(The possible solution to your problem is the last paragraph)
Memory allocation on most modern operating systems with virtual memory is a two-phase process. First, a portion of the virtual address space of the process is reserved and the virtual memory size of the process (
VmSize) increases accordingly. This creates entries in the so-called process page table. Pages are initially not associated with phyiscal memory frames, i.e. no physical memory is actually used. Whenever some part of this allocated portion is actually read from or written to, a page fault occurs and the operating system installs (maps) a free page from the physical memory. This increases the resident set size of the process (
VmRSS). When some other process needs memory, the OS might store the content of some infrequently used page (the definition of "infrequently used page" is highly implementation-dependent) to some persistent storage (hard drive in most cases, or generally to the swap device) and then unmap up. This process decreases the RSS but leaves
VmSize intact. If this page is later accessed, a page fault would again occur and it will be brought back. The virutal memory size only decreases when virtual memory allocations are freed. Note that
VmSize also counts for memory mapped files (i.e. the executable file and all shared libraries it links to or other explicitly mapped files) and shared memory blocks.
There are two generic types of memory in a process - statically allocated memory and heap memory. The statically allocated memory keeps all constants and global/static variables. It is part of the data segment, whose size is shown by the
VmData metric. The data segment also hosts part of the program heap, where dynamic memory is being allocated. The data segment is continuous, i.e. it starts at a certain location and grows upwards towards the stack (which starts at a very high address and then grows downwards). The problem with the heap in the data segment is that it is managed by a special heap allocator that takes care of subdividing the contiguous data segment into smaller memory chunks. On the other side, in Linux dynamic memory can also be allocated by directly mapping virtual memory. This is usually done only for large allocations in order to conserve memory, since it only allows memory in multiples of the page size (usually 4 KiB) to be allocated.
The stack is also an important source of heavy memory usage, especially if big arrays are allocated in the automatic (stack) storage. The stack starts near the very top of the usable virtual address space and grows downwards. In some cases it could reach the top of the data segment or it could reach the end of some other virtual allocation. Bad things happen then. The stack size is accounted in the
VmStack metric and also in the
One can summarise it as so:
VmSize accounts for all virtual memory allocations (file mappings, shared memory, heap memory, whatever memory) and grows almost every time new memory is being allocated. Almost, because if the new heap memory allocation is made in the place of a freed old allocation in the data segment, no new virtual memory would be allocated. It decreses whenever virtual allocations are being freed.
VmPeak tracks the max value of
VmSize - it could only increase in time.
VmRSS grows as memory is being accessed and decreases as memory is paged out to the swap device.
VmData grows as the data segment part of the heap is being utilised. It almost never shrinks as current heap allocators keep the freed memory in case future allocations need it.
If you are running on a cluster with InfiniBand or other RDMA-based fabrics, another kind of memory comes into play - the locked (registered) memory (
VmLck). This is memory which is not allowed to be paged out. How it grows and shrinks depends on the MPI implementation. Some never unregister an already registered block (the technical details about why are too complex to be described here), others do so in order to play better with the virtual memory manager.
In your case you say that you are running into a virtual memory size limit. This could mean that this limit is set too low or that you are running into an OS-imposed limits. First, Linux (and most Unixes) have means to impose artificial restrictions through the
ulimit mechanism. Running
ulimit -v in the shell would tell you what the limit on the virtual memory size is in KiB. You can set the limit using
ulimit -v <value in KiB>. This only applies to processes spawned by the current shell and to their children, grandchilren and so on. You need to instruct
mpirun) to propagate this value to all other processes, if they are to be launched on remote nodes. if you are running your program under the control of some workload manager like LSF, Sun/Oracle Grid Engine, Torque/PBS, etc., there are job parameters which control the virtual memory size limit. And last but not least, 32-bit processes are usually restricted to 2 GiB of usable virtual memory.