FreeCalypso > hg > freecalypso-tools
view doc/Binary-file-formats @ 988:5a6019ed7e72
pln-ppb-test: implement read-id
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 03 Dec 2023 00:04:18 +0000 |
parents | b6b8307d195b |
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In FreeCalypso we use 3 different file formats for Calypso binary images, i.e., code images to be loaded into either flash or RAM or retrieved flash dumps. These 3 different file formats are straight binary (*.bin), moko-style m0 (*.m0) and little-endian S-records (*.srec). Straight binary (*.bin) ======================= Straight binary is our preferred format for flash dumps. It is written in the native little-endian byte order of the Calypso ARM7 processor, i.e., the order of bytes in the raw binary file directly corresponds to incrementing byte addresses as visible to the ARM7 - any ASCII strings in the image thus appear naturally. We also use the same straight binary format in native LE byte order for flashable code images generated with the gcc+binutils toolchain (as opposed to TI's TMS470), generated with arm-elf-objcopy -O binary - although we don't have too many such code images currently given that neither FC Citrine nor FC Selenite ever achieved production quality. Another unrelated use of this straight binary format is for RAM-loadable code images that are fed to Compal's bootloader (Motorola C1xx and Sony Ericsson J100) as opposed to Calypso boot ROM. Our generally preferred image format for RAM-loadable code pieces is little-endian S-records (*.srec, see below), but for Compal's bootloader we use straight binary instead because of the way this bootloader protocol works. moko-style m0 ============= This format is a variant of Motorola hex (S-records), a variant invented by TI rather than by us. This format is produced by TI's hex470 tool when run with -m -memwidth 16 -romwidth 16 options, which is the configuration used by TI in the Calypso program, and is read by TI's flash programming tool called FLUID. TI used this format not only for flashable firmware images, but also for various RAM-loadable code pieces, particularly those that comprise the target-side component of FLUID. The special quirk of this S-record variant format is its peculiar byte order. TI viewed it as "16-bit hex", meaning that the image is logically viewed as consisting of 16-bit words rather than 8-bit bytes, each S3 record carries an even number of bytes to be loaded at an even address, and each 16-bit word (4 hex digits) appears in these S3 records with its most-significant hex nibble toward the left, just like the address field of each S-record. But if this image gets interpreted by some more naive tool (for example, objcopy from GNU binutils) as bytes rather than 16-bit words, the result will be a reversed byte order, with all strings etc messed up. In FreeCalypso we use this moko-style m0 format (our new name for what TI called 16-bit hex) only for flashable firmware images built with TI's TMS470 toolchain (can be our own FC Magnetite or historical ones built by Openmoko or other similar historical vendors), but never for any RAM-loadable code pieces - we use little-endian SREC for the latter as explained below. And what about the name? Why do we call it moko-style m0 rather than just m0? The reason is because Compal muddied our waters by introducing their own *.m0 files that were generated with -memwidth 8 -romwidth 8 instead of -memwidth 16 -romwidth 16, producing 8-bit hex instead of 16-bit hex. We do not support Compal's different *.m0 files at all, and we needed some name to specifically identify TI-style m0 files rather than Compal-style. We ended up with the name moko-style rather than TI-style because we already had our mokosrec2bin program going back to 2013-04-15, one of the very first programs written in the FreeCalypso family of projects: our very first encounter with this file format were mokoN firmware images put out in this *.m0 format by That Company. Little-endian S-records (*.srec) ================================ Back at the beginning of FreeCalypso in the spring/summer of 2013 I (Mother Mychaela) decided to use S-records instead of straight binary for our RAM-loadable code pieces, i.e., code that is loaded into RAM either through the Calypso boot ROM (fc-iram) or by chain-loading via loadagent (fc-xram). I made this decision based on two factors: 1) ARM code generated by common toolchains (both TI's TMS470 and gcc+binutils) without special contortions is not position-independent: a code image that was linked for a given address needs to be loaded at that specific address, not some other. 2) An S-record image has its load address embedded in the image itself, whereas a raw binary naturally does not carry any such extra metadata. With SREC as the standardized hand-off format from code generation tools to loadtools, the choice of load address is made entirely on the code generation side; loadtools do not impose a fixed load address, nor do they require it to be communicated via extra command line arguments or options. However, the variant of SREC we use for RAM-loadable code pieces is not the same as moko-style m0 - the byte order is the opposite, with our RAM-loadable code pieces using the native little-endian byte order of the ARM7 processor as the byte order within S3 records. Prior to the introduction of RAM-loadable FC Magnetite fw images for Pirelli DP-L10 in late 2016 (and then likewise for our own FCDEV3B), the only RAM-loadable code pieces we have had were built with gcc+binutils, not with TMS470, and GNU binutils got a different take on the S-record format than TI did: they generate byte-oriented SREC files, with the byte order being the same as it would be in a straight binary file, matching the target processor's memory byte addressing order. Thus GNU-style SREC has been adopted as the format for our RAM-loadable code images for both fc-iram and fc-xram, as opposed to TI-style SREC aka moko-style m0. The convention we have adopted is that *.m0 filename suffix means TI-style aka moko-style, whereas *.srec means GNU-style. Besides the S3 record byte order, there is one other difference between TI-built *.m0 code images and GNU-built *.srec ones: the final S7 record carries the entry point address in GNU-built *.srec images, whereas TI's *.m0 images always have a zero dummy address in there. Our fc-iram and fc-xram tools require the real entry point address in the S7 record. How do we generate ramimage.srec RAM-loadable images for fc-xram in FC Magnetite? Answer: FC Magnetite build system includes a special ad hoc converter program that reads ramimage.m0 produced by TI's hex470 tool and produces ramimage.srec: it reverses the order of bytes, adds another S3 record that writes the boot-ROM-redirected interrupt and exception vectors and generates an S7 record with the right entry point address. This little-endian *.srec format is actively used only for RAM-loadable code pieces in FreeCalypso, not for anything that goes into or gets read from flash. We do have flash dump2srec and flash program-srec commands in fc-loadtool, they were implemented back in the founding stage of FreeCalypso in 2013 for the sake of completeness and symmetry (it seemed right to support both binary and S-record formats), but they never got any practical use: if you are making a flash dump, you would normally want to examine it afterward, and any such examination almost always needs a straight binary image, not S-records.