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Rev | Author | Line No. | Line |
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119 | jermar | 1 | Memory management |
2 | ================= |
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3 | |||
703 | jermar | 4 | 1. Virtual Address Translation |
119 | jermar | 5 | |
703 | jermar | 6 | 1.1 Hierarchical 4-level per address space page tables |
119 | jermar | 7 | |
703 | jermar | 8 | SPARTAN kernel deploys generic interface for 4-level page tables |
9 | for these architectures: amd64, ia32, mips32 and ppc32. In this |
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10 | setting, page tables are hierarchical and are not shared by |
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11 | address spaces (i.e. one set of page tables per address space). |
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12 | |||
13 | |||
119 | jermar | 14 | VADDR |
15 | +-----------------------------------------------------------------------------+ |
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16 | | PTL0_INDEX | PTL1_INDEX | PTL2_INDEX | PTL3_INDEX | OFFSET | |
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17 | +-----------------------------------------------------------------------------+ |
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18 | |||
19 | |||
20 | PTL0 PTL1 PTL2 PTL3 |
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21 | +--------+ +--------+ +--------+ +--------+ |
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22 | | | | | | PTL3 | -----\ | | |
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23 | | | | | +--------+ | | | |
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24 | | | +--------+ | | | | | |
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25 | | | | PTL2 | -----\ | | | | | |
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26 | | | +--------+ | | | | | | |
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27 | | | | | | | | | +--------+ |
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28 | +--------+ | | | | | | | FRAME | |
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29 | | PTL1 | -----\ | | | | | | +--------+ |
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30 | +--------+ | | | | | | | | | |
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31 | | | | | | | | | | | | |
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32 | | | | | | | | | | | | |
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33 | +--------+ \----> +--------+ \----> +--------+ \----> +--------+ |
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34 | ^ |
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35 | | |
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36 | | |
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37 | +--------+ |
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38 | | PTL0 | |
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39 | +--------+ |
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40 | |||
41 | |||
42 | PTL0 Page Table Level 0 (Page Directory) |
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43 | PTL1 Page Table Level 1 |
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44 | PTL2 Page Table Level 2 |
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45 | PTL3 Page Table Level 3 |
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46 | |||
47 | PTL0_INDEX Index into PTL0 |
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48 | PTL1_INDEX Index into PTL1 |
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49 | PTL2_INDEX Index into PTL2 |
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50 | PTL3_INDEX Index into PTL3 |
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51 | |||
52 | VADDR Virtual address for which mapping is looked up |
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53 | FRAME Physical address of memory frame to which VADDR is mapped |
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54 | |||
55 | |||
56 | On architectures whose hardware has fewer levels, PTL2 and, if need be, PTL1 are |
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57 | left out. TLB-only architectures are to define custom format for software page |
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58 | tables. |
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703 | jermar | 59 | |
60 | 1.2 Single global page hash table |
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61 | |||
62 | Generic page hash table interface is deployed on 64-bit architectures without |
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63 | implied hardware support for hierarchical page tables, i.e. ia64 and sparc64. |
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64 | There is only one global page hash table in the system shared by all address |
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65 | spaces. |
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822 | palkovsky | 66 | |
1297 | jermar | 67 | |
68 | 2. Memory allocators |
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69 | |||
822 | palkovsky | 70 | 2.1 General allocator |
71 | |||
72 | 'malloc' function accepts flags as a second argument. The flags are directly |
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73 | passed to the underlying frame_alloc function. |
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74 | |||
75 | 1) If the flags parameter contains FRAME_ATOMIC, the allocator will not sleep. |
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76 | The allocator CAN return NULL, when memory is not directly available. |
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77 | The caller MUST check if NULL was not returned |
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78 | |||
79 | 2) If the flags parameter does not contain FRAME_ATOMIC, the allocator |
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80 | will never return NULL, but it CAN sleep indefinitely. The caller |
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81 | does not have to check the return value. |
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82 | |||
1950 | jermar | 83 | 3) The maximum size that can be allocated using malloc is 256K |
822 | palkovsky | 84 | |
85 | Rules 1) and 2) apply to slab_alloc as well. Using SLAB allocator |
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86 | to allocate too large values is not recommended. |
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87 |