I have been searching but have gotten no luck with finding a supposed compiler flag or something of the sorts that would allow me to build my FORTRAN DLL (using Intel Visual Fortran Composer XE 2013 compiler) in order for it to load with a random base address each time. I am explicitly loading my FORTRAN DLL in my C++ code and it loads/unloads fine but I just noticed that the address in which it loads to each time is the EXACT same location. I wonder if that is why at times my FORTRAN DLL would load successfully and other times fail when I run my program multiple times simultaneously. Does there exist any random base address compiler options for the Intel Fortran compiler? I have read in the release notes for it but no luck either.
To answer your immediate question: yes, it is possible to mark a DLL so that recent Windows versions would load it at a slightly randomised base address. This is achieved by passing the /DYNAMICBASE option to the linker (
Note that the
However it is not really necessary. Explanation why follows.
Just to clearly summarise the comments. Each process on Windows (and not only on Windows, but also on virtually any modern OS like *BSD, Linux, OS X, etc.) has its own virtual linear address space and all memory in user-space is operated using those virtual addresses. Virtual memory is divided into pages, which are backed by frames of physical memory. One physical memory frame might be mapped to many virtual memory pages, even from the address spaces of different processes, thus facilitating memory sharing between processes. The mapping between virtual memory pages and physical memory frames is maintained in the so-called page tables. Those are local to the processes and hence the mapping is local, meaning that the same virtual memory address in two different processes would most likely map to completely different physical memory addresses. Some operating systems (Windows included) split the virtual address space of each process in two parts - lower and upper. The lower part belongs to the process while the upper part in all processes maps to the operating system's kernel memory area. This is of little interest to the application developers since the kernel memory is not accessible from user-space because they lack the necessary privileges and hence only manifests itself as a reduction of the available virtual memory space (e.g. only 2 or 3 GiB accessible out of 4 GiB on 32-bit systems). Other operating systems (with OS X being the most popular desktop OS among them) have the entire virtual address space private to the process and the kernel runs in its own separate virtual memory space.
Executables on Windows (and most other OSes that implement virtual memory management) generally consists of different sections, with sections being grouped into segments. The executable file format is designed so that it can be loaded in memory by directly mapping parts of it into the virtual address space - a process know as memory mapping. Usually the section of the executable that contain program instructions (often named
Fortran COMMON blocks usually live in the
Windows DLLs have a feature known as "preferred base address". Whenever the OS loads such DLL, it tries to place it at the specified preferred base address. If it can not (e.g. parts of the required virtual address space are already occupied), then it relocates the library to a different base address. The reason for that behaviour is that DLL relocation is expensive on Windows since absolute addressing is used to access global symbols and addresses must be patched (fixed-up) by the loader whenever the library has to be relocated. In contrast, many Unix systems have their dynamic libraries as PICs (position-independent code) and those can be loaded at any base virtual address. But PIC code execute a bit slower than normal position-dependent code.
Older Windows versions have their most fundamental libraries like