[NTOSKRNL] Define the Mm global variables related to Cc on Mm init.
[reactos.git] / ntoskrnl / include / internal / i386 / mm.h
1 /*
2 * kernel internal memory management definitions for x86
3 */
4 #pragma once
5
6 #ifdef _PAE_
7 #define _MI_PAGING_LEVELS 3
8 #else
9 #define _MI_PAGING_LEVELS 2
10 #endif
11
12 /* Memory layout base addresses */
13 #define MI_USER_PROBE_ADDRESS (PVOID)0x7FFF0000
14 #define MI_DEFAULT_SYSTEM_RANGE_START (PVOID)0x80000000
15 #ifndef PAE
16 #define HYPER_SPACE 0xC0400000
17 #define HYPER_SPACE_END 0xC07FFFFF
18 #else
19 #define HYPER_SPACE 0xC0800000
20 #define HYPER_SPACE_END 0xC0BFFFFF
21 #endif
22 #define MI_SYSTEM_CACHE_WS_START (PVOID)0xC0C00000
23 #define MI_SYSTEM_CACHE_START (PVOID)0xC1000000
24 #define MI_PAGED_POOL_START (PVOID)0xE1000000
25 #define MI_NONPAGED_POOL_END (PVOID)0xFFBE0000
26 #define MI_DEBUG_MAPPING (PVOID)0xFFBFF000
27 #define MI_HIGHEST_SYSTEM_ADDRESS (PVOID)0xFFFFFFFF
28
29 /* FIXME: These are different for PAE */
30 #define PTE_BASE 0xC0000000
31 #define PDE_BASE 0xC0300000
32 #define PDE_TOP 0xC0300FFF
33 #define PTE_TOP 0xC03FFFFF
34
35 #define PTE_PER_PAGE 0x400
36 #define PDE_PER_PAGE 0x400
37 #define PPE_PER_PAGE 1
38
39 /* Misc address definitions */
40 #define MI_SYSTEM_PTE_BASE (PVOID)MiAddressToPte(NULL)
41 #define MM_HIGHEST_VAD_ADDRESS \
42 (PVOID)((ULONG_PTR)MM_HIGHEST_USER_ADDRESS - (16 * PAGE_SIZE))
43 #define MI_MAPPING_RANGE_START (ULONG)HYPER_SPACE
44 #define MI_MAPPING_RANGE_END (MI_MAPPING_RANGE_START + \
45 MI_HYPERSPACE_PTES * PAGE_SIZE)
46 #define MI_DUMMY_PTE (PMMPTE)((ULONG_PTR)MI_MAPPING_RANGE_END + \
47 PAGE_SIZE)
48 #define MI_VAD_BITMAP (PMMPTE)((ULONG_PTR)MI_DUMMY_PTE + \
49 PAGE_SIZE)
50 #define MI_WORKING_SET_LIST (PMMPTE)((ULONG_PTR)MI_VAD_BITMAP + \
51 PAGE_SIZE)
52
53 /* Memory sizes */
54 #define MI_MIN_PAGES_FOR_NONPAGED_POOL_TUNING ((255 * _1MB) >> PAGE_SHIFT)
55 #define MI_MIN_PAGES_FOR_SYSPTE_TUNING ((19 * _1MB) >> PAGE_SHIFT)
56 #define MI_MIN_PAGES_FOR_SYSPTE_BOOST ((32 * _1MB) >> PAGE_SHIFT)
57 #define MI_MIN_PAGES_FOR_SYSPTE_BOOST_BOOST ((256 * _1MB) >> PAGE_SHIFT)
58 #define MI_MIN_INIT_PAGED_POOLSIZE (32 * _1MB)
59 #define MI_MAX_INIT_NONPAGED_POOL_SIZE (128 * _1MB)
60 #define MI_MAX_NONPAGED_POOL_SIZE (128 * _1MB)
61 #define MI_SYSTEM_VIEW_SIZE (32 * _1MB)
62 #define MI_SESSION_VIEW_SIZE (48 * _1MB)
63 #define MI_SESSION_POOL_SIZE (16 * _1MB)
64 #define MI_SESSION_IMAGE_SIZE (8 * _1MB)
65 #define MI_SESSION_WORKING_SET_SIZE (4 * _1MB)
66 #define MI_SESSION_SIZE (MI_SESSION_VIEW_SIZE + \
67 MI_SESSION_POOL_SIZE + \
68 MI_SESSION_IMAGE_SIZE + \
69 MI_SESSION_WORKING_SET_SIZE)
70 #define MI_MIN_ALLOCATION_FRAGMENT (4 * _1KB)
71 #define MI_ALLOCATION_FRAGMENT (64 * _1KB)
72 #define MI_MAX_ALLOCATION_FRAGMENT (2 * _1MB)
73
74 /* Misc constants */
75 #define MM_PTE_SOFTWARE_PROTECTION_BITS 5
76 #define MI_MIN_SECONDARY_COLORS 8
77 #define MI_SECONDARY_COLORS 64
78 #define MI_MAX_SECONDARY_COLORS 1024
79 #define MI_MAX_FREE_PAGE_LISTS 4
80 #define MI_HYPERSPACE_PTES (256 - 1)
81 #define MI_ZERO_PTES (32)
82 #define MI_MAX_ZERO_BITS 21
83 #define SESSION_POOL_LOOKASIDES 26
84
85 /* MMPTE related defines */
86 #define MM_EMPTY_PTE_LIST ((ULONG)0xFFFFF)
87 #define MM_EMPTY_LIST ((ULONG_PTR)-1)
88
89
90 /* Easy accessing PFN in PTE */
91 #define PFN_FROM_PTE(v) ((v)->u.Hard.PageFrameNumber)
92
93 /* Macros for portable PTE modification */
94 #define MI_MAKE_DIRTY_PAGE(x) ((x)->u.Hard.Dirty = 1)
95 #define MI_MAKE_CLEAN_PAGE(x) ((x)->u.Hard.Dirty = 0)
96 #define MI_MAKE_ACCESSED_PAGE(x) ((x)->u.Hard.Accessed = 1)
97 #define MI_PAGE_DISABLE_CACHE(x) ((x)->u.Hard.CacheDisable = 1)
98 #define MI_PAGE_WRITE_THROUGH(x) ((x)->u.Hard.WriteThrough = 1)
99 #define MI_PAGE_WRITE_COMBINED(x) ((x)->u.Hard.WriteThrough = 0)
100 #define MI_IS_PAGE_LARGE(x) ((x)->u.Hard.LargePage == 1)
101 #if !defined(CONFIG_SMP)
102 #define MI_IS_PAGE_WRITEABLE(x) ((x)->u.Hard.Write == 1)
103 #else
104 #define MI_IS_PAGE_WRITEABLE(x) ((x)->u.Hard.Writable == 1)
105 #endif
106 #define MI_IS_PAGE_COPY_ON_WRITE(x)((x)->u.Hard.CopyOnWrite == 1)
107 #ifdef _PAE_
108 #define MI_IS_PAGE_EXECUTABLE(x) ((x)->u.Hard.NoExecute == 0)
109 #else
110 #define MI_IS_PAGE_EXECUTABLE(x) TRUE
111 #endif
112 #define MI_IS_PAGE_DIRTY(x) ((x)->u.Hard.Dirty == 1)
113 #define MI_MAKE_OWNER_PAGE(x) ((x)->u.Hard.Owner = 1)
114 #if !defined(CONFIG_SMP)
115 #define MI_MAKE_WRITE_PAGE(x) ((x)->u.Hard.Write = 1)
116 #else
117 #define MI_MAKE_WRITE_PAGE(x) ((x)->u.Hard.Writable = 1)
118 #endif
119
120
121 /* Macros to identify the page fault reason from the error code */
122 #define MI_IS_NOT_PRESENT_FAULT(FaultCode) !BooleanFlagOn(FaultCode, 0x1)
123 #define MI_IS_WRITE_ACCESS(FaultCode) BooleanFlagOn(FaultCode, 0x2)
124 #define MI_IS_INSTRUCTION_FETCH(FaultCode) BooleanFlagOn(FaultCode, 0x10)
125
126 /* On x86, these two are the same */
127 #define MI_WRITE_VALID_PPE MI_WRITE_VALID_PTE
128
129 /* Convert an address to a corresponding PTE */
130 #define MiAddressToPte(x) \
131 ((PMMPTE)(((((ULONG)(x)) >> 12) << 2) + PTE_BASE))
132
133 /* Convert an address to a corresponding PDE */
134 #define MiAddressToPde(x) \
135 ((PMMPDE)(((((ULONG)(x)) >> 22) << 2) + PDE_BASE))
136
137 /* Convert an address to a corresponding PTE offset/index */
138 #define MiAddressToPteOffset(x) \
139 ((((ULONG)(x)) << 10) >> 22)
140
141 /* Convert an address to a corresponding PDE offset/index */
142 #define MiAddressToPdeOffset(x) \
143 (((ULONG)(x)) / (1024 * PAGE_SIZE))
144 #define MiGetPdeOffset MiAddressToPdeOffset
145
146 /* Convert a PTE/PDE into a corresponding address */
147 #define MiPteToAddress(_Pte) ((PVOID)((ULONG)(_Pte) << 10))
148 #define MiPdeToAddress(_Pde) ((PVOID)((ULONG)(_Pde) << 20))
149
150 /* Translate between P*Es */
151 #define MiPdeToPte(_Pde) ((PMMPTE)MiPteToAddress(_Pde))
152 #define MiPteToPde(_Pte) ((PMMPDE)MiAddressToPte(_Pte))
153
154 /* Check P*E boundaries */
155 #define MiIsPteOnPdeBoundary(PointerPte) \
156 ((((ULONG_PTR)PointerPte) & (PAGE_SIZE - 1)) == 0)
157
158 //
159 // Decodes a Prototype PTE into the underlying PTE
160 //
161 #define MiProtoPteToPte(x) \
162 (PMMPTE)((ULONG_PTR)MmPagedPoolStart + \
163 (((x)->u.Proto.ProtoAddressHigh << 9) | (x)->u.Proto.ProtoAddressLow << 2))
164
165 //
166 // Decodes a Prototype PTE into the underlying PTE
167 //
168 #define MiSubsectionPteToSubsection(x) \
169 ((x)->u.Subsect.WhichPool == PagedPool) ? \
170 (PMMPTE)((ULONG_PTR)MmSubsectionBase + \
171 (((x)->u.Subsect.SubsectionAddressHigh << 7) | \
172 (x)->u.Subsect.SubsectionAddressLow << 3)) : \
173 (PMMPTE)((ULONG_PTR)MmNonPagedPoolEnd - \
174 (((x)->u.Subsect.SubsectionAddressHigh << 7) | \
175 (x)->u.Subsect.SubsectionAddressLow << 3))