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I have an arm cortex-a9 quad core device, and I'm programming a multi-process application. These processes share the same source of input - a DMA buffer which they all access using a mmap() call.

I noticed that the time it takes for the processes to access the DMA memory, is significantly longer than it takes if I change the source of input to be a normal allocated buffer (i.e. allocated using malloc).

I understand why a DMA buffer must be non-cacheable, however, since I have the ability to determine when the buffer is stable (unchanged by the hardware, which is the case most of the time) or dirty (data has changed) I thought I might get a significant speed improvement if I'll make the memory region temporarily cacheable.

Is there a way to do that?

I'm currently using this line to map the memory:

void *buf = mmap(0, size, PROT_READ | PROT_WRITE,MAP_SHARED, fd, phy_addr);


share|improve this question
DMA buffer is too broad of a definition. How do you obtain/create one? – user405725 Jun 10 '13 at 17:23
I create a DMA buffer with DMA_ALLOC_COHERENT in the device's kernel module. – oferlivny Jun 11 '13 at 7:24

Most modern CPUs use snooping to determine if/when cache lines must be flushed to memory or marked invalid. On such CPUs a "DMA buffer" is identical to a kmalloc() buffer. This, of course, assumes the snoop feature works correctly and that the OS takes advantage of the snoop feature. If you are seeing differences in accesses to DMA and non-DMA memory regions then I can only assume your CPU either does not have cache snooping capabilities (check CPU docs) or the capability is not used because it doesn't work (check CPU errata).

Problems with your proposed approach:

  1. Do you know when it is time to change the memory region back to non-cacheable?
  2. Changing MMU settings for a memory region is not always trivial (is CPU dependent) and I'm not sure an API even exists within your OS for changing such settings.
  3. Changing MMU settings for a memory region is risky even when it is possible and such changes must be carefully synchronized with your DMA operation or data corruption is virtually guaranteed.

Given all of these significant problems, I suggest a better approach is to copy the data from the DMA buffer to the kmalloc() buffer when you detect the DMA buffer has been updated.

share|improve this answer
I have complete control over the timing of the memory modification. Also, I'm sure that the CPU supports snoop (ARM cortex-a9 quad core). Copying is our fallback option, as we have too many processes that will have to do this memcpy to their own virtual memory space. This might be a memory intensive procedure... – oferlivny Jun 11 '13 at 6:51
I'm pretty sure I can implement such logic safely, I'm just looking for the API... – oferlivny Jun 11 '13 at 6:56
Maybe I'm confused about your system but what I'm suggesting would require only one copy from the DMA buffer to a kmalloc buffer and you then mmap() the kmalloc buffer rather than the DMA buffer. And if you are certain the cortex-a9 has working snoop architecture, then just use a kmalloc buffer as your DMA buffer. – slowjelj Jun 11 '13 at 22:34
BTW, if you are looking for the API, you will need to specify an OS and a version of that OS! – slowjelj Jun 11 '13 at 22:36
Sorry for the late reply - is copying the data to a kmalloc buffer is faster than copying it from user space after the mmap to a regualar malloc'd or memory shared buffer? as far as I know, it is more or less the same... Copying the data into such buffer is what I'm trying to avoid, as my application require low latency... – oferlivny Jun 20 '13 at 9:18

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