    2       28      668       8219        178639
LockBits      2     3       33      670       9612        197115
SetPixel      45    371     5920    97477     1563171     25811013

* Test details *

- LockBits test: Bitmap.LockBits is only called once and the benchmark
                 includes Bitmap.UnlockBits. It is expected that this
                 is the absolute best case, adding more lock/unlock calls
                 will increase the time required to complete the operation.
  • 6
    It is probably not provided as a default because it is an unmanaged object (rather, the underlying data is unmanaged) and runs counter to the philosophy of the framework. But this version is certainly more useful for frequent image manipulations.
    – marknuzz
    Commented Feb 10, 2016 at 20:27
  • 4
    DirectBitmap needs to be created from the ground up. If you need to create one from an existing Bitmap, you need to create a DirectBitmap with the same dimensions, and use a Graphics object to copy it over.
    – A.Konzel
    Commented Mar 22, 2016 at 18:14
  • 1
    @SaxxonPike Can you explain how you copy over from Graphics to DirectBitmap? If possible, a use-case sample for DirectBitmap would be great.
    – B.K.
    Commented Aug 19, 2016 at 9:39
  • 1
    @SaxxonPike Sorry to ask, but how exactly would I use this class to do someling like 'img.SetPixel(x,y,Color.Transparent);' ? I know how to create the class and adapt the constructor to my needs, but I don't seem to figure out how to use the bits to change the color of a pixel. Again, sorry for asking, I never worked on bits or bytes.
    – Dark
    Commented Aug 25, 2016 at 12:31
  • 2
    I suggest modifying this code to call Dispose() in the ~DirectBitmap() finalize method, or providing an example usage which creates the DirectBitmap in a using (DirectBitmap bmp = new DirectBitmap()) { ... } block.
    – Gladclef
    Commented May 23, 2018 at 23:10

The reason bitmap operations are so slow in C# is due to locking and unlocking. Every operation will perform a lock on the required bits, manipulate the bits, and then unlock the bits.

You can vastly improve the speed by handling the operations yourself. See the following example.

using (var tile = new Bitmap(tilePart.Width, tilePart.Height))
      BitmapData srcData = sourceImage.LockBits(tilePart, ImageLockMode.ReadOnly, PixelFormat.Format32bppArgb);
      BitmapData dstData = tile.LockBits(new Rectangle(0, 0, tile.Width, tile.Height), ImageLockMode.ReadWrite, PixelFormat.Format32bppArgb);

          byte* dstPointer = (byte*)dstData.Scan0;
          byte* srcPointer = (byte*)srcData.Scan0;

          for (int i = 0; i < tilePart.Height; i++)
              for (int j = 0; j < tilePart.Width; j++)
                  dstPointer[0] = srcPointer[0]; // Blue
                  dstPointer[1] = srcPointer[1]; // Green
                  dstPointer[2] = srcPointer[2]; // Red
                  dstPointer[3] = srcPointer[3]; // Alpha

                  srcPointer += BytesPerPixel;
                  dstPointer += BytesPerPixel;
              srcPointer += srcStrideOffset + srcTileOffset;
              dstPointer += dstStrideOffset;


  catch (InvalidOperationException e)

  • 1
    My guess is that it wouldn't be efficient to hold the entire bitmap in memory normally. 1024*1024*4 = 4,194,304 bytes = 4 megabytes.
    – Bort
    Commented Jul 11, 2014 at 17:09
  • 1
    Sorry, didn't expect that to send when pressing enter. The bits are in memory at all times. The problem is the overhead of the function call and looking up the pixel format and location of the desired pixel. With a loop based on LockBits, you only have to do that once, instead of once per pixel. The performance improvement depends on your use case (including the image size), but be advised GDI+ performs poorly in general and is not suitable for real-time applications. Commented Jul 11, 2014 at 22:55
  • 10
    The answers here are wrong. Why locking? Because .NET uses a Garbage Collector that asynchronously frees unused memory. After freeing a block of memory it moves the remaining memory to other locations to get longer consistent blocks of free memory. If the garbage collector would move your bitmap to another location just in the moment while you are reading the pixels you would read nonsense values. So .NET forces you to lock the bitmap which prohibits the garbage collector to move it. The bitmap data stays in memory at the same location until you unlock it.
    – Elmue
    Commented Aug 2, 2014 at 0:17
  • 3
    The two strides can be taken directly from the BitmapData objects, by the way. This code offers no insight into where the stride comes from. Nor is it clear what srcTileOffset is, for that matter.
    – Nyerguds
    Commented Jan 4, 2018 at 14:08
  • 5
    tilePart.Width and tilePart.Weight are extremely slow. Consider putting their result in a separate width/height variable. In my case this boosted performance 40x on 2048x2048 images.
    – blade
    Commented May 28, 2018 at 10:34

It's been some time, but I found an example that might be useful.

var btm = new Bitmap("image.png");

BitmapData btmDt = btm.LockBits(
    new Rectangle(0, 0, btm.Width, btm.Height),
IntPtr pointer = btmDt.Scan0;
int size = Math.Abs(btmDt.Stride) * btm.Height;
byte[] pixels = new byte[size];
Marshal.Copy(pointer, pixels, 0, size);
for (int b = 0; b < pixels.Length; b++)
    pixels[b] = 255; //Do something here 

Marshal.Copy(pixels, 0, pointer, size);

You can use Bitmap.LockBits method. Also if you want to use parallel task execution, you can use the Parallel class in System.Threading.Tasks namespace. Following links have some samples and explanations.


This code should be parallelized, there is a massive performance gain being missed by running this synchronously. Almost no modern Microchip will have less than 4 threads available and some chips will have 40 threads available.

There is absolutely no reason to run that first loop synchronously. You can go through either the width or the length using many, many threads.

        private void TakeApart_Fast(Bitmap processedBitmap)
            BitmapData bitmapData = processedBitmap.LockBits(new Rectangle(0, 0, processedBitmap.Width, processedBitmap.Height), ImageLockMode.ReadWrite, PixelFormat.Format24bppRgb);
            ConcurrentBag<byte> points = new ConcurrentBag<byte>();   
                int bytesPerPixel = System.Drawing.Bitmap.GetPixelFormatSize(processedBitmap.PixelFormat) / 8;
                int heightInPixels = bitmapData.Height;
                int widthInBytes = bitmapData.Width * bytesPerPixel;
                _RedMin = byte.MaxValue;
                _RedMax = byte.MinValue;
                byte* PtrFirstPixel = (byte*)bitmapData.Scan0;
                Parallel.For(0, heightInPixels, y =>
                    byte* currentLine = PtrFirstPixel + (y * bitmapData.Stride);
                    for (int x = 0; x < widthInBytes; x = x + bytesPerPixel)
                        // red
                        byte redPixel = currentLine[x + 2];
                        //save information with the concurrentbag

a benchmark wouldn't mean much because the answer to how much this will speed up the proccess depends 100% on what hardware you are using, and what else is running in the background, it all depends on how many free threads are available. If your running this on a 4000 series graphics card with thousands of streaming proccessors you may be able to do iterate through every column of the image at the same time.

if your running it with and old quad core you may only have 5 or 6 threads which is still incredibly significant.

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