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Line 44... Line 44...
44 
#include <arch/types.h>
 44 
#include <arch/types.h>
45 
#include <typedefs.h>
 45 
#include <typedefs.h>
46 
#include <arch/asm.h>
 46 
#include <arch/asm.h>
47 
#include <memstr.h>
 47 
#include <memstr.h>
48 
 
 48 
 
49 
static void pt_mapping_insert(as_t *as, __address page, __address frame, int flags);
 49 
static void pt_mapping_insert(as_t *as, uintptr_t page, uintptr_t frame, int flags);
50 
static void pt_mapping_remove(as_t *as, __address page);
 50 
static void pt_mapping_remove(as_t *as, uintptr_t page);
51 
static pte_t *pt_mapping_find(as_t *as, __address page);
 51 
static pte_t *pt_mapping_find(as_t *as, uintptr_t page);
52 
 
 52 
 
53 
page_mapping_operations_t pt_mapping_operations = {
 53 
page_mapping_operations_t pt_mapping_operations = {
54 
    .mapping_insert = pt_mapping_insert,
 54 
    .mapping_insert = pt_mapping_insert,
55 
    .mapping_remove = pt_mapping_remove,
 55 
    .mapping_remove = pt_mapping_remove,
56 
    .mapping_find = pt_mapping_find
 56 
    .mapping_find = pt_mapping_find
Line 66... Line 66...
66 
 * @param as Address space to wich page belongs.
 66 
 * @param as Address space to wich page belongs.
67 
 * @param page Virtual address of the page to be mapped.
 67 
 * @param page Virtual address of the page to be mapped.
68 
 * @param frame Physical address of memory frame to which the mapping is done.
 68 
 * @param frame Physical address of memory frame to which the mapping is done.
69 
 * @param flags Flags to be used for mapping.
 69 
 * @param flags Flags to be used for mapping.
70 
 */
 70 
 */
71 
void pt_mapping_insert(as_t *as, __address page, __address frame, int flags)
 71 
void pt_mapping_insert(as_t *as, uintptr_t page, uintptr_t frame, int flags)
72 
{
 72 
{
73 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
 73 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
74 
    pte_t *newpt;
 74 
    pte_t *newpt;
75 
 
 75 
 
76 
    ptl0 = (pte_t *) PA2KA((__address) as->page_table);
 76 
    ptl0 = (pte_t *) PA2KA((uintptr_t) as->page_table);
77 
 
 77 
 
78 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT) {
 78 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT) {
79 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
 79 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
80 
        memsetb((__address)newpt, PAGE_SIZE, 0);
 80 
        memsetb((uintptr_t)newpt, PAGE_SIZE, 0);
81 
        SET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page), KA2PA(newpt));
 81 
        SET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page), KA2PA(newpt));
82 
        SET_PTL1_FLAGS(ptl0, PTL0_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
 82 
        SET_PTL1_FLAGS(ptl0, PTL0_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
83 
    }
 83 
    }
84 
 
 84 
 
85 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));
 85 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));
86 
 
 86 
 
87 
    if (GET_PTL2_FLAGS(ptl1, PTL1_INDEX(page)) & PAGE_NOT_PRESENT) {
 87 
    if (GET_PTL2_FLAGS(ptl1, PTL1_INDEX(page)) & PAGE_NOT_PRESENT) {
88 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
 88 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
89 
        memsetb((__address)newpt, PAGE_SIZE, 0);
 89 
        memsetb((uintptr_t)newpt, PAGE_SIZE, 0);
90 
        SET_PTL2_ADDRESS(ptl1, PTL1_INDEX(page), KA2PA(newpt));
 90 
        SET_PTL2_ADDRESS(ptl1, PTL1_INDEX(page), KA2PA(newpt));
91 
        SET_PTL2_FLAGS(ptl1, PTL1_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
 91 
        SET_PTL2_FLAGS(ptl1, PTL1_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
92 
    }
 92 
    }
93 
 
 93 
 
94 
    ptl2 = (pte_t *) PA2KA(GET_PTL2_ADDRESS(ptl1, PTL1_INDEX(page)));
 94 
    ptl2 = (pte_t *) PA2KA(GET_PTL2_ADDRESS(ptl1, PTL1_INDEX(page)));
95 
 
 95 
 
96 
    if (GET_PTL3_FLAGS(ptl2, PTL2_INDEX(page)) & PAGE_NOT_PRESENT) {
 96 
    if (GET_PTL3_FLAGS(ptl2, PTL2_INDEX(page)) & PAGE_NOT_PRESENT) {
97 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
 97 
        newpt = (pte_t *)frame_alloc(ONE_FRAME, FRAME_KA);
98 
        memsetb((__address)newpt, PAGE_SIZE, 0);
 98 
        memsetb((uintptr_t)newpt, PAGE_SIZE, 0);
99 
        SET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page), KA2PA(newpt));
 99 
        SET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page), KA2PA(newpt));
100 
        SET_PTL3_FLAGS(ptl2, PTL2_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
 100 
        SET_PTL3_FLAGS(ptl2, PTL2_INDEX(page), PAGE_PRESENT | PAGE_USER | PAGE_EXEC | PAGE_CACHEABLE | PAGE_WRITE);
101 
    }
 101 
    }
102 
 
 102 
 
103 
    ptl3 = (pte_t *) PA2KA(GET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page)));
 103 
    ptl3 = (pte_t *) PA2KA(GET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page)));
Line 117... Line 117...
117 
 * The page table must be locked and interrupts must be disabled.
 117 
 * The page table must be locked and interrupts must be disabled.
118 
 *
 118 
 *
119 
 * @param as Address space to wich page belongs.
 119 
 * @param as Address space to wich page belongs.
120 
 * @param page Virtual address of the page to be demapped.
 120 
 * @param page Virtual address of the page to be demapped.
121 
 */
 121 
 */
122 
void pt_mapping_remove(as_t *as, __address page)
 122 
void pt_mapping_remove(as_t *as, uintptr_t page)
123 
{
 123 
{
124 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
 124 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
125 
    bool empty = true;
 125 
    bool empty = true;
126 
    int i;
 126 
    int i;
127 
 
 127 
 
128 
    /*
 128 
    /*
129 
     * First, remove the mapping, if it exists.
 129 
     * First, remove the mapping, if it exists.
130 
     */
 130 
     */
131 
 
 131 
 
132 
    ptl0 = (pte_t *) PA2KA((__address) as->page_table);
 132 
    ptl0 = (pte_t *) PA2KA((uintptr_t) as->page_table);
133 
 
 133 
 
134 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT)
 134 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT)
135 
        return;
 135 
        return;
136 
 
 136 
 
137 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));
 137 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));
Line 145... Line 145...
145 
        return;
 145 
        return;
146 
 
 146 
 
147 
    ptl3 = (pte_t *) PA2KA(GET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page)));
 147 
    ptl3 = (pte_t *) PA2KA(GET_PTL3_ADDRESS(ptl2, PTL2_INDEX(page)));
148 
 
 148 
 
149 
    /* Destroy the mapping. Setting to PAGE_NOT_PRESENT is not sufficient. */
 149 
    /* Destroy the mapping. Setting to PAGE_NOT_PRESENT is not sufficient. */
150 
    memsetb((__address) &ptl3[PTL3_INDEX(page)], sizeof(pte_t), 0);
 150 
    memsetb((uintptr_t) &ptl3[PTL3_INDEX(page)], sizeof(pte_t), 0);
151 
 
 151 
 
152 
    /*
 152 
    /*
153 
     * Second, free all empty tables along the way from PTL3 down to PTL0.
 153 
     * Second, free all empty tables along the way from PTL3 down to PTL0.
154 
     */
 154 
     */
155 
   
 155 
   
Line 163... Line 163...
163 
    if (empty) {
 163 
    if (empty) {
164 
        /*
 164 
        /*
165 
         * PTL3 is empty.
 165 
         * PTL3 is empty.
166 
         * Release the frame and remove PTL3 pointer from preceding table.
 166 
         * Release the frame and remove PTL3 pointer from preceding table.
167 
         */
 167 
         */
168 
        frame_free(KA2PA((__address) ptl3));
 168 
        frame_free(KA2PA((uintptr_t) ptl3));
169 
        if (PTL2_ENTRIES)
 169 
        if (PTL2_ENTRIES)
170 
            memsetb((__address) &ptl2[PTL2_INDEX(page)], sizeof(pte_t), 0);
 170 
            memsetb((uintptr_t) &ptl2[PTL2_INDEX(page)], sizeof(pte_t), 0);
171 
        else if (PTL1_ENTRIES)
 171 
        else if (PTL1_ENTRIES)
172 
            memsetb((__address) &ptl1[PTL1_INDEX(page)], sizeof(pte_t), 0);
 172 
            memsetb((uintptr_t) &ptl1[PTL1_INDEX(page)], sizeof(pte_t), 0);
173 
        else
 173 
        else
174 
            memsetb((__address) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
 174 
            memsetb((uintptr_t) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
175 
    } else {
 175 
    } else {
176 
        /*
 176 
        /*
177 
         * PTL3 is not empty.
 177 
         * PTL3 is not empty.
178 
         * Therefore, there must be a path from PTL0 to PTL3 and
 178 
         * Therefore, there must be a path from PTL0 to PTL3 and
179 
         * thus nothing to free in higher levels.
 179 
         * thus nothing to free in higher levels.
Line 192... Line 192...
192 
        if (empty) {
 192 
        if (empty) {
193 
            /*
 193 
            /*
194 
             * PTL2 is empty.
 194 
             * PTL2 is empty.
195 
             * Release the frame and remove PTL2 pointer from preceding table.
 195 
             * Release the frame and remove PTL2 pointer from preceding table.
196 
             */
 196 
             */
197 
            frame_free(KA2PA((__address) ptl2));
 197 
            frame_free(KA2PA((uintptr_t) ptl2));
198 
            if (PTL1_ENTRIES)
 198 
            if (PTL1_ENTRIES)
199 
                memsetb((__address) &ptl1[PTL1_INDEX(page)], sizeof(pte_t), 0);
 199 
                memsetb((uintptr_t) &ptl1[PTL1_INDEX(page)], sizeof(pte_t), 0);
200 
            else
 200 
            else
201 
                memsetb((__address) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
 201 
                memsetb((uintptr_t) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
202 
        }
 202 
        }
203 
        else {
 203 
        else {
204 
            /*
 204 
            /*
205 
             * PTL2 is not empty.
 205 
             * PTL2 is not empty.
206 
             * Therefore, there must be a path from PTL0 to PTL2 and
 206 
             * Therefore, there must be a path from PTL0 to PTL2 and
Line 221... Line 221...
221 
        if (empty) {
 221 
        if (empty) {
222 
            /*
 222 
            /*
223 
             * PTL1 is empty.
 223 
             * PTL1 is empty.
224 
             * Release the frame and remove PTL1 pointer from preceding table.
 224 
             * Release the frame and remove PTL1 pointer from preceding table.
225 
             */
 225 
             */
226 
            frame_free(KA2PA((__address) ptl1));
 226 
            frame_free(KA2PA((uintptr_t) ptl1));
227 
            memsetb((__address) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
 227 
            memsetb((uintptr_t) &ptl0[PTL0_INDEX(page)], sizeof(pte_t), 0);
228 
        }
 228 
        }
229 
    }
 229 
    }
230 
 
 230 
 
231 
}
 231 
}
232 
 
 232 
 
Line 239... Line 239...
239 
 * @param as Address space to which page belongs.
 239 
 * @param as Address space to which page belongs.
240 
 * @param page Virtual page.
 240 
 * @param page Virtual page.
241 
 *
 241 
 *
242 
 * @return NULL if there is no such mapping; entry from PTL3 describing the mapping otherwise.
 242 
 * @return NULL if there is no such mapping; entry from PTL3 describing the mapping otherwise.
243 
 */
 243 
 */
244 
pte_t *pt_mapping_find(as_t *as, __address page)
 244 
pte_t *pt_mapping_find(as_t *as, uintptr_t page)
245 
{
 245 
{
246 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
 246 
    pte_t *ptl0, *ptl1, *ptl2, *ptl3;
247 
 
 247 
 
248 
    ptl0 = (pte_t *) PA2KA((__address) as->page_table);
 248 
    ptl0 = (pte_t *) PA2KA((uintptr_t) as->page_table);
249 
 
 249 
 
250 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT)
 250 
    if (GET_PTL1_FLAGS(ptl0, PTL0_INDEX(page)) & PAGE_NOT_PRESENT)
251 
        return NULL;
 251 
        return NULL;
252 
 
 252 
 
253 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));
 253 
    ptl1 = (pte_t *) PA2KA(GET_PTL1_ADDRESS(ptl0, PTL0_INDEX(page)));