/*--------------------------------------------------------------------*/
/*--- Darwin-specific syscalls, etc. syswrap-amd64-darwin.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2005-2013 Apple Inc.
Greg Parker gparker@apple.com
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307, USA.
The GNU General Public License is contained in the file COPYING.
*/
#if defined(VGP_amd64_darwin)
#include "config.h" // DARWIN_VERS
#include "pub_core_basics.h"
#include "pub_core_vki.h"
#include "pub_core_libcsetjmp.h" // to keep _threadstate.h happy
#include "pub_core_threadstate.h"
#include "pub_core_aspacemgr.h"
#include "pub_core_xarray.h"
#include "pub_core_clientstate.h"
#include "pub_core_debuglog.h"
#include "pub_core_debuginfo.h" // VG_(di_notify_*)
#include "pub_core_transtab.h" // VG_(discard_translations)
#include "pub_core_libcbase.h"
#include "pub_core_libcassert.h"
#include "pub_core_libcfile.h"
#include "pub_core_libcprint.h"
#include "pub_core_libcproc.h"
#include "pub_core_libcsignal.h"
#include "pub_core_mallocfree.h"
#include "pub_core_options.h"
#include "pub_core_scheduler.h"
#include "pub_core_sigframe.h" // For VG_(sigframe_destroy)()
#include "pub_core_signals.h"
#include "pub_core_syscall.h"
#include "pub_core_syswrap.h"
#include "pub_core_tooliface.h"
#include "priv_types_n_macros.h"
#include "priv_syswrap-generic.h" /* for decls of generic wrappers */
#include "priv_syswrap-darwin.h" /* for decls of darwin-ish wrappers */
#include "priv_syswrap-main.h"
#include <mach/mach.h>
static void x86_thread_state64_from_vex(x86_thread_state64_t *mach,
VexGuestAMD64State *vex)
{
mach->__rax = vex->guest_RAX;
mach->__rbx = vex->guest_RBX;
mach->__rcx = vex->guest_RCX;
mach->__rdx = vex->guest_RDX;
mach->__rdi = vex->guest_RDI;
mach->__rsi = vex->guest_RSI;
mach->__rbp = vex->guest_RBP;
mach->__rsp = vex->guest_RSP;
mach->__rflags = LibVEX_GuestAMD64_get_rflags(vex);
mach->__rip = vex->guest_RIP;
mach->__r8 = vex->guest_R8;
mach->__r9 = vex->guest_R9;
mach->__r10 = vex->guest_R10;
mach->__r11 = vex->guest_R11;
mach->__r12 = vex->guest_R12;
mach->__r13 = vex->guest_R13;
mach->__r14 = vex->guest_R14;
mach->__r15 = vex->guest_R15;
/* GrP fixme
mach->__cs = vex->guest_CS;
mach->__fs = vex->guest_FS;
mach->__gs = vex->guest_GS;
*/
}
static void x86_float_state64_from_vex(x86_float_state64_t *mach,
VexGuestAMD64State *vex)
{
// DDD: #warning GrP fixme fp state
// JRS: what about the YMMHI bits? Are they important?
VG_(memcpy)(&mach->__fpu_xmm0, &vex->guest_YMM0, sizeof(mach->__fpu_xmm0));
VG_(memcpy)(&mach->__fpu_xmm1, &vex->guest_YMM1, sizeof(mach->__fpu_xmm1));
VG_(memcpy)(&mach->__fpu_xmm2, &vex->guest_YMM2, sizeof(mach->__fpu_xmm2));
VG_(memcpy)(&mach->__fpu_xmm3, &vex->guest_YMM3, sizeof(mach->__fpu_xmm3));
VG_(memcpy)(&mach->__fpu_xmm4, &vex->guest_YMM4, sizeof(mach->__fpu_xmm4));
VG_(memcpy)(&mach->__fpu_xmm5, &vex->guest_YMM5, sizeof(mach->__fpu_xmm5));
VG_(memcpy)(&mach->__fpu_xmm6, &vex->guest_YMM6, sizeof(mach->__fpu_xmm6));
VG_(memcpy)(&mach->__fpu_xmm7, &vex->guest_YMM7, sizeof(mach->__fpu_xmm7));
VG_(memcpy)(&mach->__fpu_xmm8, &vex->guest_YMM8, sizeof(mach->__fpu_xmm8));
VG_(memcpy)(&mach->__fpu_xmm9, &vex->guest_YMM9, sizeof(mach->__fpu_xmm9));
VG_(memcpy)(&mach->__fpu_xmm10, &vex->guest_YMM10, sizeof(mach->__fpu_xmm10));
VG_(memcpy)(&mach->__fpu_xmm11, &vex->guest_YMM11, sizeof(mach->__fpu_xmm11));
VG_(memcpy)(&mach->__fpu_xmm12, &vex->guest_YMM12, sizeof(mach->__fpu_xmm12));
VG_(memcpy)(&mach->__fpu_xmm13, &vex->guest_YMM13, sizeof(mach->__fpu_xmm13));
VG_(memcpy)(&mach->__fpu_xmm14, &vex->guest_YMM14, sizeof(mach->__fpu_xmm14));
VG_(memcpy)(&mach->__fpu_xmm15, &vex->guest_YMM15, sizeof(mach->__fpu_xmm15));
}
void thread_state_from_vex(thread_state_t mach_generic,
thread_state_flavor_t flavor,
mach_msg_type_number_t count,
VexGuestArchState *vex_generic)
{
VexGuestAMD64State *vex = (VexGuestAMD64State *)vex_generic;
switch (flavor) {
case x86_THREAD_STATE64:
vg_assert(count == x86_THREAD_STATE64_COUNT);
x86_thread_state64_from_vex((x86_thread_state64_t *)mach_generic, vex);
break;
case x86_FLOAT_STATE64:
vg_assert(count == x86_FLOAT_STATE64_COUNT);
x86_float_state64_from_vex((x86_float_state64_t *)mach_generic, vex);
break;
default:
vg_assert(0);
}
}
static void x86_thread_state64_to_vex(const x86_thread_state64_t *mach,
VexGuestAMD64State *vex)
{
LibVEX_GuestAMD64_initialise(vex);
vex->guest_RAX = mach->__rax;
vex->guest_RBX = mach->__rbx;
vex->guest_RCX = mach->__rcx;
vex->guest_RDX = mach->__rdx;
vex->guest_RDI = mach->__rdi;
vex->guest_RSI = mach->__rsi;
vex->guest_RBP = mach->__rbp;
vex->guest_RSP = mach->__rsp;
// DDD: #warning GrP fixme eflags
vex->guest_RIP = mach->__rip;
vex->guest_R8 = mach->__r8;
vex->guest_R9 = mach->__r9;
vex->guest_R10 = mach->__r10;
vex->guest_R11 = mach->__r11;
vex->guest_R12 = mach->__r12;
vex->guest_R13 = mach->__r13;
vex->guest_R14 = mach->__r14;
vex->guest_R15 = mach->__r15;
/* GrP fixme
vex->guest_CS = mach->__cs;
vex->guest_FS = mach->__fs;
vex->guest_GS = mach->__gs;
*/
}
static void x86_float_state64_to_vex(const x86_float_state64_t *mach,
VexGuestAMD64State *vex)
{
// DDD: #warning GrP fixme fp state
// JRS: what about the YMMHI bits? Are they important?
VG_(memcpy)(&vex->guest_YMM0, &mach->__fpu_xmm0, sizeof(mach->__fpu_xmm0));
VG_(memcpy)(&vex->guest_YMM1, &mach->__fpu_xmm1, sizeof(mach->__fpu_xmm1));
VG_(memcpy)(&vex->guest_YMM2, &mach->__fpu_xmm2, sizeof(mach->__fpu_xmm2));
VG_(memcpy)(&vex->guest_YMM3, &mach->__fpu_xmm3, sizeof(mach->__fpu_xmm3));
VG_(memcpy)(&vex->guest_YMM4, &mach->__fpu_xmm4, sizeof(mach->__fpu_xmm4));
VG_(memcpy)(&vex->guest_YMM5, &mach->__fpu_xmm5, sizeof(mach->__fpu_xmm5));
VG_(memcpy)(&vex->guest_YMM6, &mach->__fpu_xmm6, sizeof(mach->__fpu_xmm6));
VG_(memcpy)(&vex->guest_YMM7, &mach->__fpu_xmm7, sizeof(mach->__fpu_xmm7));
VG_(memcpy)(&vex->guest_YMM8, &mach->__fpu_xmm8, sizeof(mach->__fpu_xmm8));
VG_(memcpy)(&vex->guest_YMM9, &mach->__fpu_xmm9, sizeof(mach->__fpu_xmm9));
VG_(memcpy)(&vex->guest_YMM10, &mach->__fpu_xmm10, sizeof(mach->__fpu_xmm10));
VG_(memcpy)(&vex->guest_YMM11, &mach->__fpu_xmm11, sizeof(mach->__fpu_xmm11));
VG_(memcpy)(&vex->guest_YMM12, &mach->__fpu_xmm12, sizeof(mach->__fpu_xmm12));
VG_(memcpy)(&vex->guest_YMM13, &mach->__fpu_xmm13, sizeof(mach->__fpu_xmm13));
VG_(memcpy)(&vex->guest_YMM14, &mach->__fpu_xmm14, sizeof(mach->__fpu_xmm14));
VG_(memcpy)(&vex->guest_YMM15, &mach->__fpu_xmm15, sizeof(mach->__fpu_xmm15));
}
void thread_state_to_vex(const thread_state_t mach_generic,
thread_state_flavor_t flavor,
mach_msg_type_number_t count,
VexGuestArchState *vex_generic)
{
VexGuestAMD64State *vex = (VexGuestAMD64State *)vex_generic;
switch(flavor) {
case x86_THREAD_STATE64:
vg_assert(count == x86_THREAD_STATE64_COUNT);
x86_thread_state64_to_vex((const x86_thread_state64_t*)mach_generic,vex);
break;
case x86_FLOAT_STATE64:
vg_assert(count == x86_FLOAT_STATE64_COUNT);
x86_float_state64_to_vex((const x86_float_state64_t*)mach_generic,vex);
break;
default:
vg_assert(0);
break;
}
}
ThreadState *build_thread(const thread_state_t state,
thread_state_flavor_t flavor,
mach_msg_type_number_t count)
{
ThreadId tid = VG_(alloc_ThreadState)();
ThreadState *tst = VG_(get_ThreadState)(tid);
vg_assert(flavor == x86_THREAD_STATE64);
vg_assert(count == x86_THREAD_STATE64_COUNT);
// Initialize machine registers
thread_state_to_vex(state, flavor, count, &tst->arch.vex);
I_die_here;
// GrP fixme signals, sig_mask, tmp_sig_mask, os_state.parent
find_stack_segment(tid, tst->arch.vex.guest_RSP);
return tst;
}
// Edit the thread state to send to the real kernel.
// The real thread will run start_thread_NORETURN(tst)
// on a separate non-client stack.
void hijack_thread_state(thread_state_t mach_generic,
thread_state_flavor_t flavor,
mach_msg_type_number_t count,
ThreadState *tst)
{
x86_thread_state64_t *mach = (x86_thread_state64_t *)mach_generic;
char *stack;
vg_assert(flavor == x86_THREAD_STATE64);
vg_assert(count == x86_THREAD_STATE64_COUNT);
stack = (char *)allocstack(tst->tid);
stack -= 64+320; // make room for top frame
memset(stack, 0, 64+320); // ...and clear it
*(uintptr_t *)stack = 0; // push fake return address
mach->__rdi = (uintptr_t)tst; // arg1 = tst
mach->__rip = (uintptr_t)&start_thread_NORETURN;
mach->__rsp = (uintptr_t)stack;
}
/* Call f(arg1), but first switch stacks, using 'stack' as the new
stack, and use 'retaddr' as f's return-to address. Also, clear all
the integer registers before entering f.*/
__attribute__((noreturn))
void call_on_new_stack_0_1 ( Addr stack,
Addr retaddr,
void (*f)(Word),
Word arg1 );
// %rdi == stack (must be 16-byte aligned)
// %rsi == retaddr
// %rdx == f
// %rcx == arg1
asm(
".globl _call_on_new_stack_0_1\n"
"_call_on_new_stack_0_1:\n"
" movq %rsp, %rbp\n" // remember old stack pointer
" movq %rdi, %rsp\n" // set new stack
" movq %rcx, %rdi\n" // set arg1
" pushq %rsi\n" // retaddr to new stack
" pushq %rdx\n" // f to new stack
" movq $0, %rax\n" // zero all other GP regs
" movq $0, %rbx\n"
" movq $0, %rcx\n"
" movq $0, %rdx\n"
" movq $0, %rsi\n"
" movq $0, %rbp\n"
" movq $0, %r8\n"
" movq $0, %r9\n"
" movq $0, %r10\n"
" movq $0, %r11\n"
" movq $0, %r12\n"
" movq $0, %r13\n"
" movq $0, %r14\n"
" movq $0, %r15\n"
" ret\n" // jump to f
" ud2\n" // should never get here
);
asm(
".globl _pthread_hijack_asm\n"
"_pthread_hijack_asm:\n"
" movq %rsp,%rbp\n"
" push $0\n" // alignment pad
" push %rbp\n" // original sp
// other values stay where they are in registers
" push $0\n" // fake return address
" jmp _pthread_hijack\n"
);
void pthread_hijack(Addr self, Addr kport, Addr func, Addr func_arg,
Addr stacksize, Addr flags, Addr sp)
{
vki_sigset_t blockall;
ThreadState *tst = (ThreadState *)func_arg;
VexGuestAMD64State *vex = &tst->arch.vex;
// VG_(printf)("pthread_hijack pthread %p, machthread %p, func %p, arg %p, stack %p, flags %p, stack %p\n", self, kport, func, func_arg, stacksize, flags, sp);
// Wait for parent thread's permission.
// The parent thread holds V's lock on our behalf.
semaphore_wait(tst->os_state.child_go);
/* Start the thread with all signals blocked. VG_(scheduler) will
set the mask correctly when we finally get there. */
VG_(sigfillset)(&blockall);
VG_(sigprocmask)(VKI_SIG_SETMASK, &blockall, NULL);
// Set thread's registers
// Do this FIRST because some code below tries to collect a backtrace,
// which requires valid register data.
LibVEX_GuestAMD64_initialise(vex);
vex->guest_RIP = pthread_starter;
vex->guest_RDI = self;
vex->guest_RSI = kport;
vex->guest_RDX = func;
vex->guest_RCX = tst->os_state.func_arg;
vex->guest_R8 = stacksize;
vex->guest_R9 = flags;
vex->guest_RSP = sp;
// Record thread's stack and Mach port and pthread struct
tst->os_state.pthread = self;
tst->os_state.lwpid = kport;
record_named_port(tst->tid, kport, MACH_PORT_RIGHT_SEND, "thread-%p");
if ((flags & 0x01000000) == 0) {
// kernel allocated stack - needs mapping
Addr stack = VG_PGROUNDUP(sp) - stacksize;
tst->client_stack_highest_word = stack+stacksize;
tst->client_stack_szB = stacksize;
// pthread structure
ML_(notify_core_and_tool_of_mmap)(
stack+stacksize, pthread_structsize,
VKI_PROT_READ|VKI_PROT_WRITE, VKI_MAP_PRIVATE, -1, 0);
// stack contents
ML_(notify_core_and_tool_of_mmap)(
stack, stacksize,
VKI_PROT_READ|VKI_PROT_WRITE, VKI_MAP_PRIVATE, -1, 0);
// guard page
ML_(notify_core_and_tool_of_mmap)(
stack-VKI_PAGE_SIZE, VKI_PAGE_SIZE,
0, VKI_MAP_PRIVATE, -1, 0);
} else {
// client allocated stack
find_stack_segment(tst->tid, sp);
}
ML_(sync_mappings)("after", "pthread_hijack", 0);
// DDD: should this be here rather than in POST(sys_bsdthread_create)?
// But we don't have ptid here...
//VG_TRACK ( pre_thread_ll_create, ptid, tst->tid );
// Tell parent thread's POST(sys_bsdthread_create) that we're done
// initializing registers and mapping memory.
semaphore_signal(tst->os_state.child_done);
// LOCK IS GONE BELOW THIS POINT
// Go!
call_on_new_stack_0_1(tst->os_state.valgrind_stack_init_SP, 0,
start_thread_NORETURN, (Word)tst);
/*NOTREACHED*/
vg_assert(0);
}
asm(
".globl _wqthread_hijack_asm\n"
"_wqthread_hijack_asm:\n"
" movq %rsp,%r9\n" // original sp
// other values stay where they are in registers
" push $0\n" // fake return address
" jmp _wqthread_hijack\n"
);
/* wqthread note: The kernel may create or destroy pthreads in the
wqthread pool at any time with no userspace interaction,
and wqthread_start may be entered at any time with no userspace
interaction.
To handle this in valgrind, we create and destroy a valgrind
thread for every work item.
*/
void wqthread_hijack(Addr self, Addr kport, Addr stackaddr, Addr workitem,
Int reuse, Addr sp)
{
ThreadState *tst;
VexGuestAMD64State *vex;
Addr stack;
SizeT stacksize;
vki_sigset_t blockall;
/* When we enter here we hold no lock (!), so we better acquire it
pronto. Why do we hold no lock? Because (presumably) the only
way to get here is as a result of a SfMayBlock syscall
"workq_ops(WQOPS_THREAD_RETURN)", which will have dropped the
lock. At least that's clear for the 'reuse' case. The
non-reuse case? Dunno, perhaps it's a new thread the kernel
pulled out of a hat. In any case we still need to take a
lock. */
VG_(acquire_BigLock_LL)("wqthread_hijack");
if (0) VG_(printf)(
"wqthread_hijack: self %#lx, kport %#lx, "
"stackaddr %#lx, workitem %#lx, reuse/flags %x, sp %#lx\n",
self, kport, stackaddr, workitem, reuse, sp);
/* Start the thread with all signals blocked. VG_(scheduler) will
set the mask correctly when we finally get there. */
VG_(sigfillset)(&blockall);
VG_(sigprocmask)(VKI_SIG_SETMASK, &blockall, NULL);
/* For 10.7 and earlier, |reuse| appeared to be used as a simple
boolean. In 10.8 and later its name changed to |flags| and has
various other bits OR-d into it too, so it's necessary to fish
out just the relevant parts. Hence: */
# if DARWIN_VERS <= DARWIN_10_7
Bool is_reuse = reuse != 0;
# elif DARWIN_VERS == DARWIN_10_8
Bool is_reuse = (reuse & 0x20000 /* == WQ_FLAG_THREAD_REUSE */) != 0;
# endif
if (is_reuse) {
/* For whatever reason, tst->os_state.pthread appear to have a
constant offset of 96 on 10.7, but zero on 10.6 and 10.5. No
idea why. */
# if DARWIN_VERS <= DARWIN_10_6
UWord magic_delta = 0;
# elif DARWIN_VERS >= DARWIN_10_7
UWord magic_delta = 0x60;
# endif
// This thread already exists; we're merely re-entering
// after leaving via workq_ops(WQOPS_THREAD_RETURN).
// Don't allocate any V thread resources.
// Do reset thread registers.
ThreadId tid = VG_(lwpid_to_vgtid)(kport);
vg_assert(VG_(is_valid_tid)(tid));
vg_assert(mach_thread_self() == kport);
tst = VG_(get_ThreadState)(tid);
if (0) VG_(printf)("wqthread_hijack reuse %s: tid %d, tst %p, "
"tst->os_state.pthread %#lx\n",
tst->os_state.pthread == self ? "SAME" : "DIFF",
tid, tst, tst->os_state.pthread);
vex = &tst->arch.vex;
vg_assert(tst->os_state.pthread - magic_delta == self);
}
else {
// This is a new thread.
tst = VG_(get_ThreadState)(VG_(alloc_ThreadState)());
vex = &tst->arch.vex;
allocstack(tst->tid);
LibVEX_GuestAMD64_initialise(vex);
}
// Set thread's registers
// Do this FIRST because some code below tries to collect a backtrace,
// which requires valid register data.
vex->guest_RIP = wqthread_starter;
vex->guest_RDI = self;
vex->guest_RSI = kport;
vex->guest_RDX = stackaddr;
vex->guest_RCX = workitem;
vex->guest_R8 = reuse;
vex->guest_R9 = 0;
vex->guest_RSP = sp;
stacksize = 512*1024; // wq stacks are always DEFAULT_STACK_SIZE
stack = VG_PGROUNDUP(sp) - stacksize;
if (is_reuse) {
// Continue V's thread back in the scheduler.
// The client thread is of course in another location entirely.
/* Drop the lock before going into
ML_(wqthread_continue_NORETURN). The latter will immediately
attempt to reacquire it in non-LL mode, which is a bit
wasteful but I don't think is harmful. A better solution
would be to not drop the lock but instead "upgrade" it from a
LL lock to a full lock, but that's too much like hard work
right now. */
VG_(release_BigLock_LL)("wqthread_hijack(1)");
ML_(wqthread_continue_NORETURN)(tst->tid);
}
else {
// Record thread's stack and Mach port and pthread struct
tst->os_state.pthread = self;
tst->os_state.lwpid = kport;
record_named_port(tst->tid, kport, MACH_PORT_RIGHT_SEND, "wqthread-%p");
// kernel allocated stack - needs mapping
tst->client_stack_highest_word = stack+stacksize;
tst->client_stack_szB = stacksize;
// GrP fixme scheduler lock?!
// pthread structure
ML_(notify_core_and_tool_of_mmap)(
stack+stacksize, pthread_structsize,
VKI_PROT_READ|VKI_PROT_WRITE, VKI_MAP_PRIVATE, -1, 0);
// stack contents
// GrP fixme uninitialized!
ML_(notify_core_and_tool_of_mmap)(
stack, stacksize,
VKI_PROT_READ|VKI_PROT_WRITE, VKI_MAP_PRIVATE, -1, 0);
// guard page
// GrP fixme ban_mem_stack!
ML_(notify_core_and_tool_of_mmap)(
stack-VKI_PAGE_SIZE, VKI_PAGE_SIZE,
0, VKI_MAP_PRIVATE, -1, 0);
ML_(sync_mappings)("after", "wqthread_hijack", 0);
// Go!
/* Same comments as the 'release' in the then-clause.
start_thread_NORETURN calls run_thread_NORETURN calls
thread_wrapper which acquires the lock before continuing.
Let's hope nothing non-thread-local happens until that point.
DDD: I think this is plain wrong .. if we get to
thread_wrapper not holding the lock, and someone has recycled
this thread slot in the meantime, we're hosed. Is that
possible, though? */
VG_(release_BigLock_LL)("wqthread_hijack(2)");
call_on_new_stack_0_1(tst->os_state.valgrind_stack_init_SP, 0,
start_thread_NORETURN, (Word)tst);
}
/*NOTREACHED*/
vg_assert(0);
}
#endif // defined(VGP_amd64_darwin)
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/