The final images produced by compliers contain both bin file and extended loader format ELf file ,what is the difference between the two , especially the utility of ELF file.
A Bin file is a pure binary file with no memory fix-ups or relocations, more than likely it has explicit instructions to be loaded at a specific memory address. Whereas....
ELF files are Executable Linkable Format which consists of a symbol look-ups and relocatable table, that is, it can be loaded at any memory address by the kernel and automatically, all symbols used, are adjusted to the offset from that memory address where it was loaded into. Usually ELF files have a number of sections, such as 'data', 'text', 'bss', to name but a few...it is within those sections where the run-time can calculate where to adjust the symbol's memory references dynamically at run-time.
A bin file is just the bits and bytes that go into the rom or a particular address from which you will run the program. You can take this data and load it directly as is, you need to know what the base address is though as that is normally not in there.
An elf file contains the bin information but it is surrounded by lots of other information, possible debug info, symbols, can distinguish code from data within the binary. Allows for more than one chunk of binary data (when you dump one of these to a bin you get one big bin file with fill data to pad it to the next block). Tells you how much binary you have and how much bss data is there that wants to be initialised to zeros (gnu tools have problems creating bin files correctly).
The elf file format is a standard, arm publishes its enhancements/variations on the standard. I recommend everyone writes an elf parsing program to understand what is in there, dont bother with a library, it is quite simple to just use the information and structures in the spec. Helps to overcome gnu problems in general creating .bin files as well as debugging linker scripts and other things that can help to mess up your bin or elf output.
- ELF for the ARM architecture
- ELF from wiki
ELF format is generally the default output of compiling. if you use GNU tool chains, you can translate it to binary format by using objcopy, such as:
arm-elf-objcopy -O binary [elf-input-file] [binary-output-file]
or using fromELF utility(built in most IDEs such as ADS though):
fromelf -bin -o [binary-output-file] [elf-input-file]
bin is the final way that the memory looks before the CPU starts executing it.
ELF is a cut-up/compressed version of that, which the CPU/MCU thus can't run directly.
The (dynamic) linker first has to sufficiently reverse that (and thus modify offsets back to the correct positions).
But there is no linker/OS on the MCU, hence you have to flash the bin instead.
Moreover, Ahmed Gamal is correct.
Compiling and linking are separate stages; the whole process is called "building", hence the GNU Compiler Collection has separate executables:
One for the compiler (which technically outputs assembly), another one for the assembler (which outputs object code in the ELF format), then one for the linker (which combines several object files into a single ELF file), and finally, at runtime, there is the dynamic linker, which effectively turns an elf into a bin, but purely in memory, for the CPU to run.
Note that it is common to refer to the whole process as "compiling" (as in GCC's name itself), but that then causes confusion when the specifics are discussed,
such as in this case, and Ahmed was clarifying.
It's a common problem due to the inexact nature of human language itself.
To avoid confusion, GCC outputs object code (after internally using the assembler) using the ELF format. The linker simply takes several of them (with an .o extension), and produces a single combined result, probably even compressing them (into "a.out").
But all of them, even ".so" are ELF. It is like several Word documents, each ending in ".chapter", all being combined into a final ".book", where all files technically use the same standard/format and hence could have had ".docx" as the extension.
The bin is then kind of like converting the book into a ".txt" file while adding as many whitespace as necessary to be equivalent to the size of the final book (printed on a single spool), with places for all the pictures to be overlaid.
Pure binary is a sequence of executable opcodes to be executed from his 0 offset, ** but not only **.
Pure binaries are generally used on microcontrollers, bare metal programming and initial boots, where there is no "laoder" except the ROM loader.
Pure binaries includes .bss and .data, that from binaries that are read from flash memory as in a microcontroller, have to be relocated somewhere in ram. A binary file can include a vector table, symbol tables for "rel" or "rela" relocation (see -fPIC), got table and so on. All this additional data are obtained from the ELF->binary conversion, since the addresses of this specific tables are obtained from the ELF.
Another important point for the binary production are "linker scripts", they produce section offsets, and different addresses used in the absolute jumps depending of the declared sections.
Final note: pure binaries code (.text) is also often relocated to ram, since cpu internal sram is generally not too big. For this, such relocation tables comes into use.