ref: 037bc7b4328948994f8b8fa2be487aac1cca835f
dir: /sys/src/9/pc64/mmu.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" /* * Simple segment descriptors with no translation. */ #define EXECSEGM(p) { 0, SEGL|SEGP|SEGPL(p)|SEGEXEC } #define DATASEGM(p) { 0, SEGB|SEGG|SEGP|SEGPL(p)|SEGDATA|SEGW } #define EXEC32SEGM(p) { 0xFFFF, SEGG|SEGD|(0xF<<16)|SEGP|SEGPL(p)|SEGEXEC|SEGR } #define DATA32SEGM(p) { 0xFFFF, SEGB|SEGG|(0xF<<16)|SEGP|SEGPL(p)|SEGDATA|SEGW } Segdesc gdt[NGDT] = { [NULLSEG] { 0, 0}, /* null descriptor */ [KESEG] EXECSEGM(0), /* kernel code */ [KDSEG] DATASEGM(0), /* kernel data */ [UE32SEG] EXEC32SEGM(3), /* user code 32 bit*/ [UDSEG] DATA32SEGM(3), /* user data/stack */ [UESEG] EXECSEGM(3), /* user code */ }; static struct { Lock; MMU *free; ulong nalloc; ulong nfree; } mmupool; enum { /* level */ PML4E = 2, PDPE = 1, PDE = 0, MAPBITS = 8*sizeof(m->mmumap[0]), }; static void loadptr(u16int lim, uintptr off, void (*load)(void*)) { u64int b[2], *o; u16int *s; o = &b[1]; s = ((u16int*)o)-1; *s = lim; *o = off; (*load)(s); } static void taskswitch(uintptr stack) { Tss *tss; tss = m->tss; tss->rsp0[0] = (u32int)stack; tss->rsp0[1] = stack >> 32; tss->rsp1[0] = (u32int)stack; tss->rsp1[1] = stack >> 32; tss->rsp2[0] = (u32int)stack; tss->rsp2[1] = stack >> 32; mmuflushtlb(PADDR(m->pml4)); } static void kernelro(void); void mmuinit(void) { uintptr x; vlong v; int i; /* zap double map done by l.s */ m->pml4[512] = 0; m->pml4[0] = 0; if(m->machno == 0) kernelro(); m->tss = mallocz(sizeof(Tss), 1); if(m->tss == nil) panic("mmuinit: no memory for Tss"); m->tss->iomap = 0xDFFF; for(i=0; i<14; i+=2){ x = (uintptr)m + MACHSIZE; m->tss->ist[i] = x; m->tss->ist[i+1] = x>>32; } /* * We used to keep the GDT in the Mach structure, but it * turns out that that slows down access to the rest of the * page. Since the Mach structure is accessed quite often, * it pays off anywhere from a factor of 1.25 to 2 on real * hardware to separate them (the AMDs are more sensitive * than Intels in this regard). Under VMware it pays off * a factor of about 10 to 100. */ memmove(m->gdt, gdt, sizeof gdt); x = (uintptr)m->tss; m->gdt[TSSSEG+0].d0 = (x<<16)|(sizeof(Tss)-1); m->gdt[TSSSEG+0].d1 = (x&0xFF000000)|((x>>16)&0xFF)|SEGTSS|SEGPL(0)|SEGP; m->gdt[TSSSEG+1].d0 = x>>32; m->gdt[TSSSEG+1].d1 = 0; loadptr(sizeof(gdt)-1, (uintptr)m->gdt, lgdt); loadptr(sizeof(Segdesc)*512-1, (uintptr)IDTADDR, lidt); taskswitch((uintptr)m + MACHSIZE); ltr(TSSSEL); wrmsr(FSbase, 0ull); wrmsr(GSbase, (uvlong)&machp[m->machno]); wrmsr(KernelGSbase, 0ull); /* enable syscall extension */ rdmsr(Efer, &v); v |= 1ull; wrmsr(Efer, v); wrmsr(Star, ((uvlong)UE32SEL << 48) | ((uvlong)KESEL << 32)); wrmsr(Lstar, (uvlong)syscallentry); wrmsr(Sfmask, 0x200); } /* * These could go back to being macros once the kernel is debugged, * but the extra checking is nice to have. */ void* kaddr(uintptr pa) { if(pa >= (uintptr)-KZERO) panic("kaddr: pa=%#p pc=%#p", pa, getcallerpc(&pa)); return (void*)(pa+KZERO); } uintptr paddr(void *v) { uintptr va; va = (uintptr)v; if(va >= KZERO) return va-KZERO; if(va >= VMAP) return va-VMAP; panic("paddr: va=%#p pc=%#p", va, getcallerpc(&v)); } static MMU* mmualloc(void) { MMU *p; int i, n; p = m->mmufree; if(p != nil){ m->mmufree = p->next; m->mmucount--; } else { lock(&mmupool); p = mmupool.free; if(p != nil){ mmupool.free = p->next; mmupool.nfree--; } else { unlock(&mmupool); n = 256; p = malloc(n * sizeof(MMU)); if(p == nil) panic("mmualloc: out of memory for MMU"); p->page = mallocalign(n * PTSZ, BY2PG, 0, 0); if(p->page == nil) panic("mmualloc: out of memory for MMU pages"); for(i=1; i<n; i++){ p[i].page = p[i-1].page + (1<<PTSHIFT); p[i-1].next = &p[i]; } lock(&mmupool); p[n-1].next = mmupool.free; mmupool.free = p->next; mmupool.nalloc += n; mmupool.nfree += n-1; } unlock(&mmupool); } p->next = nil; return p; } static uintptr* mmucreate(uintptr *table, uintptr va, int level, int index) { uintptr *page, flags; MMU *p; flags = PTEWRITE|PTEVALID; if(va < VMAP){ assert(up != nil); assert((va < USTKTOP) || (va >= KMAP && va < KMAP+KMAPSIZE)); p = mmualloc(); p->index = index; p->level = level; if(va < USTKTOP){ flags |= PTEUSER; if(level == PML4E){ if((p->next = up->mmuhead) == nil) up->mmutail = p; up->mmuhead = p; m->mmumap[index/MAPBITS] |= 1ull<<(index%MAPBITS); } else { up->mmutail->next = p; up->mmutail = p; } up->mmucount++; } else { if(level == PML4E){ up->kmaptail = p; up->kmaphead = p; } else { up->kmaptail->next = p; up->kmaptail = p; } up->kmapcount++; } page = p->page; } else { page = rampage(); } memset(page, 0, PTSZ); table[index] = PADDR(page) | flags; return page; } uintptr* mmuwalk(uintptr* table, uintptr va, int level, int create) { uintptr pte; int i, x; x = PTLX(va, 3); for(i = 2; i >= level; i--){ pte = table[x]; if(pte & PTEVALID){ if(pte & PTESIZE) return 0; pte = PPN(pte); if(pte >= (uintptr)-KZERO) table = (void*)(pte + VMAP); else table = (void*)(pte + KZERO); } else { if(!create) return 0; table = mmucreate(table, va, i, x); } x = PTLX(va, i); } return &table[x]; } static int ptecount(uintptr va, int level) { return (1<<PTSHIFT) - (va & PGLSZ(level+1)-1) / PGLSZ(level); } static void ptesplit(uintptr* table, uintptr va) { uintptr *pte, pa, off; pte = mmuwalk(table, va, 1, 0); if(pte == nil || (*pte & PTESIZE) == 0 || (va & PGLSZ(1)-1) == 0) return; table = rampage(); va &= -PGLSZ(1); pa = *pte & ~PTESIZE; for(off = 0; off < PGLSZ(1); off += PGLSZ(0)) table[PTLX(va + off, 0)] = pa + off; *pte = PADDR(table) | PTEVALID|PTEWRITE; invlpg(va); } /* * map kernel text segment readonly * and everything else no-execute. */ static void kernelro(void) { uintptr *pte, psz, va; ptesplit(m->pml4, APBOOTSTRAP); ptesplit(m->pml4, KTZERO); ptesplit(m->pml4, (uintptr)etext-1); for(va = KZERO; va != 0; va += psz){ psz = PGLSZ(0); pte = mmuwalk(m->pml4, va, 0, 0); if(pte == nil){ if(va & PGLSZ(1)-1) continue; pte = mmuwalk(m->pml4, va, 1, 0); if(pte == nil) continue; psz = PGLSZ(1); } if((*pte & PTEVALID) == 0) continue; if(va >= KTZERO && va < (uintptr)etext) *pte &= ~PTEWRITE; else if(va != (APBOOTSTRAP & -BY2PG)) *pte |= PTENOEXEC; invlpg(va); } } void pmap(uintptr pa, uintptr va, vlong size) { uintptr *pte, *ptee, flags; int z, l; if(size <= 0 || va < VMAP) panic("pmap: pa=%#p va=%#p size=%lld", pa, va, size); flags = pa; pa = PPN(pa); flags -= pa; flags |= PTEACCESSED|PTEDIRTY; if(va >= KZERO) flags |= PTEGLOBAL; while(size > 0){ if(size >= PGLSZ(1) && (va % PGLSZ(1)) == 0) flags |= PTESIZE; l = (flags & PTESIZE) != 0; z = PGLSZ(l); pte = mmuwalk(m->pml4, va, l, 1); if(pte == nil){ pte = mmuwalk(m->pml4, va, ++l, 0); if(pte && (*pte & PTESIZE)){ flags |= PTESIZE; z = va & (PGLSZ(l)-1); va -= z; pa -= z; size += z; continue; } panic("pmap: pa=%#p va=%#p size=%lld", pa, va, size); } ptee = pte + ptecount(va, l); while(size > 0 && pte < ptee){ *pte++ = pa | flags; pa += z; va += z; size -= z; } } } void punmap(uintptr va, vlong size) { uintptr *pte; int l; va = PPN(va); while(size > 0){ if((va % PGLSZ(1)) != 0 || size < PGLSZ(1)) ptesplit(m->pml4, va); l = 0; pte = mmuwalk(m->pml4, va, l, 0); if(pte == nil && (va % PGLSZ(1)) == 0 && size >= PGLSZ(1)) pte = mmuwalk(m->pml4, va, ++l, 0); if(pte){ *pte = 0; invlpg(va); } va += PGLSZ(l); size -= PGLSZ(l); } } static void mmuzap(void) { uintptr *pte; u64int w; int i, x; pte = m->pml4; pte[PTLX(KMAP, 3)] = 0; /* common case */ pte[PTLX(UTZERO, 3)] = 0; pte[PTLX(USTKTOP-1, 3)] = 0; m->mmumap[PTLX(UTZERO, 3)/MAPBITS] &= ~(1ull<<(PTLX(UTZERO, 3)%MAPBITS)); m->mmumap[PTLX(USTKTOP-1, 3)/MAPBITS] &= ~(1ull<<(PTLX(USTKTOP-1, 3)%MAPBITS)); for(i = 0; i < nelem(m->mmumap); pte += MAPBITS, i++){ if((w = m->mmumap[i]) == 0) continue; m->mmumap[i] = 0; for(x = 0; w != 0; w >>= 1, x++){ if(w & 1) pte[x] = 0; } } } static void mmufree(Proc *proc) { MMU *p; p = proc->mmutail; if(p == nil) return; if(m->mmucount+proc->mmucount < 256){ p->next = m->mmufree; m->mmufree = proc->mmuhead; m->mmucount += proc->mmucount; } else { lock(&mmupool); p->next = mmupool.free; mmupool.free = proc->mmuhead; mmupool.nfree += proc->mmucount; unlock(&mmupool); } proc->mmuhead = proc->mmutail = nil; proc->mmucount = 0; } void flushmmu(void) { int x; x = splhi(); up->newtlb = 1; mmuswitch(up); splx(x); } void mmuswitch(Proc *proc) { MMU *p; mmuzap(); if(proc->newtlb){ mmufree(proc); proc->newtlb = 0; } if((p = proc->kmaphead) != nil) m->pml4[PTLX(KMAP, 3)] = PADDR(p->page) | PTEWRITE|PTEVALID; for(p = proc->mmuhead; p != nil && p->level == PML4E; p = p->next){ m->mmumap[p->index/MAPBITS] |= 1ull<<(p->index%MAPBITS); m->pml4[p->index] = PADDR(p->page) | PTEUSER|PTEWRITE|PTEVALID; } taskswitch((uintptr)proc); } void mmurelease(Proc *proc) { MMU *p; mmuzap(); if((p = proc->kmaptail) != nil){ if((p->next = proc->mmuhead) == nil) proc->mmutail = p; proc->mmuhead = proc->kmaphead; proc->mmucount += proc->kmapcount; proc->kmaphead = proc->kmaptail = nil; proc->kmapcount = proc->kmapindex = 0; } mmufree(proc); taskswitch((uintptr)m+MACHSIZE); } void putmmu(uintptr va, uintptr pa, Page *) { uintptr *pte, old; int x; x = splhi(); pte = mmuwalk(m->pml4, va, 0, 1); if(pte == 0) panic("putmmu: bug: va=%#p pa=%#p", va, pa); old = *pte; *pte = pa | PTEACCESSED|PTEDIRTY|PTEUSER; splx(x); if(old & PTEVALID) invlpg(va); } /* * Double-check the user MMU. * Error checking only. */ void checkmmu(uintptr va, uintptr pa) { uintptr *pte, old; int x; x = splhi(); pte = mmuwalk(m->pml4, va, 0, 0); if(pte == 0 || ((old = *pte) & PTEVALID) == 0 || PPN(old) == pa){ splx(x); return; } splx(x); print("%ld %s: va=%#p pa=%#p pte=%#p\n", up->pid, up->text, va, pa, old); } uintptr cankaddr(uintptr pa) { if(pa >= -KZERO) return 0; return -KZERO - pa; } KMap* kmap(Page *page) { uintptr *pte, pa, va; int x; pa = page->pa; if(cankaddr(pa) != 0) return (KMap*)KADDR(pa); x = splhi(); va = KMAP + (((uintptr)up->kmapindex++ << PGSHIFT) & (KMAPSIZE-1)); pte = mmuwalk(m->pml4, va, 0, 1); if(pte == 0 || (*pte & PTEVALID) != 0) panic("kmap: pa=%#p va=%#p", pa, va); *pte = pa | PTEACCESSED|PTEDIRTY|PTEWRITE|PTENOEXEC|PTEVALID; splx(x); invlpg(va); return (KMap*)va; } void kunmap(KMap *k) { uintptr *pte, va; int x; va = (uintptr)k; if(va >= KZERO) return; x = splhi(); pte = mmuwalk(m->pml4, va, 0, 0); if(pte == 0 || (*pte & PTEVALID) == 0) panic("kunmap: va=%#p", va); *pte = 0; splx(x); } /* * Add a device mapping to the vmap range. * note that the VMAP and KZERO PDPs are shared * between processors (see mpstartap) so no * synchronization is being done. */ void* vmap(uvlong pa, vlong size) { uintptr va; int o; if(pa < BY2PG || size <= 0 || -pa < size || pa+size > VMAPSIZE){ print("vmap pa=%llux size=%lld pc=%#p\n", pa, size, getcallerpc(&pa)); return nil; } va = pa+VMAP; /* * might be asking for less than a page. */ o = pa & (BY2PG-1); pa -= o; va -= o; size += o; pmap(pa | PTEUNCACHED|PTEWRITE|PTENOEXEC|PTEVALID, va, size); return (void*)(va+o); } void vunmap(void *v, vlong) { paddr(v); /* will panic on error */ } /* * mark pages as write combining (used for framebuffer) */ void patwc(void *a, int n) { uintptr *pte, mask, attr, va; int z, l; vlong v; /* check if pat is usable */ if((MACHP(0)->cpuiddx & Pat) == 0 || rdmsr(0x277, &v) == -1 || ((v >> PATWC*8) & 7) != 1) return; /* set the bits for all pages in range */ for(va = (uintptr)a; n > 0; n -= z, va += z){ l = 0; pte = mmuwalk(m->pml4, va, l, 0); if(pte == 0) pte = mmuwalk(m->pml4, va, ++l, 0); if(pte == 0 || (*pte & PTEVALID) == 0) panic("patwc: va=%#p", va); z = PGLSZ(l); z -= va & (z-1); mask = l == 0 ? 3<<3 | 1<<7 : 3<<3 | 1<<12; attr = (((PATWC&3)<<3) | ((PATWC&4)<<5) | ((PATWC&4)<<10)); *pte = (*pte & ~mask) | (attr & mask); } } /* * The palloc.pages array and mmupool can be a large chunk * out of the 2GB window above KZERO, so we allocate from * upages and map in the VMAP window before pageinit() */ void preallocpages(void) { Confmem *cm; uintptr va, base, top; vlong tsize, psize; ulong np, nt; int i; np = 0; for(i=0; i<nelem(conf.mem); i++){ cm = &conf.mem[i]; np += cm->npage - nkpages(cm); } nt = np / 50; /* 2% for mmupool */ np -= nt; nt = (uvlong)nt*BY2PG / (sizeof(MMU)+PTSZ); tsize = (uvlong)nt * (sizeof(MMU)+PTSZ); psize = (uvlong)np * BY2PG; psize += sizeof(Page) + BY2PG; psize = (psize / (sizeof(Page)+BY2PG)) * sizeof(Page); psize += tsize; psize = ROUND(psize, PGLSZ(1)); for(i=0; i<nelem(conf.mem); i++){ cm = &conf.mem[i]; base = cm->base; top = base + (uvlong)cm->npage * BY2PG; base += (uvlong)nkpages(cm) * BY2PG; top &= -PGLSZ(1); if(top <= VMAPSIZE && (vlong)(top - base) >= psize){ /* steal memory from the end of the bank */ top -= psize; cm->npage = (top - cm->base) / BY2PG; va = top + VMAP; pmap(top | PTEGLOBAL|PTEWRITE|PTENOEXEC|PTEVALID, va, psize); palloc.pages = (void*)(va + tsize); mmupool.nfree = mmupool.nalloc = nt; mmupool.free = (void*)(va + (uvlong)nt*PTSZ); for(i=0; i<nt; i++){ mmupool.free[i].page = (uintptr*)va; mmupool.free[i].next = &mmupool.free[i+1]; va += PTSZ; } mmupool.free[i-1].next = nil; break; } } }