pte.h revision 1.4
1 1.4 matt /* $NetBSD: pte.h,v 1.4 2011/06/23 01:27:20 matt Exp $ */ 2 1.1 matt /*- 3 1.2 matt * Copyright (c) 2010, 2011 The NetBSD Foundation, Inc. 4 1.1 matt * All rights reserved. 5 1.1 matt * 6 1.1 matt * This code is derived from software contributed to The NetBSD Foundation 7 1.2 matt * by Raytheon BBN Technologies Corp and Defense Advanced Research Projects 8 1.2 matt * Agency and which was developed by Matt Thomas of 3am Software Foundry. 9 1.2 matt * 10 1.2 matt * This material is based upon work supported by the Defense Advanced Research 11 1.2 matt * Projects Agency and Space and Naval Warfare Systems Center, Pacific, under 12 1.2 matt * Contract No. N66001-09-C-2073. 13 1.2 matt * Approved for Public Release, Distribution Unlimited 14 1.1 matt * 15 1.1 matt * Redistribution and use in source and binary forms, with or without 16 1.1 matt * modification, are permitted provided that the following conditions 17 1.1 matt * are met: 18 1.1 matt * 1. Redistributions of source code must retain the above copyright 19 1.1 matt * notice, this list of conditions and the following disclaimer. 20 1.1 matt * 2. Redistributions in binary form must reproduce the above copyright 21 1.1 matt * notice, this list of conditions and the following disclaimer in the 22 1.1 matt * documentation and/or other materials provided with the distribution. 23 1.1 matt * 24 1.1 matt * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 25 1.1 matt * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 26 1.1 matt * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 27 1.1 matt * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 28 1.1 matt * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 29 1.1 matt * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 30 1.1 matt * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 31 1.1 matt * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 32 1.1 matt * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 33 1.1 matt * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 34 1.1 matt * POSSIBILITY OF SUCH DAMAGE. 35 1.1 matt */ 36 1.1 matt 37 1.1 matt #ifndef _POWERPC_BOOKE_PTE_H_ 38 1.1 matt #define _POWERPC_BOOKE_PTE_H_ 39 1.1 matt 40 1.1 matt #ifndef _LOCORE 41 1.4 matt #ifndef __BSD_PT_ENTRY_T 42 1.4 matt #define __BSD_PT_ENTRY_T __uint32_t 43 1.4 matt typedef __BSD_PT_ENTRY_T pt_entry_t; 44 1.4 matt #endif 45 1.1 matt #endif 46 1.1 matt 47 1.2 matt #include <powerpc/booke/spr.h> 48 1.2 matt 49 1.1 matt /* 50 1.1 matt * The PTE format is software and must be translated into the various portions 51 1.1 matt * X W R are separted by single bits so that they can map to the MAS2 bits 52 1.1 matt * UX/UW/UR or SX/SW/SR by a mask and a shift. 53 1.1 matt */ 54 1.2 matt #define PTE_IO (PTE_I|PTE_G|PTE_xW|PTE_xR) 55 1.2 matt #define PTE_DEFAULT (PTE_M|PTE_xX|PTE_xW|PTE_xR) 56 1.2 matt #define PTE_MAS3_MASK (MAS3_RPN|MAS3_U2|MAS3_U0) 57 1.1 matt #define PTE_MAS2_MASK (MAS2_WIMGE) 58 1.1 matt #define PTE_RPN_MASK MAS3_RPN /* MAS3[RPN] */ 59 1.1 matt #define PTE_RWX_MASK (PTE_xX|PTE_xW|PTE_xR) 60 1.1 matt #define PTE_WIRED (MAS3_U0 << 2) /* page is wired (PTE only) */ 61 1.1 matt #define PTE_xX (MAS3_U0 << 1) /* MAS2[UX] | MAS2[SX] */ 62 1.1 matt #define PTE_UNSYNCED MAS3_U0 /* page needs isync */ 63 1.1 matt #define PTE_xW MAS3_U1 /* MAS2[UW] | MAS2[SW] */ 64 1.1 matt #define PTE_UNMODIFIED MAS3_U2 /* page is unmodified */ 65 1.1 matt #define PTE_xR MAS3_U3 /* MAS2[UR] | MAS2[SR] */ 66 1.2 matt #define PTE_RWX_SHIFT 6 67 1.2 matt #define PTE_UNUSED 0x00000020 68 1.1 matt #define PTE_WIMGE_MASK MAS2_WIMGE 69 1.2 matt #define PTE_WIG (PTE_W|PTE_I|PTE_G) 70 1.1 matt #define PTE_W MAS2_W /* Write-through */ 71 1.1 matt #define PTE_I MAS2_I /* cache-Inhibited */ 72 1.1 matt #define PTE_M MAS2_M /* Memory coherence */ 73 1.1 matt #define PTE_G MAS2_G /* Guarded */ 74 1.1 matt #define PTE_E MAS2_E /* [Little] Endian */ 75 1.1 matt 76 1.2 matt #ifndef _LOCORE 77 1.2 matt #ifdef _KERNEL 78 1.2 matt 79 1.2 matt static inline bool 80 1.2 matt pte_cached_p(pt_entry_t pt_entry) 81 1.2 matt { 82 1.2 matt return (pt_entry & PTE_I) == 0; 83 1.2 matt } 84 1.2 matt 85 1.2 matt static inline bool 86 1.2 matt pte_modified_p(pt_entry_t pt_entry) 87 1.2 matt { 88 1.2 matt return (pt_entry & (PTE_UNMODIFIED|PTE_xW)) == PTE_xW; 89 1.2 matt } 90 1.2 matt 91 1.2 matt static inline bool 92 1.2 matt pte_valid_p(pt_entry_t pt_entry) 93 1.2 matt { 94 1.2 matt return pt_entry != 0; 95 1.2 matt } 96 1.2 matt 97 1.2 matt static inline bool 98 1.2 matt pte_exec_p(pt_entry_t pt_entry) 99 1.2 matt { 100 1.2 matt return (pt_entry & PTE_xX) != 0; 101 1.2 matt } 102 1.2 matt 103 1.2 matt static inline bool 104 1.2 matt pte_deferred_exec_p(pt_entry_t pt_entry) 105 1.2 matt { 106 1.2 matt //return (pt_entry & (PTE_xX|PTE_UNSYNCED)) == (PTE_xX|PTE_UNSYNCED); 107 1.2 matt return (pt_entry & PTE_UNSYNCED) == PTE_UNSYNCED; 108 1.2 matt } 109 1.2 matt 110 1.2 matt static inline bool 111 1.2 matt pte_wired_p(pt_entry_t pt_entry) 112 1.2 matt { 113 1.2 matt return (pt_entry & PTE_WIRED) != 0; 114 1.2 matt } 115 1.2 matt 116 1.2 matt static inline pt_entry_t 117 1.2 matt pte_nv_entry(bool kernel) 118 1.2 matt { 119 1.2 matt return 0; 120 1.2 matt } 121 1.2 matt 122 1.2 matt static inline paddr_t 123 1.2 matt pte_to_paddr(pt_entry_t pt_entry) 124 1.2 matt { 125 1.2 matt return (paddr_t)(pt_entry & PTE_RPN_MASK); 126 1.2 matt } 127 1.2 matt 128 1.2 matt static inline pt_entry_t 129 1.2 matt pte_iouncached_bits(void) 130 1.2 matt { 131 1.2 matt return PTE_W|PTE_I|PTE_G; 132 1.2 matt } 133 1.2 matt 134 1.2 matt static inline pt_entry_t 135 1.2 matt pte_ionocached_bits(void) 136 1.2 matt { 137 1.2 matt return PTE_WIG; 138 1.2 matt } 139 1.2 matt 140 1.2 matt static inline pt_entry_t 141 1.2 matt pte_iocached_bits(void) 142 1.2 matt { 143 1.2 matt return PTE_G; 144 1.2 matt } 145 1.2 matt 146 1.2 matt static inline pt_entry_t 147 1.2 matt pte_nocached_bits(void) 148 1.2 matt { 149 1.2 matt return PTE_M|PTE_I; 150 1.2 matt } 151 1.2 matt 152 1.2 matt static inline pt_entry_t 153 1.2 matt pte_cached_bits(void) 154 1.2 matt { 155 1.2 matt return PTE_M; 156 1.2 matt } 157 1.2 matt 158 1.2 matt static inline pt_entry_t 159 1.2 matt pte_cached_change(pt_entry_t pt_entry, bool cached) 160 1.2 matt { 161 1.2 matt return (pt_entry & ~PTE_I) | (cached ? 0 : PTE_I); 162 1.2 matt } 163 1.2 matt 164 1.2 matt static inline pt_entry_t 165 1.2 matt pte_wired_entry(void) 166 1.2 matt { 167 1.2 matt return PTE_WIRED; 168 1.2 matt } 169 1.2 matt 170 1.2 matt static inline pt_entry_t 171 1.2 matt pte_prot_nowrite(pt_entry_t pt_entry) 172 1.2 matt { 173 1.2 matt return pt_entry & ~(PTE_xW|PTE_UNMODIFIED); 174 1.2 matt } 175 1.2 matt 176 1.2 matt static inline pt_entry_t 177 1.2 matt pte_prot_downgrade(pt_entry_t pt_entry, vm_prot_t newprot) 178 1.2 matt { 179 1.2 matt pt_entry &= ~(PTE_xW|PTE_UNMODIFIED); 180 1.2 matt if ((newprot & VM_PROT_EXECUTE) == 0) 181 1.2 matt pt_entry &= ~(PTE_xX|PTE_UNSYNCED); 182 1.2 matt return pt_entry; 183 1.2 matt } 184 1.2 matt 185 1.2 matt static inline pt_entry_t 186 1.3 matt pte_prot_bits(struct vm_page_md *mdpg, vm_prot_t prot) 187 1.2 matt { 188 1.2 matt KASSERT(prot & VM_PROT_READ); 189 1.2 matt pt_entry_t pt_entry = PTE_xR; 190 1.2 matt if (prot & VM_PROT_EXECUTE) { 191 1.2 matt #if 0 192 1.2 matt pt_entry |= PTE_xX; 193 1.3 matt if (mdpg != NULL && !VM_PAGEMD_EXECPAGE_P(mdpg)) 194 1.2 matt pt_entry |= PTE_UNSYNCED; 195 1.2 matt #elif 1 196 1.3 matt if (mdpg != NULL && !VM_PAGEMD_EXECPAGE_P(mdpg)) 197 1.2 matt pt_entry |= PTE_UNSYNCED; 198 1.2 matt else 199 1.2 matt pt_entry |= PTE_xX; 200 1.2 matt #else 201 1.2 matt pt_entry |= PTE_UNSYNCED; 202 1.2 matt #endif 203 1.2 matt } 204 1.2 matt if (prot & VM_PROT_WRITE) { 205 1.2 matt pt_entry |= PTE_xW; 206 1.3 matt if (mdpg != NULL && !VM_PAGEMD_MODIFIED_P(mdpg)) 207 1.2 matt pt_entry |= PTE_UNMODIFIED; 208 1.2 matt } 209 1.2 matt return pt_entry; 210 1.2 matt } 211 1.2 matt 212 1.2 matt static inline pt_entry_t 213 1.3 matt pte_flag_bits(struct vm_page_md *mdpg, int flags) 214 1.2 matt { 215 1.2 matt if (__predict_false(flags & PMAP_MD_NOCACHE)) { 216 1.3 matt if (__predict_true(mdpg != NULL)) { 217 1.2 matt return pte_nocached_bits(); 218 1.2 matt } else { 219 1.2 matt return pte_ionocached_bits(); 220 1.2 matt } 221 1.2 matt } else { 222 1.3 matt if (__predict_false(mdpg != NULL)) { 223 1.2 matt return pte_cached_bits(); 224 1.2 matt } else { 225 1.2 matt return pte_iocached_bits(); 226 1.2 matt } 227 1.2 matt } 228 1.2 matt } 229 1.2 matt 230 1.2 matt static inline pt_entry_t 231 1.3 matt pte_make_enter(paddr_t pa, struct vm_page_md *mdpg, vm_prot_t prot, 232 1.2 matt int flags, bool kernel) 233 1.2 matt { 234 1.2 matt pt_entry_t pt_entry = (pt_entry_t) pa & PTE_RPN_MASK; 235 1.2 matt 236 1.3 matt pt_entry |= pte_flag_bits(mdpg, flags); 237 1.3 matt pt_entry |= pte_prot_bits(mdpg, prot); 238 1.2 matt 239 1.2 matt return pt_entry; 240 1.2 matt } 241 1.2 matt 242 1.2 matt static inline pt_entry_t 243 1.3 matt pte_make_kenter_pa(paddr_t pa, struct vm_page_md *mdpg, vm_prot_t prot, 244 1.2 matt int flags) 245 1.2 matt { 246 1.2 matt pt_entry_t pt_entry = (pt_entry_t) pa & PTE_RPN_MASK; 247 1.2 matt 248 1.3 matt pt_entry |= pte_flag_bits(mdpg, flags); 249 1.2 matt pt_entry |= pte_prot_bits(NULL, prot); /* pretend unmanaged */ 250 1.2 matt 251 1.2 matt return pt_entry; 252 1.2 matt } 253 1.2 matt #endif /* _KERNEL */ 254 1.2 matt #endif /* !_LOCORE */ 255 1.2 matt 256 1.1 matt #endif /* !_POWERPC_BOOKE_PTE_H_ */ 257
Indexes created Mon Sep 29 21:09:56 GMT 2025