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percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com> |
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README.mm |
Memory management for CRIS/MMU ------------------------------ HISTORY: $Log: README.mm,v $ Revision 1.1 2001/12/17 13:59:27 bjornw Initial revision Revision 1.1 2000/07/10 16:25:21 bjornw Initial revision Revision 1.4 2000/01/17 02:31:59 bjornw Added discussion of paging and VM. Revision 1.3 1999/12/03 16:43:23 hp Blurb about that the 3.5G-limitation is not a MMU limitation Revision 1.2 1999/12/03 16:04:21 hp Picky comment about not mapping the first page Revision 1.1 1999/12/03 15:41:30 bjornw First version of CRIS/MMU memory layout specification. ------------------------------ See the ETRAX-NG HSDD for reference. We use the page-size of 8 kbytes, as opposed to the i386 page-size of 4 kbytes. The MMU can, apart from the normal mapping of pages, also do a top-level segmentation of the kernel memory space. We use this feature to avoid having to use page-tables to map the physical memory into the kernel's address space. We also use it to keep the user-mode virtual mapping in the same map during kernel-mode, so that the kernel easily can access the corresponding user-mode process' data. As a comparision, the Linux/i386 2.0 puts the kernel and physical RAM at address 0, overlapping with the user-mode virtual space, so that descriptor registers are needed for each memory access to specify which MMU space to map through. That changed in 2.2, putting the kernel/physical RAM at 0xc0000000, to co-exist with the user-mode mapping. We will do something quite similar, but with the additional complexity of having to map the internal chip I/O registers and the flash memory area (including SRAM and peripherial chip-selets). The kernel-mode segmentation map: ------------------------ ------------------------ FFFFFFFF| | => cached | | | kernel seg_f | flash | | F0000000|______________________| | | EFFFFFFF| | => uncached | | | kernel seg_e | flash | | E0000000|______________________| | DRAM | DFFFFFFF| | paged to any | Un-cached | | kernel seg_d | =======> | | D0000000|______________________| | | CFFFFFFF| | | | | kernel seg_c |==\ | | C0000000|______________________| \ |______________________| BFFFFFFF| | uncached | | | kernel seg_b |=====\=========>| Registers | B0000000|______________________| \c |______________________| AFFFFFFF| | \a | | | | \c | FLASH/SRAM/Peripheral| | | \h |______________________| | | \e | | | | \d | | | kernel seg_0 - seg_a | \==>| DRAM | | | | Cached | | | paged to any | | | | =======> |______________________| | | | | | | | Illegal | | | |______________________| | | | | | | | FLASH/SRAM/Peripheral| 00000000|______________________| |______________________| In user-mode it looks the same except that only the space 0-AFFFFFFF is available. Therefore, in this model, the virtual address space per process is limited to 0xb0000000 bytes (minus 8192 bytes, since the first page, 0..8191, is never mapped, in order to trap NULL references). It also means that the total physical RAM that can be mapped is 256 MB (kseg_c above). More RAM can be mapped by choosing a different segmentation and shrinking the user-mode memory space. The MMU can map all 4 GB in user mode, but doing that would mean that a few extra instructions would be needed for each access to user mode memory. The kernel needs access to both cached and uncached flash. Uncached is necessary because of the special write/erase sequences. Also, the peripherial chip-selects are decoded from that region. The kernel also needs its own virtual memory space. That is kseg_d. It is used by the vmalloc() kernel function to allocate virtual contiguous chunks of memory not possible using the normal kmalloc physical RAM allocator. The setting of the actual MMU control registers to use this layout would be something like this: R_MMU_KSEG = ( ( seg_f, seg ) | // Flash cached ( seg_e, seg ) | // Flash uncached ( seg_d, page ) | // kernel vmalloc area ( seg_c, seg ) | // kernel linear segment ( seg_b, seg ) | // kernel linear segment ( seg_a, page ) | ( seg_9, page ) | ( seg_8, page ) | ( seg_7, page ) | ( seg_6, page ) | ( seg_5, page ) | ( seg_4, page ) | ( seg_3, page ) | ( seg_2, page ) | ( seg_1, page ) | ( seg_0, page ) ); R_MMU_KBASE_HI = ( ( base_f, 0x0 ) | // flash/sram/periph cached ( base_e, 0x8 ) | // flash/sram/periph uncached ( base_d, 0x0 ) | // don't care ( base_c, 0x4 ) | // physical RAM cached area ( base_b, 0xb ) | // uncached on-chip registers ( base_a, 0x0 ) | // don't care ( base_9, 0x0 ) | // don't care ( base_8, 0x0 ) ); // don't care R_MMU_KBASE_LO = ( ( base_7, 0x0 ) | // don't care ( base_6, 0x0 ) | // don't care ( base_5, 0x0 ) | // don't care ( base_4, 0x0 ) | // don't care ( base_3, 0x0 ) | // don't care ( base_2, 0x0 ) | // don't care ( base_1, 0x0 ) | // don't care ( base_0, 0x0 ) ); // don't care NOTE: while setting up the MMU, we run in a non-mapped mode in the DRAM (0x40 segment) and need to setup the seg_4 to a unity mapping, so that we don't get a fault before we have had time to jump into the real kernel segment (0xc0). This is done in head.S temporarily, but fixed by the kernel later in paging_init. Paging - PTE's, PMD's and PGD's ------------------------------- [ References: asm/pgtable.h, asm/page.h, asm/mmu.h ] The paging mechanism uses virtual addresses to split a process memory-space into pages, a page being the smallest unit that can be freely remapped in memory. On Linux/CRIS, a page is 8192 bytes (for technical reasons not equal to 4096 as in most other 32-bit architectures). It would be inefficient to let a virtual memory mapping be controlled by a long table of page mappings, so it is broken down into a 2-level structure with a Page Directory containing pointers to Page Tables which each have maps of up to 2048 pages (8192 / sizeof(void *)). Linux can actually handle 3-level structures as well, with a Page Middle Directory in between, but in many cases, this is folded into a two-level structure by excluding the Middle Directory. We'll take a look at how an address is translated while we discuss how it's handled in the Linux kernel. The example address is 0xd004000c; in binary this is: 31 23 15 7 0 11010000 00000100 00000000 00001100 |______| |__________||____________| PGD PTE page offset Given the top-level Page Directory, the offset in that directory is calculated using the upper 8 bits: static inline pgd_t * pgd_offset(struct mm_struct * mm, unsigned long address) { return mm->pgd + (address >> PGDIR_SHIFT); } PGDIR_SHIFT is the log2 of the amount of memory an entry in the PGD can map; in our case it is 24, corresponding to 16 MB. This means that each entry in the PGD corresponds to 16 MB of virtual memory. The pgd_t from our example will therefore be the 208'th (0xd0) entry in mm->pgd. Since the Middle Directory does not exist, it is a unity mapping: static inline pmd_t * pmd_offset(pgd_t * dir, unsigned long address) { return (pmd_t *) dir; } The Page Table provides the final lookup by using bits 13 to 23 as index: static inline pte_t * pte_offset(pmd_t * dir, unsigned long address) { return (pte_t *) pmd_page(*dir) + ((address >> PAGE_SHIFT) & (PTRS_PER_PTE - 1)); } PAGE_SHIFT is the log2 of the size of a page; 13 in our case. PTRS_PER_PTE is the number of pointers that fit in a Page Table and is used to mask off the PGD-part of the address. The so-far unused bits 0 to 12 are used to index inside a page linearily. The VM system ------------- The kernels own page-directory is the swapper_pg_dir, cleared in paging_init, and contains the kernels virtual mappings (the kernel itself is not paged - it is mapped linearily using kseg_c as described above). Architectures without kernel segments like the i386, need to setup swapper_pg_dir directly in head.S to map the kernel itself. swapper_pg_dir is pointed to by init_mm.pgd as the init-task's PGD. To see what support functions are used to setup a page-table, let's look at the kernel's internal paged memory system, vmalloc/vfree. void * vmalloc(unsigned long size) The vmalloc-system keeps a paged segment in kernel-space at 0xd0000000. What happens first is that a virtual address chunk is allocated to the request using get_vm_area(size). After that, physical RAM pages are allocated and put into the kernel's page-table using alloc_area_pages(addr, size). static int alloc_area_pages(unsigned long address, unsigned long size) First the PGD entry is found using init_mm.pgd. This is passed to alloc_area_pmd (remember the 3->2 folding). It uses pte_alloc_kernel to check if the PGD entry points anywhere - if not, a page table page is allocated and the PGD entry updated. Then the alloc_area_pte function is used just like alloc_area_pmd to check which page table entry is desired, and a physical page is allocated and the table entry updated. All of this is repeated at the top-level until the entire address range specified has been mapped.