/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Copyright (c) 1992 Terrence R. Lambert. * Copyright (c) 1990 The Regents of the University of California. * All rights reserved. * * This code is derived from software contributed to Berkeley by * William Jolitz. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)machdep.c 7.4 (Berkeley) 6/3/91 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef __xpv #include #include #endif #include #include #include #include /* * cpu0 and default tables and structures. */ user_desc_t *gdt0; #if !defined(__xpv) desctbr_t gdt0_default_r; #endif gate_desc_t *idt0; /* interrupt descriptor table */ #if defined(__i386) desctbr_t idt0_default_r; /* describes idt0 in IDTR format */ #endif struct tss *ktss0; /* kernel task state structure */ #if defined(__i386) struct tss *dftss0; /* #DF double-fault exception */ #endif /* __i386 */ user_desc_t zero_udesc; /* base zero user desc native procs */ user_desc_t null_udesc; /* null user descriptor */ system_desc_t null_sdesc; /* null system descriptor */ #if defined(__amd64) user_desc_t zero_u32desc; /* 32-bit compatibility procs */ #endif /* __amd64 */ #if defined(__amd64) user_desc_t ucs_on; user_desc_t ucs_off; user_desc_t ucs32_on; user_desc_t ucs32_off; #endif /* __amd64 */ #pragma align 16(dblfault_stack0) char dblfault_stack0[DEFAULTSTKSZ]; extern void fast_null(void); extern hrtime_t get_hrtime(void); extern hrtime_t gethrvtime(void); extern hrtime_t get_hrestime(void); extern uint64_t getlgrp(void); void (*(fasttable[]))(void) = { fast_null, /* T_FNULL routine */ fast_null, /* T_FGETFP routine (initially null) */ fast_null, /* T_FSETFP routine (initially null) */ (void (*)())get_hrtime, /* T_GETHRTIME */ (void (*)())gethrvtime, /* T_GETHRVTIME */ (void (*)())get_hrestime, /* T_GETHRESTIME */ (void (*)())getlgrp /* T_GETLGRP */ }; /* * Structure containing pre-computed descriptors to allow us to temporarily * interpose on a standard handler. */ struct interposing_handler { int ih_inum; gate_desc_t ih_interp_desc; gate_desc_t ih_default_desc; }; /* * The brand infrastructure interposes on two handlers, and we use one as a * NULL signpost. */ static struct interposing_handler brand_tbl[3]; /* * software prototypes for default local descriptor table */ /* * Routines for loading segment descriptors in format the hardware * can understand. */ #if defined(__amd64) /* * In long mode we have the new L or long mode attribute bit * for code segments. Only the conforming bit in type is used along * with descriptor priority and present bits. Default operand size must * be zero when in long mode. In 32-bit compatibility mode all fields * are treated as in legacy mode. For data segments while in long mode * only the present bit is loaded. */ void set_usegd(user_desc_t *dp, uint_t lmode, void *base, size_t size, uint_t type, uint_t dpl, uint_t gran, uint_t defopsz) { ASSERT(lmode == SDP_SHORT || lmode == SDP_LONG); /* * 64-bit long mode. */ if (lmode == SDP_LONG) dp->usd_def32 = 0; /* 32-bit operands only */ else /* * 32-bit compatibility mode. */ dp->usd_def32 = defopsz; /* 0 = 16, 1 = 32-bit ops */ dp->usd_long = lmode; /* 64-bit mode */ dp->usd_type = type; dp->usd_dpl = dpl; dp->usd_p = 1; dp->usd_gran = gran; /* 0 = bytes, 1 = pages */ dp->usd_lobase = (uintptr_t)base; dp->usd_midbase = (uintptr_t)base >> 16; dp->usd_hibase = (uintptr_t)base >> (16 + 8); dp->usd_lolimit = size; dp->usd_hilimit = (uintptr_t)size >> 16; } #elif defined(__i386) /* * Install user segment descriptor for code and data. */ void set_usegd(user_desc_t *dp, void *base, size_t size, uint_t type, uint_t dpl, uint_t gran, uint_t defopsz) { dp->usd_lolimit = size; dp->usd_hilimit = (uintptr_t)size >> 16; dp->usd_lobase = (uintptr_t)base; dp->usd_midbase = (uintptr_t)base >> 16; dp->usd_hibase = (uintptr_t)base >> (16 + 8); dp->usd_type = type; dp->usd_dpl = dpl; dp->usd_p = 1; dp->usd_def32 = defopsz; /* 0 = 16, 1 = 32 bit operands */ dp->usd_gran = gran; /* 0 = bytes, 1 = pages */ } #endif /* __i386 */ /* * Install system segment descriptor for LDT and TSS segments. */ #if defined(__amd64) void set_syssegd(system_desc_t *dp, void *base, size_t size, uint_t type, uint_t dpl) { dp->ssd_lolimit = size; dp->ssd_hilimit = (uintptr_t)size >> 16; dp->ssd_lobase = (uintptr_t)base; dp->ssd_midbase = (uintptr_t)base >> 16; dp->ssd_hibase = (uintptr_t)base >> (16 + 8); dp->ssd_hi64base = (uintptr_t)base >> (16 + 8 + 8); dp->ssd_type = type; dp->ssd_zero1 = 0; /* must be zero */ dp->ssd_zero2 = 0; dp->ssd_dpl = dpl; dp->ssd_p = 1; dp->ssd_gran = 0; /* force byte units */ } void * get_ssd_base(system_desc_t *dp) { uintptr_t base; base = (uintptr_t)dp->ssd_lobase | (uintptr_t)dp->ssd_midbase << 16 | (uintptr_t)dp->ssd_hibase << (16 + 8) | (uintptr_t)dp->ssd_hi64base << (16 + 8 + 8); return ((void *)base); } #elif defined(__i386) void set_syssegd(system_desc_t *dp, void *base, size_t size, uint_t type, uint_t dpl) { dp->ssd_lolimit = size; dp->ssd_hilimit = (uintptr_t)size >> 16; dp->ssd_lobase = (uintptr_t)base; dp->ssd_midbase = (uintptr_t)base >> 16; dp->ssd_hibase = (uintptr_t)base >> (16 + 8); dp->ssd_type = type; dp->ssd_zero = 0; /* must be zero */ dp->ssd_dpl = dpl; dp->ssd_p = 1; dp->ssd_gran = 0; /* force byte units */ } void * get_ssd_base(system_desc_t *dp) { uintptr_t base; base = (uintptr_t)dp->ssd_lobase | (uintptr_t)dp->ssd_midbase << 16 | (uintptr_t)dp->ssd_hibase << (16 + 8); return ((void *)base); } #endif /* __i386 */ /* * Install gate segment descriptor for interrupt, trap, call and task gates. */ #if defined(__amd64) void set_gatesegd(gate_desc_t *dp, void (*func)(void), selector_t sel, uint_t type, uint_t dpl) { dp->sgd_looffset = (uintptr_t)func; dp->sgd_hioffset = (uintptr_t)func >> 16; dp->sgd_hi64offset = (uintptr_t)func >> (16 + 16); dp->sgd_selector = (uint16_t)sel; /* * For 64 bit native we use the IST stack mechanism * for double faults. All other traps use the CPL = 0 * (tss_rsp0) stack. */ #if !defined(__xpv) if (type == T_DBLFLT) dp->sgd_ist = 1; else #endif dp->sgd_ist = 0; dp->sgd_type = type; dp->sgd_dpl = dpl; dp->sgd_p = 1; } #elif defined(__i386) void set_gatesegd(gate_desc_t *dp, void (*func)(void), selector_t sel, uint_t type, uint_t dpl) { dp->sgd_looffset = (uintptr_t)func; dp->sgd_hioffset = (uintptr_t)func >> 16; dp->sgd_selector = (uint16_t)sel; dp->sgd_stkcpy = 0; /* always zero bytes */ dp->sgd_type = type; dp->sgd_dpl = dpl; dp->sgd_p = 1; } #endif /* __i386 */ /* * Updates a single user descriptor in the the GDT of the current cpu. * Caller is responsible for preventing cpu migration. */ void gdt_update_usegd(uint_t sidx, user_desc_t *udp) { #if defined(__xpv) uint64_t dpa = CPU->cpu_m.mcpu_gdtpa + sizeof (*udp) * sidx; if (HYPERVISOR_update_descriptor(pa_to_ma(dpa), *(uint64_t *)udp)) panic("gdt_update_usegd: HYPERVISOR_update_descriptor"); #else /* __xpv */ CPU->cpu_gdt[sidx] = *udp; #endif /* __xpv */ } /* * Writes single descriptor pointed to by udp into a processes * LDT entry pointed to by ldp. */ int ldt_update_segd(user_desc_t *ldp, user_desc_t *udp) { #if defined(__xpv) uint64_t dpa; dpa = mmu_ptob(hat_getpfnum(kas.a_hat, (caddr_t)ldp)) | ((uintptr_t)ldp & PAGEOFFSET); /* * The hypervisor is a little more restrictive about what it * supports in the LDT. */ if (HYPERVISOR_update_descriptor(pa_to_ma(dpa), *(uint64_t *)udp) != 0) return (EINVAL); #else /* __xpv */ *ldp = *udp; #endif /* __xpv */ return (0); } #if defined(__xpv) /* * Converts hw format gate descriptor into pseudo-IDT format for the hypervisor. * Returns true if a valid entry was written. */ int xen_idt_to_trap_info(uint_t vec, gate_desc_t *sgd, void *ti_arg) { trap_info_t *ti = ti_arg; /* XXPV Aargh - segments.h comment */ /* * skip holes in the IDT */ if (GATESEG_GETOFFSET(sgd) == 0) return (0); ASSERT(sgd->sgd_type == SDT_SYSIGT); ti->vector = vec; TI_SET_DPL(ti, sgd->sgd_dpl); /* * Is this an interrupt gate? */ if (sgd->sgd_type == SDT_SYSIGT) { /* LINTED */ TI_SET_IF(ti, 1); } ti->cs = sgd->sgd_selector; #if defined(__amd64) ti->cs |= SEL_KPL; /* force into ring 3. see KCS_SEL */ #endif ti->address = GATESEG_GETOFFSET(sgd); return (1); } /* * Convert a single hw format gate descriptor and write it into our virtual IDT. */ void xen_idt_write(gate_desc_t *sgd, uint_t vec) { trap_info_t trapinfo[2]; bzero(trapinfo, sizeof (trapinfo)); if (xen_idt_to_trap_info(vec, sgd, &trapinfo[0]) == 0) return; if (xen_set_trap_table(trapinfo) != 0) panic("xen_idt_write: xen_set_trap_table() failed"); } #endif /* __xpv */ #if defined(__amd64) /* * Build kernel GDT. */ static void init_gdt_common(user_desc_t *gdt) { int i; /* * 64-bit kernel code segment. */ set_usegd(&gdt[GDT_KCODE], SDP_LONG, NULL, 0, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); /* * 64-bit kernel data segment. The limit attribute is ignored in 64-bit * mode, but we set it here to 0xFFFF so that we can use the SYSRET * instruction to return from system calls back to 32-bit applications. * SYSRET doesn't update the base, limit, or attributes of %ss or %ds * descriptors. We therefore must ensure that the kernel uses something, * though it will be ignored by hardware, that is compatible with 32-bit * apps. For the same reason we must set the default op size of this * descriptor to 32-bit operands. */ set_usegd(&gdt[GDT_KDATA], SDP_LONG, NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); gdt[GDT_KDATA].usd_def32 = 1; /* * 64-bit user code segment. */ set_usegd(&gdt[GDT_UCODE], SDP_LONG, NULL, 0, SDT_MEMERA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * 32-bit user code segment. */ set_usegd(&gdt[GDT_U32CODE], SDP_SHORT, NULL, -1, SDT_MEMERA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * See gdt_ucode32() and gdt_ucode_native(). */ ucs_on = ucs_off = gdt[GDT_UCODE]; ucs_off.usd_p = 0; /* forces #np fault */ ucs32_on = ucs32_off = gdt[GDT_U32CODE]; ucs32_off.usd_p = 0; /* forces #np fault */ /* * 32 and 64 bit data segments can actually share the same descriptor. * In long mode only the present bit is checked but all other fields * are loaded. But in compatibility mode all fields are interpreted * as in legacy mode so they must be set correctly for a 32-bit data * segment. */ set_usegd(&gdt[GDT_UDATA], SDP_SHORT, NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); #if !defined(__xpv) /* * The 64-bit kernel has no default LDT. By default, the LDT descriptor * in the GDT is 0. */ /* * Kernel TSS */ set_syssegd((system_desc_t *)&gdt[GDT_KTSS], ktss0, sizeof (*ktss0) - 1, SDT_SYSTSS, SEL_KPL); #endif /* !__xpv */ /* * Initialize fs and gs descriptors for 32 bit processes. * Only attributes and limits are initialized, the effective * base address is programmed via fsbase/gsbase. */ set_usegd(&gdt[GDT_LWPFS], SDP_SHORT, NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); set_usegd(&gdt[GDT_LWPGS], SDP_SHORT, NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * Initialize the descriptors set aside for brand usage. * Only attributes and limits are initialized. */ for (i = GDT_BRANDMIN; i <= GDT_BRANDMAX; i++) set_usegd(&gdt0[i], SDP_SHORT, NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * Initialize convenient zero base user descriptors for clearing * lwp private %fs and %gs descriptors in GDT. See setregs() for * an example. */ set_usegd(&zero_udesc, SDP_LONG, 0, 0, SDT_MEMRWA, SEL_UPL, SDP_BYTES, SDP_OP32); set_usegd(&zero_u32desc, SDP_SHORT, 0, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); } #if defined(__xpv) static user_desc_t * init_gdt(void) { uint64_t gdtpa; ulong_t ma[1]; /* XXPV should be a memory_t */ ulong_t addr; #if !defined(__lint) /* * Our gdt is never larger than a single page. */ ASSERT((sizeof (*gdt0) * NGDT) <= PAGESIZE); #endif gdt0 = (user_desc_t *)BOP_ALLOC(bootops, (caddr_t)GDT_VA, PAGESIZE, PAGESIZE); bzero(gdt0, PAGESIZE); init_gdt_common(gdt0); /* * XXX Since we never invoke kmdb until after the kernel takes * over the descriptor tables why not have it use the kernel's * selectors? */ if (boothowto & RB_DEBUG) { set_usegd(&gdt0[GDT_B32DATA], SDP_LONG, NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); set_usegd(&gdt0[GDT_B64CODE], SDP_LONG, NULL, -1, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); } /* * Clear write permission for page containing the gdt and install it. */ gdtpa = pfn_to_pa(va_to_pfn(gdt0)); ma[0] = (ulong_t)(pa_to_ma(gdtpa) >> PAGESHIFT); kbm_read_only((uintptr_t)gdt0, gdtpa); xen_set_gdt(ma, NGDT); /* * Reload the segment registers to use the new GDT. * On 64-bit, fixup KCS_SEL to be in ring 3. * See KCS_SEL in segments.h. */ load_segment_registers((KCS_SEL | SEL_KPL), KFS_SEL, KGS_SEL, KDS_SEL); /* * setup %gs for kernel */ xen_set_segment_base(SEGBASE_GS_KERNEL, (ulong_t)&cpus[0]); /* * XX64 We should never dereference off "other gsbase" or * "fsbase". So, we should arrange to point FSBASE and * KGSBASE somewhere truly awful e.g. point it at the last * valid address below the hole so that any attempts to index * off them cause an exception. * * For now, point it at 8G -- at least it should be unmapped * until some 64-bit processes run. */ addr = 0x200000000ul; xen_set_segment_base(SEGBASE_FS, addr); xen_set_segment_base(SEGBASE_GS_USER, addr); xen_set_segment_base(SEGBASE_GS_USER_SEL, 0); return (gdt0); } #else /* __xpv */ static user_desc_t * init_gdt(void) { desctbr_t r_bgdt, r_gdt; user_desc_t *bgdt; #if !defined(__lint) /* * Our gdt is never larger than a single page. */ ASSERT((sizeof (*gdt0) * NGDT) <= PAGESIZE); #endif gdt0 = (user_desc_t *)BOP_ALLOC(bootops, (caddr_t)GDT_VA, PAGESIZE, PAGESIZE); bzero(gdt0, PAGESIZE); init_gdt_common(gdt0); /* * Copy in from boot's gdt to our gdt. * Entry 0 is the null descriptor by definition. */ rd_gdtr(&r_bgdt); bgdt = (user_desc_t *)r_bgdt.dtr_base; if (bgdt == NULL) panic("null boot gdt"); gdt0[GDT_B32DATA] = bgdt[GDT_B32DATA]; gdt0[GDT_B32CODE] = bgdt[GDT_B32CODE]; gdt0[GDT_B16CODE] = bgdt[GDT_B16CODE]; gdt0[GDT_B16DATA] = bgdt[GDT_B16DATA]; gdt0[GDT_B64CODE] = bgdt[GDT_B64CODE]; /* * Install our new GDT */ r_gdt.dtr_limit = (sizeof (*gdt0) * NGDT) - 1; r_gdt.dtr_base = (uintptr_t)gdt0; wr_gdtr(&r_gdt); /* * Reload the segment registers to use the new GDT */ load_segment_registers(KCS_SEL, KFS_SEL, KGS_SEL, KDS_SEL); /* * setup %gs for kernel */ wrmsr(MSR_AMD_GSBASE, (uint64_t)&cpus[0]); /* * XX64 We should never dereference off "other gsbase" or * "fsbase". So, we should arrange to point FSBASE and * KGSBASE somewhere truly awful e.g. point it at the last * valid address below the hole so that any attempts to index * off them cause an exception. * * For now, point it at 8G -- at least it should be unmapped * until some 64-bit processes run. */ wrmsr(MSR_AMD_FSBASE, 0x200000000ul); wrmsr(MSR_AMD_KGSBASE, 0x200000000ul); return (gdt0); } #endif /* __xpv */ #elif defined(__i386) static void init_gdt_common(user_desc_t *gdt) { int i; /* * Text and data for both kernel and user span entire 32 bit * address space. */ /* * kernel code segment. */ set_usegd(&gdt[GDT_KCODE], NULL, -1, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); /* * kernel data segment. */ set_usegd(&gdt[GDT_KDATA], NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); /* * user code segment. */ set_usegd(&gdt[GDT_UCODE], NULL, -1, SDT_MEMERA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * user data segment. */ set_usegd(&gdt[GDT_UDATA], NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); #if !defined(__xpv) /* * TSS for T_DBLFLT (double fault) handler */ set_syssegd((system_desc_t *)&gdt[GDT_DBFLT], dftss0, sizeof (*dftss0) - 1, SDT_SYSTSS, SEL_KPL); /* * TSS for kernel */ set_syssegd((system_desc_t *)&gdt[GDT_KTSS], ktss0, sizeof (*ktss0) - 1, SDT_SYSTSS, SEL_KPL); #endif /* !__xpv */ /* * %gs selector for kernel */ set_usegd(&gdt[GDT_GS], &cpus[0], sizeof (struct cpu) -1, SDT_MEMRWA, SEL_KPL, SDP_BYTES, SDP_OP32); /* * Initialize lwp private descriptors. * Only attributes and limits are initialized, the effective * base address is programmed via fsbase/gsbase. */ set_usegd(&gdt[GDT_LWPFS], NULL, (size_t)-1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); set_usegd(&gdt[GDT_LWPGS], NULL, (size_t)-1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * Initialize the descriptors set aside for brand usage. * Only attributes and limits are initialized. */ for (i = GDT_BRANDMIN; i <= GDT_BRANDMAX; i++) set_usegd(&gdt0[i], NULL, (size_t)-1, SDT_MEMRWA, SEL_UPL, SDP_PAGES, SDP_OP32); /* * Initialize convenient zero base user descriptor for clearing * lwp private %fs and %gs descriptors in GDT. See setregs() for * an example. */ set_usegd(&zero_udesc, NULL, -1, SDT_MEMRWA, SEL_UPL, SDP_BYTES, SDP_OP32); } #if defined(__xpv) static user_desc_t * init_gdt(void) { uint64_t gdtpa; ulong_t ma[1]; /* XXPV should be a memory_t */ #if !defined(__lint) /* * Our gdt is never larger than a single page. */ ASSERT((sizeof (*gdt0) * NGDT) <= PAGESIZE); #endif gdt0 = (user_desc_t *)BOP_ALLOC(bootops, (caddr_t)GDT_VA, PAGESIZE, PAGESIZE); bzero(gdt0, PAGESIZE); init_gdt_common(gdt0); gdtpa = pfn_to_pa(va_to_pfn(gdt0)); /* * XXX Since we never invoke kmdb until after the kernel takes * over the descriptor tables why not have it use the kernel's * selectors? */ if (boothowto & RB_DEBUG) { set_usegd(&gdt0[GDT_B32DATA], NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); set_usegd(&gdt0[GDT_B32CODE], NULL, -1, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); } /* * Clear write permission for page containing the gdt and install it. */ ma[0] = (ulong_t)(pa_to_ma(gdtpa) >> PAGESHIFT); kbm_read_only((uintptr_t)gdt0, gdtpa); xen_set_gdt(ma, NGDT); /* * Reload the segment registers to use the new GDT */ load_segment_registers( KCS_SEL, KDS_SEL, KDS_SEL, KFS_SEL, KGS_SEL, KDS_SEL); return (gdt0); } #else /* __xpv */ static user_desc_t * init_gdt(void) { desctbr_t r_bgdt, r_gdt; user_desc_t *bgdt; #if !defined(__lint) /* * Our gdt is never larger than a single page. */ ASSERT((sizeof (*gdt0) * NGDT) <= PAGESIZE); #endif /* * XXX this allocation belongs in our caller, not here. */ gdt0 = (user_desc_t *)BOP_ALLOC(bootops, (caddr_t)GDT_VA, PAGESIZE, PAGESIZE); bzero(gdt0, PAGESIZE); init_gdt_common(gdt0); /* * Copy in from boot's gdt to our gdt entries. * Entry 0 is null descriptor by definition. */ rd_gdtr(&r_bgdt); bgdt = (user_desc_t *)r_bgdt.dtr_base; if (bgdt == NULL) panic("null boot gdt"); gdt0[GDT_B32DATA] = bgdt[GDT_B32DATA]; gdt0[GDT_B32CODE] = bgdt[GDT_B32CODE]; gdt0[GDT_B16CODE] = bgdt[GDT_B16CODE]; gdt0[GDT_B16DATA] = bgdt[GDT_B16DATA]; /* * Install our new GDT */ r_gdt.dtr_limit = (sizeof (*gdt0) * NGDT) - 1; r_gdt.dtr_base = (uintptr_t)gdt0; wr_gdtr(&r_gdt); /* * Reload the segment registers to use the new GDT */ load_segment_registers( KCS_SEL, KDS_SEL, KDS_SEL, KFS_SEL, KGS_SEL, KDS_SEL); return (gdt0); } #endif /* __xpv */ #endif /* __i386 */ /* * Build kernel IDT. * * Note that for amd64 we pretty much require every gate to be an interrupt * gate which blocks interrupts atomically on entry; that's because of our * dependency on using 'swapgs' every time we come into the kernel to find * the cpu structure. If we get interrupted just before doing that, %cs could * be in kernel mode (so that the trap prolog doesn't do a swapgs), but * %gsbase is really still pointing at something in userland. Bad things will * ensue. We also use interrupt gates for i386 as well even though this is not * required for some traps. * * Perhaps they should have invented a trap gate that does an atomic swapgs? */ static void init_idt_common(gate_desc_t *idt) { set_gatesegd(&idt[T_ZERODIV], &div0trap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_SGLSTP], &dbgtrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_NMIFLT], &nmiint, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_BPTFLT], &brktrap, KCS_SEL, SDT_SYSIGT, TRP_UPL); set_gatesegd(&idt[T_OVFLW], &ovflotrap, KCS_SEL, SDT_SYSIGT, TRP_UPL); set_gatesegd(&idt[T_BOUNDFLT], &boundstrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_ILLINST], &invoptrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_NOEXTFLT], &ndptrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); /* * double fault handler. * * Note that on the hypervisor a guest does not receive #df faults. * Instead a failsafe event is injected into the guest if its selectors * and/or stack is in a broken state. See xen_failsafe_callback. */ #if !defined(__xpv) #if defined(__amd64) set_gatesegd(&idt[T_DBLFLT], &syserrtrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); #elif defined(__i386) /* * task gate required. */ set_gatesegd(&idt[T_DBLFLT], NULL, DFTSS_SEL, SDT_SYSTASKGT, TRP_KPL); #endif /* __i386 */ #endif /* !__xpv */ /* * T_EXTOVRFLT coprocessor-segment-overrun not supported. */ set_gatesegd(&idt[T_TSSFLT], &invtsstrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_SEGFLT], &segnptrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_STKFLT], &stktrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_GPFLT], &gptrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_PGFLT], &pftrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_EXTERRFLT], &ndperr, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_ALIGNMENT], &achktrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_MCE], &mcetrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); set_gatesegd(&idt[T_SIMDFPE], &xmtrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); /* * install "int80" handler at, well, 0x80. */ set_gatesegd(&idt0[T_INT80], &sys_int80, KCS_SEL, SDT_SYSIGT, TRP_UPL); /* * install fast trap handler at 210. */ set_gatesegd(&idt[T_FASTTRAP], &fasttrap, KCS_SEL, SDT_SYSIGT, TRP_UPL); /* * System call handler. */ #if defined(__amd64) set_gatesegd(&idt[T_SYSCALLINT], &sys_syscall_int, KCS_SEL, SDT_SYSIGT, TRP_UPL); #elif defined(__i386) set_gatesegd(&idt[T_SYSCALLINT], &sys_call, KCS_SEL, SDT_SYSIGT, TRP_UPL); #endif /* __i386 */ /* * Install the DTrace interrupt handler for the pid provider. */ set_gatesegd(&idt[T_DTRACE_RET], &dtrace_ret, KCS_SEL, SDT_SYSIGT, TRP_UPL); /* * Prepare interposing descriptors for the branded "int80" * and syscall handlers and cache copies of the default * descriptors. */ brand_tbl[0].ih_inum = T_INT80; brand_tbl[0].ih_default_desc = idt0[T_INT80]; set_gatesegd(&(brand_tbl[0].ih_interp_desc), &brand_sys_int80, KCS_SEL, SDT_SYSIGT, TRP_UPL); brand_tbl[1].ih_inum = T_SYSCALLINT; brand_tbl[1].ih_default_desc = idt0[T_SYSCALLINT]; #if defined(__amd64) set_gatesegd(&(brand_tbl[1].ih_interp_desc), &brand_sys_syscall_int, KCS_SEL, SDT_SYSIGT, TRP_UPL); #elif defined(__i386) set_gatesegd(&(brand_tbl[1].ih_interp_desc), &brand_sys_call, KCS_SEL, SDT_SYSIGT, TRP_UPL); #endif /* __i386 */ brand_tbl[2].ih_inum = 0; } #if defined(__xpv) static void init_idt(gate_desc_t *idt) { /* * currently nothing extra for the hypervisor */ init_idt_common(idt); } #else /* __xpv */ static void init_idt(gate_desc_t *idt) { char ivctname[80]; void (*ivctptr)(void); int i; /* * Initialize entire table with 'reserved' trap and then overwrite * specific entries. T_EXTOVRFLT (9) is unsupported and reserved * since it can only be generated on a 386 processor. 15 is also * unsupported and reserved. */ for (i = 0; i < NIDT; i++) set_gatesegd(&idt[i], &resvtrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); /* * 20-31 reserved */ for (i = 20; i < 32; i++) set_gatesegd(&idt[i], &invaltrap, KCS_SEL, SDT_SYSIGT, TRP_KPL); /* * interrupts 32 - 255 */ for (i = 32; i < 256; i++) { (void) snprintf(ivctname, sizeof (ivctname), "ivct%d", i); ivctptr = (void (*)(void))kobj_getsymvalue(ivctname, 0); if (ivctptr == NULL) panic("kobj_getsymvalue(%s) failed", ivctname); set_gatesegd(&idt[i], ivctptr, KCS_SEL, SDT_SYSIGT, TRP_KPL); } /* * Now install the common ones. Note that it will overlay some * entries installed above like T_SYSCALLINT, T_FASTTRAP etc. */ init_idt_common(idt); } #endif /* __xpv */ /* * The kernel does not deal with LDTs unless a user explicitly creates * one. Under normal circumstances, the LDTR contains 0. Any process attempting * to reference the LDT will therefore cause a #gp. System calls made via the * obsolete lcall mechanism are emulated by the #gp fault handler. */ static void init_ldt(void) { #if defined(__xpv) xen_set_ldt(NULL, 0); #else wr_ldtr(0); #endif } #if !defined(__xpv) #if defined(__amd64) static void init_tss(void) { /* * tss_rsp0 is dynamically filled in by resume() on each context switch. * All exceptions but #DF will run on the thread stack. * Set up the double fault stack here. */ ktss0->tss_ist1 = (uint64_t)&dblfault_stack0[sizeof (dblfault_stack0)]; /* * Set I/O bit map offset equal to size of TSS segment limit * for no I/O permission map. This will force all user I/O * instructions to generate #gp fault. */ ktss0->tss_bitmapbase = sizeof (*ktss0); /* * Point %tr to descriptor for ktss0 in gdt. */ wr_tsr(KTSS_SEL); } #elif defined(__i386) static void init_tss(void) { /* * ktss0->tss_esp dynamically filled in by resume() on each * context switch. */ ktss0->tss_ss0 = KDS_SEL; ktss0->tss_eip = (uint32_t)_start; ktss0->tss_ds = ktss0->tss_es = ktss0->tss_ss = KDS_SEL; ktss0->tss_cs = KCS_SEL; ktss0->tss_fs = KFS_SEL; ktss0->tss_gs = KGS_SEL; ktss0->tss_ldt = ULDT_SEL; /* * Initialize double fault tss. */ dftss0->tss_esp0 = (uint32_t)&dblfault_stack0[sizeof (dblfault_stack0)]; dftss0->tss_ss0 = KDS_SEL; /* * tss_cr3 will get initialized in hat_kern_setup() once our page * tables have been setup. */ dftss0->tss_eip = (uint32_t)syserrtrap; dftss0->tss_esp = (uint32_t)&dblfault_stack0[sizeof (dblfault_stack0)]; dftss0->tss_cs = KCS_SEL; dftss0->tss_ds = KDS_SEL; dftss0->tss_es = KDS_SEL; dftss0->tss_ss = KDS_SEL; dftss0->tss_fs = KFS_SEL; dftss0->tss_gs = KGS_SEL; /* * Set I/O bit map offset equal to size of TSS segment limit * for no I/O permission map. This will force all user I/O * instructions to generate #gp fault. */ ktss0->tss_bitmapbase = sizeof (*ktss0); /* * Point %tr to descriptor for ktss0 in gdt. */ wr_tsr(KTSS_SEL); } #endif /* __i386 */ #endif /* !__xpv */ #if defined(__xpv) void init_desctbls(void) { uint_t vec; user_desc_t *gdt; /* * Setup and install our GDT. */ gdt = init_gdt(); /* * Store static pa of gdt to speed up pa_to_ma() translations * on lwp context switches. */ ASSERT(IS_P2ALIGNED((uintptr_t)gdt, PAGESIZE)); CPU->cpu_gdt = gdt; CPU->cpu_m.mcpu_gdtpa = pfn_to_pa(va_to_pfn(gdt)); /* * Setup and install our IDT. */ #if !defined(__lint) ASSERT(NIDT * sizeof (*idt0) <= PAGESIZE); #endif idt0 = (gate_desc_t *)BOP_ALLOC(bootops, (caddr_t)IDT_VA, PAGESIZE, PAGESIZE); init_idt(idt0); for (vec = 0; vec < NIDT; vec++) xen_idt_write(&idt0[vec], vec); CPU->cpu_idt = idt0; /* * set default kernel stack */ xen_stack_switch(KDS_SEL, (ulong_t)&dblfault_stack0[sizeof (dblfault_stack0)]); xen_init_callbacks(); init_ldt(); } #else /* __xpv */ void init_desctbls(void) { user_desc_t *gdt; desctbr_t idtr; /* * Allocate IDT and TSS structures on unique pages for better * performance in virtual machines. */ #if !defined(__lint) ASSERT(NIDT * sizeof (*idt0) <= PAGESIZE); #endif idt0 = (gate_desc_t *)BOP_ALLOC(bootops, (caddr_t)IDT_VA, PAGESIZE, PAGESIZE); #if !defined(__lint) ASSERT(sizeof (*ktss0) <= PAGESIZE); #endif ktss0 = (struct tss *)BOP_ALLOC(bootops, (caddr_t)KTSS_VA, PAGESIZE, PAGESIZE); #if defined(__i386) #if !defined(__lint) ASSERT(sizeof (*dftss0) <= PAGESIZE); #endif dftss0 = (struct tss *)BOP_ALLOC(bootops, (caddr_t)DFTSS_VA, PAGESIZE, PAGESIZE); #endif /* * Setup and install our GDT. */ gdt = init_gdt(); ASSERT(IS_P2ALIGNED((uintptr_t)gdt, PAGESIZE)); CPU->cpu_gdt = gdt; /* * Setup and install our IDT. */ init_idt(idt0); idtr.dtr_base = (uintptr_t)idt0; idtr.dtr_limit = (NIDT * sizeof (*idt0)) - 1; wr_idtr(&idtr); CPU->cpu_idt = idt0; #if defined(__i386) /* * We maintain a description of idt0 in convenient IDTR format * for #pf's on some older pentium processors. See pentium_pftrap(). */ idt0_default_r = idtr; #endif /* __i386 */ init_tss(); CPU->cpu_tss = ktss0; init_ldt(); } #endif /* __xpv */ /* * In the early kernel, we need to set up a simple GDT to run on. * * XXPV Can dboot use this too? See dboot_gdt.s */ void init_boot_gdt(user_desc_t *bgdt) { #if defined(__amd64) set_usegd(&bgdt[GDT_B32DATA], SDP_LONG, NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); set_usegd(&bgdt[GDT_B64CODE], SDP_LONG, NULL, -1, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); #elif defined(__i386) set_usegd(&bgdt[GDT_B32DATA], NULL, -1, SDT_MEMRWA, SEL_KPL, SDP_PAGES, SDP_OP32); set_usegd(&bgdt[GDT_B32CODE], NULL, -1, SDT_MEMERA, SEL_KPL, SDP_PAGES, SDP_OP32); #endif /* __i386 */ } /* * Enable interpositioning on the system call path by rewriting the * sys{call|enter} MSRs and the syscall-related entries in the IDT to use * the branded entry points. */ void brand_interpositioning_enable(void) { gate_desc_t *idt = CPU->cpu_idt; int i; ASSERT(curthread->t_preempt != 0 || getpil() >= DISP_LEVEL); for (i = 0; brand_tbl[i].ih_inum; i++) { idt[brand_tbl[i].ih_inum] = brand_tbl[i].ih_interp_desc; #if defined(__xpv) xen_idt_write(&idt[brand_tbl[i].ih_inum], brand_tbl[i].ih_inum); #endif } #if defined(__amd64) #if defined(__xpv) /* * Currently the hypervisor only supports 64-bit syscalls via * syscall instruction. The 32-bit syscalls are handled by * interrupt gate above. */ xen_set_callback(brand_sys_syscall, CALLBACKTYPE_syscall, CALLBACKF_mask_events); #else if (x86_feature & X86_ASYSC) { wrmsr(MSR_AMD_LSTAR, (uintptr_t)brand_sys_syscall); wrmsr(MSR_AMD_CSTAR, (uintptr_t)brand_sys_syscall32); } #endif #endif /* __amd64 */ if (x86_feature & X86_SEP) wrmsr(MSR_INTC_SEP_EIP, (uintptr_t)brand_sys_sysenter); } /* * Disable interpositioning on the system call path by rewriting the * sys{call|enter} MSRs and the syscall-related entries in the IDT to use * the standard entry points, which bypass the interpositioning hooks. */ void brand_interpositioning_disable(void) { gate_desc_t *idt = CPU->cpu_idt; int i; ASSERT(curthread->t_preempt != 0 || getpil() >= DISP_LEVEL); for (i = 0; brand_tbl[i].ih_inum; i++) { idt[brand_tbl[i].ih_inum] = brand_tbl[i].ih_default_desc; #if defined(__xpv) xen_idt_write(&idt[brand_tbl[i].ih_inum], brand_tbl[i].ih_inum); #endif } #if defined(__amd64) #if defined(__xpv) /* * See comment above in brand_interpositioning_enable. */ xen_set_callback(sys_syscall, CALLBACKTYPE_syscall, CALLBACKF_mask_events); #else if (x86_feature & X86_ASYSC) { wrmsr(MSR_AMD_LSTAR, (uintptr_t)sys_syscall); wrmsr(MSR_AMD_CSTAR, (uintptr_t)sys_syscall32); } #endif #endif /* __amd64 */ if (x86_feature & X86_SEP) wrmsr(MSR_INTC_SEP_EIP, (uintptr_t)sys_sysenter); }