#define align_4byte 4
#define align_8byte 8
#define align_16byte 16
+#define align_page 4096
#else
#define align_4byte 2
#define align_8byte 3
#define align_16byte 4
+#define align_page 12
#endif
/*
#define SIZE(name)
#endif
+/* Helper macros for access to thread-locals slots for both OS types:
+ * ------------------------------------------------------------------------
+ *
+ * Windows TEB block
+ * ================== __________
+ * | Win32 %FS base | ----> | | 0
+ * ================== | | 1
+ * z z
+ * TLS slots start here> |XXXXXXXX| e10 = TEB_STATIC_TLS_SLOTS_OFFSET
+ * |XXXXXXXX| e11
+ * z ... z
+ * |XXXXXXXX| e4e
+ * TLS ends here> ,- |XXXXXXXX| e4f = TEB_STATIC_TLS_SLOTS_OFFSET+63
+ * / z z
+ * | ---------- "os_address" ----.
+ * | |
+ * | big blob of SBCL-specific thread-local data |
+ * | |----------------------------------------| <--'
+ * | | CONTROL, BINDING, ALIEN STACK |
+ * | z z
+ * ================== | |----------------------------------------|
+ * | Linux %FS base | -->| | FFI stack pointer |
+ * ================== | | (extra page for mprotect) |
+ * \ |----------------------------------------|
+ * (union p_t_d) -----> \-> | struct thread { | dynamic_values[0] |
+ * . | ... | [1] |
+ * . z ... z ... z
+ * [tls data begins] | } | ... | <-
+ * [declared end of p_t_d] |----------------------------------------| . |
+ * . | ... | . |
+ * . | [TLS_SIZE-1] | <-|
+ * [tls data actually ends] |----------------------------------------| |
+ * . | ALTSTACK | |
+ * . |----------------------------------------| |
+ * . | struct nonpointer_thread_data { } | |
+ * . ------------------------------------------ |
+ * [blob actually ends] |
+ * /
+ * /
+ * /
+ * ______________________ /
+ * | struct symbol { | /
+ * z ... z /
+ * | fixnum tls_index; // fixnum value relative to union /
+ * | } | (< TLS_SIZE = 4096)
+ * ---------------------|
+ */
+#ifdef LISP_FEATURE_WIN32
+# define TEB_STATIC_TLS_SLOTS_OFFSET 0xE10
+# define TEB_SBCL_THREAD_BASE_OFFSET (TEB_STATIC_TLS_SLOTS_OFFSET+(63*4))
+# define SBCL_THREAD_BASE_EA %fs:TEB_SBCL_THREAD_BASE_OFFSET
+# define MAYBE_FS(addr) addr
+# define LoadTlSymbolValueAddress(symbol,reg) ; \
+ movl SBCL_THREAD_BASE_EA, reg ; \
+ addl (symbol+SYMBOL_TLS_INDEX_OFFSET), reg ;
+# define LoadCurrentThreadSlot(offset,reg); \
+ movl SBCL_THREAD_BASE_EA, reg ; \
+ movl offset(reg), reg ;
+#elif defined(LISP_FEATURE_LINUX) || defined(LISP_FEATURE_SUNOS) || defined(LISP_FEATURE_FREEBSD)
+ /* see comment in arch_os_thread_init */
+# define SBCL_THREAD_BASE_EA %fs:THREAD_SELFPTR_OFFSET
+# define MAYBE_FS(addr) addr
+#else
+ /* perhaps there's an OS out there that actually supports %fs without
+ * jumping through hoops, so just in case, here a default definition: */
+# define SBCL_THREAD_BASE_EA $0
+# define MAYBE_FS(addr) %fs:addr
+#endif
+
+/* gas can't parse 4096LU; redefine */
+#if BACKEND_PAGE_BYTES == 4096
+# undef BACKEND_PAGE_BYTES
+# define BACKEND_PAGE_BYTES 4096
+#elif BACKEND_PAGE_BYTES == 32768
+# undef BACKEND_PAGE_BYTES
+# define BACKEND_PAGE_BYTES 32768
+#else
+# error BACKEND_PAGE_BYTES mismatch
+#endif
+
+/* OAOOM because we don't have the C headers here */
+#define THREAD_CSP_PAGE_SIZE BACKEND_PAGE_BYTES
+
+/* the CSP page sits right before the thread */
+#define THREAD_SAVED_CSP_OFFSET (-THREAD_CSP_PAGE_SIZE)
+
/*
* x86/darwin (as of MacOS X 10.4.5) doesn't reliably file signal
* handlers (SIGTRAP or Mach exception handlers) for 0xCC, wo we have
* for this instruction in the SIGILL handler and if we see it, we
* advance the EIP by two bytes to skip over ud2 instruction and
* call sigtrap_handler. */
-#if defined(LISP_FEATURE_DARWIN)
+#if defined(LISP_FEATURE_UD2_BREAKPOINTS)
#define END()
#define TRAP ud2
#else
#endif
.text
- .globl GNAME(foreign_function_call_active)
.globl GNAME(all_threads)
\f
/*
* floats.
*
* This should work for Lisp calls C calls Lisp calls C..
+ *
+ * FIXME & OAOOM: This duplicates call-out in src/compiler/x86/c-call.lisp,
+ * so if you tweak this, change that too!
*/
+/*
+ * Note on sections specific to LISP_FEATURE_SB_SAFEPOINT:
+ *
+ * The code below is essential to safepoint-based garbage collection,
+ * and several details need to be considered for correct implementation.
+ *
+ * The stack spilling approach:
+ * On SB-SAFEPOINT platforms, the CALL-OUT vop is defined to spill all
+ * live Lisp TNs to the stack to provide information for conservative
+ * GC cooperatively (avoiding the need to retrieve register values
+ * from POSIX signal contexts or Windows GetThreadContext()).
+ *
+ * Finding the SP at all:
+ * The main remaining value needed by GC is the stack pointer (SP) at
+ * the moment of entering the foreign function. For this purpose, a
+ * thread-local field for the SP is used. Two stores to that field
+ * are done for each C call, one to save the SP before calling out and
+ * and one to undo that store afterwards.
+ *
+ * Stores as synchronization points:
+ * These two stores delimit the C call: While the SP is set, our
+ * thread is known not to run Lisp code: During GC, memory protection
+ * ensures that no thread proceeds across stores.
+ *
+ * The return PC issue:
+ * (Note that CALL-OUT has, in principle, two versions: Inline
+ * assembly in the VOP -or- alternatively the out-of-line version you
+ * are currently reading. In reality, safepoint builds currently
+ * lack the inline code entirely.)
+ *
+ * Both versions need to take special care with the return PC:
+ * - In the inline version of the code (if it existed), the two stores
+ * would be done directly in the CALL-OUT vop. In that theoretical
+ * implementation, there is a time interval between return of the
+ * actual C call and a second SP store during which the return
+ * address might not be on the stack anymore.
+ * - In this out-of-line version, the stores are done during
+ * call_into_c's frame, but an equivalent problem arises: In order
+ * to present the stack of arguments as our foreign function expects
+ * them, call_into_c has to pop the Lisp return address into a
+ * register first; this register has to be preserved by GENCGC
+ * separately: our return address is not in the stack anymore.
+ * In both case, stack scanning alone is not sufficient to pin
+ * the return address, and we communicate it to GC explicitly
+ * in addition to the SP.
+ *
+ * Note on look-alike accessor macros with vastly different behaviour:
+ * THREAD_PC_AROUND_FOREIGN_CALL_OFFSET is an "ordinary" field of the
+ * struct thread, whereas THREAD_SAVED_CSP_OFFSET is a synchronization
+ * point on a potentially write-protected page.
+*/
+
.text
.align align_16byte,0x90
.globl GNAME(call_into_c)
TYPE(GNAME(call_into_c))
GNAME(call_into_c):
- movl $1,GNAME(foreign_function_call_active)
-
/* Save the return Lisp address in ebx. */
popl %ebx
/* Setup the NPX for C */
+ /* The VOP says regarding CLD: "Clear out DF: Darwin, Windows,
+ * and Solaris at least require this, and it should not hurt
+ * others either." call_into_c didn't have it, but better safe than
+ * sorry. */
+ cld
fstp %st(0)
fstp %st(0)
fstp %st(0)
fstp %st(0)
fstp %st(0)
-#ifdef LISP_FEATURE_WIN32
- cld
+#ifdef LISP_FEATURE_SB_SAFEPOINT
+ /* enter safe region: store SP and return PC */
+ movl SBCL_THREAD_BASE_EA,%edi
+ movl %esp,MAYBE_FS(THREAD_SAVED_CSP_OFFSET(%edi))
+ movl %ebx,MAYBE_FS(THREAD_PC_AROUND_FOREIGN_CALL_OFFSET(%edi))
#endif
-#ifdef LISP_FEATURE_DARWIN
- andl $0xfffffff0,%esp # align stack to 16-byte boundary before calling C
+ /* foreign call, preserving ESI, EDI, and EBX */
+ call *%eax # normal callout using Lisp stack
+ /* return values now in eax/edx OR st(0) */
+
+#ifdef LISP_FEATURE_SB_SAFEPOINT
+ /* leave region: clear the SP! (Also unpin the return PC.) */
+ xorl %ecx,%ecx
+ movl %ecx,MAYBE_FS(THREAD_SAVED_CSP_OFFSET(%edi))
+ movl %ecx,MAYBE_FS(THREAD_PC_AROUND_FOREIGN_CALL_OFFSET(%edi))
#endif
- call *%eax # normal callout using Lisp stack
- movl %eax,%ecx # remember integer return value
+ movl %eax,%ecx # remember integer return value
/* Check for a return FP value. */
fxam
- fnstsw %eax
+ fnstsw %ax
andl $0x4500,%eax
cmpl $0x4100,%eax
jne Lfp_rtn_value
/* Restore the return value. */
movl %ecx,%eax # maybe return value
- movl $0,GNAME(foreign_function_call_active)
/* Return. */
jmp *%ebx
/* We don't need to restore eax, because the result is in st(0). */
- movl $0,GNAME(foreign_function_call_active)
-/* Return. */
+/* Return. FIXME: It would be nice to restructure this to use RET. */
jmp *%ebx
SIZE(GNAME(call_into_c))
.globl GNAME(call_into_lisp_first_time)
TYPE(GNAME(call_into_lisp_first_time))
-/* The *ALIEN-STACK* pointer is set up on the first call_into_lisp when
- * the stack changes. We don't worry too much about saving registers
+/* We don't worry too much about saving registers
* here, because we never expect to return from the initial call to lisp
* anyway */
pushl %ebp # Save old frame pointer.
movl %esp,%ebp # Establish new frame.
#ifndef LISP_FEATURE_WIN32
- movl %esp,ALIEN_STACK + SYMBOL_VALUE_OFFSET
movl GNAME(all_threads),%eax
- movl THREAD_CONTROL_STACK_START_OFFSET(%eax) ,%esp
- /* don't think too hard about what happens if we get interrupted
- * here */
- addl $(THREAD_CONTROL_STACK_SIZE),%esp
+ /* pthread machinery takes care of this for other threads */
+ movl THREAD_CONTROL_STACK_END_OFFSET(%eax) ,%esp
#else
/* Win32 -really- doesn't like you switching stacks out from under it. */
movl GNAME(all_threads),%eax
GNAME(call_into_lisp):
pushl %ebp # Save old frame pointer.
movl %esp,%ebp # Establish new frame.
+
Lstack:
/* Save the NPX state */
fwait # Catch any pending NPX exceptions.
xorl %esi,%esi # third arg
/* no longer in function call */
- movl %eax, GNAME(foreign_function_call_active)
-
movl %esp,%ebx # remember current stack
pushl %ebx # Save entry stack on (maybe) new stack.
Ldone:
/* Registers eax, ecx, edx, edi, and esi are now live. */
+#ifdef LISP_FEATURE_WIN32
+ /* Establish an SEH frame. */
+#ifdef LISP_FEATURE_SB_THREAD
+ /* Save binding stack pointer */
+ subl $4, %esp
+ pushl %eax
+ movl SBCL_THREAD_BASE_EA, %eax
+ movl THREAD_BINDING_STACK_POINTER_OFFSET(%eax), %eax
+ movl %eax, 4(%esp)
+ popl %eax
+#else
+ pushl BINDING_STACK_POINTER + SYMBOL_VALUE_OFFSET
+#endif
+ pushl $GNAME(exception_handler_wrapper)
+ pushl %fs:0
+ movl %esp, %fs:0
+#endif
+
/* Alloc new frame. */
- mov %esp,%ebx # The current sp marks start of new frame.
- push %ebp # fp in save location S0
- sub $8,%esp # Ensure 3 slots are allocated, one above.
- mov %ebx,%ebp # Switch to new frame.
+ push %ebp # Dummy for return address
+ push %ebp # fp in save location S1
+ mov %esp,%ebp # The current sp marks start of new frame.
+ sub $4,%esp # Ensure 3 slots are allocated, two above.
call *CLOSURE_FUN_OFFSET(%eax)
LsingleValue:
/* A singled value function returns here */
+#ifdef LISP_FEATURE_WIN32
+ /* Remove our SEH frame. */
+ mov %fs:0,%esp
+ popl %fs:0
+ add $8, %esp
+#endif
+
/* Restore the stack, in case there was a stack change. */
popl %esp # c-sp
* the undefined-function trampoline
*/
.text
- .align align_4byte,0x90
+ .align align_16byte,0x90
.globl GNAME(undefined_tramp)
TYPE(GNAME(undefined_tramp))
.byte 0, 0, 0, SIMPLE_FUN_HEADER_WIDETAG
GNAME(undefined_tramp):
+ pop 4(%ebp) # Save return PC for backtrace.
TRAP
.byte trap_Error
.byte 2
ret
SIZE(GNAME(undefined_tramp))
+/* KLUDGE: FIND-ESCAPED-FRAME (SYS:SRC;CODE;DEBUG-INT.LISP) needs
+ * to know the name of the function immediately following the
+ * undefined-function trampoline. */
+
/*
* the closure trampoline
*/
.text
- .align align_4byte,0x90
+ .align align_16byte,0x90
.globl GNAME(closure_tramp)
TYPE(GNAME(closure_tramp))
.byte 0, 0, 0, SIMPLE_FUN_HEADER_WIDETAG
SIZE(GNAME(closure_tramp))
.text
- .align align_4byte,0x90
+ .align align_16byte,0x90
.globl GNAME(funcallable_instance_tramp)
TYPE(GNAME(funcallable_instance_tramp))
GNAME(funcallable_instance_tramp):
/*
* fun-end breakpoint magic
*/
+
+/*
+ * For an explanation of the magic involved in function-end
+ * breakpoints, see the implementation in ppc-assem.S.
+ */
+
.text
.globl GNAME(fun_end_breakpoint_guts)
- .align align_4byte
+ .align align_16byte
GNAME(fun_end_breakpoint_guts):
/* Multiple Value return */
jc multiple_value_return
\f
.globl GNAME(do_pending_interrupt)
TYPE(GNAME(do_pending_interrupt))
- .align align_4byte,0x90
+ .align align_16byte,0x90
GNAME(do_pending_interrupt):
TRAP
.byte trap_PendingInterrupt
ret
SIZE(GNAME(do_pending_interrupt))
\f
-
-/*
- * Allocate bytes and return the start of the allocated space
+/* Allocate bytes and return the start of the allocated space
* in the specified destination register.
*
* In the general case the size will be in the destination register.
* All registers must be preserved except the destination.
* The C conventions will preserve ebx, esi, edi, and ebp.
* So only eax, ecx, and edx need special care here.
+ *
+ * ALLOC factors out the logic of calling alloc(): stack alignment, etc.
+ *
+ * DEFINE_ALLOC_TO_FOO defines an alloction routine.
*/
-
- .globl GNAME(alloc_to_eax)
- TYPE(GNAME(alloc_to_eax))
- .align align_4byte,0x90
-GNAME(alloc_to_eax):
- pushl %ecx # Save ecx and edx as C could destroy them.
- pushl %edx
- pushl %eax # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- popl %edx # Restore ecx and edx.
- popl %ecx
- ret
- SIZE(GNAME(alloc_to_eax))
-
- .globl GNAME(alloc_8_to_eax)
- TYPE(GNAME(alloc_8_to_eax))
- .align align_4byte,0x90
-GNAME(alloc_8_to_eax):
- pushl %ecx # Save ecx and edx as C could destroy them.
- pushl %edx
- pushl $8 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- popl %edx # Restore ecx and edx.
- popl %ecx
- ret
- SIZE(GNAME(alloc_8_to_eax))
-
- .globl GNAME(alloc_8_to_eax)
- TYPE(GNAME(alloc_8_to_eax))
- .align align_4byte,0x90
-
- .globl GNAME(alloc_16_to_eax)
- TYPE(GNAME(alloc_16_to_eax))
- .align align_4byte,0x90
-GNAME(alloc_16_to_eax):
- pushl %ecx # Save ecx and edx as C could destroy them.
- pushl %edx
- pushl $16 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- popl %edx # Restore ecx and edx.
- popl %ecx
- ret
- SIZE(GNAME(alloc_16_to_eax))
-
- .globl GNAME(alloc_to_ecx)
- TYPE(GNAME(alloc_to_ecx))
- .align align_4byte,0x90
-GNAME(alloc_to_ecx):
- pushl %eax # Save eax and edx as C could destroy them.
- pushl %edx
- pushl %ecx # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%ecx # Set up the destination.
- popl %edx # Restore eax and edx.
- popl %eax
- ret
- SIZE(GNAME(alloc_to_ecx))
-
- .globl GNAME(alloc_8_to_ecx)
- TYPE(GNAME(alloc_8_to_ecx))
- .align align_4byte,0x90
-GNAME(alloc_8_to_ecx):
- pushl %eax # Save eax and edx as C could destroy them.
- pushl %edx
- pushl $8 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%ecx # Set up the destination.
- popl %edx # Restore eax and edx.
- popl %eax
- ret
- SIZE(GNAME(alloc_8_to_ecx))
-
- .globl GNAME(alloc_16_to_ecx)
- TYPE(GNAME(alloc_16_to_ecx))
- .align align_4byte,0x90
-GNAME(alloc_16_to_ecx):
- pushl %eax # Save eax and edx as C could destroy them.
- pushl %edx
- pushl $16 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%ecx # Set up the destination.
- popl %edx # Restore eax and edx.
- popl %eax
- ret
- SIZE(GNAME(alloc_16_to_ecx))
-
-
- .globl GNAME(alloc_to_edx)
- TYPE(GNAME(alloc_to_edx))
- .align align_4byte,0x90
-GNAME(alloc_to_edx):
- pushl %eax # Save eax and ecx as C could destroy them.
- pushl %ecx
- pushl %edx # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%edx # Set up the destination.
- popl %ecx # Restore eax and ecx.
- popl %eax
- ret
- SIZE(GNAME(alloc_to_edx))
-
- .globl GNAME(alloc_8_to_edx)
- TYPE(GNAME(alloc_8_to_edx))
- .align align_4byte,0x90
-GNAME(alloc_8_to_edx):
- pushl %eax # Save eax and ecx as C could destroy them.
- pushl %ecx
- pushl $8 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%edx # Set up the destination.
- popl %ecx # Restore eax and ecx.
- popl %eax
- ret
- SIZE(GNAME(alloc_8_to_edx))
-
- .globl GNAME(alloc_16_to_edx)
- TYPE(GNAME(alloc_16_to_edx))
- .align align_4byte,0x90
-GNAME(alloc_16_to_edx):
- pushl %eax # Save eax and ecx as C could destroy them.
- pushl %ecx
- pushl $16 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%edx # Set up the destination.
- popl %ecx # Restore eax and ecx.
- popl %eax
- ret
- SIZE(GNAME(alloc_16_to_edx))
-
-
-
- .globl GNAME(alloc_to_ebx)
- TYPE(GNAME(alloc_to_ebx))
- .align align_4byte,0x90
-GNAME(alloc_to_ebx):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl %ebx # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%ebx # Set up the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_to_ebx))
-
- .globl GNAME(alloc_8_to_ebx)
- TYPE(GNAME(alloc_8_to_ebx))
- .align align_4byte,0x90
-GNAME(alloc_8_to_ebx):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $8 # Push the size.
- call GNAME(alloc)
- addl $4,%esp # Pop the size arg.
- movl %eax,%ebx # Set up the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_8_to_ebx))
-
- .globl GNAME(alloc_16_to_ebx)
- TYPE(GNAME(alloc_16_to_ebx))
- .align align_4byte,0x90
-GNAME(alloc_16_to_ebx):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $16 # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%ebx # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_16_to_ebx))
-
-
-
- .globl GNAME(alloc_to_esi)
- TYPE(GNAME(alloc_to_esi))
- .align align_4byte,0x90
-GNAME(alloc_to_esi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl %esi # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%esi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_to_esi))
-
- .globl GNAME(alloc_8_to_esi)
- TYPE(GNAME(alloc_8_to_esi))
- .align align_4byte,0x90
-GNAME(alloc_8_to_esi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $8 # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%esi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_8_to_esi))
-
- .globl GNAME(alloc_16_to_esi)
- TYPE(GNAME(alloc_16_to_esi))
- .align align_4byte,0x90
-GNAME(alloc_16_to_esi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $16 # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%esi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_16_to_esi))
-
-
- .globl GNAME(alloc_to_edi)
- TYPE(GNAME(alloc_to_edi))
- .align align_4byte,0x90
-GNAME(alloc_to_edi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl %edi # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%edi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_to_edi))
-
- .globl GNAME(alloc_8_to_edi)
- TYPE(GNAME(alloc_8_to_edi))
- .align align_4byte,0x90
-GNAME(alloc_8_to_edi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $8 # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%edi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_8_to_edi))
-
- .globl GNAME(alloc_16_to_edi)
- TYPE(GNAME(alloc_16_to_edi))
- .align align_4byte,0x90
-GNAME(alloc_16_to_edi):
- pushl %eax # Save eax, ecx, and edx as C could destroy them.
- pushl %ecx
- pushl %edx
- pushl $16 # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
- movl %eax,%edi # setup the destination.
- popl %edx # Restore eax, ecx and edx.
- popl %ecx
- popl %eax
- ret
- SIZE(GNAME(alloc_16_to_edi))
-
+#ifdef LISP_FEATURE_DARWIN
+#define ALLOC(size) \
+ pushl %ebp; /* Save EBP */ \
+ movl %esp,%ebp; /* Save ESP to EBP */ \
+ pushl $0; /* Reserve space for arg */ \
+ andl $0xfffffff0,%esp; /* Align stack to 16bytes */ \
+ movl size, (%esp); /* Argument to alloc */ \
+ call GNAME(alloc); \
+ movl %ebp,%esp; /* Restore ESP from EBP */ \
+ popl %ebp; /* Restore EBP */
+#else
+#define ALLOC(size) \
+ pushl size; /* Argument to alloc */ \
+ call GNAME(alloc); \
+ addl $4,%esp; /* Pop argument */
+#endif
+
+#define DEFINE_ALLOC_TO_EAX(name,size) \
+ .globl GNAME(name); \
+ TYPE(GNAME(name)); \
+ .align align_16byte,0x90; \
+GNAME(name): \
+ pushl %ecx; /* Save ECX and EDX */ \
+ pushl %edx; \
+ ALLOC(size) \
+ popl %edx; /* Restore ECX and EDX */ \
+ popl %ecx; \
+ ret; \
+ SIZE(GNAME(name))
+
+#define DEFINE_ALLOC_TO_ECX(name,size) \
+ .globl GNAME(name); \
+ TYPE(GNAME(name)); \
+ .align align_16byte,0x90; \
+GNAME(name): \
+ pushl %eax; /* Save EAX and EDX */ \
+ pushl %edx; \
+ ALLOC(size) \
+ movl %eax,%ecx; /* Result to destination */ \
+ popl %edx; \
+ popl %eax; \
+ ret; \
+ SIZE(GNAME(name))
+
+#define DEFINE_ALLOC_TO_EDX(name,size) \
+ .globl GNAME(name); \
+ TYPE(GNAME(name)); \
+ .align align_16byte,0x90; \
+GNAME(name): \
+ pushl %eax; /* Save EAX and ECX */ \
+ pushl %ecx; \
+ ALLOC(size) \
+ movl %eax,%edx; /* Restore EAX and ECX */ \
+ popl %ecx; \
+ popl %eax; \
+ ret; \
+ SIZE(GNAME(name))
+
+#define DEFINE_ALLOC_TO_REG(name,reg,size) \
+ .globl GNAME(name); \
+ TYPE(GNAME(name)); \
+ .align align_16byte,0x90; \
+GNAME(name): \
+ pushl %eax; /* Save EAX, ECX, and EDX */ \
+ pushl %ecx; \
+ pushl %edx; \
+ ALLOC(size) \
+ movl %eax,reg; /* Restore them */ \
+ popl %edx; \
+ popl %ecx; \
+ popl %eax; \
+ ret; \
+ SIZE(GNAME(name))
+
+DEFINE_ALLOC_TO_EAX(alloc_to_eax,%eax)
+DEFINE_ALLOC_TO_EAX(alloc_8_to_eax,$8)
+DEFINE_ALLOC_TO_EAX(alloc_16_to_eax,$16)
+
+DEFINE_ALLOC_TO_ECX(alloc_to_ecx,%ecx)
+DEFINE_ALLOC_TO_ECX(alloc_8_to_ecx,$8)
+DEFINE_ALLOC_TO_ECX(alloc_16_to_ecx,$16)
+
+DEFINE_ALLOC_TO_EDX(alloc_to_edx,%edx)
+DEFINE_ALLOC_TO_EDX(alloc_8_to_edx,$8)
+DEFINE_ALLOC_TO_EDX(alloc_16_to_edx,$16)
+
+DEFINE_ALLOC_TO_REG(alloc_to_ebx,%ebx,%ebx)
+DEFINE_ALLOC_TO_REG(alloc_8_to_ebx,%ebx,$8)
+DEFINE_ALLOC_TO_REG(alloc_16_to_ebx,%ebx,$16)
+
+DEFINE_ALLOC_TO_REG(alloc_to_esi,%esi,%esi)
+DEFINE_ALLOC_TO_REG(alloc_8_to_esi,%esi,$8)
+DEFINE_ALLOC_TO_REG(alloc_16_to_esi,%esi,$16)
+
+DEFINE_ALLOC_TO_REG(alloc_to_edi,%edi,%edi)
+DEFINE_ALLOC_TO_REG(alloc_8_to_edi,%edi,$8)
+DEFINE_ALLOC_TO_REG(alloc_16_to_edi,%edi,$16)
+
/* Called from lisp when an inline allocation overflows.
- Every register except the result needs to be preserved.
- We depend on C to preserve ebx, esi, edi, and ebp.
- But where necessary must save eax, ecx, edx. */
+ * Every register except the result needs to be preserved.
+ * We depend on C to preserve ebx, esi, edi, and ebp.
+ * But where necessary must save eax, ecx, edx. */
#ifdef LISP_FEATURE_SB_THREAD
#define START_REGION %fs:THREAD_ALLOC_REGION_OFFSET
#else
#define START_REGION GNAME(boxed_region)
#endif
-
+
+#if defined(LISP_FEATURE_SB_THREAD) && defined(LISP_FEATURE_WIN32)
+#define ALLOC_OVERFLOW(size,scratch) \
+ movl SBCL_THREAD_BASE_EA, scratch; \
+ /* Calculate the size for the allocation. */ \
+ subl THREAD_ALLOC_REGION_OFFSET(scratch),size; \
+ ALLOC(size)
+#else
+#define ALLOC_OVERFLOW(size,scratch) \
+ /* Calculate the size for the allocation. */ \
+ subl START_REGION,size; \
+ ALLOC(size)
+#endif
+
/* This routine handles an overflow with eax=crfp+size. So the
size=eax-crfp. */
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_eax)
TYPE(GNAME(alloc_overflow_eax))
GNAME(alloc_overflow_eax):
pushl %ecx # Save ecx
pushl %edx # Save edx
- /* Calculate the size for the allocation. */
- subl START_REGION,%eax
- pushl %eax # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%eax,%edx)
popl %edx # Restore edx.
popl %ecx # Restore ecx.
ret
SIZE(GNAME(alloc_overflow_eax))
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_ecx)
TYPE(GNAME(alloc_overflow_ecx))
GNAME(alloc_overflow_ecx):
pushl %eax # Save eax
pushl %edx # Save edx
- /* Calculate the size for the allocation. */
- subl START_REGION,%ecx
- pushl %ecx # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%ecx,%edx)
movl %eax,%ecx # setup the destination.
popl %edx # Restore edx.
popl %eax # Restore eax.
ret
SIZE(GNAME(alloc_overflow_ecx))
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_edx)
TYPE(GNAME(alloc_overflow_edx))
GNAME(alloc_overflow_edx):
pushl %eax # Save eax
pushl %ecx # Save ecx
- /* Calculate the size for the allocation. */
- subl START_REGION,%edx
- pushl %edx # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%edx,%ecx)
movl %eax,%edx # setup the destination.
popl %ecx # Restore ecx.
popl %eax # Restore eax.
/* This routine handles an overflow with ebx=crfp+size. So the
size=ebx-crfp. */
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_ebx)
TYPE(GNAME(alloc_overflow_ebx))
GNAME(alloc_overflow_ebx):
pushl %eax # Save eax
pushl %ecx # Save ecx
pushl %edx # Save edx
- /* Calculate the size for the allocation. */
- subl START_REGION,%ebx
- pushl %ebx # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%ebx,%edx)
movl %eax,%ebx # setup the destination.
popl %edx # Restore edx.
popl %ecx # Restore ecx.
/* This routine handles an overflow with esi=crfp+size. So the
size=esi-crfp. */
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_esi)
TYPE(GNAME(alloc_overflow_esi))
GNAME(alloc_overflow_esi):
pushl %eax # Save eax
pushl %ecx # Save ecx
pushl %edx # Save edx
- /* Calculate the size for the allocation. */
- subl START_REGION,%esi
- pushl %esi # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%esi,%edx)
movl %eax,%esi # setup the destination.
popl %edx # Restore edx.
popl %ecx # Restore ecx.
ret
SIZE(GNAME(alloc_overflow_esi))
- .align align_4byte
+ .align align_16byte
.globl GNAME(alloc_overflow_edi)
TYPE(GNAME(alloc_overflow_edi))
GNAME(alloc_overflow_edi):
pushl %eax # Save eax
pushl %ecx # Save ecx
pushl %edx # Save edx
- /* Calculate the size for the allocation. */
- subl START_REGION,%edi
- pushl %edi # Push the size
- call GNAME(alloc)
- addl $4,%esp # pop the size arg.
+ ALLOC_OVERFLOW(%edi,%edx)
movl %eax,%edi # setup the destination.
popl %edx # Restore edx.
popl %ecx # Restore ecx.
SIZE(GNAME(alloc_overflow_edi))
+#ifdef LISP_FEATURE_WIN32
+ /* The guts of the exception-handling system doesn't use
+ * frame pointers, which manages to throw off backtraces
+ * rather badly. So here we grab the (known-good) EBP
+ * and EIP from the exception context and use it to fake
+ * up a stack frame which will skip over the system SEH
+ * code. */
+ .align align_16byte
+ .globl GNAME(exception_handler_wrapper)
+ TYPE(GNAME(exception_handler_wrapper))
+GNAME(exception_handler_wrapper):
+ /* Context layout is: */
+ /* 7 dwords before FSA. (0x1c) */
+ /* 8 dwords and 0x50 bytes in the FSA. (0x70/0x8c) */
+ /* 4 dwords segregs. (0x10/0x9c) */
+ /* 6 dwords non-stack GPRs. (0x18/0xb4) */
+ /* EBP (at 0xb4) */
+ /* EIP (at 0xb8) */
+#define CONTEXT_EBP_OFFSET 0xb4
+#define CONTEXT_EIP_OFFSET 0xb8
+ /* some other stuff we don't care about. */
+ pushl %ebp
+ movl 0x10(%esp), %ebp /* context */
+ pushl CONTEXT_EIP_OFFSET(%ebp)
+ pushl CONTEXT_EBP_OFFSET(%ebp)
+ movl %esp, %ebp
+ pushl 0x1c(%esp)
+ pushl 0x1c(%esp)
+ pushl 0x1c(%esp)
+ pushl 0x1c(%esp)
+ call GNAME(handle_exception)
+ lea 8(%ebp), %esp
+ popl %ebp
+ ret
+ SIZE(GNAME(exception_handler_wrapper))
+#endif
+
#ifdef LISP_FEATURE_DARWIN
- .align align_4byte
+ .align align_16byte
.globl GNAME(call_into_lisp_tramp)
TYPE(GNAME(call_into_lisp_tramp))
GNAME(call_into_lisp_tramp):
SIZE(call_into_lisp_tramp)
#endif
- .align align_4byte,0x90
+ .align align_16byte,0x90
.globl GNAME(post_signal_tramp)
TYPE(GNAME(post_signal_tramp))
GNAME(post_signal_tramp):
ret
SIZE(GNAME(post_signal_tramp))
-#ifdef LISP_FEATURE_WIN32
- /*
- * This is part of the funky magic for exception handling on win32.
- * see sigtrap_emulator() in win32-os.c for details.
- */
- .globl GNAME(sigtrap_trampoline)
-GNAME(sigtrap_trampoline):
- pushl %eax
- pushl %ebp
- movl %esp, %ebp
- call GNAME(sigtrap_wrapper)
- pop %eax
- pop %eax
- TRAP
- .byte trap_ContextRestore
- hlt # We should never return here.
-
- /*
- * This is part of the funky magic for exception handling on win32.
- * see handle_exception() in win32-os.c for details.
- */
- .globl GNAME(exception_trampoline)
-GNAME(exception_trampoline):
- pushl %eax
- pushl %ebp
- movl %esp, %ebp
- call GNAME(handle_win32_exception_wrapper)
- pop %eax
- pop %eax
- TRAP
- .byte trap_ContextRestore
- hlt # We should never return here.
-#endif
/* fast_bzero implementations and code to detect which implementation
* to use.
\f
.globl GNAME(fast_bzero_pointer)
.data
- .align align_4byte
+ .align align_16byte
GNAME(fast_bzero_pointer):
/* Variable containing a pointer to the bzero function to use.
* Initially points to a basic function. Change this variable
.long GNAME(fast_bzero_base)
\f
.text
- .align align_8byte,0x90
+ .align align_16byte,0x90
.globl GNAME(fast_bzero)
TYPE(GNAME(fast_bzero))
GNAME(fast_bzero):
\f
.text
- .align align_8byte,0x90
+ .align align_16byte,0x90
.globl GNAME(fast_bzero_detect)
TYPE(GNAME(fast_bzero_detect))
GNAME(fast_bzero_detect):
\f
.text
- .align align_8byte,0x90
+ .align align_16byte,0x90
.globl GNAME(fast_bzero_sse)
TYPE(GNAME(fast_bzero_sse))
\f
.text
- .align align_8byte,0x90
+ .align align_16byte,0x90
.globl GNAME(fast_bzero_base)
TYPE(GNAME(fast_bzero_base))
xor %eax, %eax /* Zero EAX */
shr $2, %ecx /* Amount of 4-byte blocks to copy */
jz Lend_base
- cld /* Set direction of STOSL to increment */
rep
stosl /* Store EAX to *EDI, ECX times, incrementing
pop %eax
ret
SIZE(GNAME(fast_bzero_base))
-
-\f
+
+\f
+/* When LISP_FEATURE_C_STACK_IS_CONTROL_STACK, we cannot safely scrub
+ * the control stack from C, largely due to not knowing where the
+ * active stack frame ends. On such platforms, we reimplement the
+ * core scrubbing logic in assembly, in this case here:
+ */
+ .text
+ .align align_16byte,0x90
+ .globl GNAME(arch_scrub_control_stack)
+ TYPE(GNAME(arch_scrub_control_stack))
+GNAME(arch_scrub_control_stack):
+ /* We are passed three parameters:
+ * A (struct thread *) at [ESP+4],
+ * the address of the guard page at [ESP+8], and
+ * the address of the hard guard page at [ESP+12].
+ * We may trash EAX, ECX, and EDX with impunity.
+ * [ESP] is our return address, [ESP-4] is the first
+ * stack slot to scrub. */
+
+ /* We start by setting up our scrub pointer in EAX, our
+ * guard page upper bound in ECX, and our hard guard
+ * page upper bound in EDX. */
+ lea -4(%esp), %eax
+ mov GNAME(os_vm_page_size),%edx
+ mov %edx, %ecx
+ add 8(%esp), %ecx
+ add 12(%esp), %edx
+
+ /* We need to do a memory operation relative to the
+ * thread pointer, so put it in %ecx and our guard
+ * page upper bound in 4(%esp). */
+ xchg 4(%esp), %ecx
+
+ /* Now we begin our main scrub loop. */
+ascs_outer_loop:
+
+ /* If we're about to scrub the hard guard page, exit. */
+ cmp %edx, %eax
+ jae ascs_check_guard_page
+ cmp 12(%esp), %eax
+ ja ascs_finished
+
+ascs_check_guard_page:
+ /* If we're about to scrub the guard page, and the guard
+ * page is protected, exit. */
+ cmp 4(%esp), %eax
+ jae ascs_clear_loop
+ cmp 8(%esp), %eax
+ jbe ascs_clear_loop
+ cmpl $(NIL), THREAD_CONTROL_STACK_GUARD_PAGE_PROTECTED_OFFSET(%ecx)
+ jne ascs_finished
+
+ /* Clear memory backwards to the start of the (4KiB) page */
+ascs_clear_loop:
+ movl $0, (%eax)
+ test $0xfff, %eax
+ lea -4(%eax), %eax
+ jnz ascs_clear_loop
+
+ /* If we're about to hit the hard guard page, exit. */
+ cmp %edx, %eax
+ jae ascs_finished
+
+ /* If the next (previous?) 4KiB page contains a non-zero
+ * word, continue scrubbing. */
+ascs_check_loop:
+ testl $-1, (%eax)
+ jnz ascs_outer_loop
+ test $0xfff, %eax
+ lea -4(%eax), %eax
+ jnz ascs_check_loop
+
+ascs_finished:
+ ret
+ SIZE(GNAME(arch_scrub_control_stack))
+\f
END()
-
\ No newline at end of file