I have a auto-generated C++ source file, around 40 MB in size. It largely consists of push_back commands for some vectors and string constants that shall be pushed.
When I try to compile this file, g++ exits and says that it couldn't reserve enough virtual memory (around 3 GB). Googling this problem, I found that using the command line switches
--param ggc-min-expand=0 --param ggc-min-heapsize=4096
may solve the problem. They, however, only seem to work when optimization is turned on.
1) Is this really the solution that I am looking for?
2) Or is there a faster, better (compiling takes ages with these options acitvated) way to do this?
Update: Thanks for all the good ideas. I tried most of them. Using an array instead of several push_back() operations reduced memory usage, but as the file that I was trying to compile was so big, it still crashed, only later. In a way, this behaviour is really interesting, as there is not much to optimize in such a setting -- what does the GCC do behind the scenes that costs so much memory? (I compiled with deactivating all optimizations as well and got the same results)
The solution that I switched to now is reading in the original data from a binary object file that I created from the original file using
objcopy. This is what I originally did not want to do, because creating the data structures in a higher-level language (in this case Perl) was more convenient than having to do this in C++.
However, getting this running under Win32 was more complicated than expected. objcopy seems to generate files in the ELF format, and it seems that some of the problems I had disappeared when I manually set the output format to
pe-i386. The symbols in the object file are by standard named after the file name, e.g. converting the file
inbuilt_training_data.bin would result in these two symbols: binary_inbuilt_training_data_bin_start and binary_inbuilt_training_data_bin_end. I found some tutorials on the web which claim that these symbols should be declared as
extern char _binary_inbuilt_training_data_bin_start;, but this does not seem to be right -- only
extern char binary_inbuilt_training_data_bin_start; worked for me.