Is linux kernel allocating memory consecutively, e.g from
malloc ? If there's no big part available, but smaller part in pieces that works as a total, will Linux use that ?
I AM ASSUMING THAT IN THE QUESTION BY CONSECUTIVE YOU ARE REFERRING TO PHYSICAL MEMORY.
All the address that you see as a process executes.Ex when you use gdb or addr2line are all virtual address,mapping to physical memory stays under the hood.
The MMU doesn't immediately allocate 10 pages worth memory on physical memory,instead new entries(10 in this case) are added to the invoking process's address space i.e entries are added in the page table of this process (this virtual memory will be contiguous i.e 10 * 4096 bytes of memory but in virtual 4gb of that process).
Now assume later in the execution the process tries to save or use this new allocated memory ,at that time a page fault is invoked as a process touched unallocated memory, now the mmu allocates an actual physical page(4096 continuous btyes) on RAM and updates the page table then allowing the execution of process to continue.
So we can be sure that only 4096 bytes out of 40960 bytes are contigous in physical memory (RAM), but the entire 40960 (10 pages) appears as continuous in the virtual memory.All the 10 pages may be paged to 10 pages in RAM at 10 scattered 4096 blocks/frame/page.
Virtual Memory hides this and presents a clean continuous 4gb (usually) of memory to a process.MMU uses page table to provide a backend support by mapping virtual to physical memory.
I believe that the physical mapping of the allocated memory can be non-contiguous using malloc() and really is the OS' responsibility. It may or may not be contiguous.
A function comes to mind named kmalloc() which will allocate contiguous 'physical' memory, if available.
In linux kernel, memory allocation is done using kmalloc or vmalloc. kmalloc allocates physically contiguous memories while vmalloc allocates physically non-contiguous memories. Both kmalloc and vmalloc will give you contiguous virtual memory space. This is done using page tables.