;;; FIXME: Since SBCL, unlike CMU CL, uses this as an opaque type,
;;; it's no longer architecture-dependent, and probably belongs in
;;; some other package, perhaps SB-KERNEL.
-(def-alien-type os-context-t (struct os-context-t-struct))
+(define-alien-type os-context-t (struct os-context-t-struct))
\f
;;;; MACHINE-TYPE and MACHINE-VERSION
(defun machine-type ()
#!+sb-doc
- "Returns a string describing the type of the local machine."
+ "Return a string describing the type of the local machine."
"X86")
-(defun machine-version ()
- #!+sb-doc
- "Returns a string describing the version of the local machine."
- "X86")
+;;; arch-specific support for CL:MACHINE-VERSION, defined OAOO elsewhere
+(defun get-machine-version ()
+ #!+linux
+ (with-open-file (stream "/proc/cpuinfo"
+ ;; Even on Linux it's an option to build
+ ;; kernels without /proc filesystems, so
+ ;; degrade gracefully.
+ :if-does-not-exist nil)
+ (loop with line while (setf line (read-line stream nil))
+ ;; The field "model name" exists on kernel 2.4.21-rc6-ac1
+ ;; anyway, with values e.g.
+ ;; "AMD Athlon(TM) XP 2000+"
+ ;; "Intel(R) Pentium(R) M processor 1300MHz"
+ ;; which seem comparable to the information in the example
+ ;; in the MACHINE-VERSION page of the ANSI spec.
+ when (eql (search "model name" line) 0)
+ return (string-trim " " (subseq line (1+ (position #\: line))))))
+ #!-linux
+ nil)
\f
;;;; :CODE-OBJECT fixups
(defvar *num-fixups* 0)
;;; FIXME: When the system runs, it'd be interesting to see what this is.
+(declaim (inline adjust-fixup-array))
+(defun adjust-fixup-array (array size)
+ (let ((new (make-array size :element-type '(unsigned-byte 32))))
+ (replace new array)
+ new))
+
;;; This gets called by LOAD to resolve newly positioned objects
;;; with things (like code instructions) that have to refer to them.
;;;
(let ((fixups (code-header-ref code code-constants-offset)))
(cond ((typep fixups '(simple-array (unsigned-byte 32) (*)))
(let ((new-fixups
- (adjust-array fixups (1+ (length fixups))
- :element-type '(unsigned-byte 32))))
+ (adjust-fixup-array fixups (1+ (length fixups)))))
(setf (aref new-fixups (length fixups)) offset)
(setf (code-header-ref code code-constants-offset)
new-fixups)))
(t
- (unless (or (eq (get-type fixups)
- sb!vm:unbound-marker-type)
+ (unless (or (eq (widetag-of fixups)
+ unbound-marker-widetag)
(zerop fixups))
(format t "** Init. code FU = ~S~%" fixups)) ; FIXME
(setf (code-header-ref code code-constants-offset)
- (make-specializable-array
+ (make-array
1
:element-type '(unsigned-byte 32)
:initial-element offset)))))))
(sb!kernel:code-instructions code)))
(obj-start-addr (logand (sb!kernel:get-lisp-obj-address code)
#xfffffff8))
- #+nil (const-start-addr (+ obj-start-addr (* 5 4)))
+ ;; FIXME: what is this 5?
+ #+nil (const-start-addr (+ obj-start-addr (* 5 n-word-bytes)))
(code-start-addr (sb!sys:sap-int (sb!kernel:code-instructions
code)))
(ncode-words (sb!kernel:code-header-ref code 1))
- (code-end-addr (+ code-start-addr (* ncode-words 4))))
+ (code-end-addr (+ code-start-addr (* ncode-words n-word-bytes))))
(unless (member kind '(:absolute :relative))
(error "Unknown code-object-fixup kind ~S." kind))
(ecase kind
(add-fixup code offset))
;; Replace word with value to add to that loc to get there.
(let* ((loc-sap (+ (sap-int sap) offset))
- (rel-val (- fixup loc-sap 4)))
+ (rel-val (- fixup loc-sap n-word-bytes)))
(declare (type (unsigned-byte 32) loc-sap)
(type (signed-byte 32) rel-val))
(setf (signed-sap-ref-32 sap offset) rel-val))))))
nil))
-;;; Add a code fixup to a code object generated by GENESIS. The fixup has
-;;; already been applied, it's just a matter of placing the fixup in the code's
-;;; fixup vector if necessary.
+;;; Add a code fixup to a code object generated by GENESIS. The fixup
+;;; has already been applied, it's just a matter of placing the fixup
+;;; in the code's fixup vector if necessary.
;;;
;;; KLUDGE: I'd like a good explanation of why this has to be done at
;;; load time instead of in GENESIS. It's probably simple, I just haven't
;;; figured it out, or found it written down anywhere. -- WHN 19990908
#!+gencgc
-(defun !do-load-time-code-fixup (code offset fixup kind)
- (flet ((add-load-time-code-fixup (code offset)
- (let ((fixups (code-header-ref code sb!vm:code-constants-offset)))
+(defun !envector-load-time-code-fixup (code offset fixup kind)
+ (flet ((frob (code offset)
+ (let ((fixups (code-header-ref code code-constants-offset)))
(cond ((typep fixups '(simple-array (unsigned-byte 32) (*)))
(let ((new-fixups
- (adjust-array fixups (1+ (length fixups))
- :element-type '(unsigned-byte 32))))
+ (adjust-fixup-array fixups (1+ (length fixups)))))
(setf (aref new-fixups (length fixups)) offset)
- (setf (code-header-ref code sb!vm:code-constants-offset)
+ (setf (code-header-ref code code-constants-offset)
new-fixups)))
(t
- (unless (or (eq (get-type fixups)
- sb!vm:unbound-marker-type)
+ (unless (or (eq (widetag-of fixups)
+ unbound-marker-widetag)
(zerop fixups))
(sb!impl::!cold-lose "Argh! can't process fixup"))
- (setf (code-header-ref code sb!vm:code-constants-offset)
- (make-specializable-array
+ (setf (code-header-ref code code-constants-offset)
+ (make-array
1
:element-type '(unsigned-byte 32)
:initial-element offset)))))))
(code-start-addr (sb!sys:sap-int (sb!kernel:code-instructions
code)))
(ncode-words (sb!kernel:code-header-ref code 1))
- (code-end-addr (+ code-start-addr (* ncode-words 4))))
+ (code-end-addr (+ code-start-addr (* ncode-words n-word-bytes))))
(ecase kind
(:absolute
;; Record absolute fixups that point within the code object.
(when (> code-end-addr (sap-ref-32 sap offset) obj-start-addr)
- (add-load-time-code-fixup code offset)))
+ (frob code offset)))
(:relative
;; Record relative fixups that point outside the code object.
(when (or (< fixup obj-start-addr) (> fixup code-end-addr))
- (add-load-time-code-fixup code offset)))))))
+ (frob code offset)))))))
\f
;;;; low-level signal context access functions
;;;;
;;;; and internal error handling) the extra runtime cost should be
;;;; negligible.
-(def-alien-routine ("os_context_pc_addr" context-pc-addr) (* unsigned-int)
+(define-alien-routine ("os_context_pc_addr" context-pc-addr) (* unsigned-int)
;; (Note: Just as in CONTEXT-REGISTER-ADDR, we intentionally use an
;; 'unsigned *' interpretation for the 32-bit word passed to us by
;; the C code, even though the C code may think it's an 'int *'.)
(declare (type (alien (* unsigned-int)) addr))
(int-sap (deref addr))))
-(def-alien-routine ("os_context_register_addr" context-register-addr)
+(define-alien-routine ("os_context_register_addr" context-register-addr)
(* unsigned-int)
;; (Note the mismatch here between the 'int *' value that the C code
;; may think it's giving us and the 'unsigned *' value that we
;;; Given a signal context, return the floating point modes word in
;;; the same format as returned by FLOATING-POINT-MODES.
+#!-linux
(defun context-floating-point-modes (context)
;; FIXME: As of sbcl-0.6.7 and the big rewrite of signal handling for
;; POSIXness and (at the Lisp level) opaque signal contexts,
(logior (ash (logand sw #xffff) 16) (logxor (logand cw #xffff) #x3f)))
0)
+
+#!+linux
+(define-alien-routine ("os_context_fp_control" context-floating-point-modes)
+ (sb!alien:unsigned 32)
+ (context (* os-context-t)))
\f
-;;;; INTERNAL-ERROR-ARGUMENTS
+;;;; INTERNAL-ERROR-ARGS
;;; Given a (POSIX) signal context, extract the internal error
;;; arguments from the instruction stream.
-(defun internal-error-arguments (context)
+(defun internal-error-args (context)
(declare (type (alien (* os-context-t)) context))
- (/show0 "entering INTERNAL-ERROR-ARGUMENTS, CONTEXT=..")
+ (/show0 "entering INTERNAL-ERROR-ARGS, CONTEXT=..")
(/hexstr context)
(let ((pc (context-pc context)))
(declare (type system-area-pointer pc))
(/show0 "LENGTH,VECTOR,ERROR-NUMBER=..")
(/hexstr length)
(/hexstr vector)
- (copy-from-system-area pc (* sb!vm:byte-bits 2)
- vector (* sb!vm:word-bits
- sb!vm:vector-data-offset)
- (* length sb!vm:byte-bits))
+ (copy-from-system-area pc (* n-byte-bits 2)
+ vector (* n-word-bits vector-data-offset)
+ (* length n-byte-bits))
(let* ((index 0)
- (error-number (sb!c::read-var-integer vector index)))
+ (error-number (sb!c:read-var-integer vector index)))
(/hexstr error-number)
(collect ((sc-offsets))
(loop
(/hexstr index)
(when (>= index length)
(return))
- (let ((sc-offset (sb!c::read-var-integer vector index)))
+ (let ((sc-offset (sb!c:read-var-integer vector index)))
(/show0 "SC-OFFSET=..")
(/hexstr sc-offset)
(sc-offsets sc-offset)))
(values error-number (sc-offsets)))))))
\f
-;;; Do whatever is necessary to make the given code component
-;;; executable. (This is a no-op on the x86.)
-(defun sanctify-for-execution (component)
- (declare (ignore component))
- nil)
-
;;; This is used in error.lisp to insure that floating-point exceptions
;;; are properly trapped. The compiler translates this to a VOP.
(defun float-wait ()
;;; than the i387 load constant instructions to avoid consing in some
;;; cases. Note these are initialized by GENESIS as they are needed
;;; early.
-(defvar *fp-constant-0s0*)
-(defvar *fp-constant-1s0*)
+(defvar *fp-constant-0f0*)
+(defvar *fp-constant-1f0*)
(defvar *fp-constant-0d0*)
(defvar *fp-constant-1d0*)
;;; the long-float constants
;;; the current alien stack pointer; saved/restored for non-local exits
(defvar *alien-stack*)
-(defun sb!kernel::%instance-set-conditional (object slot test-value new-value)
- (declare (type instance object)
- (type index slot))
- #!+sb-doc
- "Atomically compare object's slot value to test-value and if EQ store
- new-value in the slot. The original value of the slot is returned."
- (sb!kernel::%instance-set-conditional object slot test-value new-value))
-
;;; Support for the MT19937 random number generator. The update
;;; function is implemented as an assembly routine. This definition is
;;; transformed to a call to the assembly routine allowing its use in
-;;; byte compiled code.
+;;; interpreted code.
(defun random-mt19937 (state)
(declare (type (simple-array (unsigned-byte 32) (627)) state))
(random-mt19937 state))