;;; taken through the source to reach the form. This provides a way to
;;; keep track of the location of original source forms, even when
;;; macroexpansions and other arbitary permutations of the code
-;;; happen. This table is initialized by calling Find-Source-Paths on
+;;; happen. This table is initialized by calling FIND-SOURCE-PATHS on
;;; the original source.
(declaim (hash-table *source-paths*))
(defvar *source-paths*)
-;;; *CURRENT-COMPONENT* is the Component structure which we link
+;;; *CURRENT-COMPONENT* is the COMPONENT structure which we link
;;; blocks into as we generate them. This just serves to glue the
;;; emitted blocks together until local call analysis and flow graph
;;; canonicalization figure out what is really going on. We need to
;;; FIXME: It's confusing having one variable named *CURRENT-COMPONENT*
;;; and another named *COMPONENT-BEING-COMPILED*. (In CMU CL they
;;; were called *CURRENT-COMPONENT* and *COMPILE-COMPONENT* respectively,
-;;; which also confusing.)
+;;; which was also confusing.)
(declaim (type (or component null) *current-component*))
(defvar *current-component*)
;;; *CURRENT-PATH* is the source path of the form we are currently
;;; translating. See NODE-SOURCE-PATH in the NODE structure.
(declaim (list *current-path*))
-(defvar *current-path* nil)
+(defvar *current-path*)
(defvar *derive-function-types* nil
"Should the compiler assume that function types will never change,
to optimize code which uses those definitions? Setting this true
gives non-ANSI, early-CMU-CL behavior. It can be useful for improving
the efficiency of stable code.")
+
+(defvar *fun-names-in-this-file* nil)
+
+;;; *ALLOW-DEBUG-CATCH-TAG* controls whether we should allow the
+;;; insertion a (CATCH ...) around code to allow the debugger RETURN
+;;; command to function.
+(defvar *allow-debug-catch-tag* t)
\f
;;;; namespace management utilities
+(defun fun-lexically-notinline-p (name)
+ (let ((fun (lexenv-find name funs :test #'equal)))
+ ;; a declaration will trump a proclamation
+ (if (and fun (defined-fun-p fun))
+ (eq (defined-fun-inlinep fun) :notinline)
+ (eq (info :function :inlinep name) :notinline))))
+
;;; Return a GLOBAL-VAR structure usable for referencing the global
;;; function NAME.
-(defun find-free-really-function (name)
+(defun find-free-really-fun (name)
(unless (info :function :kind name)
(setf (info :function :kind name) :function)
(setf (info :function :where-from name) :assumed))
;; definedness at runtime, which is what matters.
#-sb-xc-host (not (fboundp name)))
(note-undefined-reference name :function))
- (make-global-var :kind :global-function
- :name name
- :type (if (or *derive-function-types*
- (eq where :declared))
- (info :function :type name)
- (specifier-type 'function))
- :where-from where)))
-
-;;; Return a SLOT-ACCESSOR structure usable for referencing the slot
-;;; accessor NAME. CLASS is the structure class.
-(defun find-structure-slot-accessor (class name)
- (declare (type sb!xc:class class))
- (let* ((info (layout-info
- (or (info :type :compiler-layout (sb!xc:class-name class))
- (class-layout class))))
- (accessor (if (listp name) (cadr name) name))
- (slot (find accessor (dd-slots info) :key #'sb!kernel:dsd-accessor))
- (type (dd-name info))
- (slot-type (dsd-type slot)))
- (unless slot
- (error "can't find slot ~S" type))
- (make-slot-accessor
- :name name
- :type (specifier-type
- (if (listp name)
- `(function (,slot-type ,type) ,slot-type)
- `(function (,type) ,slot-type)))
- :for class
- :slot slot)))
-
-;;; If NAME is already entered in *FREE-FUNCTIONS*, then return the
-;;; value. Otherwise, make a new GLOBAL-VAR using information from the
-;;; global environment and enter it in *FREE-FUNCTIONS*. If NAME names
-;;; a macro or special form, then we error out using the supplied
-;;; context which indicates what we were trying to do that demanded a
-;;; function.
-(defun find-free-function (name context)
- (declare (string context))
- (declare (values global-var))
- (or (gethash name *free-functions*)
+ (make-global-var
+ :kind :global-function
+ :%source-name name
+ :type (if (or *derive-function-types*
+ (eq where :declared)
+ (and (member name *fun-names-in-this-file* :test #'equal)
+ (not (fun-lexically-notinline-p name))))
+ (info :function :type name)
+ (specifier-type 'function))
+ :where-from where)))
+
+;;; Has the *FREE-FUNS* entry FREE-FUN become invalid?
+;;;
+;;; In CMU CL, the answer was implicitly always true, so this
+;;; predicate didn't exist.
+;;;
+;;; This predicate was added to fix bug 138 in SBCL. In some obscure
+;;; circumstances, it was possible for a *FREE-FUNS* entry to contain a
+;;; DEFINED-FUN whose DEFINED-FUN-FUNCTIONAL object contained IR1
+;;; stuff (NODEs, BLOCKs...) referring to an already compiled (aka
+;;; "dead") component. When this IR1 stuff was reused in a new
+;;; component, under further obscure circumstances it could be used by
+;;; WITH-IR1-ENVIRONMENT-FROM-NODE to generate a binding for
+;;; *CURRENT-COMPONENT*. At that point things got all confused, since
+;;; IR1 conversion was sending code to a component which had already
+;;; been compiled and would never be compiled again.
+(defun invalid-free-fun-p (free-fun)
+ ;; There might be other reasons that *FREE-FUN* entries could
+ ;; become invalid, but the only one we've been bitten by so far
+ ;; (sbcl-0.pre7.118) is this one:
+ (and (defined-fun-p free-fun)
+ (let ((functional (defined-fun-functional free-fun)))
+ (or (and functional
+ (eql (functional-kind functional) :deleted))
+ (and (lambda-p functional)
+ (or
+ ;; (The main reason for this first test is to bail
+ ;; out early in cases where the LAMBDA-COMPONENT
+ ;; call in the second test would fail because links
+ ;; it needs are uninitialized or invalid.)
+ ;;
+ ;; If the BIND node for this LAMBDA is null, then
+ ;; according to the slot comments, the LAMBDA has
+ ;; been deleted or its call has been deleted. In
+ ;; that case, it seems rather questionable to reuse
+ ;; it, and certainly it shouldn't be necessary to
+ ;; reuse it, so we cheerfully declare it invalid.
+ (null (lambda-bind functional))
+ ;; If this IR1 stuff belongs to a dead component,
+ ;; then we can't reuse it without getting into
+ ;; bizarre confusion.
+ (eql (component-info (lambda-component functional))
+ :dead)))))))
+
+;;; If NAME already has a valid entry in *FREE-FUNS*, then return
+;;; the value. Otherwise, make a new GLOBAL-VAR using information from
+;;; the global environment and enter it in *FREE-FUNS*. If NAME
+;;; names a macro or special form, then we error out using the
+;;; supplied context which indicates what we were trying to do that
+;;; demanded a function.
+(declaim (ftype (sfunction (t string) global-var) find-free-fun))
+(defun find-free-fun (name context)
+ (or (let ((old-free-fun (gethash name *free-funs*)))
+ (and (not (invalid-free-fun-p old-free-fun))
+ old-free-fun))
(ecase (info :function :kind name)
;; FIXME: The :MACRO and :SPECIAL-FORM cases could be merged.
(:macro
name
context))
((:function nil)
- (check-function-name name)
- (note-if-setf-function-and-macro name)
- (let ((expansion (info :function :inline-expansion name))
+ (check-fun-name name)
+ (note-if-setf-fun-and-macro name)
+ (let ((expansion (fun-name-inline-expansion name))
(inlinep (info :function :inlinep name)))
- (setf (gethash name *free-functions*)
+ (setf (gethash name *free-funs*)
(if (or expansion inlinep)
- (make-defined-function
- :name name
+ (make-defined-fun
+ :%source-name name
:inline-expansion expansion
:inlinep inlinep
:where-from (info :function :where-from name)
- :type (info :function :type name))
- (let ((info (info :function :accessor-for name)))
- (etypecase info
- (null
- (find-free-really-function name))
- (sb!xc:structure-class
- (find-structure-slot-accessor info name))
- (sb!xc:class
- (if (typep (layout-info (info :type :compiler-layout
- (sb!xc:class-name
- info)))
- 'defstruct-description)
- (find-structure-slot-accessor info name)
- (find-free-really-function name))))))))))))
+ :type (if (eq inlinep :notinline)
+ (specifier-type 'function)
+ (info :function :type name)))
+ (find-free-really-fun name))))))))
;;; Return the LEAF structure for the lexically apparent function
;;; definition of NAME.
-(declaim (ftype (function (t string) leaf) find-lexically-apparent-function))
-(defun find-lexically-apparent-function (name context)
- (let ((var (lexenv-find name functions :test #'equal)))
+(declaim (ftype (sfunction (t string) leaf) find-lexically-apparent-fun))
+(defun find-lexically-apparent-fun (name context)
+ (let ((var (lexenv-find name funs :test #'equal)))
(cond (var
(unless (leaf-p var)
(aver (and (consp var) (eq (car var) 'macro)))
(compiler-error "found macro name ~S ~A" name context))
var)
(t
- (find-free-function name context)))))
+ (find-free-fun name context)))))
;;; Return the LEAF node for a global variable reference to NAME. If
-;;; NAME is already entered in *FREE-VARIABLES*, then we just return
-;;; the corresponding value. Otherwise, we make a new leaf using
+;;; NAME is already entered in *FREE-VARS*, then we just return the
+;;; corresponding value. Otherwise, we make a new leaf using
;;; information from the global environment and enter it in
-;;; *FREE-VARIABLES*. If the variable is unknown, then we emit a
-;;; warning.
-(defun find-free-variable (name)
- (declare (values (or leaf heap-alien-info)))
+;;; *FREE-VARS*. If the variable is unknown, then we emit a warning.
+(declaim (ftype (sfunction (t) (or leaf cons heap-alien-info)) find-free-var))
+(defun find-free-var (name)
(unless (symbolp name)
(compiler-error "Variable name is not a symbol: ~S." name))
- (or (gethash name *free-variables*)
+ (or (gethash name *free-vars*)
(let ((kind (info :variable :kind name))
(type (info :variable :type name))
(where-from (info :variable :where-from name)))
(when (and (eq where-from :assumed) (eq kind :global))
(note-undefined-reference name :variable))
-
- (setf (gethash name *free-variables*)
- (if (eq kind :alien)
- (info :variable :alien-info name)
- (multiple-value-bind (val valp)
- (info :variable :constant-value name)
- (if (and (eq kind :constant) valp)
- (make-constant :value val
- :name name
- :type (ctype-of val)
- :where-from where-from)
- (make-global-var :kind kind
- :name name
- :type type
- :where-from where-from))))))))
+ (setf (gethash name *free-vars*)
+ (case kind
+ (:alien
+ (info :variable :alien-info name))
+ ;; FIXME: The return value in this case should really be
+ ;; of type SB!C::LEAF. I don't feel too badly about it,
+ ;; because the MACRO idiom is scattered throughout this
+ ;; file, but it should be cleaned up so we're not
+ ;; throwing random conses around. --njf 2002-03-23
+ (:macro
+ (let ((expansion (info :variable :macro-expansion name))
+ (type (type-specifier (info :variable :type name))))
+ `(MACRO . (the ,type ,expansion))))
+ (:constant
+ (let ((value (info :variable :constant-value name)))
+ (make-constant :value value
+ :%source-name name
+ :type (ctype-of value)
+ :where-from where-from)))
+ (t
+ (make-global-var :kind kind
+ :%source-name name
+ :type type
+ :where-from where-from)))))))
\f
;;; Grovel over CONSTANT checking for any sub-parts that need to be
;;; processed with MAKE-LOAD-FORM. We have to be careful, because
;;; CONSTANT might be circular. We also check that the constant (and
;;; any subparts) are dumpable at all.
(eval-when (:compile-toplevel :load-toplevel :execute)
- ;; The EVAL-WHEN is necessary for #.(1+ LIST-TO-HASH-TABLE-THRESHOLD)
+ ;; The EVAL-WHEN is necessary for #.(1+ LIST-TO-HASH-TABLE-THRESHOLD)
;; below. -- AL 20010227
- (defconstant list-to-hash-table-threshold 32))
+ (def!constant list-to-hash-table-threshold 32))
(defun maybe-emit-make-load-forms (constant)
(let ((things-processed nil)
(count 0))
;;;; some flow-graph hacking utilities
;;; This function sets up the back link between the node and the
-;;; continuation which continues at it.
-#!-sb-fluid (declaim (inline prev-link))
-(defun prev-link (node cont)
- (declare (type node node) (type continuation cont))
- (aver (not (continuation-next cont)))
- (setf (continuation-next cont) node)
- (setf (node-prev node) cont))
-
-;;; This function is used to set the continuation for a node, and thus
-;;; determine what receives the value and what is evaluated next. If
-;;; the continuation has no block, then we make it be in the block
-;;; that the node is in. If the continuation heads its block, we end
-;;; our block and link it to that block. If the continuation is not
-;;; currently used, then we set the derived-type for the continuation
-;;; to that of the node, so that a little type propagation gets done.
-;;;
-;;; We also deal with a bit of THE's semantics here: we weaken the
-;;; assertion on CONT to be no stronger than the assertion on CONT in
-;;; our scope. See the IR1-CONVERT method for THE.
-#!-sb-fluid (declaim (inline use-continuation))
-(defun use-continuation (node cont)
- (declare (type node node) (type continuation cont))
- (let ((node-block (continuation-block (node-prev node))))
- (case (continuation-kind cont)
- (:unused
- (setf (continuation-block cont) node-block)
- (setf (continuation-kind cont) :inside-block)
- (setf (continuation-use cont) node)
- (setf (node-cont node) cont))
- (t
- (%use-continuation node cont)))))
-(defun %use-continuation (node cont)
- (declare (type node node) (type continuation cont) (inline member))
- (let ((block (continuation-block cont))
- (node-block (continuation-block (node-prev node))))
- (aver (eq (continuation-kind cont) :block-start))
+;;; ctran which continues at it.
+(defun link-node-to-previous-ctran (node ctran)
+ (declare (type node node) (type ctran ctran))
+ (aver (not (ctran-next ctran)))
+ (setf (ctran-next ctran) node)
+ (setf (node-prev node) ctran))
+
+;;; This function is used to set the ctran for a node, and thus
+;;; determine what is evaluated next. If the ctran has no block, then
+;;; we make it be in the block that the node is in. If the ctran heads
+;;; its block, we end our block and link it to that block.
+#!-sb-fluid (declaim (inline use-ctran))
+(defun use-ctran (node ctran)
+ (declare (type node node) (type ctran ctran))
+ (if (eq (ctran-kind ctran) :unused)
+ (let ((node-block (ctran-block (node-prev node))))
+ (setf (ctran-block ctran) node-block)
+ (setf (ctran-kind ctran) :inside-block)
+ (setf (ctran-use ctran) node)
+ (setf (node-next node) ctran))
+ (%use-ctran node ctran)))
+(defun %use-ctran (node ctran)
+ (declare (type node node) (type ctran ctran) (inline member))
+ (let ((block (ctran-block ctran))
+ (node-block (ctran-block (node-prev node))))
+ (aver (eq (ctran-kind ctran) :block-start))
(when (block-last node-block)
(error "~S has already ended." node-block))
(setf (block-last node-block) node)
(setf (block-succ node-block) (list block))
(when (memq node-block (block-pred block))
(error "~S is already a predecessor of ~S." node-block block))
- (push node-block (block-pred block))
- (add-continuation-use node cont)
- (unless (eq (continuation-asserted-type cont) *wild-type*)
- (let ((new (values-type-union (continuation-asserted-type cont)
- (or (lexenv-find cont type-restrictions)
- *wild-type*))))
- (when (type/= new (continuation-asserted-type cont))
- (setf (continuation-asserted-type cont) new)
- (reoptimize-continuation cont))))))
+ (push node-block (block-pred block))))
+
+;;; This function is used to set the ctran for a node, and thus
+;;; determine what receives the value.
+(defun use-lvar (node lvar)
+ (declare (type valued-node node) (type (or lvar null) lvar))
+ (aver (not (node-lvar node)))
+ (when lvar
+ (setf (node-lvar node) lvar)
+ (cond ((null (lvar-uses lvar))
+ (setf (lvar-uses lvar) node))
+ ((listp (lvar-uses lvar))
+ (aver (not (memq node (lvar-uses lvar))))
+ (push node (lvar-uses lvar)))
+ (t
+ (aver (neq node (lvar-uses lvar)))
+ (setf (lvar-uses lvar) (list node (lvar-uses lvar)))))
+ (reoptimize-lvar lvar)))
+
+#!-sb-fluid(declaim (inline use-continuation))
+(defun use-continuation (node ctran lvar)
+ (use-ctran node ctran)
+ (use-lvar node lvar))
\f
;;;; exported functions
-;;; This function takes a form and the top-level form number for that
+;;; This function takes a form and the top level form number for that
;;; form, and returns a lambda representing the translation of that
-;;; form in the current global environment. The lambda is top-level
-;;; lambda that can be called to cause evaluation of the forms. This
-;;; lambda is in the initial component. If FOR-VALUE is T, then the
-;;; value of the form is returned from the function, otherwise NIL is
-;;; returned.
+;;; form in the current global environment. The returned lambda is a
+;;; top level lambda that can be called to cause evaluation of the
+;;; forms. This lambda is in the initial component. If FOR-VALUE is T,
+;;; then the value of the form is returned from the function,
+;;; otherwise NIL is returned.
;;;
;;; This function may have arbitrary effects on the global environment
-;;; due to processing of PROCLAIMs and EVAL-WHENs. All syntax error
-;;; checking is done, with erroneous forms being replaced by a proxy
-;;; which signals an error if it is evaluated. Warnings about possibly
-;;; inconsistent or illegal changes to the global environment will
-;;; also be given.
+;;; due to processing of EVAL-WHENs. All syntax error checking is
+;;; done, with erroneous forms being replaced by a proxy which signals
+;;; an error if it is evaluated. Warnings about possibly inconsistent
+;;; or illegal changes to the global environment will also be given.
;;;
;;; We make the initial component and convert the form in a PROGN (and
;;; an optional NIL tacked on the end.) We then return the lambda. We
;;; The hashtables used to hold global namespace info must be
;;; reallocated elsewhere. Note also that *LEXENV* is not bound, so
;;; that local macro definitions can be introduced by enclosing code.
-(defun ir1-top-level (form path for-value)
+(defun ir1-toplevel (form path for-value)
(declare (list path))
(let* ((*current-path* path)
(component (make-empty-component))
(setf (component-name component) "initial component")
(setf (component-kind component) :initial)
(let* ((forms (if for-value `(,form) `(,form nil)))
- (res (ir1-convert-lambda-body forms ())))
- (setf (leaf-name res) "top-level form")
- (setf (functional-entry-function res) res)
- (setf (functional-arg-documentation res) ())
- (setf (functional-kind res) :top-level)
+ (res (ir1-convert-lambda-body
+ forms ()
+ :debug-name (debug-namify "top level form " form))))
+ (setf (functional-entry-fun res) res
+ (functional-arg-documentation res) ()
+ (functional-kind res) :toplevel)
res)))
;;; *CURRENT-FORM-NUMBER* is used in FIND-SOURCE-PATHS to compute the
;;; form number to associate with a source path. This should be bound
-;;; to 0 around the processing of each truly top-level form.
+;;; to an initial value of 0 before the processing of each truly
+;;; top level form.
(declaim (type index *current-form-number*))
(defvar *current-form-number*)
;;; This function is called on freshly read forms to record the
;;; initial location of each form (and subform.) Form is the form to
-;;; find the paths in, and TLF-NUM is the top-level form number of the
-;;; truly top-level form.
+;;; find the paths in, and TLF-NUM is the top level form number of the
+;;; truly top level form.
;;;
;;; This gets a bit interesting when the source code is circular. This
;;; can (reasonably?) happen in the case of circular list constants.
\f
;;;; IR1-CONVERT, macroexpansion and special form dispatching
+(declaim (ftype (sfunction (ctran ctran (or lvar null) t) (values))
+ ir1-convert))
(macrolet (;; Bind *COMPILER-ERROR-BAILOUT* to a function that throws
;; out of the body and converts a proxy form instead.
- (ir1-error-bailout ((start
- cont
+ (ir1-error-bailout ((start next result
form
&optional
- (proxy ``(error "execution of a form compiled with errors:~% ~S"
- ',,form)))
+ (proxy ``(error 'simple-program-error
+ :format-control "execution of a form compiled with errors:~% ~S"
+ :format-arguments (list ',,form))))
&body body)
- (let ((skip (gensym "SKIP")))
+ (with-unique-names (skip)
`(block ,skip
(catch 'ir1-error-abort
(let ((*compiler-error-bailout*
(throw 'ir1-error-abort nil))))
,@body
(return-from ,skip nil)))
- (ir1-convert ,start ,cont ,proxy)))))
+ (ir1-convert ,start ,next ,result ,proxy)))))
;; Translate FORM into IR1. The code is inserted as the NEXT of the
- ;; continuation START. CONT is the continuation which receives the
- ;; value of the FORM to be translated. The translators call this
- ;; function recursively to translate their subnodes.
+ ;; CTRAN START. RESULT is the LVAR which receives the value of the
+ ;; FORM to be translated. The translators call this function
+ ;; recursively to translate their subnodes.
;;
;; As a special hack to make life easier in the compiler, a LEAF
;; IR1-converts into a reference to that LEAF structure. This allows
;; the creation using backquote of forms that contain leaf
;; references, without having to introduce dummy names into the
;; namespace.
- (declaim (ftype (function (continuation continuation t) (values)) ir1-convert))
- (defun ir1-convert (start cont form)
- (ir1-error-bailout (start cont form)
+ (defun ir1-convert (start next result form)
+ (ir1-error-bailout (start next result form)
(let ((*current-path* (or (gethash form *source-paths*)
(cons form *current-path*))))
(if (atom form)
(cond ((and (symbolp form) (not (keywordp form)))
- (ir1-convert-variable start cont form))
+ (ir1-convert-var start next result form))
((leaf-p form)
- (reference-leaf start cont form))
+ (reference-leaf start next result form))
(t
- (reference-constant start cont form)))
- (let ((fun (car form)))
- (cond
- ((symbolp fun)
- (let ((lexical-def (lexenv-find fun functions)))
- (typecase lexical-def
- (null (ir1-convert-global-functoid start cont form))
- (functional
- (ir1-convert-local-combination start
- cont
- form
- lexical-def))
- (global-var
- (ir1-convert-srctran start cont lexical-def form))
+ (reference-constant start next result form)))
+ (let ((opname (car form)))
+ (cond ((or (symbolp opname) (leaf-p opname))
+ (let ((lexical-def (if (leaf-p opname)
+ opname
+ (lexenv-find opname funs))))
+ (typecase lexical-def
+ (null
+ (ir1-convert-global-functoid start next result
+ form))
+ (functional
+ (ir1-convert-local-combination start next result
+ form
+ lexical-def))
+ (global-var
+ (ir1-convert-srctran start next result
+ lexical-def form))
+ (t
+ (aver (and (consp lexical-def)
+ (eq (car lexical-def) 'macro)))
+ (ir1-convert start next result
+ (careful-expand-macro (cdr lexical-def)
+ form))))))
+ ((or (atom opname) (not (eq (car opname) 'lambda)))
+ (compiler-error "illegal function call"))
(t
- (aver (and (consp lexical-def)
- (eq (car lexical-def) 'macro)))
- (ir1-convert start cont
- (careful-expand-macro (cdr lexical-def)
- form))))))
- ((or (atom fun) (not (eq (car fun) 'lambda)))
- (compiler-error "illegal function call"))
- (t
- (ir1-convert-combination start
- cont
- form
- (ir1-convert-lambda fun))))))))
+ ;; implicitly (LAMBDA ..) because the LAMBDA
+ ;; expression is the CAR of an executed form
+ (ir1-convert-combination start next result
+ form
+ (ir1-convert-lambda
+ opname
+ :debug-name (debug-namify
+ "LAMBDA CAR "
+ opname)
+ :allow-debug-catch-tag t))))))))
(values))
;; Generate a reference to a manifest constant, creating a new leaf
;; if necessary. If we are producing a fasl file, make sure that
;; MAKE-LOAD-FORM gets used on any parts of the constant that it
;; needs to be.
- (defun reference-constant (start cont value)
- (declare (type continuation start cont)
+ (defun reference-constant (start next result value)
+ (declare (type ctran start next)
+ (type (or lvar null) result)
(inline find-constant))
(ir1-error-bailout
- (start cont value
- '(error "attempt to reference undumpable constant"))
+ (start next result value '(error "attempt to reference undumpable constant"))
(when (producing-fasl-file)
(maybe-emit-make-load-forms value))
(let* ((leaf (find-constant value))
- (res (make-ref (leaf-type leaf) leaf)))
+ (res (make-ref leaf)))
(push res (leaf-refs leaf))
- (prev-link res start)
- (use-continuation res cont)))
+ (link-node-to-previous-ctran res start)
+ (use-continuation res next result)))
(values)))
-;;; Add Fun to the COMPONENT-REANALYZE-FUNCTIONS. Fun is returned.
- (defun maybe-reanalyze-function (fun)
- (declare (type functional fun))
- (when (typep fun '(or optional-dispatch clambda))
- (pushnew fun (component-reanalyze-functions *current-component*)))
- fun)
+;;; Add FUNCTIONAL to the COMPONENT-REANALYZE-FUNCTIONALS, unless it's
+;;; some trivial type for which reanalysis is a trivial no-op, or
+;;; unless it doesn't belong in this component at all.
+;;;
+;;; FUNCTIONAL is returned.
+(defun maybe-reanalyze-functional (functional)
+
+ (aver (not (eql (functional-kind functional) :deleted))) ; bug 148
+ (aver-live-component *current-component*)
+
+ ;; When FUNCTIONAL is of a type for which reanalysis isn't a trivial
+ ;; no-op
+ (when (typep functional '(or optional-dispatch clambda))
+
+ ;; When FUNCTIONAL knows its component
+ (when (lambda-p functional)
+ (aver (eql (lambda-component functional) *current-component*)))
-;;; Generate a Ref node for LEAF, frobbing the LEAF structure as
+ (pushnew functional
+ (component-reanalyze-functionals *current-component*)))
+
+ functional)
+
+;;; Generate a REF node for LEAF, frobbing the LEAF structure as
;;; needed. If LEAF represents a defined function which has already
;;; been converted, and is not :NOTINLINE, then reference the
;;; functional instead.
-(defun reference-leaf (start cont leaf)
- (declare (type continuation start cont) (type leaf leaf))
- (let* ((leaf (or (and (defined-function-p leaf)
- (not (eq (defined-function-inlinep leaf)
- :notinline))
- (let ((fun (defined-function-functional leaf)))
- (when (and fun (not (functional-kind fun)))
- (maybe-reanalyze-function fun))))
- leaf))
- (res (make-ref (or (lexenv-find leaf type-restrictions)
- (leaf-type leaf))
- leaf)))
- (push res (leaf-refs leaf))
+(defun reference-leaf (start next result leaf)
+ (declare (type ctran start next) (type (or lvar null) result) (type leaf leaf))
+ (when (functional-p leaf)
+ (assure-functional-live-p leaf))
+ (let* ((type (lexenv-find leaf type-restrictions))
+ (leaf (or (and (defined-fun-p leaf)
+ (not (eq (defined-fun-inlinep leaf)
+ :notinline))
+ (let ((functional (defined-fun-functional leaf)))
+ (when (and functional
+ (not (functional-kind functional)))
+ (maybe-reanalyze-functional functional))))
+ (when (and (lambda-p leaf)
+ (memq (functional-kind leaf)
+ '(nil :optional)))
+ (maybe-reanalyze-functional leaf))
+ leaf))
+ (ref (make-ref leaf)))
+ (push ref (leaf-refs leaf))
(setf (leaf-ever-used leaf) t)
- (prev-link res start)
- (use-continuation res cont)))
+ (link-node-to-previous-ctran ref start)
+ (cond (type (let* ((ref-ctran (make-ctran))
+ (ref-lvar (make-lvar))
+ (cast (make-cast ref-lvar
+ (make-single-value-type type)
+ (lexenv-policy *lexenv*))))
+ (setf (lvar-dest ref-lvar) cast)
+ (use-continuation ref ref-ctran ref-lvar)
+ (link-node-to-previous-ctran cast ref-ctran)
+ (use-continuation cast next result)))
+ (t (use-continuation ref next result)))))
;;; Convert a reference to a symbolic constant or variable. If the
-;;; symbol is entered in the LEXENV-VARIABLES we use that definition,
+;;; symbol is entered in the LEXENV-VARS we use that definition,
;;; otherwise we find the current global definition. This is also
-;;; where we pick off symbol macro and Alien variable references.
-(defun ir1-convert-variable (start cont name)
- (declare (type continuation start cont) (symbol name))
- (let ((var (or (lexenv-find name variables) (find-free-variable name))))
+;;; where we pick off symbol macro and alien variable references.
+(defun ir1-convert-var (start next result name)
+ (declare (type ctran start next) (type (or lvar null) result) (symbol name))
+ (let ((var (or (lexenv-find name vars) (find-free-var name))))
(etypecase var
(leaf
- (when (and (lambda-var-p var) (lambda-var-ignorep var))
- ;; (ANSI's specification for the IGNORE declaration requires
- ;; that this be a STYLE-WARNING, not a full WARNING.)
- (compiler-style-warning "reading an ignored variable: ~S" name))
- (reference-leaf start cont var))
+ (when (lambda-var-p var)
+ (let ((home (ctran-home-lambda-or-null start)))
+ (when home
+ (pushnew var (lambda-calls-or-closes home))))
+ (when (lambda-var-ignorep var)
+ ;; (ANSI's specification for the IGNORE declaration requires
+ ;; that this be a STYLE-WARNING, not a full WARNING.)
+ #-sb-xc-host
+ (compiler-style-warn "reading an ignored variable: ~S" name)
+ ;; there's no need for us to accept ANSI's lameness when
+ ;; processing our own code, though.
+ #+sb-xc-host
+ (compiler-warn "reading an ignored variable: ~S" name)))
+ (reference-leaf start next result var))
(cons
(aver (eq (car var) 'MACRO))
- (ir1-convert start cont (cdr var)))
+ ;; FIXME: [Free] type declarations. -- APD, 2002-01-26
+ (ir1-convert start next result (cdr var)))
(heap-alien-info
- (ir1-convert start cont `(%heap-alien ',var)))))
+ (ir1-convert start next result `(%heap-alien ',var)))))
(values))
;;; Convert anything that looks like a special form, global function
-;;; or macro call.
-(defun ir1-convert-global-functoid (start cont form)
- (declare (type continuation start cont) (list form))
- (let* ((fun (first form))
- (translator (info :function :ir1-convert fun))
- (cmacro (info :function :compiler-macro-function fun)))
- (cond (translator (funcall translator start cont form))
- ((and cmacro
- (not (eq (info :function :inlinep fun)
- :notinline)))
- (let ((res (careful-expand-macro cmacro form)))
+;;; or compiler-macro call.
+(defun ir1-convert-global-functoid (start next result form)
+ (declare (type ctran start next) (type (or lvar null) result) (list form))
+ (let* ((fun-name (first form))
+ (translator (info :function :ir1-convert fun-name))
+ (cmacro-fun (sb!xc:compiler-macro-function fun-name *lexenv*)))
+ (cond (translator
+ (when cmacro-fun
+ (compiler-warn "ignoring compiler macro for special form"))
+ (funcall translator start next result form))
+ ((and cmacro-fun
+ ;; gotcha: If you look up the DEFINE-COMPILER-MACRO
+ ;; macro in the ANSI spec, you might think that
+ ;; suppressing compiler-macro expansion when NOTINLINE
+ ;; is some pre-ANSI hack. However, if you look up the
+ ;; NOTINLINE declaration, you'll find that ANSI
+ ;; requires this behavior after all.
+ (not (eq (info :function :inlinep fun-name) :notinline)))
+ (let ((res (careful-expand-macro cmacro-fun form)))
(if (eq res form)
- (ir1-convert-global-functoid-no-cmacro start cont form fun)
- (ir1-convert start cont res))))
+ (ir1-convert-global-functoid-no-cmacro
+ start next result form fun-name)
+ (ir1-convert start next result res))))
(t
- (ir1-convert-global-functoid-no-cmacro start cont form fun)))))
-
-;;; Handle the case of where the call was not a compiler macro, or was a
-;;; compiler macro and passed.
-(defun ir1-convert-global-functoid-no-cmacro (start cont form fun)
- (declare (type continuation start cont) (list form))
+ (ir1-convert-global-functoid-no-cmacro start next result
+ form fun-name)))))
+
+;;; Handle the case of where the call was not a compiler macro, or was
+;;; a compiler macro and passed.
+(defun ir1-convert-global-functoid-no-cmacro (start next result form fun)
+ (declare (type ctran start next) (type (or lvar null) result)
+ (list form))
;; FIXME: Couldn't all the INFO calls here be converted into
;; standard CL functions, like MACRO-FUNCTION or something?
;; And what happens with lexically-defined (MACROLET) macros
;; here, anyway?
(ecase (info :function :kind fun)
(:macro
- (ir1-convert start
- cont
+ (ir1-convert start next result
(careful-expand-macro (info :function :macro-function fun)
form)))
((nil :function)
- (ir1-convert-srctran start cont (find-free-function fun "Eh?") form))))
+ (ir1-convert-srctran start next result
+ (find-free-fun fun "shouldn't happen! (no-cmacro)")
+ form))))
(defun muffle-warning-or-die ()
(muffle-warning)
- (error "internal error -- no MUFFLE-WARNING restart"))
+ (bug "no MUFFLE-WARNING restart"))
;;; Expand FORM using the macro whose MACRO-FUNCTION is FUN, trapping
;;; errors which occur during the macroexpansion.
(defun careful-expand-macro (fun form)
- (handler-bind (;; When cross-compiling, we can get style warnings
- ;; about e.g. undefined functions. An unhandled
- ;; CL:STYLE-WARNING (as opposed to a
- ;; SB!C::COMPILER-NOTE) would cause FAILURE-P to be
- ;; set on the return from #'SB!XC:COMPILE-FILE, which
- ;; would falsely indicate an error sufficiently
- ;; serious that we should stop the build process. To
- ;; avoid this, we translate CL:STYLE-WARNING
- ;; conditions from the host Common Lisp into
- ;; cross-compiler SB!C::COMPILER-NOTE calls. (It
- ;; might be cleaner to just make Python use
- ;; CL:STYLE-WARNING internally, so that the
- ;; significance of any host Common Lisp
- ;; CL:STYLE-WARNINGs is understood automatically. But
- ;; for now I'm not motivated to do this. -- WHN
- ;; 19990412)
- (style-warning (lambda (c)
- (compiler-note "(during macroexpansion)~%~A"
- c)
- (muffle-warning-or-die)))
- ;; KLUDGE: CMU CL in its wisdom (version 2.4.6 for
- ;; Debian Linux, anyway) raises a CL:WARNING
- ;; condition (not a CL:STYLE-WARNING) for undefined
- ;; symbols when converting interpreted functions,
- ;; causing COMPILE-FILE to think the file has a real
- ;; problem, causing COMPILE-FILE to return FAILURE-P
- ;; set (not just WARNINGS-P set). Since undefined
- ;; symbol warnings are often harmless forward
- ;; references, and since it'd be inordinately painful
- ;; to try to eliminate all such forward references,
- ;; these warnings are basically unavoidable. Thus, we
- ;; need to coerce the system to work through them,
- ;; and this code does so, by crudely suppressing all
- ;; warnings in cross-compilation macroexpansion. --
- ;; WHN 19990412
- #+cmu
- (warning (lambda (c)
- (compiler-note
- "(during macroexpansion)~%~
- ~A~%~
- (KLUDGE: That was a non-STYLE WARNING.~%~
- Ordinarily that would cause compilation to~%~
- fail. However, since we're running under~%~
- CMU CL, and since CMU CL emits non-STYLE~%~
- warnings for safe, hard-to-fix things (e.g.~%~
- references to not-yet-defined functions)~%~
- we're going to have to ignore it and proceed~%~
- anyway. Hopefully we're not ignoring anything~%~
- horrible here..)~%"
- c)
- (muffle-warning-or-die)))
- (error (lambda (c)
- (compiler-error "(during macroexpansion)~%~A" c))))
- (funcall sb!xc:*macroexpand-hook*
- fun
- form
- *lexenv*)))
+ (let (;; a hint I (WHN) wish I'd known earlier
+ (hint "(hint: For more precise location, try *BREAK-ON-SIGNALS*.)"))
+ (flet (;; Return a string to use as a prefix in error reporting,
+ ;; telling something about which form caused the problem.
+ (wherestring ()
+ (let ((*print-pretty* nil)
+ ;; We rely on the printer to abbreviate FORM.
+ (*print-length* 3)
+ (*print-level* 1))
+ (format
+ nil
+ #-sb-xc-host "(in macroexpansion of ~S)"
+ ;; longer message to avoid ambiguity "Was it the xc host
+ ;; or the cross-compiler which encountered the problem?"
+ #+sb-xc-host "(in cross-compiler macroexpansion of ~S)"
+ form))))
+ (handler-bind ((style-warning (lambda (c)
+ (compiler-style-warn
+ "~@<~A~:@_~A~@:_~A~:>"
+ (wherestring) hint c)
+ (muffle-warning-or-die)))
+ ;; KLUDGE: CMU CL in its wisdom (version 2.4.6 for
+ ;; Debian Linux, anyway) raises a CL:WARNING
+ ;; condition (not a CL:STYLE-WARNING) for undefined
+ ;; symbols when converting interpreted functions,
+ ;; causing COMPILE-FILE to think the file has a real
+ ;; problem, causing COMPILE-FILE to return FAILURE-P
+ ;; set (not just WARNINGS-P set). Since undefined
+ ;; symbol warnings are often harmless forward
+ ;; references, and since it'd be inordinately painful
+ ;; to try to eliminate all such forward references,
+ ;; these warnings are basically unavoidable. Thus, we
+ ;; need to coerce the system to work through them,
+ ;; and this code does so, by crudely suppressing all
+ ;; warnings in cross-compilation macroexpansion. --
+ ;; WHN 19990412
+ #+(and cmu sb-xc-host)
+ (warning (lambda (c)
+ (compiler-notify
+ "~@<~A~:@_~
+ ~A~:@_~
+ ~@<(KLUDGE: That was a non-STYLE WARNING. ~
+ Ordinarily that would cause compilation to ~
+ fail. However, since we're running under ~
+ CMU CL, and since CMU CL emits non-STYLE ~
+ warnings for safe, hard-to-fix things (e.g. ~
+ references to not-yet-defined functions) ~
+ we're going to have to ignore it and ~
+ proceed anyway. Hopefully we're not ~
+ ignoring anything horrible here..)~:@>~:>"
+ (wherestring)
+ c)
+ (muffle-warning-or-die)))
+ #-(and cmu sb-xc-host)
+ (warning (lambda (c)
+ (compiler-warn "~@<~A~:@_~A~@:_~A~:>"
+ (wherestring) hint c)
+ (muffle-warning-or-die)))
+ (error (lambda (c)
+ (compiler-error "~@<~A~:@_~A~@:_~A~:>"
+ (wherestring) hint c))))
+ (funcall sb!xc:*macroexpand-hook* fun form *lexenv*)))))
\f
;;;; conversion utilities
;;; Convert a bunch of forms, discarding all the values except the
;;; last. If there aren't any forms, then translate a NIL.
-(declaim (ftype (function (continuation continuation list) (values))
+(declaim (ftype (sfunction (ctran ctran (or lvar null) list) (values))
ir1-convert-progn-body))
-(defun ir1-convert-progn-body (start cont body)
+(defun ir1-convert-progn-body (start next result body)
(if (endp body)
- (reference-constant start cont nil)
+ (reference-constant start next result nil)
(let ((this-start start)
(forms body))
(loop
(let ((form (car forms)))
(when (endp (cdr forms))
- (ir1-convert this-start cont form)
+ (ir1-convert this-start next result form)
(return))
- (let ((this-cont (make-continuation)))
- (ir1-convert this-start this-cont form)
- (setq this-start this-cont forms (cdr forms)))))))
+ (let ((this-ctran (make-ctran)))
+ (ir1-convert this-start this-ctran nil form)
+ (setq this-start this-ctran
+ forms (cdr forms)))))))
(values))
\f
;;;; converting combinations
-;;; Convert a function call where the function (Fun) is a Leaf. We
-;;; return the Combination node so that we can poke at it if we want to.
-(declaim (ftype (function (continuation continuation list leaf) combination)
+;;; Convert a function call where the function FUN is a LEAF. FORM is
+;;; the source for the call. We return the COMBINATION node so that
+;;; the caller can poke at it if it wants to.
+(declaim (ftype (sfunction (ctran ctran (or lvar null) list leaf) combination)
ir1-convert-combination))
-(defun ir1-convert-combination (start cont form fun)
- (let ((fun-cont (make-continuation)))
- (reference-leaf start fun-cont fun)
- (ir1-convert-combination-args fun-cont cont (cdr form))))
-
-;;; Convert the arguments to a call and make the Combination node. Fun-Cont
-;;; is the continuation which yields the function to call. Form is the source
-;;; for the call. Args is the list of arguments for the call, which defaults
-;;; to the cdr of source. We return the Combination node.
-(defun ir1-convert-combination-args (fun-cont cont args)
- (declare (type continuation fun-cont cont) (list args))
- (let ((node (make-combination fun-cont)))
- (setf (continuation-dest fun-cont) node)
- (assert-continuation-type fun-cont
- (specifier-type '(or function symbol)))
- (collect ((arg-conts))
- (let ((this-start fun-cont))
+(defun ir1-convert-combination (start next result form fun)
+ (let ((ctran (make-ctran))
+ (fun-lvar (make-lvar)))
+ (ir1-convert start ctran fun-lvar `(the (or function symbol) ,fun))
+ (ir1-convert-combination-args fun-lvar ctran next result (cdr form))))
+
+;;; Convert the arguments to a call and make the COMBINATION
+;;; node. FUN-LVAR yields the function to call. ARGS is the list of
+;;; arguments for the call, which defaults to the cdr of source. We
+;;; return the COMBINATION node.
+(defun ir1-convert-combination-args (fun-lvar start next result args)
+ (declare (type ctran start next)
+ (type lvar fun-lvar)
+ (type (or lvar null) result)
+ (list args))
+ (let ((node (make-combination fun-lvar)))
+ (setf (lvar-dest fun-lvar) node)
+ (collect ((arg-lvars))
+ (let ((this-start start))
(dolist (arg args)
- (let ((this-cont (make-continuation node)))
- (ir1-convert this-start this-cont arg)
- (setq this-start this-cont)
- (arg-conts this-cont)))
- (prev-link node this-start)
- (use-continuation node cont)
- (setf (combination-args node) (arg-conts))))
+ (let ((this-ctran (make-ctran))
+ (this-lvar (make-lvar node)))
+ (ir1-convert this-start this-ctran this-lvar arg)
+ (setq this-start this-ctran)
+ (arg-lvars this-lvar)))
+ (link-node-to-previous-ctran node this-start)
+ (use-continuation node next result)
+ (setf (combination-args node) (arg-lvars))))
node))
;;; Convert a call to a global function. If not :NOTINLINE, then we do
;;; expansion, but is :INLINE, then give an efficiency note (unless a
;;; known function which will quite possibly be open-coded.) Next, we
;;; go to ok-combination conversion.
-(defun ir1-convert-srctran (start cont var form)
- (declare (type continuation start cont) (type global-var var))
- (let ((inlinep (when (defined-function-p var)
- (defined-function-inlinep var))))
+(defun ir1-convert-srctran (start next result var form)
+ (declare (type ctran start next) (type (or lvar null) result)
+ (type global-var var))
+ (let ((inlinep (when (defined-fun-p var)
+ (defined-fun-inlinep var))))
(if (eq inlinep :notinline)
- (ir1-convert-combination start cont form var)
- (let ((transform (info :function :source-transform (leaf-name var))))
- (if transform
- (multiple-value-bind (result pass) (funcall transform form)
- (if pass
- (ir1-convert-maybe-predicate start cont form var)
- (ir1-convert start cont result)))
- (ir1-convert-maybe-predicate start cont form var))))))
-
-;;; If the function has the PREDICATE attribute, and the CONT's DEST
+ (ir1-convert-combination start next result form var)
+ (let ((transform (info :function
+ :source-transform
+ (leaf-source-name var))))
+ (if transform
+ (multiple-value-bind (transformed pass) (funcall transform form)
+ (if pass
+ (ir1-convert-maybe-predicate start next result form var)
+ (ir1-convert start next result transformed)))
+ (ir1-convert-maybe-predicate start next result form var))))))
+
+;;; If the function has the PREDICATE attribute, and the RESULT's DEST
;;; isn't an IF, then we convert (IF <form> T NIL), ensuring that a
;;; predicate always appears in a conditional context.
;;;
;;; If the function isn't a predicate, then we call
;;; IR1-CONVERT-COMBINATION-CHECKING-TYPE.
-(defun ir1-convert-maybe-predicate (start cont form var)
- (declare (type continuation start cont) (list form) (type global-var var))
- (let ((info (info :function :info (leaf-name var))))
+(defun ir1-convert-maybe-predicate (start next result form var)
+ (declare (type ctran start next)
+ (type (or lvar null) result)
+ (list form)
+ (type global-var var))
+ (let ((info (info :function :info (leaf-source-name var))))
(if (and info
- (ir1-attributep (function-info-attributes info) predicate)
- (not (if-p (continuation-dest cont))))
- (ir1-convert start cont `(if ,form t nil))
- (ir1-convert-combination-checking-type start cont form var))))
+ (ir1-attributep (fun-info-attributes info) predicate)
+ (not (if-p (and result (lvar-dest result)))))
+ (ir1-convert start next result `(if ,form t nil))
+ (ir1-convert-combination-checking-type start next result form var))))
;;; Actually really convert a global function call that we are allowed
;;; to early-bind.
;;; call is legal.
;;;
;;; If the call is legal, we also propagate type assertions from the
-;;; function type to the arg and result continuations. We do this now
-;;; so that IR1 optimize doesn't have to redundantly do the check
-;;; later so that it can do the type propagation.
-(defun ir1-convert-combination-checking-type (start cont form var)
- (declare (type continuation start cont) (list form) (type leaf var))
- (let* ((node (ir1-convert-combination start cont form var))
- (fun-cont (basic-combination-fun node))
+;;; function type to the arg and result lvars. We do this now so that
+;;; IR1 optimize doesn't have to redundantly do the check later so
+;;; that it can do the type propagation.
+(defun ir1-convert-combination-checking-type (start next result form var)
+ (declare (type ctran start next) (type (or lvar null) result)
+ (list form)
+ (type leaf var))
+ (let* ((node (ir1-convert-combination start next result form var))
+ (fun-lvar (basic-combination-fun node))
(type (leaf-type var)))
(when (validate-call-type node type t)
- (setf (continuation-%derived-type fun-cont) type)
- (setf (continuation-reoptimize fun-cont) nil)
- (setf (continuation-%type-check fun-cont) nil)))
-
+ (setf (lvar-%derived-type fun-lvar)
+ (make-single-value-type type))
+ (setf (lvar-reoptimize fun-lvar) nil)))
(values))
-;;; Convert a call to a local function. If the function has already
-;;; been let converted, then throw FUN to LOCAL-CALL-LOSSAGE. This
-;;; should only happen when we are converting inline expansions for
-;;; local functions during optimization.
-(defun ir1-convert-local-combination (start cont form fun)
- (if (functional-kind fun)
- (throw 'local-call-lossage fun)
- (ir1-convert-combination start cont form
- (maybe-reanalyze-function fun))))
+;;; Convert a call to a local function, or if the function has already
+;;; been LET converted, then throw FUNCTIONAL to
+;;; LOCALL-ALREADY-LET-CONVERTED. The THROW should only happen when we
+;;; are converting inline expansions for local functions during
+;;; optimization.
+(defun ir1-convert-local-combination (start next result form functional)
+ (assure-functional-live-p functional)
+ (ir1-convert-combination start next result
+ form
+ (maybe-reanalyze-functional functional)))
\f
;;;; PROCESS-DECLS
-;;; Given a list of Lambda-Var structures and a variable name, return
-;;; the structure for that name, or NIL if it isn't found. We return
-;;; the *last* variable with that name, since LET* bindings may be
+;;; Given a list of LAMBDA-VARs and a variable name, return the
+;;; LAMBDA-VAR for that name, or NIL if it isn't found. We return the
+;;; *last* variable with that name, since LET* bindings may be
;;; duplicated, and declarations always apply to the last.
-(declaim (ftype (function (list symbol) (or lambda-var list))
+(declaim (ftype (sfunction (list symbol) (or lambda-var list))
find-in-bindings))
(defun find-in-bindings (vars name)
(let ((found nil))
(dolist (var vars)
(cond ((leaf-p var)
- (when (eq (leaf-name var) name)
+ (when (eq (leaf-source-name var) name)
(setq found var))
(let ((info (lambda-var-arg-info var)))
(when info
(let ((supplied-p (arg-info-supplied-p info)))
(when (and supplied-p
- (eq (leaf-name supplied-p) name))
+ (eq (leaf-source-name supplied-p) name))
(setq found supplied-p))))))
((and (consp var) (eq (car var) name))
(setf found (cdr var)))))
found))
-;;; Called by Process-Decls to deal with a variable type declaration.
-;;; If a lambda-var being bound, we intersect the type with the vars
-;;; type, otherwise we add a type-restriction on the var. If a symbol
+;;; Called by PROCESS-DECLS to deal with a variable type declaration.
+;;; If a LAMBDA-VAR being bound, we intersect the type with the var's
+;;; type, otherwise we add a type restriction on the var. If a symbol
;;; macro, we just wrap a THE around the expansion.
(defun process-type-decl (decl res vars)
(declare (list decl vars) (type lexenv res))
- (let ((type (specifier-type (first decl))))
+ (let ((type (compiler-specifier-type (first decl))))
(collect ((restr nil cons)
- (new-vars nil cons))
+ (new-vars nil cons))
(dolist (var-name (rest decl))
(let* ((bound-var (find-in-bindings vars var-name))
(var (or bound-var
- (lexenv-find var-name variables)
- (find-free-variable var-name))))
+ (lexenv-find var-name vars)
+ (find-free-var var-name))))
(etypecase var
(leaf
- (let* ((old-type (or (lexenv-find var type-restrictions)
- (leaf-type var)))
- (int (if (or (function-type-p type)
- (function-type-p old-type))
- type
- (type-approx-intersection2 old-type type))))
- (cond ((eq int *empty-type*)
- (unless (policy *lexenv* (= inhibit-warnings 3))
- (compiler-warning
- "The type declarations ~S and ~S for ~S conflict."
- (type-specifier old-type) (type-specifier type)
- var-name)))
- (bound-var (setf (leaf-type bound-var) int))
- (t
- (restr (cons var int))))))
+ (flet ((process-var (var bound-var)
+ (let* ((old-type (or (lexenv-find var type-restrictions)
+ (leaf-type var)))
+ (int (if (or (fun-type-p type)
+ (fun-type-p old-type))
+ type
+ (type-approx-intersection2 old-type type))))
+ (cond ((eq int *empty-type*)
+ (unless (policy *lexenv* (= inhibit-warnings 3))
+ (compiler-warn
+ "The type declarations ~S and ~S for ~S conflict."
+ (type-specifier old-type) (type-specifier type)
+ var-name)))
+ (bound-var (setf (leaf-type bound-var) int))
+ (t
+ (restr (cons var int)))))))
+ (process-var var bound-var)
+ (awhen (and (lambda-var-p var)
+ (lambda-var-specvar var))
+ (process-var it nil))))
(cons
;; FIXME: non-ANSI weirdness
(aver (eq (car var) 'MACRO))
(new-vars `(,var-name . (MACRO . (the ,(first decl)
- ,(cdr var))))))
+ ,(cdr var))))))
(heap-alien-info
(compiler-error
"~S is an alien variable, so its type can't be declared."
(if (or (restr) (new-vars))
(make-lexenv :default res
:type-restrictions (restr)
- :variables (new-vars))
+ :vars (new-vars))
res))))
;;; This is somewhat similar to PROCESS-TYPE-DECL, but handles
;;; declarations that constrain the type of lexically apparent
;;; functions.
(defun process-ftype-decl (spec res names fvars)
- (declare (list spec names fvars) (type lexenv res))
- (let ((type (specifier-type spec)))
+ (declare (type list names fvars)
+ (type lexenv res))
+ (let ((type (compiler-specifier-type spec)))
(collect ((res nil cons))
(dolist (name names)
- (let ((found (find name fvars :key #'leaf-name :test #'equal)))
+ (let ((found (find name fvars
+ :key #'leaf-source-name
+ :test #'equal)))
(cond
(found
(setf (leaf-type found) type)
(assert-definition-type found type
- :warning-function #'compiler-note
+ :unwinnage-fun #'compiler-notify
:where "FTYPE declaration"))
(t
- (res (cons (find-lexically-apparent-function
+ (res (cons (find-lexically-apparent-fun
name "in a function type declaration")
type))))))
(if (res)
(when (lambda-var-ignorep var)
;; ANSI's definition for "Declaration IGNORE, IGNORABLE"
;; requires that this be a STYLE-WARNING, not a full WARNING.
- (compiler-style-warning
+ (compiler-style-warn
"The ignored variable ~S is being declared special."
name))
(setf (lambda-var-specvar var)
(unless (assoc name (new-venv) :test #'eq)
(new-venv (cons name (specvar-for-binding name))))))))
(if (new-venv)
- (make-lexenv :default res :variables (new-venv))
+ (make-lexenv :default res :vars (new-venv))
res)))
-;;; Return a DEFINED-FUNCTION which copies a global-var but for its inlinep.
+;;; Return a DEFINED-FUN which copies a GLOBAL-VAR but for its INLINEP
+;;; (and TYPE if notinline).
(defun make-new-inlinep (var inlinep)
(declare (type global-var var) (type inlinep inlinep))
- (let ((res (make-defined-function
- :name (leaf-name var)
+ (let ((res (make-defined-fun
+ :%source-name (leaf-source-name var)
:where-from (leaf-where-from var)
- :type (leaf-type var)
+ :type (if (and (eq inlinep :notinline)
+ (not (eq (leaf-where-from var) :declared)))
+ (specifier-type 'function)
+ (leaf-type var))
:inlinep inlinep)))
- (when (defined-function-p var)
- (setf (defined-function-inline-expansion res)
- (defined-function-inline-expansion var))
- (setf (defined-function-functional res)
- (defined-function-functional var)))
+ (when (defined-fun-p var)
+ (setf (defined-fun-inline-expansion res)
+ (defined-fun-inline-expansion var))
+ (setf (defined-fun-functional res)
+ (defined-fun-functional var)))
res))
;;; Parse an inline/notinline declaration. If it's a local function we're
(let ((sense (cdr (assoc (first spec) *inlinep-translations* :test #'eq)))
(new-fenv ()))
(dolist (name (rest spec))
- (let ((fvar (find name fvars :key #'leaf-name :test #'equal)))
+ (let ((fvar (find name fvars
+ :key #'leaf-source-name
+ :test #'equal)))
(if fvar
(setf (functional-inlinep fvar) sense)
(let ((found
- (find-lexically-apparent-function
+ (find-lexically-apparent-fun
name "in an inline or notinline declaration")))
(etypecase found
(functional
(when (policy *lexenv* (>= speed inhibit-warnings))
- (compiler-note "ignoring ~A declaration not at ~
- definition of local function:~% ~S"
- sense name)))
+ (compiler-notify "ignoring ~A declaration not at ~
+ definition of local function:~% ~S"
+ sense name)))
(global-var
(push (cons name (make-new-inlinep found sense))
new-fenv)))))))
(if new-fenv
- (make-lexenv :default res :functions new-fenv)
+ (make-lexenv :default res :funs new-fenv)
res)))
-;;; Like FIND-IN-BINDINGS, but looks for #'foo in the fvars.
+;;; like FIND-IN-BINDINGS, but looks for #'FOO in the FVARS
(defun find-in-bindings-or-fbindings (name vars fvars)
(declare (list vars fvars))
(if (consp name)
(unless (eq wot 'function)
(compiler-error "The function or variable name ~S is unrecognizable."
name))
- (find fn-name fvars :key #'leaf-name :test #'equal))
+ (find fn-name fvars :key #'leaf-source-name :test #'equal))
(find-in-bindings vars name)))
;;; Process an ignore/ignorable declaration, checking for various losing
((not var)
;; ANSI's definition for "Declaration IGNORE, IGNORABLE"
;; requires that this be a STYLE-WARNING, not a full WARNING.
- (compiler-style-warning "declaring unknown variable ~S to be ignored"
- name))
+ (compiler-style-warn "declaring unknown variable ~S to be ignored"
+ name))
;; FIXME: This special case looks like non-ANSI weirdness.
- ((and (consp var) (consp (cdr var)) (eq (cadr var) 'macro))
+ ((and (consp var) (eq (car var) 'macro))
;; Just ignore the IGNORE decl.
)
((functional-p var)
(setf (leaf-ever-used var) t))
- ((lambda-var-specvar var)
+ ((and (lambda-var-specvar var) (eq (first spec) 'ignore))
;; ANSI's definition for "Declaration IGNORE, IGNORABLE"
;; requires that this be a STYLE-WARNING, not a full WARNING.
- (compiler-style-warning "declaring special variable ~S to be ignored"
- name))
+ (compiler-style-warn "declaring special variable ~S to be ignored"
+ name))
((eq (first spec) 'ignorable)
(setf (leaf-ever-used var) t))
(t
(setf (lambda-var-ignorep var) t)))))
(values))
+(defun process-dx-decl (names vars)
+ (flet ((maybe-notify (control &rest args)
+ (when (policy *lexenv* (> speed inhibit-warnings))
+ (apply #'compiler-notify control args))))
+ (if (policy *lexenv* (= stack-allocate-dynamic-extent 3))
+ (dolist (name names)
+ (cond
+ ((symbolp name)
+ (let* ((bound-var (find-in-bindings vars name))
+ (var (or bound-var
+ (lexenv-find name vars)
+ (find-free-var name))))
+ (etypecase var
+ (leaf
+ (if bound-var
+ (setf (leaf-dynamic-extent var) t)
+ (maybe-notify
+ "ignoring DYNAMIC-EXTENT declaration for free ~S"
+ name)))
+ (cons
+ (compiler-error "DYNAMIC-EXTENT on symbol-macro: ~S" name))
+ (heap-alien-info
+ (compiler-error "DYNAMIC-EXTENT on heap-alien-info: ~S"
+ name)))))
+ ((and (consp name)
+ (eq (car name) 'function)
+ (null (cddr name))
+ (valid-function-name-p (cadr name)))
+ (maybe-notify "ignoring DYNAMIC-EXTENT declaration for ~S" name))
+ (t (compiler-error "DYNAMIC-EXTENT on a weird thing: ~S" name))))
+ (maybe-notify "ignoring DYNAMIC-EXTENT declarations for ~S" names))))
+
;;; FIXME: This is non-ANSI, so the default should be T, or it should
;;; go away, I think.
(defvar *suppress-values-declaration* nil
"If true, processing of the VALUES declaration is inhibited.")
;;; Process a single declaration spec, augmenting the specified LEXENV
-;;; RES and returning it as a result. VARS and FVARS are as described in
+;;; RES. Return RES and result type. VARS and FVARS are as described
;;; PROCESS-DECLS.
-(defun process-1-decl (raw-spec res vars fvars cont)
+(defun process-1-decl (raw-spec res vars fvars)
(declare (type list raw-spec vars fvars))
(declare (type lexenv res))
- (declare (type continuation cont))
- (let ((spec (canonized-decl-spec raw-spec)))
- (case (first spec)
- (special (process-special-decl spec res vars))
- (ftype
- (unless (cdr spec)
- (compiler-error "No type specified in FTYPE declaration: ~S" spec))
- (process-ftype-decl (second spec) res (cddr spec) fvars))
- ((inline notinline maybe-inline)
- (process-inline-decl spec res fvars))
- ((ignore ignorable)
- (process-ignore-decl spec vars fvars)
- res)
- (optimize
- (make-lexenv
- :default res
- :policy (process-optimize-decl spec (lexenv-policy res))))
- (type
- (process-type-decl (cdr spec) res vars))
- (values
- (if *suppress-values-declaration*
- res
- (let ((types (cdr spec)))
- (do-the-stuff (if (eql (length types) 1)
- (car types)
- `(values ,@types))
- cont res 'values))))
- (dynamic-extent
- (when (policy *lexenv* (> speed inhibit-warnings))
- (compiler-note
- "compiler limitation:~
- ~% There's no special support for DYNAMIC-EXTENT (so it's ignored)."))
- res)
- (t
- (unless (info :declaration :recognized (first spec))
- (compiler-warning "unrecognized declaration ~S" raw-spec))
- res))))
+ (let ((spec (canonized-decl-spec raw-spec))
+ (result-type *wild-type*))
+ (values
+ (case (first spec)
+ (special (process-special-decl spec res vars))
+ (ftype
+ (unless (cdr spec)
+ (compiler-error "no type specified in FTYPE declaration: ~S" spec))
+ (process-ftype-decl (second spec) res (cddr spec) fvars))
+ ((inline notinline maybe-inline)
+ (process-inline-decl spec res fvars))
+ ((ignore ignorable)
+ (process-ignore-decl spec vars fvars)
+ res)
+ (optimize
+ (make-lexenv
+ :default res
+ :policy (process-optimize-decl spec (lexenv-policy res))))
+ (muffle-conditions
+ (make-lexenv
+ :default res
+ :handled-conditions (process-muffle-conditions-decl
+ spec (lexenv-handled-conditions res))))
+ (unmuffle-conditions
+ (make-lexenv
+ :default res
+ :handled-conditions (process-unmuffle-conditions-decl
+ spec (lexenv-handled-conditions res))))
+ (type
+ (process-type-decl (cdr spec) res vars))
+ (values
+ (unless *suppress-values-declaration*
+ (let ((types (cdr spec)))
+ (setq result-type
+ (compiler-values-specifier-type
+ (if (singleton-p types)
+ (car types)
+ `(values ,@types)))))
+ res))
+ (dynamic-extent
+ (process-dx-decl (cdr spec) vars)
+ res)
+ (t
+ (unless (info :declaration :recognized (first spec))
+ (compiler-warn "unrecognized declaration ~S" raw-spec))
+ res))
+ result-type)))
;;; Use a list of DECLARE forms to annotate the lists of LAMBDA-VAR
;;; and FUNCTIONAL structures which are being bound. In addition to
-;;; filling in slots in the leaf structures, we return a new LEXENV
+;;; filling in slots in the leaf structures, we return a new LEXENV,
;;; which reflects pervasive special and function type declarations,
-;;; (NOT)INLINE declarations and OPTIMIZE declarations. CONT is the
-;;; continuation affected by VALUES declarations.
+;;; (NOT)INLINE declarations and OPTIMIZE declarations, and type of
+;;; VALUES declarations.
;;;
;;; This is also called in main.lisp when PROCESS-FORM handles a use
;;; of LOCALLY.
-(defun process-decls (decls vars fvars cont &optional (env *lexenv*))
- (declare (list decls vars fvars) (type continuation cont))
- (dolist (decl decls)
- (dolist (spec (rest decl))
- (unless (consp spec)
- (compiler-error "malformed declaration specifier ~S in ~S"
- spec
- decl))
- (setq env (process-1-decl spec env vars fvars cont))))
- env)
+(defun process-decls (decls vars fvars &optional (env *lexenv*))
+ (declare (list decls vars fvars))
+ (let ((result-type *wild-type*))
+ (dolist (decl decls)
+ (dolist (spec (rest decl))
+ (unless (consp spec)
+ (compiler-error "malformed declaration specifier ~S in ~S" spec decl))
+ (multiple-value-bind (new-env new-result-type)
+ (process-1-decl spec env vars fvars)
+ (setq env new-env)
+ (unless (eq new-result-type *wild-type*)
+ (setq result-type
+ (values-type-intersection result-type new-result-type))))))
+ (values env result-type)))
+
+(defun %processing-decls (decls vars fvars ctran lvar fun)
+ (multiple-value-bind (*lexenv* result-type)
+ (process-decls decls vars fvars)
+ (cond ((eq result-type *wild-type*)
+ (funcall fun ctran lvar))
+ (t
+ (let ((value-ctran (make-ctran))
+ (value-lvar (make-lvar)))
+ (multiple-value-prog1
+ (funcall fun value-ctran value-lvar)
+ (let ((cast (make-cast value-lvar result-type
+ (lexenv-policy *lexenv*))))
+ (link-node-to-previous-ctran cast value-ctran)
+ (setf (lvar-dest value-lvar) cast)
+ (use-continuation cast ctran lvar))))))))
+(defmacro processing-decls ((decls vars fvars ctran lvar) &body forms)
+ (check-type ctran symbol)
+ (check-type lvar symbol)
+ `(%processing-decls ,decls ,vars ,fvars ,ctran ,lvar
+ (lambda (,ctran ,lvar) ,@forms)))
;;; Return the SPECVAR for NAME to use when we see a local SPECIAL
;;; declaration. If there is a global variable of that name, then
;;; anonymous GLOBAL-VAR.
(defun specvar-for-binding (name)
(cond ((not (eq (info :variable :where-from name) :assumed))
- (let ((found (find-free-variable name)))
+ (let ((found (find-free-var name)))
(when (heap-alien-info-p found)
(compiler-error
"~S is an alien variable and so can't be declared special."
name))
- (when (or (not (global-var-p found))
- (eq (global-var-kind found) :constant))
+ (unless (global-var-p found)
(compiler-error
"~S is a constant and so can't be declared special."
name))
found))
(t
(make-global-var :kind :special
- :name name
+ :%source-name name
:where-from :declared))))
-\f
-;;;; LAMBDA hackery
-
-;;;; Note: Take a look at the compiler-overview.tex section on "Hairy
-;;;; function representation" before you seriously mess with this
-;;;; stuff.
-
-;;; Verify that a thing is a legal name for a variable and return a
-;;; Var structure for it, filling in info if it is globally special.
-;;; If it is losing, we punt with a Compiler-Error. Names-So-Far is an
-;;; alist of names which have previously been bound. If the name is in
-;;; this list, then we error out.
-(declaim (ftype (function (t list) lambda-var) varify-lambda-arg))
-(defun varify-lambda-arg (name names-so-far)
- (declare (inline member))
- (unless (symbolp name)
- (compiler-error "The lambda-variable ~S is not a symbol." name))
- (when (member name names-so-far :test #'eq)
- (compiler-error "The variable ~S occurs more than once in the lambda-list."
- name))
- (let ((kind (info :variable :kind name)))
- (when (or (keywordp name) (eq kind :constant))
- (compiler-error "The name of the lambda-variable ~S is a constant."
- name))
- (cond ((eq kind :special)
- (let ((specvar (find-free-variable name)))
- (make-lambda-var :name name
- :type (leaf-type specvar)
- :where-from (leaf-where-from specvar)
- :specvar specvar)))
- (t
- (note-lexical-binding name)
- (make-lambda-var :name name)))))
-
-;;; Make the default keyword for a &KEY arg, checking that the keyword
-;;; isn't already used by one of the VARS. We also check that the
-;;; keyword isn't the magical :ALLOW-OTHER-KEYS.
-(declaim (ftype (function (symbol list t) keyword) make-keyword-for-arg))
-(defun make-keyword-for-arg (symbol vars keywordify)
- (let ((key (if (and keywordify (not (keywordp symbol)))
- (keywordicate symbol)
- symbol)))
- (when (eq key :allow-other-keys)
- (compiler-error "No &KEY arg can be called :ALLOW-OTHER-KEYS."))
- (dolist (var vars)
- (let ((info (lambda-var-arg-info var)))
- (when (and info
- (eq (arg-info-kind info) :keyword)
- (eq (arg-info-key info) key))
- (compiler-error
- "The keyword ~S appears more than once in the lambda-list."
- key))))
- key))
-
-;;; Parse a lambda-list into a list of VAR structures, stripping off
-;;; any aux bindings. Each arg name is checked for legality, and
-;;; duplicate names are checked for. If an arg is globally special,
-;;; the var is marked as :SPECIAL instead of :LEXICAL. &KEY,
-;;; &OPTIONAL and &REST args are annotated with an ARG-INFO structure
-;;; which contains the extra information. If we hit something losing,
-;;; we bug out with COMPILER-ERROR. These values are returned:
-;;; 1. a list of the var structures for each top-level argument;
-;;; 2. a flag indicating whether &KEY was specified;
-;;; 3. a flag indicating whether other &KEY args are allowed;
-;;; 4. a list of the &AUX variables; and
-;;; 5. a list of the &AUX values.
-(declaim (ftype (function (list) (values list boolean boolean list list))
- find-lambda-vars))
-(defun find-lambda-vars (list)
- (multiple-value-bind (required optional restp rest keyp keys allowp aux
- morep more-context more-count)
- (parse-lambda-list list)
- (collect ((vars)
- (names-so-far)
- (aux-vars)
- (aux-vals))
- (flet (;; PARSE-DEFAULT deals with defaults and supplied-p args
- ;; for optionals and keywords args.
- (parse-default (spec info)
- (when (consp (cdr spec))
- (setf (arg-info-default info) (second spec))
- (when (consp (cddr spec))
- (let* ((supplied-p (third spec))
- (supplied-var (varify-lambda-arg supplied-p
- (names-so-far))))
- (setf (arg-info-supplied-p info) supplied-var)
- (names-so-far supplied-p)
- (when (> (length (the list spec)) 3)
- (compiler-error
- "The list ~S is too long to be an arg specifier."
- spec)))))))
-
- (dolist (name required)
- (let ((var (varify-lambda-arg name (names-so-far))))
- (vars var)
- (names-so-far name)))
-
- (dolist (spec optional)
- (if (atom spec)
- (let ((var (varify-lambda-arg spec (names-so-far))))
- (setf (lambda-var-arg-info var) (make-arg-info :kind :optional))
- (vars var)
- (names-so-far spec))
- (let* ((name (first spec))
- (var (varify-lambda-arg name (names-so-far)))
- (info (make-arg-info :kind :optional)))
- (setf (lambda-var-arg-info var) info)
- (vars var)
- (names-so-far name)
- (parse-default spec info))))
-
- (when restp
- (let ((var (varify-lambda-arg rest (names-so-far))))
- (setf (lambda-var-arg-info var) (make-arg-info :kind :rest))
- (vars var)
- (names-so-far rest)))
-
- (when morep
- (let ((var (varify-lambda-arg more-context (names-so-far))))
- (setf (lambda-var-arg-info var)
- (make-arg-info :kind :more-context))
- (vars var)
- (names-so-far more-context))
- (let ((var (varify-lambda-arg more-count (names-so-far))))
- (setf (lambda-var-arg-info var)
- (make-arg-info :kind :more-count))
- (vars var)
- (names-so-far more-count)))
-
- (dolist (spec keys)
- (cond
- ((atom spec)
- (let ((var (varify-lambda-arg spec (names-so-far))))
- (setf (lambda-var-arg-info var)
- (make-arg-info :kind :keyword
- :key (make-keyword-for-arg spec
- (vars)
- t)))
- (vars var)
- (names-so-far spec)))
- ((atom (first spec))
- (let* ((name (first spec))
- (var (varify-lambda-arg name (names-so-far)))
- (info (make-arg-info
- :kind :keyword
- :key (make-keyword-for-arg name (vars) t))))
- (setf (lambda-var-arg-info var) info)
- (vars var)
- (names-so-far name)
- (parse-default spec info)))
- (t
- (let ((head (first spec)))
- (unless (proper-list-of-length-p head 2)
- (error "malformed &KEY argument specifier: ~S" spec))
- (let* ((name (second head))
- (var (varify-lambda-arg name (names-so-far)))
- (info (make-arg-info
- :kind :keyword
- :key (make-keyword-for-arg (first head)
- (vars)
- nil))))
- (setf (lambda-var-arg-info var) info)
- (vars var)
- (names-so-far name)
- (parse-default spec info))))))
-
- (dolist (spec aux)
- (cond ((atom spec)
- (let ((var (varify-lambda-arg spec nil)))
- (aux-vars var)
- (aux-vals nil)
- (names-so-far spec)))
- (t
- (unless (proper-list-of-length-p spec 1 2)
- (compiler-error "malformed &AUX binding specifier: ~S"
- spec))
- (let* ((name (first spec))
- (var (varify-lambda-arg name nil)))
- (aux-vars var)
- (aux-vals (second spec))
- (names-so-far name)))))
-
- (values (vars) keyp allowp (aux-vars) (aux-vals))))))
-
-;;; This is similar to IR1-CONVERT-PROGN-BODY except that we
-;;; sequentially bind each AUX-VAR to the corresponding AUX-VAL before
-;;; converting the body. If there are no bindings, just convert the
-;;; body, otherwise do one binding and recurse on the rest.
-(defun ir1-convert-aux-bindings (start cont body aux-vars aux-vals)
- (declare (type continuation start cont) (list body aux-vars aux-vals))
- (if (null aux-vars)
- (ir1-convert-progn-body start cont body)
- (let ((fun-cont (make-continuation))
- (fun (ir1-convert-lambda-body body
- (list (first aux-vars))
- :aux-vars (rest aux-vars)
- :aux-vals (rest aux-vals))))
- (reference-leaf start fun-cont fun)
- (ir1-convert-combination-args fun-cont cont
- (list (first aux-vals)))))
- (values))
-
-;;; This is similar to IR1-CONVERT-PROGN-BODY except that code to bind
-;;; the SPECVAR for each SVAR to the value of the variable is wrapped
-;;; around the body. If there are no special bindings, we just convert
-;;; the body, otherwise we do one special binding and recurse on the
-;;; rest.
-;;;
-;;; We make a cleanup and introduce it into the lexical environment.
-;;; If there are multiple special bindings, the cleanup for the blocks
-;;; will end up being the innermost one. We force CONT to start a
-;;; block outside of this cleanup, causing cleanup code to be emitted
-;;; when the scope is exited.
-(defun ir1-convert-special-bindings (start cont body aux-vars aux-vals svars)
- (declare (type continuation start cont)
- (list body aux-vars aux-vals svars))
- (cond
- ((null svars)
- (ir1-convert-aux-bindings start cont body aux-vars aux-vals))
- (t
- (continuation-starts-block cont)
- (let ((cleanup (make-cleanup :kind :special-bind))
- (var (first svars))
- (next-cont (make-continuation))
- (nnext-cont (make-continuation)))
- (ir1-convert start next-cont
- `(%special-bind ',(lambda-var-specvar var) ,var))
- (setf (cleanup-mess-up cleanup) (continuation-use next-cont))
- (let ((*lexenv* (make-lexenv :cleanup cleanup)))
- (ir1-convert next-cont nnext-cont '(%cleanup-point))
- (ir1-convert-special-bindings nnext-cont cont body aux-vars aux-vals
- (rest svars))))))
- (values))
-
-;;; Create a lambda node out of some code, returning the result. The
-;;; bindings are specified by the list of VAR structures VARS. We deal
-;;; with adding the names to the LEXENV-VARIABLES for the conversion.
-;;; The result is added to the NEW-FUNCTIONS in the
-;;; *CURRENT-COMPONENT* and linked to the component head and tail.
-;;;
-;;; We detect special bindings here, replacing the original VAR in the
-;;; lambda list with a temporary variable. We then pass a list of the
-;;; special vars to IR1-CONVERT-SPECIAL-BINDINGS, which actually emits
-;;; the special binding code.
-;;;
-;;; We ignore any ARG-INFO in the VARS, trusting that someone else is
-;;; dealing with &nonsense.
-;;;
-;;; AUX-VARS is a list of VAR structures for variables that are to be
-;;; sequentially bound. Each AUX-VAL is a form that is to be evaluated
-;;; to get the initial value for the corresponding AUX-VAR.
-(defun ir1-convert-lambda-body (body vars &key aux-vars aux-vals result)
- (declare (list body vars aux-vars aux-vals)
- (type (or continuation null) result))
- (let* ((bind (make-bind))
- (lambda (make-lambda :vars vars :bind bind))
- (result (or result (make-continuation))))
- (setf (lambda-home lambda) lambda)
- (collect ((svars)
- (new-venv nil cons))
-
- (dolist (var vars)
- (setf (lambda-var-home var) lambda)
- (let ((specvar (lambda-var-specvar var)))
- (cond (specvar
- (svars var)
- (new-venv (cons (leaf-name specvar) specvar)))
- (t
- (note-lexical-binding (leaf-name var))
- (new-venv (cons (leaf-name var) var))))))
-
- (let ((*lexenv* (make-lexenv :variables (new-venv)
- :lambda lambda
- :cleanup nil)))
- (setf (bind-lambda bind) lambda)
- (setf (node-lexenv bind) *lexenv*)
-
- (let ((cont1 (make-continuation))
- (cont2 (make-continuation)))
- (continuation-starts-block cont1)
- (prev-link bind cont1)
- (use-continuation bind cont2)
- (ir1-convert-special-bindings cont2 result body aux-vars aux-vals
- (svars)))
-
- (let ((block (continuation-block result)))
- (when block
- (let ((return (make-return :result result :lambda lambda))
- (tail-set (make-tail-set :functions (list lambda)))
- (dummy (make-continuation)))
- (setf (lambda-tail-set lambda) tail-set)
- (setf (lambda-return lambda) return)
- (setf (continuation-dest result) return)
- (setf (block-last block) return)
- (prev-link return result)
- (use-continuation return dummy))
- (link-blocks block (component-tail *current-component*))))))
-
- (link-blocks (component-head *current-component*) (node-block bind))
- (push lambda (component-new-functions *current-component*))
- lambda))
-
-;;; Create the actual entry-point function for an optional entry
-;;; point. The lambda binds copies of each of the VARS, then calls FUN
-;;; with the argument VALS and the DEFAULTS. Presumably the VALS refer
-;;; to the VARS by name. The VALS are passed in in reverse order.
-;;;
-;;; If any of the copies of the vars are referenced more than once,
-;;; then we mark the corresponding var as EVER-USED to inhibit
-;;; "defined but not read" warnings for arguments that are only used
-;;; by default forms.
-(defun convert-optional-entry (fun vars vals defaults)
- (declare (type clambda fun) (list vars vals defaults))
- (let* ((fvars (reverse vars))
- (arg-vars (mapcar (lambda (var)
- (unless (lambda-var-specvar var)
- (note-lexical-binding (leaf-name var)))
- (make-lambda-var
- :name (leaf-name var)
- :type (leaf-type var)
- :where-from (leaf-where-from var)
- :specvar (lambda-var-specvar var)))
- fvars))
- (fun
- (ir1-convert-lambda-body `((%funcall ,fun
- ,@(reverse vals)
- ,@defaults))
- arg-vars)))
- (mapc (lambda (var arg-var)
- (when (cdr (leaf-refs arg-var))
- (setf (leaf-ever-used var) t)))
- fvars arg-vars)
- fun))
-
-;;; This function deals with supplied-p vars in optional arguments. If
-;;; the there is no supplied-p arg, then we just call
-;;; IR1-CONVERT-HAIRY-ARGS on the remaining arguments, and generate a
-;;; optional entry that calls the result. If there is a supplied-p
-;;; var, then we add it into the default vars and throw a T into the
-;;; entry values. The resulting entry point function is returned.
-(defun generate-optional-default-entry (res default-vars default-vals
- entry-vars entry-vals
- vars supplied-p-p body
- aux-vars aux-vals cont)
- (declare (type optional-dispatch res)
- (list default-vars default-vals entry-vars entry-vals vars body
- aux-vars aux-vals)
- (type (or continuation null) cont))
- (let* ((arg (first vars))
- (arg-name (leaf-name arg))
- (info (lambda-var-arg-info arg))
- (supplied-p (arg-info-supplied-p info))
- (ep (if supplied-p
- (ir1-convert-hairy-args
- res
- (list* supplied-p arg default-vars)
- (list* (leaf-name supplied-p) arg-name default-vals)
- (cons arg entry-vars)
- (list* t arg-name entry-vals)
- (rest vars) t body aux-vars aux-vals cont)
- (ir1-convert-hairy-args
- res
- (cons arg default-vars)
- (cons arg-name default-vals)
- (cons arg entry-vars)
- (cons arg-name entry-vals)
- (rest vars) supplied-p-p body aux-vars aux-vals cont))))
-
- (convert-optional-entry ep default-vars default-vals
- (if supplied-p
- (list (arg-info-default info) nil)
- (list (arg-info-default info))))))
-
-;;; Create the MORE-ENTRY function for the OPTIONAL-DISPATCH RES.
-;;; ENTRY-VARS and ENTRY-VALS describe the fixed arguments. REST is
-;;; the var for any &REST arg. KEYS is a list of the &KEY arg vars.
-;;;
-;;; The most interesting thing that we do is parse keywords. We create
-;;; a bunch of temporary variables to hold the result of the parse,
-;;; and then loop over the supplied arguments, setting the appropriate
-;;; temps for the supplied keyword. Note that it is significant that
-;;; we iterate over the keywords in reverse order --- this implements
-;;; the CL requirement that (when a keyword appears more than once)
-;;; the first value is used.
-;;;
-;;; If there is no supplied-p var, then we initialize the temp to the
-;;; default and just pass the temp into the main entry. Since
-;;; non-constant &KEY args are forcibly given a supplied-p var, we
-;;; know that the default is constant, and thus safe to evaluate out
-;;; of order.
-;;;
-;;; If there is a supplied-p var, then we create temps for both the
-;;; value and the supplied-p, and pass them into the main entry,
-;;; letting it worry about defaulting.
-;;;
-;;; We deal with :ALLOW-OTHER-KEYS by delaying unknown keyword errors
-;;; until we have scanned all the keywords.
-(defun convert-more-entry (res entry-vars entry-vals rest morep keys)
- (declare (type optional-dispatch res) (list entry-vars entry-vals keys))
- (collect ((arg-vars)
- (arg-vals (reverse entry-vals))
- (temps)
- (body))
-
- (dolist (var (reverse entry-vars))
- (arg-vars (make-lambda-var :name (leaf-name var)
- :type (leaf-type var)
- :where-from (leaf-where-from var))))
-
- (let* ((n-context (gensym "N-CONTEXT-"))
- (context-temp (make-lambda-var :name n-context))
- (n-count (gensym "N-COUNT-"))
- (count-temp (make-lambda-var :name n-count
- :type (specifier-type 'index))))
-
- (arg-vars context-temp count-temp)
-
- (when rest
- (arg-vals `(%listify-rest-args ,n-context ,n-count)))
- (when morep
- (arg-vals n-context)
- (arg-vals n-count))
-
- (when (optional-dispatch-keyp res)
- (let ((n-index (gensym "N-INDEX-"))
- (n-key (gensym "N-KEY-"))
- (n-value-temp (gensym "N-VALUE-TEMP-"))
- (n-allowp (gensym "N-ALLOWP-"))
- (n-losep (gensym "N-LOSEP-"))
- (allowp (or (optional-dispatch-allowp res)
- (policy *lexenv* (zerop safety)))))
-
- (temps `(,n-index (1- ,n-count)) n-key n-value-temp)
- (body `(declare (fixnum ,n-index) (ignorable ,n-key ,n-value-temp)))
-
- (collect ((tests))
- (dolist (key keys)
- (let* ((info (lambda-var-arg-info key))
- (default (arg-info-default info))
- (keyword (arg-info-key info))
- (supplied-p (arg-info-supplied-p info))
- (n-value (gensym "N-VALUE-")))
- (temps `(,n-value ,default))
- (cond (supplied-p
- (let ((n-supplied (gensym "N-SUPPLIED-")))
- (temps n-supplied)
- (arg-vals n-value n-supplied)
- (tests `((eq ,n-key ',keyword)
- (setq ,n-supplied t)
- (setq ,n-value ,n-value-temp)))))
- (t
- (arg-vals n-value)
- (tests `((eq ,n-key ',keyword)
- (setq ,n-value ,n-value-temp)))))))
-
- (unless allowp
- (temps n-allowp n-losep)
- (tests `((eq ,n-key :allow-other-keys)
- (setq ,n-allowp ,n-value-temp)))
- (tests `(t
- (setq ,n-losep ,n-key))))
-
- (body
- `(when (oddp ,n-count)
- (%odd-key-arguments-error)))
-
- (body
- `(locally
- (declare (optimize (safety 0)))
- (loop
- (when (minusp ,n-index) (return))
- (setf ,n-value-temp (%more-arg ,n-context ,n-index))
- (decf ,n-index)
- (setq ,n-key (%more-arg ,n-context ,n-index))
- (decf ,n-index)
- (cond ,@(tests)))))
-
- (unless allowp
- (body `(when (and ,n-losep (not ,n-allowp))
- (%unknown-key-argument-error ,n-losep)))))))
-
- (let ((ep (ir1-convert-lambda-body
- `((let ,(temps)
- ,@(body)
- (%funcall ,(optional-dispatch-main-entry res)
- . ,(arg-vals)))) ; FIXME: What is the '.'? ,@?
- (arg-vars))))
- (setf (optional-dispatch-more-entry res) ep))))
-
- (values))
-
-;;; This is called by IR1-CONVERT-HAIRY-ARGS when we run into a &REST
-;;; or &KEY arg. The arguments are similar to that function, but we
-;;; split off any &REST arg and pass it in separately. REST is the
-;;; &REST arg var, or NIL if there is no &REST arg. KEYS is a list of
-;;; the &KEY argument vars.
-;;;
-;;; When there are &KEY arguments, we introduce temporary gensym
-;;; variables to hold the values while keyword defaulting is in
-;;; progress to get the required sequential binding semantics.
-;;;
-;;; This gets interesting mainly when there are &KEY arguments with
-;;; supplied-p vars or non-constant defaults. In either case, pass in
-;;; a supplied-p var. If the default is non-constant, we introduce an
-;;; IF in the main entry that tests the supplied-p var and decides
-;;; whether to evaluate the default or not. In this case, the real
-;;; incoming value is NIL, so we must union NULL with the declared
-;;; type when computing the type for the main entry's argument.
-(defun ir1-convert-more (res default-vars default-vals entry-vars entry-vals
- rest more-context more-count keys supplied-p-p
- body aux-vars aux-vals cont)
- (declare (type optional-dispatch res)
- (list default-vars default-vals entry-vars entry-vals keys body
- aux-vars aux-vals)
- (type (or continuation null) cont))
- (collect ((main-vars (reverse default-vars))
- (main-vals default-vals cons)
- (bind-vars)
- (bind-vals))
- (when rest
- (main-vars rest)
- (main-vals '()))
- (when more-context
- (main-vars more-context)
- (main-vals nil)
- (main-vars more-count)
- (main-vals 0))
-
- (dolist (key keys)
- (let* ((info (lambda-var-arg-info key))
- (default (arg-info-default info))
- (hairy-default (not (sb!xc:constantp default)))
- (supplied-p (arg-info-supplied-p info))
- (n-val (make-symbol (format nil
- "~A-DEFAULTING-TEMP"
- (leaf-name key))))
- (key-type (leaf-type key))
- (val-temp (make-lambda-var
- :name n-val
- :type (if hairy-default
- (type-union key-type (specifier-type 'null))
- key-type))))
- (main-vars val-temp)
- (bind-vars key)
- (cond ((or hairy-default supplied-p)
- (let* ((n-supplied (gensym "N-SUPPLIED-"))
- (supplied-temp (make-lambda-var :name n-supplied)))
- (unless supplied-p
- (setf (arg-info-supplied-p info) supplied-temp))
- (when hairy-default
- (setf (arg-info-default info) nil))
- (main-vars supplied-temp)
- (cond (hairy-default
- (main-vals nil nil)
- (bind-vals `(if ,n-supplied ,n-val ,default)))
- (t
- (main-vals default nil)
- (bind-vals n-val)))
- (when supplied-p
- (bind-vars supplied-p)
- (bind-vals n-supplied))))
- (t
- (main-vals (arg-info-default info))
- (bind-vals n-val)))))
-
- (let* ((main-entry (ir1-convert-lambda-body
- body (main-vars)
- :aux-vars (append (bind-vars) aux-vars)
- :aux-vals (append (bind-vals) aux-vals)
- :result cont))
- (last-entry (convert-optional-entry main-entry default-vars
- (main-vals) ())))
- (setf (optional-dispatch-main-entry res) main-entry)
- (convert-more-entry res entry-vars entry-vals rest more-context keys)
-
- (push (if supplied-p-p
- (convert-optional-entry last-entry entry-vars entry-vals ())
- last-entry)
- (optional-dispatch-entry-points res))
- last-entry)))
-
-;;; This function generates the entry point functions for the
-;;; optional-dispatch Res. We accomplish this by recursion on the list of
-;;; arguments, analyzing the arglist on the way down and generating entry
-;;; points on the way up.
-;;;
-;;; Default-Vars is a reversed list of all the argument vars processed
-;;; so far, including supplied-p vars. Default-Vals is a list of the
-;;; names of the Default-Vars.
-;;;
-;;; Entry-Vars is a reversed list of processed argument vars,
-;;; excluding supplied-p vars. Entry-Vals is a list things that can be
-;;; evaluated to get the values for all the vars from the Entry-Vars.
-;;; It has the var name for each required or optional arg, and has T
-;;; for each supplied-p arg.
-;;;
-;;; Vars is a list of the Lambda-Var structures for arguments that
-;;; haven't been processed yet. Supplied-p-p is true if a supplied-p
-;;; argument has already been processed; only in this case are the
-;;; Default-XXX and Entry-XXX different.
-;;;
-;;; The result at each point is a lambda which should be called by the
-;;; above level to default the remaining arguments and evaluate the
-;;; body. We cause the body to be evaluated by converting it and
-;;; returning it as the result when the recursion bottoms out.
-;;;
-;;; Each level in the recursion also adds its entry point function to
-;;; the result Optional-Dispatch. For most arguments, the defaulting
-;;; function and the entry point function will be the same, but when
-;;; supplied-p args are present they may be different.
-;;;
-;;; When we run into a &REST or &KEY arg, we punt out to
-;;; IR1-CONVERT-MORE, which finishes for us in this case.
-(defun ir1-convert-hairy-args (res default-vars default-vals
- entry-vars entry-vals
- vars supplied-p-p body aux-vars
- aux-vals cont)
- (declare (type optional-dispatch res)
- (list default-vars default-vals entry-vars entry-vals vars body
- aux-vars aux-vals)
- (type (or continuation null) cont))
- (cond ((not vars)
- (if (optional-dispatch-keyp res)
- ;; Handle &KEY with no keys...
- (ir1-convert-more res default-vars default-vals
- entry-vars entry-vals
- nil nil nil vars supplied-p-p body aux-vars
- aux-vals cont)
- (let ((fun (ir1-convert-lambda-body body (reverse default-vars)
- :aux-vars aux-vars
- :aux-vals aux-vals
- :result cont)))
- (setf (optional-dispatch-main-entry res) fun)
- (push (if supplied-p-p
- (convert-optional-entry fun entry-vars entry-vals ())
- fun)
- (optional-dispatch-entry-points res))
- fun)))
- ((not (lambda-var-arg-info (first vars)))
- (let* ((arg (first vars))
- (nvars (cons arg default-vars))
- (nvals (cons (leaf-name arg) default-vals)))
- (ir1-convert-hairy-args res nvars nvals nvars nvals
- (rest vars) nil body aux-vars aux-vals
- cont)))
- (t
- (let* ((arg (first vars))
- (info (lambda-var-arg-info arg))
- (kind (arg-info-kind info)))
- (ecase kind
- (:optional
- (let ((ep (generate-optional-default-entry
- res default-vars default-vals
- entry-vars entry-vals vars supplied-p-p body
- aux-vars aux-vals cont)))
- (push (if supplied-p-p
- (convert-optional-entry ep entry-vars entry-vals ())
- ep)
- (optional-dispatch-entry-points res))
- ep))
- (:rest
- (ir1-convert-more res default-vars default-vals
- entry-vars entry-vals
- arg nil nil (rest vars) supplied-p-p body
- aux-vars aux-vals cont))
- (:more-context
- (ir1-convert-more res default-vars default-vals
- entry-vars entry-vals
- nil arg (second vars) (cddr vars) supplied-p-p
- body aux-vars aux-vals cont))
- (:keyword
- (ir1-convert-more res default-vars default-vals
- entry-vars entry-vals
- nil nil nil vars supplied-p-p body aux-vars
- aux-vals cont)))))))
-
-;;; This function deals with the case where we have to make an
-;;; Optional-Dispatch to represent a lambda. We cons up the result and
-;;; call IR1-CONVERT-HAIRY-ARGS to do the work. When it is done, we
-;;; figure out the min-args and max-args.
-(defun ir1-convert-hairy-lambda (body vars keyp allowp aux-vars aux-vals cont)
- (declare (list body vars aux-vars aux-vals) (type continuation cont))
- (let ((res (make-optional-dispatch :arglist vars
- :allowp allowp
- :keyp keyp))
- (min (or (position-if #'lambda-var-arg-info vars) (length vars))))
- (push res (component-new-functions *current-component*))
- (ir1-convert-hairy-args res () () () () vars nil body aux-vars aux-vals
- cont)
- (setf (optional-dispatch-min-args res) min)
- (setf (optional-dispatch-max-args res)
- (+ (1- (length (optional-dispatch-entry-points res))) min))
-
- (flet ((frob (ep)
- (when ep
- (setf (functional-kind ep) :optional)
- (setf (leaf-ever-used ep) t)
- (setf (lambda-optional-dispatch ep) res))))
- (dolist (ep (optional-dispatch-entry-points res)) (frob ep))
- (frob (optional-dispatch-more-entry res))
- (frob (optional-dispatch-main-entry res)))
-
- res))
-
-;;; Convert a LAMBDA form into a LAMBDA leaf or an OPTIONAL-DISPATCH leaf.
-(defun ir1-convert-lambda (form &optional name)
- (unless (consp form)
- (compiler-error "A ~S was found when expecting a lambda expression:~% ~S"
- (type-of form)
- form))
- (unless (eq (car form) 'lambda)
- (compiler-error "~S was expected but ~S was found:~% ~S"
- 'lambda
- (car form)
- form))
- (unless (and (consp (cdr form)) (listp (cadr form)))
- (compiler-error
- "The lambda expression has a missing or non-list lambda-list:~% ~S"
- form))
-
- (multiple-value-bind (vars keyp allow-other-keys aux-vars aux-vals)
- (find-lambda-vars (cadr form))
- (multiple-value-bind (forms decls) (sb!sys:parse-body (cddr form))
- (let* ((cont (make-continuation))
- (*lexenv* (process-decls decls
- (append aux-vars vars)
- nil cont))
- (res (if (or (find-if #'lambda-var-arg-info vars) keyp)
- (ir1-convert-hairy-lambda forms vars keyp
- allow-other-keys
- aux-vars aux-vals cont)
- (ir1-convert-lambda-body forms vars
- :aux-vars aux-vars
- :aux-vals aux-vals
- :result cont))))
- (setf (functional-inline-expansion res) form)
- (setf (functional-arg-documentation res) (cadr form))
- (setf (leaf-name res) name)
- res))))
-\f
-;;; FIXME: This file is rather long, and contains two distinct sections,
-;;; transform machinery above this point and transforms themselves below this
-;;; point. Why not split it in two? (ir1translate.lisp and
-;;; ir1translators.lisp?) Then consider byte-compiling the translators, too.
-\f
-;;;; control special forms
-
-(def-ir1-translator progn ((&rest forms) start cont)
- #!+sb-doc
- "Progn Form*
- Evaluates each Form in order, returning the values of the last form. With no
- forms, returns NIL."
- (ir1-convert-progn-body start cont forms))
-
-(def-ir1-translator if ((test then &optional else) start cont)
- #!+sb-doc
- "If Predicate Then [Else]
- If Predicate evaluates to non-null, evaluate Then and returns its values,
- otherwise evaluate Else and return its values. Else defaults to NIL."
- (let* ((pred (make-continuation))
- (then-cont (make-continuation))
- (then-block (continuation-starts-block then-cont))
- (else-cont (make-continuation))
- (else-block (continuation-starts-block else-cont))
- (dummy-cont (make-continuation))
- (node (make-if :test pred
- :consequent then-block
- :alternative else-block)))
- (setf (continuation-dest pred) node)
- (ir1-convert start pred test)
- (prev-link node pred)
- (use-continuation node dummy-cont)
-
- (let ((start-block (continuation-block pred)))
- (setf (block-last start-block) node)
- (continuation-starts-block cont)
-
- (link-blocks start-block then-block)
- (link-blocks start-block else-block)
-
- (ir1-convert then-cont cont then)
- (ir1-convert else-cont cont else))))
-\f
-;;;; BLOCK and TAGBODY
-
-;;;; We make an Entry node to mark the start and a :Entry cleanup to
-;;;; mark its extent. When doing GO or RETURN-FROM, we emit an Exit
-;;;; node.
-
-;;; Make a :entry cleanup and emit an Entry node, then convert the
-;;; body in the modified environment. We make Cont start a block now,
-;;; since if it was done later, the block would be in the wrong
-;;; environment.
-(def-ir1-translator block ((name &rest forms) start cont)
- #!+sb-doc
- "Block Name Form*
- Evaluate the Forms as a PROGN. Within the lexical scope of the body,
- (RETURN-FROM Name Value-Form) can be used to exit the form, returning the
- result of Value-Form."
- (unless (symbolp name)
- (compiler-error "The block name ~S is not a symbol." name))
- (continuation-starts-block cont)
- (let* ((dummy (make-continuation))
- (entry (make-entry))
- (cleanup (make-cleanup :kind :block
- :mess-up entry)))
- (push entry (lambda-entries (lexenv-lambda *lexenv*)))
- (setf (entry-cleanup entry) cleanup)
- (prev-link entry start)
- (use-continuation entry dummy)
-
- (let* ((env-entry (list entry cont))
- (*lexenv* (make-lexenv :blocks (list (cons name env-entry))
- :cleanup cleanup)))
- (push env-entry (continuation-lexenv-uses cont))
- (ir1-convert-progn-body dummy cont forms))))
-
-
-;;; We make Cont start a block just so that it will have a block
-;;; assigned. People assume that when they pass a continuation into
-;;; IR1-Convert as Cont, it will have a block when it is done.
-(def-ir1-translator return-from ((name &optional value)
- start cont)
- #!+sb-doc
- "Return-From Block-Name Value-Form
- Evaluate the Value-Form, returning its values from the lexically enclosing
- BLOCK Block-Name. This is constrained to be used only within the dynamic
- extent of the BLOCK."
- (continuation-starts-block cont)
- (let* ((found (or (lexenv-find name blocks)
- (compiler-error "return for unknown block: ~S" name)))
- (value-cont (make-continuation))
- (entry (first found))
- (exit (make-exit :entry entry
- :value value-cont)))
- (push exit (entry-exits entry))
- (setf (continuation-dest value-cont) exit)
- (ir1-convert start value-cont value)
- (prev-link exit value-cont)
- (use-continuation exit (second found))))
-
-;;; Return a list of the segments of a TAGBODY. Each segment looks
-;;; like (<tag> <form>* (go <next tag>)). That is, we break up the
-;;; tagbody into segments of non-tag statements, and explicitly
-;;; represent the drop-through with a GO. The first segment has a
-;;; dummy NIL tag, since it represents code before the first tag. The
-;;; last segment (which may also be the first segment) ends in NIL
-;;; rather than a GO.
-(defun parse-tagbody (body)
- (declare (list body))
- (collect ((segments))
- (let ((current (cons nil body)))
- (loop
- (let ((tag-pos (position-if (complement #'listp) current :start 1)))
- (unless tag-pos
- (segments `(,@current nil))
- (return))
- (let ((tag (elt current tag-pos)))
- (when (assoc tag (segments))
- (compiler-error
- "The tag ~S appears more than once in the tagbody."
- tag))
- (unless (or (symbolp tag) (integerp tag))
- (compiler-error "~S is not a legal tagbody statement." tag))
- (segments `(,@(subseq current 0 tag-pos) (go ,tag))))
- (setq current (nthcdr tag-pos current)))))
- (segments)))
-
-;;; Set up the cleanup, emitting the entry node. Then make a block for
-;;; each tag, building up the tag list for LEXENV-TAGS as we go.
-;;; Finally, convert each segment with the precomputed Start and Cont
-;;; values.
-(def-ir1-translator tagbody ((&rest statements) start cont)
- #!+sb-doc
- "Tagbody {Tag | Statement}*
- Define tags for used with GO. The Statements are evaluated in order
- (skipping Tags) and NIL is returned. If a statement contains a GO to a
- defined Tag within the lexical scope of the form, then control is transferred
- to the next statement following that tag. A Tag must an integer or a
- symbol. A statement must be a list. Other objects are illegal within the
- body."
- (continuation-starts-block cont)
- (let* ((dummy (make-continuation))
- (entry (make-entry))
- (segments (parse-tagbody statements))
- (cleanup (make-cleanup :kind :tagbody
- :mess-up entry)))
- (push entry (lambda-entries (lexenv-lambda *lexenv*)))
- (setf (entry-cleanup entry) cleanup)
- (prev-link entry start)
- (use-continuation entry dummy)
-
- (collect ((tags)
- (starts)
- (conts))
- (starts dummy)
- (dolist (segment (rest segments))
- (let* ((tag-cont (make-continuation))
- (tag (list (car segment) entry tag-cont)))
- (conts tag-cont)
- (starts tag-cont)
- (continuation-starts-block tag-cont)
- (tags tag)
- (push (cdr tag) (continuation-lexenv-uses tag-cont))))
- (conts cont)
-
- (let ((*lexenv* (make-lexenv :cleanup cleanup :tags (tags))))
- (mapc (lambda (segment start cont)
- (ir1-convert-progn-body start cont (rest segment)))
- segments (starts) (conts))))))
-
-;;; Emit an EXIT node without any value.
-(def-ir1-translator go ((tag) start cont)
- #!+sb-doc
- "Go Tag
- Transfer control to the named Tag in the lexically enclosing TAGBODY. This
- is constrained to be used only within the dynamic extent of the TAGBODY."
- (continuation-starts-block cont)
- (let* ((found (or (lexenv-find tag tags :test #'eql)
- (compiler-error "Go to nonexistent tag: ~S." tag)))
- (entry (first found))
- (exit (make-exit :entry entry)))
- (push exit (entry-exits entry))
- (prev-link exit start)
- (use-continuation exit (second found))))
-\f
-;;;; translators for compiler-magic special forms
-
-;;; This handles EVAL-WHEN in non-top-level forms. (EVAL-WHENs in
-;;; top-level forms are picked off and handled by PROCESS-TOP-LEVEL-FORM,
-;;; so that they're never seen at this level.)
-;;;
-;;; ANSI "3.2.3.1 Processing of Top Level Forms" says that processing
-;;; of non-top-level EVAL-WHENs is very simple:
-;;; EVAL-WHEN forms cause compile-time evaluation only at top level.
-;;; Both :COMPILE-TOPLEVEL and :LOAD-TOPLEVEL situation specifications
-;;; are ignored for non-top-level forms. For non-top-level forms, an
-;;; eval-when specifying the :EXECUTE situation is treated as an
-;;; implicit PROGN including the forms in the body of the EVAL-WHEN
-;;; form; otherwise, the forms in the body are ignored.
-(def-ir1-translator eval-when ((situations &rest forms) start cont)
- #!+sb-doc
- "EVAL-WHEN (Situation*) Form*
- Evaluate the Forms in the specified Situations (any of :COMPILE-TOPLEVEL,
- :LOAD-TOPLEVEL, or :EXECUTE, or (deprecated) COMPILE, LOAD, or EVAL)."
- (multiple-value-bind (ct lt e) (parse-eval-when-situations situations)
- (declare (ignore ct lt))
- (ir1-convert-progn-body start cont (and e forms)))
- (values))
-
-;;; common logic for MACROLET and SYMBOL-MACROLET
-;;;
-;;; Call DEFINITIONIZE-FUN on each element of DEFINITIONS to find its
-;;; in-lexenv representation, stuff the results into *LEXENV*, and
-;;; call FUN (with no arguments).
-(defun %funcall-in-foomacrolet-lexenv (definitionize-fun
- definitionize-keyword
- definitions
- fun)
- (declare (type function definitionize-fun fun))
- (declare (type (member :variables :functions) definitionize-keyword))
- (declare (type list definitions))
- (unless (= (length definitions)
- (length (remove-duplicates definitions :key #'first)))
- (compiler-style-warning "duplicate definitions in ~S" definitions))
- (let* ((processed-definitions (mapcar definitionize-fun definitions))
- (*lexenv* (make-lexenv definitionize-keyword processed-definitions)))
- (funcall fun)))
-
-;;; Tweak *LEXENV* to include the DEFINITIONS from a MACROLET, then
-;;; call FUN (with no arguments).
-;;;
-;;; This is split off from the IR1 convert method so that it can be
-;;; shared by the special-case top-level MACROLET processing code.
-(defun funcall-in-macrolet-lexenv (definitions fun)
- (%funcall-in-foomacrolet-lexenv
- (lambda (definition)
- (unless (list-of-length-at-least-p definition 2)
- (compiler-error
- "The list ~S is too short to be a legal local macro definition."
- definition))
- (destructuring-bind (name arglist &body body) definition
- (unless (symbolp name)
- (compiler-error "The local macro name ~S is not a symbol." name))
- (let ((whole (gensym "WHOLE"))
- (environment (gensym "ENVIRONMENT")))
- (multiple-value-bind (body local-decls)
- (parse-defmacro arglist whole body name 'macrolet
- :environment environment)
- `(,name macro .
- ,(compile nil
- `(lambda (,whole ,environment)
- ,@local-decls
- (block ,name ,body))))))))
- :functions
- definitions
- fun))
-
-(def-ir1-translator macrolet ((definitions &rest body) start cont)
- #!+sb-doc
- "MACROLET ({(Name Lambda-List Form*)}*) Body-Form*
- Evaluate the Body-Forms in an environment with the specified local macros
- defined. Name is the local macro name, Lambda-List is the DEFMACRO style
- destructuring lambda list, and the Forms evaluate to the expansion. The
- Forms are evaluated in the null environment."
- (funcall-in-macrolet-lexenv definitions
- (lambda ()
- (ir1-translate-locally body start cont))))
-
-(defun funcall-in-symbol-macrolet-lexenv (definitions fun)
- (%funcall-in-foomacrolet-lexenv
- (lambda (definition)
- (unless (proper-list-of-length-p definition 2)
- (compiler-error "malformed symbol/expansion pair: ~S" definition))
- (destructuring-bind (name expansion) definition
- (unless (symbolp name)
- (compiler-error
- "The local symbol macro name ~S is not a symbol."
- name))
- `(,name . (MACRO . ,expansion))))
- :variables
- definitions
- fun))
-
-(def-ir1-translator symbol-macrolet ((macrobindings &body body) start cont)
- #!+sb-doc
- "SYMBOL-MACROLET ({(Name Expansion)}*) Decl* Form*
- Define the Names as symbol macros with the given Expansions. Within the
- body, references to a Name will effectively be replaced with the Expansion."
- (funcall-in-symbol-macrolet-lexenv
- macrobindings
- (lambda ()
- (ir1-translate-locally body start cont))))
-
-;;; not really a special form, but..
-(def-ir1-translator declare ((&rest stuff) start cont)
- (declare (ignore stuff))
- ;; We ignore START and CONT too, but we can't use DECLARE IGNORE to
- ;; tell the compiler about it here, because the DEF-IR1-TRANSLATOR
- ;; macro would put the DECLARE in the wrong place, so..
- start cont
- (compiler-error "misplaced declaration"))
-\f
-;;;; %PRIMITIVE
-;;;;
-;;;; Uses of %PRIMITIVE are either expanded into Lisp code or turned
-;;;; into a funny function.
-
-;;; Carefully evaluate a list of forms, returning a list of the results.
-(defun eval-info-args (args)
- (declare (list args))
- (handler-case (mapcar #'eval args)
- (error (condition)
- (compiler-error "Lisp error during evaluation of info args:~%~A"
- condition))))
-
-;;; If there is a primitive translator, then we expand the call.
-;;; Otherwise, we convert to the %%PRIMITIVE funny function. The first
-;;; argument is the template, the second is a list of the results of
-;;; any codegen-info args, and the remaining arguments are the runtime
-;;; arguments.
-;;;
-;;; We do a bunch of error checking now so that we don't bomb out with
-;;; a fatal error during IR2 conversion.
-;;;
-;;; KLUDGE: It's confusing having multiple names floating around for
-;;; nearly the same concept: PRIMITIVE, TEMPLATE, VOP. Now that CMU
-;;; CL's *PRIMITIVE-TRANSLATORS* stuff is gone, we could call
-;;; primitives VOPs, rename TEMPLATE to VOP-TEMPLATE, rename
-;;; BACKEND-TEMPLATE-NAMES to BACKEND-VOPS, and rename %PRIMITIVE to
-;;; VOP or %VOP.. -- WHN 2001-06-11
-;;; FIXME: Look at doing this ^, it doesn't look too hard actually.
-(def-ir1-translator %primitive ((name &rest args) start cont)
- (unless (symbolp name)
- (compiler-error "The primitive name ~S is not a symbol." name))
-
- (let* ((template (or (gethash name *backend-template-names*)
- (compiler-error
- "The primitive name ~A is not defined."
- name)))
- (required (length (template-arg-types template)))
- (info (template-info-arg-count template))
- (min (+ required info))
- (nargs (length args)))
- (if (template-more-args-type template)
- (when (< nargs min)
- (compiler-error "Primitive ~A was called with ~R argument~:P, ~
- but wants at least ~R."
- name
- nargs
- min))
- (unless (= nargs min)
- (compiler-error "Primitive ~A was called with ~R argument~:P, ~
- but wants exactly ~R."
- name
- nargs
- min)))
-
- (when (eq (template-result-types template) :conditional)
- (compiler-error
- "%PRIMITIVE was used with a conditional template."))
-
- (when (template-more-results-type template)
- (compiler-error
- "%PRIMITIVE was used with an unknown values template."))
-
- (ir1-convert start
- cont
- `(%%primitive ',template
- ',(eval-info-args
- (subseq args required min))
- ,@(subseq args 0 required)
- ,@(subseq args min)))))
-\f
-;;;; QUOTE and FUNCTION
-
-(def-ir1-translator quote ((thing) start cont)
- #!+sb-doc
- "QUOTE Value
- Return Value without evaluating it."
- (reference-constant start cont thing))
-
-(def-ir1-translator function ((thing) start cont)
- #!+sb-doc
- "FUNCTION Name
- Return the lexically apparent definition of the function Name. Name may also
- be a lambda."
- (if (consp thing)
- (case (car thing)
- ((lambda)
- (reference-leaf start cont (ir1-convert-lambda thing)))
- ((setf)
- (let ((var (find-lexically-apparent-function
- thing "as the argument to FUNCTION")))
- (reference-leaf start cont var)))
- ((instance-lambda)
- (let ((res (ir1-convert-lambda `(lambda ,@(cdr thing)))))
- (setf (getf (functional-plist res) :fin-function) t)
- (reference-leaf start cont res)))
- (t
- (compiler-error "~S is not a legal function name." thing)))
- (let ((var (find-lexically-apparent-function
- thing "as the argument to FUNCTION")))
- (reference-leaf start cont var))))
-\f
-;;;; FUNCALL
-
-;;; FUNCALL is implemented on %FUNCALL, which can only call functions
-;;; (not symbols). %FUNCALL is used directly in some places where the
-;;; call should always be open-coded even if FUNCALL is :NOTINLINE.
-(deftransform funcall ((function &rest args) * * :when :both)
- (let ((arg-names (make-gensym-list (length args))))
- `(lambda (function ,@arg-names)
- (%funcall ,(if (csubtypep (continuation-type function)
- (specifier-type 'function))
- 'function
- '(%coerce-callable-to-function function))
- ,@arg-names))))
-
-(def-ir1-translator %funcall ((function &rest args) start cont)
- (let ((fun-cont (make-continuation)))
- (ir1-convert start fun-cont function)
- (assert-continuation-type fun-cont (specifier-type 'function))
- (ir1-convert-combination-args fun-cont cont args)))
-
-;;; This source transform exists to reduce the amount of work for the
-;;; compiler. If the called function is a FUNCTION form, then convert
-;;; directly to %FUNCALL, instead of waiting around for type
-;;; inference.
-(def-source-transform funcall (function &rest args)
- (if (and (consp function) (eq (car function) 'function))
- `(%funcall ,function ,@args)
- (values nil t)))
-
-(deftransform %coerce-callable-to-function ((thing) (function) *
- :when :both
- :important t)
- "optimize away possible call to FDEFINITION at runtime"
- 'thing)
-\f
-;;; This is a frob that DEFSTRUCT expands into to establish the compiler
-;;; semantics. The other code in the expansion and %%COMPILER-DEFSTRUCT do
-;;; most of the work, we just clear all of the functions out of
-;;; *FREE-FUNCTIONS* to keep things in synch. %%COMPILER-DEFSTRUCT is also
-;;; called at load-time.
-(def-ir1-translator %compiler-defstruct ((info) start cont :kind :function)
- (let* ((info (eval info)))
- (%%compiler-defstruct info)
- (dolist (slot (dd-slots info))
- (let ((fun (dsd-accessor slot)))
- (remhash fun *free-functions*)
- (unless (dsd-read-only slot)
- (remhash `(setf ,fun) *free-functions*))))
- (remhash (dd-predicate info) *free-functions*)
- (remhash (dd-copier info) *free-functions*)
- (ir1-convert start cont `(%%compiler-defstruct ',info))))
-
-;;; Return the contents of a quoted form.
-(defun unquote (x)
- (if (and (consp x)
- (= 2 (length x))
- (eq 'quote (first x)))
- (second x)
- (error "not a quoted form")))
-
-;;; Don't actually compile anything, instead call the function now.
-(def-ir1-translator %compiler-only-defstruct
- ((info inherits) start cont :kind :function)
- (function-%compiler-only-defstruct (unquote info) (unquote inherits))
- (reference-constant start cont nil))
-\f
-;;;; LET and LET*
-;;;;
-;;;; (LET and LET* can't be implemented as macros due to the fact that
-;;;; any pervasive declarations also affect the evaluation of the
-;;;; arguments.)
-
-;;; Given a list of binding specifiers in the style of Let, return:
-;;; 1. The list of var structures for the variables bound.
-;;; 2. The initial value form for each variable.
-;;;
-;;; The variable names are checked for legality and globally special
-;;; variables are marked as such. Context is the name of the form, for
-;;; error reporting purposes.
-(declaim (ftype (function (list symbol) (values list list list))
- extract-let-variables))
-(defun extract-let-variables (bindings context)
- (collect ((vars)
- (vals)
- (names))
- (flet ((get-var (name)
- (varify-lambda-arg name
- (if (eq context 'let*)
- nil
- (names)))))
- (dolist (spec bindings)
- (cond ((atom spec)
- (let ((var (get-var spec)))
- (vars var)
- (names (cons spec var))
- (vals nil)))
- (t
- (unless (proper-list-of-length-p spec 1 2)
- (compiler-error "The ~S binding spec ~S is malformed."
- context
- spec))
- (let* ((name (first spec))
- (var (get-var name)))
- (vars var)
- (names name)
- (vals (second spec)))))))
-
- (values (vars) (vals) (names))))
-
-(def-ir1-translator let ((bindings &body body)
- start cont)
- #!+sb-doc
- "LET ({(Var [Value]) | Var}*) Declaration* Form*
- During evaluation of the Forms, bind the Vars to the result of evaluating the
- Value forms. The variables are bound in parallel after all of the Values are
- evaluated."
- (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
- (multiple-value-bind (vars values) (extract-let-variables bindings 'let)
- (let* ((*lexenv* (process-decls decls vars nil cont))
- (fun-cont (make-continuation))
- (fun (ir1-convert-lambda-body forms vars)))
- (reference-leaf start fun-cont fun)
- (ir1-convert-combination-args fun-cont cont values)))))
-
-(def-ir1-translator let* ((bindings &body body)
- start cont)
- #!+sb-doc
- "LET* ({(Var [Value]) | Var}*) Declaration* Form*
- Similar to LET, but the variables are bound sequentially, allowing each Value
- form to reference any of the previous Vars."
- (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
- (multiple-value-bind (vars values) (extract-let-variables bindings 'let*)
- (let ((*lexenv* (process-decls decls vars nil cont)))
- (ir1-convert-aux-bindings start cont forms vars values)))))
-
-;;; logic shared between IR1 translators for LOCALLY, MACROLET,
-;;; and SYMBOL-MACROLET
-;;;
-;;; Note that all these things need to preserve top-level-formness,
-;;; but we don't need to worry about that within an IR1 translator,
-;;; since top-level-formness is picked off by PROCESS-TOP-LEVEL-FOO
-;;; forms before we hit the IR1 transform level.
-(defun ir1-translate-locally (body start cont)
- (declare (type list body) (type continuation start cont))
- (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
- (let ((*lexenv* (process-decls decls nil nil cont)))
- (ir1-convert-aux-bindings start cont forms nil nil))))
-
-(def-ir1-translator locally ((&body body) start cont)
- #!+sb-doc
- "LOCALLY Declaration* Form*
- Sequentially evaluate the Forms in a lexical environment where the
- the Declarations have effect. If LOCALLY is a top-level form, then
- the Forms are also processed as top-level forms."
- (ir1-translate-locally body start cont))
-\f
-;;;; FLET and LABELS
-
-;;; Given a list of local function specifications in the style of
-;;; FLET, return lists of the function names and of the lambdas which
-;;; are their definitions.
-;;;
-;;; The function names are checked for legality. CONTEXT is the name
-;;; of the form, for error reporting.
-(declaim (ftype (function (list symbol) (values list list))
- extract-flet-variables))
-(defun extract-flet-variables (definitions context)
- (collect ((names)
- (defs))
- (dolist (def definitions)
- (when (or (atom def) (< (length def) 2))
- (compiler-error "The ~S definition spec ~S is malformed." context def))
-
- (let ((name (check-function-name (first def))))
- (names name)
- (multiple-value-bind (forms decls) (sb!sys:parse-body (cddr def))
- (defs `(lambda ,(second def)
- ,@decls
- (block ,(function-name-block-name name)
- . ,forms))))))
- (values (names) (defs))))
-
-(def-ir1-translator flet ((definitions &body body)
- start cont)
- #!+sb-doc
- "FLET ({(Name Lambda-List Declaration* Form*)}*) Declaration* Body-Form*
- Evaluate the Body-Forms with some local function definitions. The bindings
- do not enclose the definitions; any use of Name in the Forms will refer to
- the lexically apparent function definition in the enclosing environment."
- (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
- (multiple-value-bind (names defs)
- (extract-flet-variables definitions 'flet)
- (let* ((fvars (mapcar (lambda (n d)
- (ir1-convert-lambda d n))
- names defs))
- (*lexenv* (make-lexenv
- :default (process-decls decls nil fvars cont)
- :functions (pairlis names fvars))))
- (ir1-convert-progn-body start cont forms)))))
-
-;;; For LABELS, we have to create dummy function vars and add them to
-;;; the function namespace while converting the functions. We then
-;;; modify all the references to these leaves so that they point to
-;;; the real functional leaves. We also backpatch the FENV so that if
-;;; the lexical environment is used for inline expansion we will get
-;;; the right functions.
-(def-ir1-translator labels ((definitions &body body) start cont)
- #!+sb-doc
- "LABELS ({(Name Lambda-List Declaration* Form*)}*) Declaration* Body-Form*
- Evaluate the Body-Forms with some local function definitions. The bindings
- enclose the new definitions, so the defined functions can call themselves or
- each other."
- (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
- (multiple-value-bind (names defs)
- (extract-flet-variables definitions 'labels)
- (let* ((new-fenv (loop for name in names
- collect (cons name (make-functional :name name))))
- (real-funs
- (let ((*lexenv* (make-lexenv :functions new-fenv)))
- (mapcar (lambda (n d)
- (ir1-convert-lambda d n))
- names defs))))
-
- (loop for real in real-funs and env in new-fenv do
- (let ((dum (cdr env)))
- (substitute-leaf real dum)
- (setf (cdr env) real)))
-
- (let ((*lexenv* (make-lexenv
- :default (process-decls decls nil real-funs cont)
- :functions (pairlis names real-funs))))
- (ir1-convert-progn-body start cont forms))))))
-\f
-;;;; THE
-
-;;; Do stuff to recognize a THE or VALUES declaration. CONT is the
-;;; continuation that the assertion applies to, TYPE is the type
-;;; specifier and Lexenv is the current lexical environment. NAME is
-;;; the name of the declaration we are doing, for use in error
-;;; messages.
-;;;
-;;; This is somewhat involved, since a type assertion may only be made
-;;; on a continuation, not on a node. We can't just set the
-;;; continuation asserted type and let it go at that, since there may
-;;; be parallel THE's for the same continuation, i.e.:
-;;; (if ...
-;;; (the foo ...)
-;;; (the bar ...))
-;;;
-;;; In this case, our representation can do no better than the union
-;;; of these assertions. And if there is a branch with no assertion,
-;;; we have nothing at all. We really need to recognize scoping, since
-;;; we need to be able to discern between parallel assertions (which
-;;; we union) and nested ones (which we intersect).
-;;;
-;;; We represent the scoping by throwing our innermost (intersected)
-;;; assertion on CONT into the TYPE-RESTRICTIONS. As we go down, we
-;;; intersect our assertions together. If CONT has no uses yet, we
-;;; have not yet bottomed out on the first COND branch; in this case
-;;; we optimistically assume that this type will be the one we end up
-;;; with, and set the ASSERTED-TYPE to it. We can never get better
-;;; than the type that we have the first time we bottom out. Later
-;;; THE's (or the absence thereof) can only weaken this result.
-;;;
-;;; We make this work by getting USE-CONTINUATION to do the unioning
-;;; across COND branches. We can't do it here, since we don't know how
-;;; many branches there are going to be.
-(defun do-the-stuff (type cont lexenv name)
- (declare (type continuation cont) (type lexenv lexenv))
- (let* ((ctype (values-specifier-type type))
- (old-type (or (lexenv-find cont type-restrictions)
- *wild-type*))
- (intersects (values-types-equal-or-intersect old-type ctype))
- (int (values-type-intersection old-type ctype))
- (new (if intersects int old-type)))
- (when (null (find-uses cont))
- (setf (continuation-asserted-type cont) new))
- (when (and (not intersects)
- (not (policy *lexenv*
- (= inhibit-warnings 3)))) ;FIXME: really OK to suppress?
- (compiler-warning
- "The type ~S in ~S declaration conflicts with an enclosing assertion:~% ~S"
- (type-specifier ctype)
- name
- (type-specifier old-type)))
- (make-lexenv :type-restrictions `((,cont . ,new))
- :default lexenv)))
-
-;;; Assert that FORM evaluates to the specified type (which may be a
-;;; VALUES type).
-;;;
-;;; FIXME: In a version of CMU CL that I used at Cadabra ca. 20000101,
-;;; this didn't seem to expand into an assertion, at least for ALIEN
-;;; values. Check that SBCL doesn't have this problem.
-(def-ir1-translator the ((type value) start cont)
- (let ((*lexenv* (do-the-stuff type cont *lexenv* 'the)))
- (ir1-convert start cont value)))
-
-;;; This is like the THE special form, except that it believes
-;;; whatever you tell it. It will never generate a type check, but
-;;; will cause a warning if the compiler can prove the assertion is
-;;; wrong.
-;;;
-;;; Since the CONTINUATION-DERIVED-TYPE is computed as the union of
-;;; its uses's types, setting it won't work. Instead we must intersect
-;;; the type with the uses's DERIVED-TYPE.
-(def-ir1-translator truly-the ((type value) start cont)
- #!+sb-doc
- (declare (inline member))
- (let ((type (values-specifier-type type))
- (old (find-uses cont)))
- (ir1-convert start cont value)
- (do-uses (use cont)
- (unless (member use old :test #'eq)
- (derive-node-type use type)))))
-\f
-;;;; SETQ
-
-;;; If there is a definition in LEXENV-VARIABLES, just set that,
-;;; otherwise look at the global information. If the name is for a
-;;; constant, then error out.
-(def-ir1-translator setq ((&whole source &rest things) start cont)
- (let ((len (length things)))
- (when (oddp len)
- (compiler-error "odd number of args to SETQ: ~S" source))
- (if (= len 2)
- (let* ((name (first things))
- (leaf (or (lexenv-find name variables)
- (find-free-variable name))))
- (etypecase leaf
- (leaf
- (when (or (constant-p leaf)
- (and (global-var-p leaf)
- (eq (global-var-kind leaf) :constant)))
- (compiler-error "~S is a constant and thus can't be set." name))
- (when (and (lambda-var-p leaf)
- (lambda-var-ignorep leaf))
- ;; ANSI's definition of "Declaration IGNORE, IGNORABLE"
- ;; requires that this be a STYLE-WARNING, not a full warning.
- (compiler-style-warning
- "~S is being set even though it was declared to be ignored."
- name))
- (set-variable start cont leaf (second things)))
- (cons
- (aver (eq (car leaf) 'MACRO))
- (ir1-convert start cont `(setf ,(cdr leaf) ,(second things))))
- (heap-alien-info
- (ir1-convert start cont
- `(%set-heap-alien ',leaf ,(second things))))))
- (collect ((sets))
- (do ((thing things (cddr thing)))
- ((endp thing)
- (ir1-convert-progn-body start cont (sets)))
- (sets `(setq ,(first thing) ,(second thing))))))))
-
-;;; This is kind of like REFERENCE-LEAF, but we generate a SET node.
-;;; This should only need to be called in SETQ.
-(defun set-variable (start cont var value)
- (declare (type continuation start cont) (type basic-var var))
- (let ((dest (make-continuation)))
- (setf (continuation-asserted-type dest) (leaf-type var))
- (ir1-convert start dest value)
- (let ((res (make-set :var var :value dest)))
- (setf (continuation-dest dest) res)
- (setf (leaf-ever-used var) t)
- (push res (basic-var-sets var))
- (prev-link res dest)
- (use-continuation res cont))))
-\f
-;;;; CATCH, THROW and UNWIND-PROTECT
-
-;;; We turn THROW into a multiple-value-call of a magical function,
-;;; since as as far as IR1 is concerned, it has no interesting
-;;; properties other than receiving multiple-values.
-(def-ir1-translator throw ((tag result) start cont)
- #!+sb-doc
- "Throw Tag Form
- Do a non-local exit, return the values of Form from the CATCH whose tag
- evaluates to the same thing as Tag."
- (ir1-convert start cont
- `(multiple-value-call #'%throw ,tag ,result)))
-
-;;; This is a special special form used to instantiate a cleanup as
-;;; the current cleanup within the body. KIND is a the kind of cleanup
-;;; to make, and MESS-UP is a form that does the mess-up action. We
-;;; make the MESS-UP be the USE of the MESS-UP form's continuation,
-;;; and introduce the cleanup into the lexical environment. We
-;;; back-patch the ENTRY-CLEANUP for the current cleanup to be the new
-;;; cleanup, since this inner cleanup is the interesting one.
-(def-ir1-translator %within-cleanup ((kind mess-up &body body) start cont)
- (let ((dummy (make-continuation))
- (dummy2 (make-continuation)))
- (ir1-convert start dummy mess-up)
- (let* ((mess-node (continuation-use dummy))
- (cleanup (make-cleanup :kind kind
- :mess-up mess-node))
- (old-cup (lexenv-cleanup *lexenv*))
- (*lexenv* (make-lexenv :cleanup cleanup)))
- (setf (entry-cleanup (cleanup-mess-up old-cup)) cleanup)
- (ir1-convert dummy dummy2 '(%cleanup-point))
- (ir1-convert-progn-body dummy2 cont body))))
-
-;;; This is a special special form that makes an "escape function"
-;;; which returns unknown values from named block. We convert the
-;;; function, set its kind to :ESCAPE, and then reference it. The
-;;; :Escape kind indicates that this function's purpose is to
-;;; represent a non-local control transfer, and that it might not
-;;; actually have to be compiled.
-;;;
-;;; Note that environment analysis replaces references to escape
-;;; functions with references to the corresponding NLX-INFO structure.
-(def-ir1-translator %escape-function ((tag) start cont)
- (let ((fun (ir1-convert-lambda
- `(lambda ()
- (return-from ,tag (%unknown-values))))))
- (setf (functional-kind fun) :escape)
- (reference-leaf start cont fun)))
-
-;;; Yet another special special form. This one looks up a local
-;;; function and smashes it to a :CLEANUP function, as well as
-;;; referencing it.
-(def-ir1-translator %cleanup-function ((name) start cont)
- (let ((fun (lexenv-find name functions)))
- (aver (lambda-p fun))
- (setf (functional-kind fun) :cleanup)
- (reference-leaf start cont fun)))
-
-;;; We represent the possibility of the control transfer by making an
-;;; "escape function" that does a lexical exit, and instantiate the
-;;; cleanup using %WITHIN-CLEANUP.
-(def-ir1-translator catch ((tag &body body) start cont)
- #!+sb-doc
- "Catch Tag Form*
- Evaluates Tag and instantiates it as a catcher while the body forms are
- evaluated in an implicit PROGN. If a THROW is done to Tag within the dynamic
- scope of the body, then control will be transferred to the end of the body
- and the thrown values will be returned."
- (ir1-convert
- start cont
- (let ((exit-block (gensym "EXIT-BLOCK-")))
- `(block ,exit-block
- (%within-cleanup
- :catch
- (%catch (%escape-function ,exit-block) ,tag)
- ,@body)))))
-
-;;; UNWIND-PROTECT is similar to CATCH, but more hairy. We make the
-;;; cleanup forms into a local function so that they can be referenced
-;;; both in the case where we are unwound and in any local exits. We
-;;; use %CLEANUP-FUNCTION on this to indicate that reference by
-;;; %UNWIND-PROTECT ISN'T "real", and thus doesn't cause creation of
-;;; an XEP.
-(def-ir1-translator unwind-protect ((protected &body cleanup) start cont)
- #!+sb-doc
- "Unwind-Protect Protected Cleanup*
- Evaluate the form Protected, returning its values. The cleanup forms are
- evaluated whenever the dynamic scope of the Protected form is exited (either
- due to normal completion or a non-local exit such as THROW)."
- (ir1-convert
- start cont
- (let ((cleanup-fun (gensym "CLEANUP-FUN-"))
- (drop-thru-tag (gensym "DROP-THRU-TAG-"))
- (exit-tag (gensym "EXIT-TAG-"))
- (next (gensym "NEXT"))
- (start (gensym "START"))
- (count (gensym "COUNT")))
- `(flet ((,cleanup-fun () ,@cleanup nil))
- ;; FIXME: If we ever get DYNAMIC-EXTENT working, then
- ;; ,CLEANUP-FUN should probably be declared DYNAMIC-EXTENT,
- ;; and something can be done to make %ESCAPE-FUNCTION have
- ;; dynamic extent too.
- (block ,drop-thru-tag
- (multiple-value-bind (,next ,start ,count)
- (block ,exit-tag
- (%within-cleanup
- :unwind-protect
- (%unwind-protect (%escape-function ,exit-tag)
- (%cleanup-function ,cleanup-fun))
- (return-from ,drop-thru-tag ,protected)))
- (,cleanup-fun)
- (%continue-unwind ,next ,start ,count)))))))
-\f
-;;;; multiple-value stuff
-
-;;; If there are arguments, MULTIPLE-VALUE-CALL turns into an
-;;; MV-COMBINATION.
-;;;
-;;; If there are no arguments, then we convert to a normal
-;;; combination, ensuring that a MV-COMBINATION always has at least
-;;; one argument. This can be regarded as an optimization, but it is
-;;; more important for simplifying compilation of MV-COMBINATIONS.
-(def-ir1-translator multiple-value-call ((fun &rest args) start cont)
- #!+sb-doc
- "MULTIPLE-VALUE-CALL Function Values-Form*
- Call Function, passing all the values of each Values-Form as arguments,
- values from the first Values-Form making up the first argument, etc."
- (let* ((fun-cont (make-continuation))
- (node (if args
- (make-mv-combination fun-cont)
- (make-combination fun-cont))))
- (ir1-convert start fun-cont
- (if (and (consp fun) (eq (car fun) 'function))
- fun
- `(%coerce-callable-to-function ,fun)))
- (setf (continuation-dest fun-cont) node)
- (assert-continuation-type fun-cont
- (specifier-type '(or function symbol)))
- (collect ((arg-conts))
- (let ((this-start fun-cont))
- (dolist (arg args)
- (let ((this-cont (make-continuation node)))
- (ir1-convert this-start this-cont arg)
- (setq this-start this-cont)
- (arg-conts this-cont)))
- (prev-link node this-start)
- (use-continuation node cont)
- (setf (basic-combination-args node) (arg-conts))))))
-
-;;; MULTIPLE-VALUE-PROG1 is represented implicitly in IR1 by having a
-;;; the result code use result continuation (CONT), but transfer
-;;; control to the evaluation of the body. In other words, the result
-;;; continuation isn't IMMEDIATELY-USED-P by the nodes that compute
-;;; the result.
-;;;
-;;; In order to get the control flow right, we convert the result with
-;;; a dummy result continuation, then convert all the uses of the
-;;; dummy to be uses of CONT. If a use is an EXIT, then we also
-;;; substitute CONT for the dummy in the corresponding ENTRY node so
-;;; that they are consistent. Note that this doesn't amount to
-;;; changing the exit target, since the control destination of an exit
-;;; is determined by the block successor; we are just indicating the
-;;; continuation that the result is delivered to.
-;;;
-;;; We then convert the body, using another dummy continuation in its
-;;; own block as the result. After we are done converting the body, we
-;;; move all predecessors of the dummy end block to CONT's block.
-;;;
-;;; Note that we both exploit and maintain the invariant that the CONT
-;;; to an IR1 convert method either has no block or starts the block
-;;; that control should transfer to after completion for the form.
-;;; Nested MV-PROG1's work because during conversion of the result
-;;; form, we use dummy continuation whose block is the true control
-;;; destination.
-(def-ir1-translator multiple-value-prog1 ((result &rest forms) start cont)
- #!+sb-doc
- "MULTIPLE-VALUE-PROG1 Values-Form Form*
- Evaluate Values-Form and then the Forms, but return all the values of
- Values-Form."
- (continuation-starts-block cont)
- (let* ((dummy-result (make-continuation))
- (dummy-start (make-continuation))
- (cont-block (continuation-block cont)))
- (continuation-starts-block dummy-start)
- (ir1-convert start dummy-start result)
-
- (substitute-continuation-uses cont dummy-start)
-
- (continuation-starts-block dummy-result)
- (ir1-convert-progn-body dummy-start dummy-result forms)
- (let ((end-block (continuation-block dummy-result)))
- (dolist (pred (block-pred end-block))
- (unlink-blocks pred end-block)
- (link-blocks pred cont-block))
- (aver (not (continuation-dest dummy-result)))
- (delete-continuation dummy-result)
- (remove-from-dfo end-block))))
-\f
-;;;; interface to defining macros
-
-;;;; FIXME:
-;;;; classic CMU CL comment:
-;;;; DEFMACRO and DEFUN expand into calls to %DEFxxx functions
-;;;; so that we get a chance to see what is going on. We define
-;;;; IR1 translators for these functions which look at the
-;;;; definition and then generate a call to the %%DEFxxx function.
-;;;; Alas, this implementation doesn't do the right thing for
-;;;; non-toplevel uses of these forms, so this should probably
-;;;; be changed to use EVAL-WHEN instead.
-
-;;; Return a new source path with any stuff intervening between the
-;;; current path and the first form beginning with NAME stripped off.
-;;; This is used to hide the guts of DEFmumble macros to prevent
-;;; annoying error messages.
-(defun revert-source-path (name)
- (do ((path *current-path* (cdr path)))
- ((null path) *current-path*)
- (let ((first (first path)))
- (when (or (eq first name)
- (eq first 'original-source-start))
- (return path)))))
-
-;;; Warn about incompatible or illegal definitions and add the macro
-;;; to the compiler environment.
-;;;
-;;; Someday we could check for macro arguments being incompatibly
-;;; redefined. Doing this right will involve finding the old macro
-;;; lambda-list and comparing it with the new one.
-(def-ir1-translator %defmacro ((qname qdef lambda-list doc) start cont
- :kind :function)
- (let (;; QNAME is typically a quoted name. I think the idea is to let
- ;; %DEFMACRO work as an ordinary function when interpreting. Whatever
- ;; the reason it's there, we don't want it any more. -- WHN 19990603
- (name (eval qname))
- ;; QDEF should be a sharp-quoted definition. We don't want to make a
- ;; function of it just yet, so we just drop the sharp-quote.
- (def (progn
- (aver (eq 'function (first qdef)))
- (aver (proper-list-of-length-p qdef 2))
- (second qdef))))
-
- (/show "doing IR1 translator for %DEFMACRO" name)
-
- (unless (symbolp name)
- (compiler-error "The macro name ~S is not a symbol." name))
-
- (ecase (info :function :kind name)
- ((nil))
- (:function
- (remhash name *free-functions*)
- (undefine-function-name name)
- (compiler-warning
- "~S is being redefined as a macro when it was ~
- previously ~(~A~) to be a function."
- name
- (info :function :where-from name)))
- (:macro)
- (:special-form
- (compiler-error "The special form ~S can't be redefined as a macro."
- name)))
-
- (setf (info :function :kind name) :macro
- (info :function :where-from name) :defined
- (info :function :macro-function name) (coerce def 'function))
-
- (let* ((*current-path* (revert-source-path 'defmacro))
- (fun (ir1-convert-lambda def name)))
- (setf (leaf-name fun)
- (concatenate 'string "DEFMACRO " (symbol-name name)))
- (setf (functional-arg-documentation fun) (eval lambda-list))
-
- (ir1-convert start cont `(%%defmacro ',name ,fun ,doc)))
-
- (when sb!xc:*compile-print*
- ;; FIXME: It would be nice to convert this, and the other places
- ;; which create compiler diagnostic output prefixed by
- ;; semicolons, to use some common utility which automatically
- ;; prefixes all its output with semicolons. (The addition of
- ;; semicolon prefixes was introduced ca. sbcl-0.6.8.10 as the
- ;; "MNA compiler message patch", and implemented by modifying a
- ;; bunch of output statements on a case-by-case basis, which
- ;; seems unnecessarily error-prone and unclear, scattering
- ;; implicit information about output style throughout the
- ;; system.) Starting by rewriting COMPILER-MUMBLE to add
- ;; semicolon prefixes would be a good start, and perhaps also:
- ;; * Add semicolon prefixes for "FOO assembled" messages emitted
- ;; when e.g. src/assembly/x86/assem-rtns.lisp is processed.
- ;; * At least some debugger output messages deserve semicolon
- ;; prefixes too:
- ;; ** restarts table
- ;; ** "Within the debugger, you can type HELP for help."
- (compiler-mumble "~&; converted ~S~%" name))))
-
-(def-ir1-translator %define-compiler-macro ((name def lambda-list doc)
- start cont
- :kind :function)
- (let ((name (eval name))
- (def (second def))) ; We don't want to make a function just yet...
-
- (when (eq (info :function :kind name) :special-form)
- (compiler-error "attempt to define a compiler-macro for special form ~S"
- name))
-
- (setf (info :function :compiler-macro-function name)
- (coerce def 'function))
-
- (let* ((*current-path* (revert-source-path 'define-compiler-macro))
- (fun (ir1-convert-lambda def name)))
- (setf (leaf-name fun)
- (let ((*print-case* :upcase))
- (format nil "DEFINE-COMPILER-MACRO ~S" name)))
- (setf (functional-arg-documentation fun) (eval lambda-list))
-
- (ir1-convert start cont `(%%define-compiler-macro ',name ,fun ,doc)))
-
- (when sb!xc:*compile-print*
- (compiler-mumble "~&; converted ~S~%" name))))
-\f
-;;;; defining global functions
-
-;;; Convert FUN as a lambda in the null environment, but use the
-;;; current compilation policy. Note that FUN may be a
-;;; LAMBDA-WITH-ENVIRONMENT, so we may have to augment the environment
-;;; to reflect the state at the definition site.
-(defun ir1-convert-inline-lambda (fun &optional name)
- (destructuring-bind (decls macros symbol-macros &rest body)
- (if (eq (car fun) 'lambda-with-environment)
- (cdr fun)
- `(() () () . ,(cdr fun)))
- (let ((*lexenv* (make-lexenv
- :default (process-decls decls nil nil
- (make-continuation)
- (make-null-lexenv))
- :variables (copy-list symbol-macros)
- :functions
- (mapcar (lambda (x)
- `(,(car x) .
- (macro . ,(coerce (cdr x) 'function))))
- macros)
- :policy (lexenv-policy *lexenv*))))
- (ir1-convert-lambda `(lambda ,@body) name))))
-
-;;; Return a lambda that has been "closed" with respect to ENV,
-;;; returning a LAMBDA-WITH-ENVIRONMENT if there are interesting
-;;; macros or declarations. If there is something too complex (like a
-;;; lexical variable) in the environment, then we return NIL.
-(defun inline-syntactic-closure-lambda (lambda &optional (env *lexenv*))
- (let ((variables (lexenv-variables env))
- (functions (lexenv-functions env))
- (decls ())
- (symmacs ())
- (macros ()))
- (cond ((or (lexenv-blocks env) (lexenv-tags env)) nil)
- ((and (null variables) (null functions))
- lambda)
- ((dolist (x variables nil)
- (let ((name (car x))
- (what (cdr x)))
- (when (eq x (assoc name variables :test #'eq))
- (typecase what
- (cons
- (aver (eq (car what) 'macro))
- (push x symmacs))
- (global-var
- (aver (eq (global-var-kind what) :special))
- (push `(special ,name) decls))
- (t (return t))))))
- nil)
- ((dolist (x functions nil)
- (let ((name (car x))
- (what (cdr x)))
- (when (eq x (assoc name functions :test #'equal))
- (typecase what
- (cons
- (push (cons name
- (function-lambda-expression (cdr what)))
- macros))
- (global-var
- (when (defined-function-p what)
- (push `(,(car (rassoc (defined-function-inlinep what)
- *inlinep-translations*))
- ,name)
- decls)))
- (t (return t))))))
- nil)
- (t
- `(lambda-with-environment ,decls
- ,macros
- ,symmacs
- . ,(rest lambda))))))
-
-;;; Get a DEFINED-FUNCTION object for a function we are about to
-;;; define. If the function has been forward referenced, then
-;;; substitute for the previous references.
-(defun get-defined-function (name)
- (let* ((name (proclaim-as-function-name name))
- (found (find-free-function name "Eh?")))
- (note-name-defined name :function)
- (cond ((not (defined-function-p found))
- (aver (not (info :function :inlinep name)))
- (let* ((where-from (leaf-where-from found))
- (res (make-defined-function
- :name name
- :where-from (if (eq where-from :declared)
- :declared :defined)
- :type (leaf-type found))))
- (substitute-leaf res found)
- (setf (gethash name *free-functions*) res)))
- ;; If *FREE-FUNCTIONS* has a previously converted definition for this
- ;; name, then blow it away and try again.
- ((defined-function-functional found)
- (remhash name *free-functions*)
- (get-defined-function name))
- (t found))))
-
-;;; Check a new global function definition for consistency with
-;;; previous declaration or definition, and assert argument/result
-;;; types if appropriate. This assertion is suppressed by the
-;;; EXPLICIT-CHECK attribute, which is specified on functions that
-;;; check their argument types as a consequence of type dispatching.
-;;; This avoids redundant checks such as NUMBERP on the args to +,
-;;; etc.
-(defun assert-new-definition (var fun)
- (let ((type (leaf-type var))
- (for-real (eq (leaf-where-from var) :declared))
- (info (info :function :info (leaf-name var))))
- (assert-definition-type
- fun type
- ;; KLUDGE: Common Lisp is such a dynamic language that in general
- ;; all we can do here in general is issue a STYLE-WARNING. It
- ;; would be nice to issue a full WARNING in the special case of
- ;; of type mismatches within a compilation unit (as in section
- ;; 3.2.2.3 of the spec) but at least as of sbcl-0.6.11, we don't
- ;; keep track of whether the mismatched data came from the same
- ;; compilation unit, so we can't do that. -- WHN 2001-02-11
- :error-function #'compiler-style-warning
- :warning-function (cond (info #'compiler-style-warning)
- (for-real #'compiler-note)
- (t nil))
- :really-assert
- (and for-real
- (not (and info
- (ir1-attributep (function-info-attributes info)
- explicit-check))))
- :where (if for-real
- "previous declaration"
- "previous definition"))))
-
-;;; Convert a lambda doing all the basic stuff we would do if we were
-;;; converting a DEFUN. This is used both by the %DEFUN translator and
-;;; for global inline expansion.
-;;;
-;;; Unless a :INLINE function, we temporarily clobber the inline
-;;; expansion. This prevents recursive inline expansion of
-;;; opportunistic pseudo-inlines.
-(defun ir1-convert-lambda-for-defun (lambda var expansion converter)
- (declare (cons lambda) (function converter) (type defined-function var))
- (let ((var-expansion (defined-function-inline-expansion var)))
- (unless (eq (defined-function-inlinep var) :inline)
- (setf (defined-function-inline-expansion var) nil))
- (let* ((name (leaf-name var))
- (fun (funcall converter lambda name))
- (function-info (info :function :info name)))
- (setf (functional-inlinep fun) (defined-function-inlinep var))
- (assert-new-definition var fun)
- (setf (defined-function-inline-expansion var) var-expansion)
- ;; If definitely not an interpreter stub, then substitute for any
- ;; old references.
- (unless (or (eq (defined-function-inlinep var) :notinline)
- (not *block-compile*)
- (and function-info
- (or (function-info-transforms function-info)
- (function-info-templates function-info)
- (function-info-ir2-convert function-info))))
- (substitute-leaf fun var)
- ;; If in a simple environment, then we can allow backward
- ;; references to this function from following top-level forms.
- (when expansion (setf (defined-function-functional var) fun)))
- fun)))
-
-;;; Convert the definition and install it in the global environment
-;;; with a LABELS-like effect. If the lexical environment is not null,
-;;; then we only install the definition during the processing of this
-;;; DEFUN, ensuring that the function cannot be called outside of the
-;;; correct environment. If the function is globally NOTINLINE, then
-;;; that inhibits even local substitution. Also, emit top-level code
-;;; to install the definition.
-;;;
-;;; This is one of the major places where the semantics of block
-;;; compilation is handled. Substitution for global names is totally
-;;; inhibited if *BLOCK-COMPILE* is NIL. And if *BLOCK-COMPILE* is
-;;; true and entry points are specified, then we don't install global
-;;; definitions for non-entry functions (effectively turning them into
-;;; local lexical functions.)
-(def-ir1-translator %defun ((name def doc source) start cont
- :kind :function)
- (declare (ignore source))
- (let* ((name (eval name))
- (lambda (second def))
- (*current-path* (revert-source-path 'defun))
- (expansion (unless (eq (info :function :inlinep name) :notinline)
- (inline-syntactic-closure-lambda lambda))))
- ;; If not in a simple environment or NOTINLINE, then discard any
- ;; forward references to this function.
- (unless expansion (remhash name *free-functions*))
-
- (let* ((var (get-defined-function name))
- (save-expansion (and (member (defined-function-inlinep var)
- '(:inline :maybe-inline))
- expansion)))
- (setf (defined-function-inline-expansion var) expansion)
- (setf (info :function :inline-expansion name) save-expansion)
- ;; If there is a type from a previous definition, blast it,
- ;; since it is obsolete.
- (when (eq (leaf-where-from var) :defined)
- (setf (leaf-type var) (specifier-type 'function)))
-
- (let ((fun (ir1-convert-lambda-for-defun lambda
- var
- expansion
- #'ir1-convert-lambda)))
- (ir1-convert
- start cont
- (if (and *block-compile* *entry-points*
- (not (member name *entry-points* :test #'equal)))
- `',name
- `(%%defun ',name ,fun ,doc
- ,@(when save-expansion `(',save-expansion)))))
-
- (when sb!xc:*compile-print*
- (compiler-mumble "~&; converted ~S~%" name))))))