/* * 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" #include #include #include #include #include #include #if defined(__lint) #include #include #include #else /* __lint */ #include #include #include #include #include #include #include #include #include "assym.h" #endif /* __lint */ /* * We implement five flavours of system call entry points * * - syscall/sysretq (amd64 generic) * - syscall/sysretl (i386 plus SYSC bit) * - sysenter/sysexit (i386 plus SEP bit) * - int/iret (i386 generic) * - lcall/iret (i386 generic) * * The current libc included in Solaris uses int/iret as the base unoptimized * kernel entry method. Older libc implementations and legacy binaries may use * the lcall call gate, so it must continue to be supported. * * System calls that use an lcall call gate are processed in trap() via a * segment-not-present trap, i.e. lcalls are extremely slow(!). * * The basic pattern used in the 32-bit SYSC handler at this point in time is * to have the bare minimum of assembler, and get to the C handlers as * quickly as possible. * * The 64-bit handler is much closer to the sparcv9 handler; that's * because of passing arguments in registers. The 32-bit world still * passes arguments on the stack -- that makes that handler substantially * more complex. * * The two handlers share a few code fragments which are broken * out into preprocessor macros below. * * XX64 come back and speed all this up later. The 32-bit stuff looks * especially easy to speed up the argument copying part .. * * * Notes about segment register usage (c.f. the 32-bit kernel) * * In the 32-bit kernel, segment registers are dutifully saved and * restored on all mode transitions because the kernel uses them directly. * When the processor is running in 64-bit mode, segment registers are * largely ignored. * * %cs and %ss * controlled by the hardware mechanisms that make mode transitions * * The remaining segment registers have to either be pointing at a valid * descriptor i.e. with the 'present' bit set, or they can NULL descriptors * * %ds and %es * always ignored * * %fs and %gs * fsbase and gsbase are used to control the place they really point at. * The kernel only depends on %gs, and controls its own gsbase via swapgs * * Note that loading segment registers is still costly because the GDT * lookup still happens (this is because the hardware can't know that we're * not setting up these segment registers for a 32-bit program). Thus we * avoid doing this in the syscall path, and defer them to lwp context switch * handlers, so the register values remain virtualized to the lwp. */ #if defined(SYSCALLTRACE) #define ORL_SYSCALLTRACE(r32) \ orl syscalltrace(%rip), r32 #else #define ORL_SYSCALLTRACE(r32) #endif /* * In the 32-bit kernel, we do absolutely nothing before getting into the * brand callback checks. In 64-bit land, we do swapgs and then come here. * We assume that the %rsp- and %r15-stashing fields in the CPU structure * are still unused. * * When the callback is invoked, we will be on the user's %gs and * the stack will look like this: * * stack: -------------------------------------- * | callback pointer | * | | user stack pointer | * | | lwp brand data | * | | proc brand data | * v | userland return address | * | callback wrapper return addr | * -------------------------------------- * */ #define BRAND_CALLBACK(callback_id) \ movq %rsp, %gs:CPU_RTMP_RSP /* save the stack pointer */ ;\ movq %r15, %gs:CPU_RTMP_R15 /* save %r15 */ ;\ movq %gs:CPU_THREAD, %r15 /* load the thread pointer */ ;\ movq T_STACK(%r15), %rsp /* switch to the kernel stack */ ;\ subq $16, %rsp /* save space for two pointers */ ;\ pushq %r14 /* save %r14 */ ;\ movq %gs:CPU_RTMP_RSP, %r14 ;\ movq %r14, 8(%rsp) /* stash the user stack pointer */ ;\ popq %r14 /* restore %r14 */ ;\ movq T_LWP(%r15), %r15 /* load the lwp pointer */ ;\ pushq LWP_BRAND(%r15) /* push the lwp's brand data */ ;\ movq LWP_PROCP(%r15), %r15 /* load the proc pointer */ ;\ pushq P_BRAND_DATA(%r15) /* push the proc's brand data */ ;\ movq P_BRAND(%r15), %r15 /* load the brand pointer */ ;\ movq B_MACHOPS(%r15), %r15 /* load the machops pointer */ ;\ movq _CONST(_MUL(callback_id, CPTRSIZE))(%r15), %r15 ;\ cmpq $0, %r15 ;\ je 1f ;\ movq %r15, 24(%rsp) /* save the callback pointer */ ;\ movq %gs:CPU_RTMP_RSP, %r15 /* grab the user stack pointer */ ;\ pushq (%r15) /* push the return address */ ;\ movq %gs:CPU_RTMP_R15, %r15 /* restore %r15 */ ;\ swapgs ;\ call *32(%rsp) /* call callback */ ;\ swapgs ;\ 1: movq %gs:CPU_RTMP_R15, %r15 /* restore %r15 */ ;\ movq %gs:CPU_RTMP_RSP, %rsp /* restore the stack pointer */ #define MSTATE_TRANSITION(from, to) \ movl $from, %edi; \ movl $to, %esi; \ call syscall_mstate /* * Check to see if a simple (direct) return is possible i.e. * * if (t->t_post_sys_ast | syscalltrace | * lwp->lwp_pcb.pcb_rupdate == 1) * do full version ; * * Preconditions: * - t is curthread * Postconditions: * - condition code NE is set if post-sys is too complex * - rtmp is zeroed if it isn't (we rely on this!) * - ltmp is smashed */ #define CHECK_POSTSYS_NE(t, ltmp, rtmp) \ movq T_LWP(t), ltmp; \ movzbl PCB_RUPDATE(ltmp), rtmp; \ ORL_SYSCALLTRACE(rtmp); \ orl T_POST_SYS_AST(t), rtmp; \ cmpl $0, rtmp /* * Fix up the lwp, thread, and eflags for a successful return * * Preconditions: * - zwreg contains zero */ #define SIMPLE_SYSCALL_POSTSYS(t, lwp, zwreg) \ movb $LWP_USER, LWP_STATE(lwp); \ movw zwreg, T_SYSNUM(t); \ andb $_CONST(0xffff - PS_C), REGOFF_RFL(%rsp) /* * ASSERT(lwptoregs(lwp) == rp); * * This may seem obvious, but very odd things happen if this * assertion is false * * Preconditions: * (%rsp is ready for normal call sequence) * Postconditions (if assertion is true): * %r11 is smashed * * ASSERT(rp->r_cs == descnum) * * The code selector is written into the regs structure when the * lwp stack is created. We use this ASSERT to validate that * the regs structure really matches how we came in. * * Preconditions: * (%rsp is ready for normal call sequence) * Postconditions (if assertion is true): * -none- * * ASSERT(lwp->lwp_pcb.pcb_rupdate == 0); * * If this is false, it meant that we returned to userland without * updating the segment registers as we were supposed to. * * Note that we must ensure no interrupts or other traps intervene * between entering privileged mode and performing the assertion, * otherwise we may perform a context switch on the thread, which * will end up setting pcb_rupdate to 1 again. */ #if defined(DEBUG) #if !defined(__lint) __lwptoregs_msg: .string "syscall_asm_amd64.s:%d lwptoregs(%p) [%p] != rp [%p]" __codesel_msg: .string "syscall_asm_amd64.s:%d rp->r_cs [%ld] != %ld" __no_rupdate_msg: .string "syscall_asm_amd64.s:%d lwp %p, pcb_rupdate != 0" #endif /* !__lint */ #define ASSERT_LWPTOREGS(lwp, rp) \ movq LWP_REGS(lwp), %r11; \ cmpq rp, %r11; \ je 7f; \ leaq __lwptoregs_msg(%rip), %rdi; \ movl $__LINE__, %esi; \ movq lwp, %rdx; \ movq %r11, %rcx; \ movq rp, %r8; \ xorl %eax, %eax; \ call panic; \ 7: #define ASSERT_NO_RUPDATE_PENDING(lwp) \ testb $0x1, PCB_RUPDATE(lwp); \ je 8f; \ movq lwp, %rdx; \ leaq __no_rupdate_msg(%rip), %rdi; \ movl $__LINE__, %esi; \ xorl %eax, %eax; \ call panic; \ 8: #else #define ASSERT_LWPTOREGS(lwp, rp) #define ASSERT_NO_RUPDATE_PENDING(lwp) #endif /* * Do the traptrace thing and restore any registers we used * in situ. Assumes that %rsp is pointing at the base of * the struct regs, obviously .. */ #ifdef TRAPTRACE #define SYSCALL_TRAPTRACE(ttype) \ TRACE_PTR(%rdi, %rbx, %ebx, %rcx, ttype); \ TRACE_REGS(%rdi, %rsp, %rbx, %rcx); \ TRACE_STAMP(%rdi); /* rdtsc clobbers %eax, %edx */ \ movq REGOFF_RAX(%rsp), %rax; \ movq REGOFF_RBX(%rsp), %rbx; \ movq REGOFF_RCX(%rsp), %rcx; \ movq REGOFF_RDX(%rsp), %rdx; \ movl %eax, TTR_SYSNUM(%rdi); \ movq REGOFF_RDI(%rsp), %rdi #define SYSCALL_TRAPTRACE32(ttype) \ SYSCALL_TRAPTRACE(ttype); \ /* paranoia: clean the top 32-bits of the registers */ \ orl %eax, %eax; \ orl %ebx, %ebx; \ orl %ecx, %ecx; \ orl %edx, %edx; \ orl %edi, %edi #else /* TRAPTRACE */ #define SYSCALL_TRAPTRACE(ttype) #define SYSCALL_TRAPTRACE32(ttype) #endif /* TRAPTRACE */ /* * The 64-bit libc syscall wrapper does this: * * fn() * { * movq %rcx, %r10 -- because syscall smashes %rcx * movl $CODE, %eax * syscall * * } * * Thus when we come into the kernel: * * %rdi, %rsi, %rdx, %r10, %r8, %r9 contain first six args * %rax is the syscall number * %r12-%r15 contain caller state * * The syscall instruction arranges that: * * %rcx contains the return %rip * %r11d contains bottom 32-bits of %rflags * %rflags is masked (as determined by the SFMASK msr) * %cs is set to UCS_SEL (as determined by the STAR msr) * %ss is set to UDS_SEL (as determined by the STAR msr) * %rip is set to sys_syscall (as determined by the LSTAR msr) * * Or in other words, we have no registers available at all. * Only swapgs can save us! */ #if defined(__lint) /*ARGSUSED*/ void sys_syscall() {} void _allsyscalls() {} size_t _allsyscalls_size; #else /* __lint */ ENTRY_NP2(brand_sys_syscall,_allsyscalls) SWAPGS BRAND_CALLBACK(BRAND_CB_SYSCALL) SWAPGS ALTENTRY(sys_syscall) SWAPGS movq %rsp, %gs:CPU_RTMP_RSP movq %r15, %gs:CPU_RTMP_R15 movq %gs:CPU_THREAD, %r15 movq T_STACK(%r15), %rsp movl $UCS_SEL, REGOFF_CS(%rsp) movq %rcx, REGOFF_RIP(%rsp) /* syscall: %rip -> %rcx */ movq %r11, REGOFF_RFL(%rsp) /* syscall: %rfl -> %r11d */ movl $UDS_SEL, REGOFF_SS(%rsp) movl %eax, %eax /* wrapper: sysc# -> %eax */ movq %rdi, REGOFF_RDI(%rsp) movq %rsi, REGOFF_RSI(%rsp) movq %rdx, REGOFF_RDX(%rsp) movq %r10, REGOFF_RCX(%rsp) /* wrapper: %rcx -> %r10 */ movq %r10, %rcx /* arg[3] for direct calls */ movq %r8, REGOFF_R8(%rsp) movq %r9, REGOFF_R9(%rsp) movq %rax, REGOFF_RAX(%rsp) movq %rbx, REGOFF_RBX(%rsp) movq %rbp, REGOFF_RBP(%rsp) movq %r10, REGOFF_R10(%rsp) movq %gs:CPU_RTMP_RSP, %r11 movq %r11, REGOFF_RSP(%rsp) movq %r12, REGOFF_R12(%rsp) movq %r13, REGOFF_R13(%rsp) movq %r14, REGOFF_R14(%rsp) movq %gs:CPU_RTMP_R15, %r10 movq %r10, REGOFF_R15(%rsp) movq $0, REGOFF_SAVFP(%rsp) movq $0, REGOFF_SAVPC(%rsp) /* * Copy these registers here in case we end up stopped with * someone (like, say, /proc) messing with our register state. * We don't -restore- them unless we have to in update_sregs. * * Since userland -can't- change fsbase or gsbase directly, * and capturing them involves two serializing instructions, * we don't bother to capture them here. */ xorl %ebx, %ebx movw %ds, %bx movq %rbx, REGOFF_DS(%rsp) movw %es, %bx movq %rbx, REGOFF_ES(%rsp) movw %fs, %bx movq %rbx, REGOFF_FS(%rsp) movw %gs, %bx movq %rbx, REGOFF_GS(%rsp) /* * Machine state saved in the regs structure on the stack * First six args in %rdi, %rsi, %rdx, %rcx, %r8, %r9 * %eax is the syscall number * %rsp is the thread's stack, %r15 is curthread * REG_RSP(%rsp) is the user's stack */ SYSCALL_TRAPTRACE($TT_SYSC64) movq %rsp, %rbp movq T_LWP(%r15), %r14 ASSERT_NO_RUPDATE_PENDING(%r14) ENABLE_INTR_FLAGS MSTATE_TRANSITION(LMS_USER, LMS_SYSTEM) movl REGOFF_RAX(%rsp), %eax /* (%rax damaged by mstate call) */ ASSERT_LWPTOREGS(%r14, %rsp) movb $LWP_SYS, LWP_STATE(%r14) incq LWP_RU_SYSC(%r14) movb $NORMALRETURN, LWP_EOSYS(%r14) incq %gs:CPU_STATS_SYS_SYSCALL movw %ax, T_SYSNUM(%r15) movzbl T_PRE_SYS(%r15), %ebx ORL_SYSCALLTRACE(%ebx) testl %ebx, %ebx jne _syscall_pre _syscall_invoke: movq REGOFF_RDI(%rbp), %rdi movq REGOFF_RSI(%rbp), %rsi movq REGOFF_RDX(%rbp), %rdx movq REGOFF_RCX(%rbp), %rcx movq REGOFF_R8(%rbp), %r8 movq REGOFF_R9(%rbp), %r9 cmpl $NSYSCALL, %eax jae _syscall_ill shll $SYSENT_SIZE_SHIFT, %eax leaq sysent(%rax), %rbx call *SY_CALLC(%rbx) movq %rax, %r12 movq %rdx, %r13 /* * If the handler returns two ints, then we need to split the * 64-bit return value into two 32-bit values. */ testw $SE_32RVAL2, SY_FLAGS(%rbx) je 5f movq %r12, %r13 shrq $32, %r13 /* upper 32-bits into %edx */ movl %r12d, %r12d /* lower 32-bits into %eax */ 5: /* * Optimistically assume that there's no post-syscall * work to do. (This is to avoid having to call syscall_mstate() * with interrupts disabled) */ MSTATE_TRANSITION(LMS_SYSTEM, LMS_USER) /* * We must protect ourselves from being descheduled here; * If we were, and we ended up on another cpu, or another * lwp got in ahead of us, it could change the segment * registers without us noticing before we return to userland. */ CLI(%r14) CHECK_POSTSYS_NE(%r15, %r14, %ebx) jne _syscall_post SIMPLE_SYSCALL_POSTSYS(%r15, %r14, %bx) movq %r12, REGOFF_RAX(%rsp) movq %r13, REGOFF_RDX(%rsp) /* * To get back to userland, we need the return %rip in %rcx and * the return %rfl in %r11d. The sysretq instruction also arranges * to fix up %cs and %ss; everything else is our responsibility. */ movq REGOFF_RDI(%rsp), %rdi movq REGOFF_RSI(%rsp), %rsi movq REGOFF_RDX(%rsp), %rdx /* %rcx used to restore %rip value */ movq REGOFF_R8(%rsp), %r8 movq REGOFF_R9(%rsp), %r9 movq REGOFF_RAX(%rsp), %rax movq REGOFF_RBX(%rsp), %rbx movq REGOFF_RBP(%rsp), %rbp movq REGOFF_R10(%rsp), %r10 /* %r11 used to restore %rfl value */ movq REGOFF_R12(%rsp), %r12 movq REGOFF_R13(%rsp), %r13 movq REGOFF_R14(%rsp), %r14 movq REGOFF_R15(%rsp), %r15 movq REGOFF_RIP(%rsp), %rcx movl REGOFF_RFL(%rsp), %r11d movq REGOFF_RSP(%rsp), %rsp SWAPGS sysretq _syscall_pre: call pre_syscall movl %eax, %r12d testl %eax, %eax jne _syscall_post_call /* * Didn't abort, so reload the syscall args and invoke the handler. */ movzwl T_SYSNUM(%r15), %eax jmp _syscall_invoke _syscall_ill: call nosys movq %rax, %r12 movq %rdx, %r13 jmp _syscall_post_call _syscall_post: STI /* * Sigh, our optimism wasn't justified, put it back to LMS_SYSTEM * so that we can account for the extra work it takes us to finish. */ MSTATE_TRANSITION(LMS_USER, LMS_SYSTEM) _syscall_post_call: movq %r12, %rdi movq %r13, %rsi call post_syscall MSTATE_TRANSITION(LMS_SYSTEM, LMS_USER) jmp _sys_rtt SET_SIZE(sys_syscall) SET_SIZE(brand_sys_syscall) #endif /* __lint */ #if defined(__lint) /*ARGSUSED*/ void sys_syscall32() {} #else /* __lint */ ENTRY_NP(brand_sys_syscall32) SWAPGS BRAND_CALLBACK(BRAND_CB_SYSCALL32) SWAPGS ALTENTRY(sys_syscall32) SWAPGS movl %esp, %r10d movq %gs:CPU_THREAD, %r15 movq T_STACK(%r15), %rsp movl %eax, %eax movl $U32CS_SEL, REGOFF_CS(%rsp) movl %ecx, REGOFF_RIP(%rsp) /* syscall: %rip -> %rcx */ movq %r11, REGOFF_RFL(%rsp) /* syscall: %rfl -> %r11d */ movq %r10, REGOFF_RSP(%rsp) movl $UDS_SEL, REGOFF_SS(%rsp) _syscall32_save: movl %edi, REGOFF_RDI(%rsp) movl %esi, REGOFF_RSI(%rsp) movl %ebp, REGOFF_RBP(%rsp) movl %ebx, REGOFF_RBX(%rsp) movl %edx, REGOFF_RDX(%rsp) movl %ecx, REGOFF_RCX(%rsp) movl %eax, REGOFF_RAX(%rsp) /* wrapper: sysc# -> %eax */ movq $0, REGOFF_SAVFP(%rsp) movq $0, REGOFF_SAVPC(%rsp) /* * Copy these registers here in case we end up stopped with * someone (like, say, /proc) messing with our register state. * We don't -restore- them unless we have to in update_sregs. * * Since userland -can't- change fsbase or gsbase directly, * we don't bother to capture them here. */ xorl %ebx, %ebx movw %ds, %bx movq %rbx, REGOFF_DS(%rsp) movw %es, %bx movq %rbx, REGOFF_ES(%rsp) movw %fs, %bx movq %rbx, REGOFF_FS(%rsp) movw %gs, %bx movq %rbx, REGOFF_GS(%rsp) /* * Application state saved in the regs structure on the stack * %eax is the syscall number * %rsp is the thread's stack, %r15 is curthread * REG_RSP(%rsp) is the user's stack */ SYSCALL_TRAPTRACE32($TT_SYSC) movq %rsp, %rbp movq T_LWP(%r15), %r14 ASSERT_NO_RUPDATE_PENDING(%r14) ENABLE_INTR_FLAGS MSTATE_TRANSITION(LMS_USER, LMS_SYSTEM) movl REGOFF_RAX(%rsp), %eax /* (%rax damaged by mstate call) */ ASSERT_LWPTOREGS(%r14, %rsp) incq %gs:CPU_STATS_SYS_SYSCALL /* * Make some space for MAXSYSARGS (currently 8) 32-bit args placed * into 64-bit (long) arg slots, maintaining 16 byte alignment. Or * more succinctly: * * SA(MAXSYSARGS * sizeof (long)) == 64 */ #define SYS_DROP 64 /* drop for args */ subq $SYS_DROP, %rsp movb $LWP_SYS, LWP_STATE(%r14) movq %r15, %rdi movq %rsp, %rsi call syscall_entry /* * Fetch the arguments copied onto the kernel stack and put * them in the right registers to invoke a C-style syscall handler. * %rax contains the handler address. * * Ideas for making all this go faster of course include simply * forcibly fetching 6 arguments from the user stack under lofault * protection, reverting to copyin_args only when watchpoints * are in effect. * * (If we do this, make sure that exec and libthread leave * enough space at the top of the stack to ensure that we'll * never do a fetch from an invalid page.) * * Lots of ideas here, but they won't really help with bringup B-) * Correctness can't wait, performance can wait a little longer .. */ movq %rax, %rbx movl 0(%rsp), %edi movl 8(%rsp), %esi movl 0x10(%rsp), %edx movl 0x18(%rsp), %ecx movl 0x20(%rsp), %r8d movl 0x28(%rsp), %r9d call *SY_CALLC(%rbx) movq %rbp, %rsp /* pop the args */ /* * amd64 syscall handlers -always- return a 64-bit value in %rax. * On the 32-bit kernel, they always return that value in %eax:%edx * as required by the 32-bit ABI. * * Simulate the same behaviour by unconditionally splitting the * return value in the same way. */ movq %rax, %r13 shrq $32, %r13 /* upper 32-bits into %edx */ movl %eax, %r12d /* lower 32-bits into %eax */ /* * Optimistically assume that there's no post-syscall * work to do. (This is to avoid having to call syscall_mstate() * with interrupts disabled) */ MSTATE_TRANSITION(LMS_SYSTEM, LMS_USER) /* * We must protect ourselves from being descheduled here; * If we were, and we ended up on another cpu, or another * lwp got in ahead of us, it could change the segment * registers without us noticing before we return to userland. */ CLI(%r14) CHECK_POSTSYS_NE(%r15, %r14, %ebx) jne _full_syscall_postsys32 SIMPLE_SYSCALL_POSTSYS(%r15, %r14, %bx) /* * To get back to userland, we need to put the return %rip in %rcx and * the return %rfl in %r11d. The sysret instruction also arranges * to fix up %cs and %ss; everything else is our responsibility. */ movl %r12d, %eax /* %eax: rval1 */ movl REGOFF_RBX(%rsp), %ebx /* %ecx used for return pointer */ movl %r13d, %edx /* %edx: rval2 */ movl REGOFF_RBP(%rsp), %ebp movl REGOFF_RSI(%rsp), %esi movl REGOFF_RDI(%rsp), %edi movl REGOFF_RFL(%rsp), %r11d /* %r11 -> eflags */ movl REGOFF_RIP(%rsp), %ecx /* %ecx -> %eip */ movl REGOFF_RSP(%rsp), %esp swapgs sysretl _full_syscall_postsys32: STI /* * Sigh, our optimism wasn't justified, put it back to LMS_SYSTEM * so that we can account for the extra work it takes us to finish. */ MSTATE_TRANSITION(LMS_USER, LMS_SYSTEM) movq %r15, %rdi movq %r12, %rsi /* rval1 - %eax */ movq %r13, %rdx /* rval2 - %edx */ call syscall_exit MSTATE_TRANSITION(LMS_SYSTEM, LMS_USER) jmp _sys_rtt SET_SIZE(sys_syscall32) SET_SIZE(brand_sys_syscall32) #endif /* __lint */ /* * System call handler via the sysenter instruction * Used only for 32-bit system calls on the 64-bit kernel. * * The caller in userland has arranged that: * * - %eax contains the syscall number * - %ecx contains the user %esp * - %edx contains the return %eip * - the user stack contains the args to the syscall * * Hardware and (privileged) initialization code have arranged that by * the time the sysenter instructions completes: * * - %rip is pointing to sys_sysenter (below). * - %cs and %ss are set to kernel text and stack (data) selectors. * - %rsp is pointing at the lwp's stack * - interrupts have been disabled. * * Note that we are unable to return both "rvals" to userland with * this call, as %edx is used by the sysexit instruction. * * One final complication in this routine is its interaction with * single-stepping in a debugger. For most of the system call mechanisms, * the CPU automatically clears the single-step flag before we enter the * kernel. The sysenter mechanism does not clear the flag, so a user * single-stepping through a libc routine may suddenly find him/herself * single-stepping through the kernel. To detect this, kmdb compares the * trap %pc to the [brand_]sys_enter addresses on each single-step trap. * If it finds that we have single-stepped to a sysenter entry point, it * explicitly clears the flag and executes the sys_sysenter routine. * * One final complication in this final complication is the fact that we * have two different entry points for sysenter: brand_sys_sysenter and * sys_sysenter. If we enter at brand_sys_sysenter and start single-stepping * through the kernel with kmdb, we will eventually hit the instruction at * sys_sysenter. kmdb cannot distinguish between that valid single-step * and the undesirable one mentioned above. To avoid this situation, we * simply add a jump over the instruction at sys_sysenter to make it * impossible to single-step to it. */ #if defined(__lint) void sys_sysenter() {} #else /* __lint */ ENTRY_NP(brand_sys_sysenter) SWAPGS ALTENTRY(_brand_sys_sysenter_post_swapgs) BRAND_CALLBACK(BRAND_CB_SYSENTER) /* * Jump over sys_sysenter to allow single-stepping as described * above. */ jmp _sys_sysenter_post_swapgs ALTENTRY(sys_sysenter) SWAPGS ALTENTRY(_sys_sysenter_post_swapgs) movq %gs:CPU_THREAD, %r15 movl $U32CS_SEL, REGOFF_CS(%rsp) movl %ecx, REGOFF_RSP(%rsp) /* wrapper: %esp -> %ecx */ movl %edx, REGOFF_RIP(%rsp) /* wrapper: %eip -> %edx */ pushfq popq %r10 movl $UDS_SEL, REGOFF_SS(%rsp) /* * Set the interrupt flag before storing the flags to the * flags image on the stack so we can return to user with * interrupts enabled if we return via sys_rtt_syscall32 */ orq $PS_IE, %r10 movq %r10, REGOFF_RFL(%rsp) movl %edi, REGOFF_RDI(%rsp) movl %esi, REGOFF_RSI(%rsp) movl %ebp, REGOFF_RBP(%rsp) movl %ebx, REGOFF_RBX(%rsp) movl %edx, REGOFF_RDX(%rsp) movl %ecx, REGOFF_RCX(%rsp) movl %eax, REGOFF_RAX(%rsp) /* wrapper: sysc# -> %eax */ movq $0, REGOFF_SAVFP(%rsp) movq $0, REGOFF_SAVPC(%rsp) /* * Copy these registers here in case we end up stopped with * someone (like, say, /proc) messing with our register state. * We don't -restore- them unless we have to in update_sregs. * * Since userland -can't- change fsbase or gsbase directly, * we don't bother to capture them here. */ xorl %ebx, %ebx movw %ds, %bx movq %rbx, REGOFF_DS(%rsp) movw %es, %bx movq %rbx, REGOFF_ES(%rsp) movw %fs, %bx movq %rbx, REGOFF_FS(%rsp) movw %gs, %bx movq %rbx, REGOFF_GS(%rsp) /* * Application state saved in the regs structure on the stack * %eax is the syscall number * %rsp is the thread's stack, %r15 is curthread * REG_RSP(%rsp) is the user's stack */ SYSCALL_TRAPTRACE($TT_SYSENTER) movq %rsp, %rbp movq T_LWP(%r15), %r14 ASSERT_NO_RUPDATE_PENDING(%r14) ENABLE_INTR_FLAGS /* * Catch 64-bit process trying to issue sysenter instruction * on Nocona based systems. */ movq LWP_PROCP(%r14), %rax cmpq $DATAMODEL_ILP32, P_MODEL(%rax) je 7f /* * For a non-32-bit process, simulate a #ud, since that's what * native hardware does. The traptrace entry (above) will * let you know what really happened. */ movq $T_ILLINST, REGOFF_TRAPNO(%rsp) movq REGOFF_CS(%rsp), %rdi movq %rdi, REGOFF_ERR(%rsp) movq %rsp, %rdi movq REGOFF_RIP(%rsp), %rsi movl %gs:CPU_ID, %edx call trap jmp _sys_rtt 7: MSTATE_TRANSITION(LMS_USER, LMS_SYSTEM) movl REGOFF_RAX(%rsp), %eax /* (%rax damaged by mstate calls) */ ASSERT_LWPTOREGS(%r14, %rsp) incq %gs:CPU_STATS_SYS_SYSCALL /* * Make some space for MAXSYSARGS (currently 8) 32-bit args * placed into 64-bit (long) arg slots, plus one 64-bit * (long) arg count, maintaining 16 byte alignment. */ subq $SYS_DROP, %rsp movb $LWP_SYS, LWP_STATE(%r14) movq %r15, %rdi movq %rsp, %rsi call syscall_entry /* * Fetch the arguments copied onto the kernel stack and put * them in the right registers to invoke a C-style syscall handler. * %rax contains the handler address. */ movq %rax, %rbx movl 0(%rsp), %edi movl 8(%rsp), %esi movl 0x10(%rsp), %edx movl 0x18(%rsp), %ecx movl 0x20(%rsp), %r8d movl 0x28(%rsp), %r9d call *SY_CALLC(%rbx) movq %rbp, %rsp /* pop the args */ /* * amd64 syscall handlers -always- return a 64-bit value in %rax. * On the 32-bit kernel, the always return that value in %eax:%edx * as required by the 32-bit ABI. * * Simulate the same behaviour by unconditionally splitting the * return value in the same way. */ movq %rax, %r13 shrq $32, %r13 /* upper 32-bits into %edx */ movl %eax, %r12d /* lower 32-bits into %eax */ /* * Optimistically assume that there's no post-syscall * work to do. (This is to avoid having to call syscall_mstate() * with interrupts disabled) */ MSTATE_TRANSITION(LMS_SYSTEM, LMS_USER) /* * We must protect ourselves from being descheduled here; * If we were, and we ended up on another cpu, or another * lwp got int ahead of us, it could change the segment * registers without us noticing before we return to userland. */ cli CHECK_POSTSYS_NE(%r15, %r14, %ebx) jne _full_syscall_postsys32 SIMPLE_SYSCALL_POSTSYS(%r15, %r14, %bx) /* * To get back to userland, load up the 32-bit registers and * sysexit back where we came from. */ /* * Interrupts will be turned on by the 'sti' executed just before * sysexit. The following ensures that restoring the user's rflags * doesn't enable interrupts too soon. */ andq $_BITNOT(PS_IE), REGOFF_RFL(%rsp) /* * (There's no point in loading up %edx because the sysexit * mechanism smashes it.) */ movl %r12d, %eax movl REGOFF_RBX(%rsp), %ebx movl REGOFF_RBP(%rsp), %ebp movl REGOFF_RSI(%rsp), %esi movl REGOFF_RDI(%rsp), %edi movl REGOFF_RIP(%rsp), %edx /* sysexit: %edx -> %eip */ pushq REGOFF_RFL(%rsp) popfq movl REGOFF_RSP(%rsp), %ecx /* sysexit: %ecx -> %esp */ swapgs sti sysexit SET_SIZE(sys_sysenter) SET_SIZE(_sys_sysenter_post_swapgs) SET_SIZE(brand_sys_sysenter) #endif /* __lint */ #if defined(__lint) /* * System call via an int80. This entry point is only used by the Linux * application environment. Unlike the other entry points, there is no * default action to take if no callback is registered for this process. */ void sys_int80() {} #else /* __lint */ ENTRY_NP(brand_sys_int80) swapgs BRAND_CALLBACK(BRAND_CB_INT80) swapgs ENTRY_NP(sys_int80) /* * We hit an int80, but this process isn't of a brand with an int80 * handler. Bad process! Make it look as if the INT failed. * Modify %eip to point before the INT, push the expected error * code and fake a GP fault. * */ subq $2, (%rsp) /* int insn 2-bytes */ pushq $_CONST(_MUL(T_INT80, GATE_DESC_SIZE) + 2) jmp gptrap / GP fault SET_SIZE(sys_int80) SET_SIZE(brand_sys_int80) #endif /* __lint */ /* * This is the destination of the "int $T_SYSCALLINT" interrupt gate, used by * the generic i386 libc to do system calls. We do a small amount of setup * before jumping into the existing sys_syscall32 path. */ #if defined(__lint) /*ARGSUSED*/ void sys_syscall_int() {} #else /* __lint */ ENTRY_NP(brand_sys_syscall_int) SWAPGS BRAND_CALLBACK(BRAND_CB_INT91) swapgs ALTENTRY(sys_syscall_int) swapgs movq %gs:CPU_THREAD, %r15 movq T_STACK(%r15), %rsp movl %eax, %eax /* * Set t_post_sys on this thread to force ourselves out via the slow * path. It might be possible at some later date to optimize this out * and use a faster return mechanism. */ movb $1, T_POST_SYS(%r15) CLEAN_CS jmp _syscall32_save SET_SIZE(sys_syscall_int) SET_SIZE(brand_sys_syscall_int) #endif /* __lint */ /* * Legacy 32-bit applications and old libc implementations do lcalls; * we should never get here because the LDT entry containing the syscall * segment descriptor has the "segment present" bit cleared, which means * we end up processing those system calls in trap() via a not-present trap. * * We do it this way because a call gate unhelpfully does -nothing- to the * interrupt flag bit, so an interrupt can run us just after the lcall * completes, but just before the swapgs takes effect. Thus the INTR_PUSH and * INTR_POP paths would have to be slightly more complex to dance around * this problem, and end up depending explicitly on the first * instruction of this handler being either swapgs or cli. */ #if defined(__lint) /*ARGSUSED*/ void sys_lcall32() {} #else /* __lint */ ENTRY_NP(sys_lcall32) SWAPGS pushq $0 pushq %rbp movq %rsp, %rbp leaq __lcall_panic_str(%rip), %rdi xorl %eax, %eax call panic SET_SIZE(sys_lcall32) __lcall_panic_str: .string "sys_lcall32: shouldn't be here!" /* * Declare a uintptr_t which covers the entire pc range of syscall * handlers for the stack walkers that need this. */ .align CPTRSIZE .globl _allsyscalls_size .type _allsyscalls_size, @object _allsyscalls_size: .NWORD . - _allsyscalls SET_SIZE(_allsyscalls_size) #endif /* __lint */ /* * These are the thread context handlers for lwps using sysenter/sysexit. */ #if defined(__lint) /*ARGSUSED*/ void sep_save(void *ksp) {} /*ARGSUSED*/ void sep_restore(void *ksp) {} #else /* __lint */ /* * setting this value to zero as we switch away causes the * stack-pointer-on-sysenter to be NULL, ensuring that we * don't silently corrupt another (preempted) thread stack * when running an lwp that (somehow) didn't get sep_restore'd */ ENTRY_NP(sep_save) xorl %edx, %edx xorl %eax, %eax movl $MSR_INTC_SEP_ESP, %ecx wrmsr ret SET_SIZE(sep_save) /* * Update the kernel stack pointer as we resume onto this cpu. */ ENTRY_NP(sep_restore) movq %rdi, %rdx shrq $32, %rdx movl %edi, %eax movl $MSR_INTC_SEP_ESP, %ecx wrmsr ret SET_SIZE(sep_restore) #endif /* __lint */