With that specific struct, the issue you're most likely to encounter is endian-ness. On a little-endian system, the lowest-addressed byte of that
int contains the least significant 8 bits. On a big-endian system, the most significant 8 bits.
Therefore if you write the bytes of that struct to a file on one kind of system, transfer the file to the other kind of system, and read it back, then you'll see a different value in
There are other issues that you could encounter with other structs, though, or with unusual systems/compilers:
- size of the basic types -
int is generally 4 bytes but is not required to be.
long is of different sizes on different common systems (4 bytes on Windows, 8 bytes on 64 bit Linux). Obviously if you try to read a struct from a file, and expect a different number of bytes from what was actually written by some other C++ implementation, you have a problem.
- padding - the compiler is allowed to put unused bytes into the structure between members. This generally happens in order to ensure alignment. For example in many compilers, the offset of an
int member is always a multiple of 4. Since 40 is a multiple of 4 anyway in your struct this wouldn't make any difference, but if the first array was 39 bytes then an implementation that aligns
int would insert an unused byte, and one that didn't would not. On some CPUs (for example x86) it is helpful but not essential that
int be aligned, in which case compilers commonly have ways to annotate a structure to say whether or not to pad it.
Since these kinds of differences exist, it is not legitimate in general to write a struct directly to file (or socket). You can get away with it in the specific case where whoever reads it has exactly the same memory representation for that struct, which means that you can do it if you first work out exactly what bytes go where with what meaning, and then ensure that all programs that need to read/write the file can work with that format.