In general, a DMA operation just refers to a device other than the CPU accessing memory. On x86, there are not separate MMIO and RAM address spaces -- everything is unified. Some examples of typical DMA operations:
- A network card might receive a packet from the network and use DMA to write the packet contents into the system's RAM.
- A SATA controller might get a write command and use DMA to read the data to send to the hard disk from system RAM.
- A graphics card might use DMA to read texture data from system RAM into its own video memory. The video memory is visible to the system CPU through a PCI BAR (MMIO), but that's not really relevant here.
dma_addr_t type holds a "bus address" in Linux. The address that, for example, a PCI device (like a NIC / SATA controller / GPU) sees a given part of memory mapped at can be different than the address the CPU uses. So Linux has the abstraction of "DMA mapping" to handle this difference.
In the first example above, the network stack would allocate a buffer in RAM, and then pass it to a
dma_map function to get a bus address that it hands to the NIC. The NIC would use that address to write the packet into memory.
In older x86 systems, there wasn't really any difference between the physical address that the CPU used and the bus address that external devices used, and the
dma_map functions were pretty much NOPs. However, with modern technologies like VT-d, the bus address that a PCI device uses might be completely different than the CPU's physical address, and so it is important to do the DMA mapping and use a
dma_addr_t for all addresses that are used by external DMA devices.