I have done work on exactly this problem.
I found that the existing SPI module provided with the PSoC 5 components library is not ideally suited to bulk transfers to / from an SD card. As far as I could tell, it was necessary to clear SPI module flags in software on each byte transfer, rendering DMA much less useful. I think one solution is to use two TDs (Transfer descriptors) - one to perform the data transfer and a second to clear the RX flag after the first TD has completed - anyway, that's off topic.
I also found that the emFile component supplied in the components library is limited in its capabilities. I couldn't see any way to attach DMA, and even if I could, its clock speed appeared to be very poor. On top of this, emFile requires compile-time selection of FAT16 or FAT32, limiting your design to one or another filesystem only.
As I didn't like the idea of a more complicated DMA setup, I decided to design my own SPI component hardware in the UDB editor. The project containing the component can be found at: https://github.com/PolyVinalDistillate/NSDSPI
This incorporates the excellent FatFS library mentioned above (thanks ChaN), which takes care of FAT12, FAT16 and FAT32 formatted cards. As stated, without the filesystem layer, you will only be accessing raw data blocks of 512 bytes each. With FatFS, you get analogues of fopen(), fclose(), etc.
If you look at my component in PSoC Creator, you'll see it's actually composed of 2 components: One is the specialised UDB component implementing the main SPI logic, the other is a schematic connecting my UDB component to DMA and some control logic. This second component also has the API files containing my hardware-specific code and is the component to drop into your TopDesign schematic.
FatFS is included as a precompiled library, and LowLevelFilesys.h in the API folder provides access to all the file functions.
This component was designed with bulk-reads in mind and the API does the following for read:
- Sets up a DMA TD of the required data length and tells my SPI component how many bytes will be transferred.
- Triggers the transfer, causing my SPI component to send 0xFF automatically (no need to write 0xFF to the SPI for every byte received), while copying each received byte into the receive buffer via DMA.
Writing the card is performed in a more typical fashion, with the DMA simply sending data to the SPI module after preparing the SD card for it.
If you run my project on your PSoC system, it will perform a read / write test on the SD card, depositing a file reporting the specs:
Writing 16000 bytes to file, non-DMA
Took 94 ms
Rate 1361 kbps
Reading 16000 bytes to file, non-DMA
Took 50 ms
Verifying... All Good! :D
Rate 2560 kbps
Writing 16000 bytes to file, DMA
Took 17 ms
Rate 7529 kbps
Reading 16000 bytes to file, DMA
Took 12 ms
Verifying... All Good! :D
Rate 10666 kbps
Some SD cards give better results, some give worse. I believe this is down to the SD card itself (e.g. class, usage, age of tech, etc).