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I've become rather familiar with the System.Drawing namespace in terms of knowing the basic steps of how to generate an image, draw on it, write text on it, etc. However, it's so darn slow for anything approaching print-quality. I have seen some suggestions using COM to talk to native Windows GDI to do this quicker but I was wondering if there were any optimizations I could make to allow for high speed, high quality image generation. I have tried playing with the anti-aliasing options and such immediately available to the Graphics, Bitmap and Image objects but are there any other techniques I can employ to do this high speed?

Writing this I just had the thought to use the task library in .Net 4 to do MORE work even though each generation task wouldn't be any quicker.

Anyway, thoughts and comments appreciated.


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Is there some specific code you have performance problems with you would like to show so that we can have a base for discussion? – Darin Dimitrov Apr 28 '11 at 21:10
up vote 5 down vote accepted

If you want raw speed, the best option is to use DirectX. The next best is probably to use GDI from C++ and provide a managed interface to call it. Then probably to p/invoke to GDI directly from C#, and last to use GDI+ in C#. But depending on what you're doing you may not see a huge difference. Multithreading may not help you if you're limited by the speed at which the graphics card can be driven by GDI+, but could be beneficial if you're processor bound while working out "what to draw". If you're printing many images in sequence, you may gain by running precalculation, rendering, and printing "phases" on separate threads.

However, there are a number of things you can do to optimise redraw speed, both optimisations and compromises, and these approaches will apply to any rendering system you choose. Indeed, most of these stem from the same principles used when optimising code.

How can you minimise the amount that you draw?

Firstly, eliminate unnecessary work. Think about each element you are drawing - is it really necessary? Often a simpler design can actually look better while saving a lot of rendering effort. Consider whether a grad fill can be replaced by a flat fill, or whether a rounded rectangle will look acceptable as a plain rectangle (and test whether doing this even provides any speed benefit on your hardware before throwing it away!)

Challenge your assumptions - e.g. the "high resolution" requirement - often if you're printing on something like a dye-sub printer (which is a process that introduces a bit of colour bleed) or a CMYK printer that uses any form of dithering to mix colours (which has a much lower practical resolution than the dot pitch the printer can resolve), a relatively low resolution anti-aliased image can often produce just as good a result as a super-high-res one. If you're outputting to a 2400dpi black and white printer, you may still find that 1200dpi or even 600dpi is acceptable (you get ever decreasing returns as you increase the resolution, and most people won't notice the difference between 600dpi and 2400dpi). Just print some typical examples out using different source resolutions to see what the results are like. If you can halve the resolution you could potentially render as much as 4x faster.

Generally try to avoid overdrawing the same area - If you want to draw a black frame around a region, you could draw a white rectangle inside a black rectangle, but this means filling all the pixels in the middle twice. You may improve the performance by drawing 4 black rectangles around the outside to draw the frame exactly. Conversely, if you have a lot of drawing primitives, can you reduce the number of primitives you're drawing? e.g. If you are drawing a lot of stripes, you can draw alternating rectangles of different colours (= 2n rectangles), or you can fill the entire background with one colour and then only draw the rectangles for the second colour (= n+1 rectangles). Reducing the number of individual calls to GDI+ methods can often provide significant gains, especially if you have fast graphics hardware.

If you draw any portion of the image more than once, consider caching it (render it into a bitmap and then blitting it to your final image when needed). The more complex this sub-image is, the more likely it is that caching it will pay off. For example, if you have a repeating pattern like a ruler, don't draw every ruler marking as a separate line - render a repeating section of the ruler (e.g. 10 lines or 50) and then blit this prerendered only a few times to draw the final ruler.

Similarly, avoid doing lots of unnecessary work (like many MeasureString calls for values that could be precalculated once or even approximated. Or if you're stepping through a lot of Y values, try to do it by adding an offset on each iteration rather than recaclualting the absolute position using mutliples every time).

Try to "batch" drawing to minimise the number of state changes and/or drawing method calls that are necessary - e.g. draw all the elements that are in one colour/texture/brush before you move on to the next colour. Use "batch" rendering calls (e.g. Draw a polyline primitive once rather than calling DrawLine 100 times).

If you're doing any per-pixel operations, then it's usually a lot faster to grab the raw image buffer and manipulate it directly than to call GetPixel/SetPixel methods.

And as you've already mentioned, you can turn off expensive operations such as anti-aliasing and font smoothing that won't be of any/much benefit in your specific case.

And of course, look at the code you're rendering with - profile it and apply the usual optimisations to help it flow efficiently.

Lastly, there comes a point where you should consider whether a hardware upgrade might be a cheap and effective solution - if you have a slow PC and a low end graphics card there may be a significant gain to be had by just buying a new PC with a better graphics card in it. Or if the images are huge, you may find a couple of GB more RAM eliminates virtual memory paging overheads. It may sound expensive, but there comes a point where the cost/benefit of new hardware is better than ploughing more money into additional work on optimisations (and their ever decreasing returns).

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Several good suggestions. In particular I didn't think about caching, so to speak, repeatedly drawn areas. The work with this deals a lot by getting images from disc so I/O overhead is pretty high. I can cut that down by "watching" for repeated calls to the same image and keep it in memory for a while. Thanks again! – Michael Apr 28 '11 at 22:16

I have a few ideas:

  1. Look at the code in It is an open source paint program written in C#. It could give you some good ideas. You could certainly do this in conjunction with ideas 2 and 3.

  2. If the jobs need to be done in an "immediate" way, you could use something asynchronous to create the images. Depending on the scope of the overall application, you might even use something like NServiceBus to queue an image processing component with the task. Once the task is completed, the sending component would receive a notification via subscribing to the message published upon completion.

  3. The task based solution is good for delayed processing. You could batch the creation of the images and use either the Task approach or something called ( It's an open source job scheduler that I use for all my time based jobs.

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You can create a new Bitmap image and do LockBits(...), specifying the pixel format you want. Once you have the bits, if you want to use unmanaged code to draw into it, bring in the library, pin the data in memory, and use that library against it. I think you can use GDI+ against raw pixel data, but I was under the impression that System.Drawing is already a thin layer on top of GDI+. Anyways, whether or not I'm wrong about that, with LockBits, you have direct access to pixel data, which can be as fast or slow as you program it.

Once you're done with drawing, you can UnlockBits and viola you have the new image.

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Actually, if you're looking for fast print-quality graphics, maybe you could use vector drawing techniques instead of bitmapped. – Kevin Hsu Apr 28 '11 at 21:58
Thanks I didn't know about that. I'd provide code but it's apparently well over the 600 or so characters this box provides. – Michael Apr 28 '11 at 22:01

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