FreeCalypso > hg > freecalypso-reveng
view objgrep/README @ 188:3e78a1bf9ebc
leo-obj/l1_int/dl1_com.hints: created
author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
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date | Sun, 17 Aug 2014 18:41:11 +0000 |
parents | 10a9a0ca9d07 |
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We have TI's reference firmware for the Calypso/Iota/Rita chipset (Leonardo) in the form of linkable COFF objects and some source pieces, but when it comes to practically usable "dumbphones" based on this chipset, we only have the binary fw images read out of flash, without any kind of symbolic info. The tools in this directory perform a kind of grep operation, searching an unknown binary fw image for the bits of code or data contained in a linkable COFF object. The objective was to determine whether or not our "reference" Leonardo objects could be found verbatim in the set of proprietary firmwares from Compal and Foxconn (Pirelli DP-L10) that run on our "dumbphone" targets. The tools are as follows: objgrep This tool extracts one section (e.g., .text or .const, to be specified on the command line) from a "needle" COFF object and searches for it in the "haystack" unknown binary. The byte positions in the sought-for object section where relocs are to be applied at linking time are masked as appopriate for each reloc type, and the section is expected to start on a 4-byte-aligned boundary in the unknown binary. If a match is found, objgrep can print out the list of symbol addresses in the sought-for and found section, and it can also deduce some symbols external to the module or belonging to the module's other sections by looking where the relocs that were masked for the match point to in the unknown binary. In order for this form of grep to be effective, the section being searched for should be "meaty", i.e., mostly code or constant data with some interspersed relocs. If the sought-for section is very small, fits the same pattern after reloc masking as other unrelated bits of code, or consists mostly of relocs, the most likely result will be a useless false hit. objgrep-fe This program is a front-end to objgrep. It reads a line-based text file listing the objects and sections to be grepped for, and invokes objgrep for each listed section. The output of objgrep is captured through a pipe; objgrep-fe collates together the symbol addresses found with each individual objgrep hit and produces a sorted symbol listing. Results ======= The idea proved quite successful in the case of Pirelli DP-L10 firmware, specifically version D910.0.3.98: this fw appears to have been built with exactly the same RTS, Nucleus and GPF libraries that are featured in our Leonardo semi-src as "very stable blobs", i.e., *.lib files in the source tree itself, rather than blobs under g23m/__out__ for which TI's closed source police excluded the corresponding source. Every object that comes from these libraries in our leo2moko build was also found in Pirelli's fw. It is worth noting that the GPF libraries in particular contain a few objects with embedded second-granularity timestamps, courtesy of the C compiler's __DATE__ and __TIME__ preprocessor definitions, i.e., the timestamp strings with times to the second are emitted into the code image built with these libraries. These timestamped objects were found in Pirelli's fw with our objgrep tools along with the rest of GPF, proving beyond any doubt that this fw has been built with exactly the same GPF libs as our leo2moko. This confirmation in the case of Pirelli's fw is very reassuring because this fw has received a lot of real-life testing: I've been using a Pirelli running its original proprietary fw (as no free fw exists yet, for this or any other dumbphone) as my personal everyday cellphone for over a year now. That is a lot more real life experience than I can get with anything Openmoko-based, and it is reassuring to know that the GPF libraries we have painstakingly reconstructed are used not only in the largely-untested moko firmware, but also in the much more real-life-tested Pirelli DP-L10 fw. Attemping the same grep against Compal's fw yielded far fewer hits, however. A lot of RTS modules were found, but very little from Nucleus or GPF libs. Nucleus' tct and tmt assembly modules were found, but not much else. Manual examination of Compal's INC_Initialize() function (which is easy to locate even in a totally unknown fw binary, as it's only one ARM->Thumb call veneer away from the boilerplate code at the boot entry point) has revealed that it's the same code, but compiled slightly differently, probably a slightly newer C compiler version. (The version in our reference libs saves one more call- preserved register than necessary; the version that appears in Compal's fw is fully optimal in this regard.) I reason that the same compiler difference must be responsible for the great scarcity of hits in general, as these kinds of compiler changes would produce differences in just about every module.