README for the spi_boot core ============================ Version: $Date: 2005/04/14 21:32:58 $ Description ----------- The SD/MMC Bootloader is a CPLD design that manages configuration and bootstrapping of FPGAs. It is able to retrieve the required data from SecureDigital (SD) cards or MultiMediaCards (MMC) and manages the FPGA configuration process. SD cards as well as MMCs are operated in SPI mode which is part of both standards thus eliminating the need for dedicated implementations. The SD/MMC Bootloader fits both. Beyond configuration, this core supports a bootstrapping strategy where multiple images are stored on one single memory card. For example consider a system completely based on SRAM. The bootloader provides the initial configuration data from the first image to the FPGA. This image contains a design which pulls the next image from the memory card and transfers this data to SRAM. In the third step the final FPGA design is loaded from the third image. These images are clustered in sets which can be selected by external switches for example. Several configuration sets can be stored on one memory card allowing you to provide a number of applications which are downloaded quickly to the FPGA. The schematic (rev. B) shows how the core can be used with an FPGA board. I use it to configure/boot the Xilinx Spartan IIe on BurchED's B5-X300 board. SV2 fits the "SERIAL MODE" connector on this board but you will have to add a separate wire from R6 to attach INIT. Please check the proper use of the pull-up resistors for your specific board. Features -------- * Configuration mode: configures SRAM based FPGAs via slave serial mode (Xilinx and Altera) * Data mode: provides stored data over a simple synchronous serial interface * Broad compatability using SPI mode + SecureDigital cards using dedicated initialization command + MultiMediaCards (see below) * Operation triggerd by power-up or card insertion * Multiple configuration sets stored on on single memory card Compatability ------------- These cards have been tested with the SD/MMC Bootloader: * Hama 64 MB SD * SanDisk 128 MB SD * SanDisk 64 MB MMC * Panasonic 32 MB SD Some MMC might fail with this core as not all cards support CMD18 (READ_MULTIPLE_BLOCK). Please consult the data sheet of your specific model. In case your MMC does not implement CMD18 you might want to have a look at the FPGA MMC-Card Config project. Tools ----- Downloading the configuration data to the card is a straight forward process. The images have to be written starting at dedicated locations. For the provided toplevel designs, these locations are multiples of 256 K. I.e. 0, 0x40000, 0x80000 and so forth. dd (part of the GNU coreutils) serves this purpose: $ dd if=ram_loader.bin of=/dev/sdX bs=512 $ dd if=pongrom_6.bin of=/dev/sdX bs=512 seek=512 $ dd if=pacman.bin of=/dev/sdX bs=512 seek=1024 The name of the device node depends on how the card reader is attached to the kernel. For Linux systems this is most often something like /dev/sdX with X ranging from a-z. Please note that it is essential to use the device without any trailing numbers as they refer to partitions leading to wrong offsets for data written to the card. All this works perfectly for my Spartan IIe device as this FPGA expects the configuration data as it is delivered from the card: Consecutive bytes each with its most significant bit first. Altera devices like the FLEX family are different here. They expect the bytes with least significant bit first. Therefore, the configuration data has to be swapped bitwise before it is written to the card. Verification ------------ The spi_boot core comes with a simple testbench that simulates an SD/MMC card. All four implementations of the core are verified there in parallel while transferring the data for several sets. You should normally not need to run the testbench. But in case you modified the VHDL code the testbench gives some hints if the design has been broken. Directory Structure ------------------- The core's directory structure follows the proposal of OpenCores.org. spi_boot | \--+-- doc : Documentation | | | \-- src : Source files of documentation | +-- rtl | | | \-- vhdl : VHDL code containing the RTL description | of the core. | +-- bench | | | \-- vhdl : VHDL testbench code. | \-- sim | \-- rtl_sim : Directory for running simulations. RAM Loader ---------- Directory rtl/vhdl/ram_loader contains the sample design which loads the next image from the card and stores its contents to external asynchronous RAM. After reading 64 KB it triggers a new configuration process for the final FPGA design. Refer to the code for the mechanisms involved. Compiling the VHDL Code ----------------------- VHDL compilation and simulation tasks take place inside in sim/rtl_sim directory. The project setup supports only the GHDL simulator (see http://ghdl.free.fr). To compile the code simply type at the shell $ make This should result in a file called tb_behav_c0 which can be executed as any other executable. The basic simple sequence list can be found in COMPILE_LIST. This can be useful to quickly set up the analyze stage of any compiler or synthesizer. Especially when synthesizing the code, you want to skip the VHDL configurations in *-c.vhd and everything below the bench/ directory. References ---------- * SanDisk SD Card Product Manual http://www.sandisk.com/pdf/oem/ProdManualSDCardv1.9.pdf * SanDisk MMC Product Manual http://www.sandisk.com/pdf/oem/manual-rs-mmcv1.0.pdf * Toshiba SD Card Specification http://i.cmpnet.com/chipcenter/memory/images/prod055.pdf * BurchED http://burched.biz/ * FPGA MMC-Card Config project http://www.opencores.org/projects.cgi/web/mmcfpgaconfig/overview