;;;; This software is part of the SBCL system. See the README file for ;;;; more information. ;;;; ;;;; While most of SBCL is derived from the CMU CL system, the test ;;;; files (like this one) were written from scratch after the fork ;;;; from CMU CL. ;;;; ;;;; This software is in the public domain and is provided with ;;;; absolutely no warranty. See the COPYING and CREDITS files for ;;;; more information. (load "assertoid.lisp") (load "compiler-test-util.lisp") (use-package "ASSERTOID") ;;;; examples from, or close to, the Common Lisp DEFSTRUCT spec ;;; Type mismatch of slot default init value isn't an error until the ;;; default init value is actually used. (The justification is ;;; somewhat bogus, but the requirement is clear.) (defstruct person age (name 007 :type string)) ; not an error until 007 used (make-person :name "James") ; not an error, 007 not used #+#.(cl:if (cl:eq sb-ext:*evaluator-mode* :compile) '(and) '(or)) (assert (raises-error? (make-person) type-error)) #+#.(cl:if (cl:eq sb-ext:*evaluator-mode* :compile) '(and) '(or)) (assert (raises-error? (setf (person-name (make-person :name "Q")) 1) type-error)) ;;; An &AUX variable in a boa-constructor without a default value ;;; means "do not initialize slot" and does not cause type error (declaim (notinline opaque-identity)) (defun opaque-identity (x) x) (defstruct (boa-saux (:constructor make-boa-saux (&aux a (b 3) (c)))) (a #\! :type (integer 1 2)) (b #\? :type (integer 3 4)) (c #\# :type (integer 5 6))) (let ((s (make-boa-saux))) (locally (declare (optimize (safety 3)) (inline boa-saux-a)) (assert (raises-error? (opaque-identity (boa-saux-a s)) type-error))) (setf (boa-saux-a s) 1) (setf (boa-saux-c s) 5) (assert (eql (boa-saux-a s) 1)) (assert (eql (boa-saux-b s) 3)) (assert (eql (boa-saux-c s) 5))) ; these two checks should be ; kept separated #+#.(cl:if (cl:eq sb-ext:*evaluator-mode* :compile) '(and) '(or)) (let ((s (make-boa-saux))) (locally (declare (optimize (safety 0)) (inline boa-saux-a)) (assert (eql (opaque-identity (boa-saux-a s)) 0))) (setf (boa-saux-a s) 1) (setf (boa-saux-c s) 5) (assert (eql (boa-saux-a s) 1)) (assert (eql (boa-saux-b s) 3)) (assert (eql (boa-saux-c s) 5))) (let ((s (make-boa-saux))) (locally (declare (optimize (safety 3)) (notinline boa-saux-a)) (assert (raises-error? (opaque-identity (boa-saux-a s)) type-error))) (setf (boa-saux-a s) 1) (setf (boa-saux-c s) 5) (assert (eql (boa-saux-a s) 1)) (assert (eql (boa-saux-b s) 3)) (assert (eql (boa-saux-c s) 5))) ;;; basic inheritance (defstruct (astronaut (:include person) (:conc-name astro-)) helmet-size (favorite-beverage 'tang)) (let ((x (make-astronaut :name "Buzz" :helmet-size 17.5))) (assert (equal (person-name x) "Buzz")) (assert (equal (astro-name x) "Buzz")) (assert (eql (astro-favorite-beverage x) 'tang)) (assert (null (astro-age x)))) (defstruct (ancient-astronaut (:include person (age 77))) helmet-size (favorite-beverage 'tang)) (assert (eql (ancient-astronaut-age (make-ancient-astronaut :name "John")) 77)) ;;; interaction of :TYPE and :INCLUDE and :INITIAL-OFFSET (defstruct (binop (:type list) :named (:initial-offset 2)) (operator '? :type symbol) operand-1 operand-2) (defstruct (annotated-binop (:type list) (:initial-offset 3) (:include binop)) commutative associative identity) (assert (equal (make-annotated-binop :operator '* :operand-1 'x :operand-2 5 :commutative t :associative t :identity 1) '(nil nil binop * x 5 nil nil nil t t 1))) ;;; effect of :NAMED on :TYPE (defstruct (named-binop (:type list) :named) (operator '? :type symbol) operand-1 operand-2) (let ((named-binop (make-named-binop :operator '+ :operand-1 'x :operand-2 5))) ;; The data representation is specified to look like this. (assert (equal named-binop '(named-binop + x 5))) ;; A meaningful NAMED-BINOP-P is defined. (assert (named-binop-p named-binop)) (assert (named-binop-p (copy-list named-binop))) (assert (not (named-binop-p (cons 11 named-binop)))) (assert (not (named-binop-p (find-package :cl))))) ;;; example 1 (defstruct town area watertowers (firetrucks 1 :type fixnum) population (elevation 5128 :read-only t)) (let ((town1 (make-town :area 0 :watertowers 0))) (assert (town-p town1)) (assert (not (town-p 1))) (assert (eql (town-area town1) 0)) (assert (eql (town-elevation town1) 5128)) (assert (null (town-population town1))) (setf (town-population town1) 99) (assert (eql (town-population town1) 99)) (let ((town2 (copy-town town1))) (dolist (slot-accessor-name '(town-area town-watertowers town-firetrucks town-population town-elevation)) (assert (eql (funcall slot-accessor-name town1) (funcall slot-accessor-name town2)))) (assert (not (fboundp '(setf town-elevation)))))) ; 'cause it's :READ-ONLY ;;; example 2 (defstruct (clown (:conc-name bozo-)) (nose-color 'red) frizzy-hair-p polkadots) (let ((funny-clown (make-clown))) (assert (eql (bozo-nose-color funny-clown) 'red))) (defstruct (klown (:constructor make-up-klown) (:copier clone-klown) (:predicate is-a-bozo-p)) nose-color frizzy-hair-p polkadots) (assert (is-a-bozo-p (make-up-klown))) ;;;; systematically testing variants of DEFSTRUCT: ;;;; * native, :TYPE LIST, and :TYPE VECTOR ;;; FIXME: things to test: ;;; * Slot readers work. ;;; * Slot writers work. ;;; * Predicates work. ;;; FIXME: things that would be nice to test systematically someday: ;;; * constructors (default, boa..) ;;; * copiers ;;; * no type checks when (> SPEED SAFETY) ;;; * Tests of inclusion would be good. (It's tested very lightly ;;; above, and then tested a fair amount by the system compiling ;;; itself.) (defun string+ (&rest rest) (apply #'concatenate 'string (mapcar #'string rest))) (defun symbol+ (&rest rest) (values (intern (apply #'string+ rest)))) (defun accessor-name (conc-name slot-name) (symbol+ conc-name slot-name)) ;;; Use the ordinary FDEFINITIONs of accessors (not inline expansions) ;;; to read and write a structure slot. (defun read-slot-notinline (conc-name slot-name instance) (funcall (accessor-name conc-name slot-name) instance)) (defun write-slot-notinline (new-value conc-name slot-name instance) (funcall (fdefinition `(setf ,(accessor-name conc-name slot-name))) new-value instance)) ;;; Use inline expansions of slot accessors, if possible, to read and ;;; write a structure slot. (defun read-slot-inline (conc-name slot-name instance) (funcall (compile nil `(lambda (instance) (,(accessor-name conc-name slot-name) instance))) instance)) (defun write-slot-inline (new-value conc-name slot-name instance) (funcall (compile nil `(lambda (new-value instance) (setf (,(accessor-name conc-name slot-name) instance) new-value))) new-value instance)) ;;; Read a structure slot, checking that the inline and out-of-line ;;; accessors give the same result. (defun read-slot (conc-name slot-name instance) (let ((inline-value (read-slot-inline conc-name slot-name instance)) (notinline-value (read-slot-notinline conc-name slot-name instance))) (assert (eql inline-value notinline-value)) inline-value)) ;;; Write a structure slot, using INLINEP argument to decide ;;; on inlineness of accessor used. (defun write-slot (new-value conc-name slot-name instance inlinep) (if inlinep (write-slot-inline new-value conc-name slot-name instance) (write-slot-notinline new-value conc-name slot-name instance))) ;;; bound during the tests so that we can get to it even if the ;;; debugger is having a bad day (defvar *instance*) (declaim (optimize (debug 2))) (defmacro test-variant (defstructname &key colontype boa-constructor-p) `(progn (format t "~&/beginning PROGN for COLONTYPE=~S~%" ',colontype) (defstruct (,defstructname ,@(when colontype `((:type ,colontype))) ,@(when boa-constructor-p `((:constructor ,(symbol+ "CREATE-" defstructname) (id &optional (optional-test 2 optional-test-p) &key (home nil home-p) (no-home-comment "Home package CL not provided.") (comment (if home-p "" no-home-comment)) (refcount (if optional-test-p optional-test nil)) hash weight))))) ;; some ordinary tagged slots id (home nil :type package :read-only t) (comment "" :type simple-string) ;; some raw slots (weight 1.0 :type single-float) (hash 1 :type (integer 1 #.(* 3 most-positive-fixnum)) :read-only t) ;; more ordinary tagged slots (refcount 0 :type (and unsigned-byte fixnum))) (format t "~&/done with DEFSTRUCT~%") (let* ((cn (string+ ',defstructname "-")) ; conc-name (ctor (symbol-function ',(symbol+ (if boa-constructor-p "CREATE-" "MAKE-") defstructname))) (*instance* (funcall ctor ,@(unless boa-constructor-p `(:id)) "some id" ,@(when boa-constructor-p '(1)) :home (find-package :cl) :hash (+ 14 most-positive-fixnum) ,@(unless boa-constructor-p `(:refcount 1))))) ;; Check that ctor set up slot values correctly. (format t "~&/checking constructed structure~%") (assert (string= "some id" (read-slot cn "ID" *instance*))) (assert (eql (find-package :cl) (read-slot cn "HOME" *instance*))) (assert (string= "" (read-slot cn "COMMENT" *instance*))) (assert (= 1.0 (read-slot cn "WEIGHT" *instance*))) (assert (eql (+ 14 most-positive-fixnum) (read-slot cn "HASH" *instance*))) (assert (= 1 (read-slot cn "REFCOUNT" *instance*))) ;; There should be no writers for read-only slots. (format t "~&/checking no read-only writers~%") (assert (not (fboundp `(setf ,(symbol+ cn "HOME"))))) (assert (not (fboundp `(setf ,(symbol+ cn "HASH"))))) ;; (Read-only slot values are checked in the loop below.) (dolist (inlinep '(t nil)) (format t "~&/doing INLINEP=~S~%" inlinep) ;; Fiddle with writable slot values. (let ((new-id (format nil "~S" (random 100))) (new-comment (format nil "~X" (random 5555))) (new-weight (random 10.0))) (write-slot new-id cn "ID" *instance* inlinep) (write-slot new-comment cn "COMMENT" *instance* inlinep) (write-slot new-weight cn "WEIGHT" *instance* inlinep) (assert (eql new-id (read-slot cn "ID" *instance*))) (assert (eql new-comment (read-slot cn "COMMENT" *instance*))) ;;(unless (eql new-weight (read-slot cn "WEIGHT" *instance*)) ;; (error "WEIGHT mismatch: ~S vs. ~S" ;; new-weight (read-slot cn "WEIGHT" *instance*))) (assert (eql new-weight (read-slot cn "WEIGHT" *instance*))))) (format t "~&/done with INLINEP loop~%") ;; :TYPE FOO objects don't go in the Lisp type system, so we ;; can't test TYPEP stuff for them. ;; ;; FIXME: However, when they're named, they do define ;; predicate functions, and we could test those. ,@(unless colontype `(;; Fiddle with predicate function. (let ((pred-name (symbol+ ',defstructname "-P"))) (format t "~&/doing tests on PRED-NAME=~S~%" pred-name) (assert (funcall pred-name *instance*)) (assert (not (funcall pred-name 14))) (assert (not (funcall pred-name "test"))) (assert (not (funcall pred-name (make-hash-table)))) (let ((compiled-pred (compile nil `(lambda (x) (,pred-name x))))) (format t "~&/doing COMPILED-PRED tests~%") (assert (funcall compiled-pred *instance*)) (assert (not (funcall compiled-pred 14))) (assert (not (funcall compiled-pred #())))) ;; Fiddle with TYPEP. (format t "~&/doing TYPEP tests, COLONTYPE=~S~%" ',colontype) (assert (typep *instance* ',defstructname)) (assert (not (typep 0 ',defstructname))) (assert (funcall (symbol+ "TYPEP") *instance* ',defstructname)) (assert (not (funcall (symbol+ "TYPEP") nil ',defstructname))) (let* ((typename ',defstructname) (compiled-typep (compile nil `(lambda (x) (typep x ',typename))))) (assert (funcall compiled-typep *instance*)) (assert (not (funcall compiled-typep nil)))))))) (format t "~&/done with PROGN for COLONTYPE=~S~%" ',colontype))) (test-variant vanilla-struct) (test-variant vector-struct :colontype vector) (test-variant list-struct :colontype list) (test-variant vanilla-struct :boa-constructor-p t) (test-variant vector-struct :colontype vector :boa-constructor-p t) (test-variant list-struct :colontype list :boa-constructor-p t) ;;;; testing raw slots harder ;;;; ;;;; The offsets of raw slots need to be rescaled during the punning ;;;; process which is used to access them. That seems like a good ;;;; place for errors to lurk, so we'll try hunting for them by ;;;; verifying that all the raw slot data gets written successfully ;;;; into the object, can be copied with the object, and can then be ;;;; read back out (with none of it ending up bogusly outside the ;;;; object, so that it couldn't be copied, or bogusly overwriting ;;;; some other raw slot). (defstruct manyraw (a (expt 2 30) :type (unsigned-byte #.sb-vm:n-word-bits)) (b 0.1 :type single-float) (c 0.2d0 :type double-float) (d #c(0.3 0.3) :type (complex single-float)) unraw-slot-just-for-variety (e #c(0.4d0 0.4d0) :type (complex double-float)) (aa (expt 2 30) :type (unsigned-byte #.sb-vm:n-word-bits)) (bb 0.1 :type single-float) (cc 0.2d0 :type double-float) (dd #c(0.3 0.3) :type (complex single-float)) (ee #c(0.4d0 0.4d0) :type (complex double-float))) (defvar *manyraw* (make-manyraw)) (assert (eql (manyraw-a *manyraw*) (expt 2 30))) (assert (eql (manyraw-b *manyraw*) 0.1)) (assert (eql (manyraw-c *manyraw*) 0.2d0)) (assert (eql (manyraw-d *manyraw*) #c(0.3 0.3))) (assert (eql (manyraw-e *manyraw*) #c(0.4d0 0.4d0))) (assert (eql (manyraw-aa *manyraw*) (expt 2 30))) (assert (eql (manyraw-bb *manyraw*) 0.1)) (assert (eql (manyraw-cc *manyraw*) 0.2d0)) (assert (eql (manyraw-dd *manyraw*) #c(0.3 0.3))) (assert (eql (manyraw-ee *manyraw*) #c(0.4d0 0.4d0))) (setf (manyraw-aa *manyraw*) (expt 2 31) (manyraw-bb *manyraw*) 0.11 (manyraw-cc *manyraw*) 0.22d0 (manyraw-dd *manyraw*) #c(0.33 0.33) (manyraw-ee *manyraw*) #c(0.44d0 0.44d0)) (let ((copy (copy-manyraw *manyraw*))) (assert (eql (manyraw-a copy) (expt 2 30))) (assert (eql (manyraw-b copy) 0.1)) (assert (eql (manyraw-c copy) 0.2d0)) (assert (eql (manyraw-d copy) #c(0.3 0.3))) (assert (eql (manyraw-e copy) #c(0.4d0 0.4d0))) (assert (eql (manyraw-aa copy) (expt 2 31))) (assert (eql (manyraw-bb copy) 0.11)) (assert (eql (manyraw-cc copy) 0.22d0)) (assert (eql (manyraw-dd copy) #c(0.33 0.33))) (assert (eql (manyraw-ee copy) #c(0.44d0 0.44d0)))) ;;;; Since GC treats raw slots specially now, let's try this with more objects ;;;; and random values as a stress test. (setf *manyraw* nil) (defconstant +n-manyraw+ 10) (defconstant +m-manyraw+ 1000) (defun check-manyraws (manyraws) (assert (eql (length manyraws) (* +n-manyraw+ +m-manyraw+))) (loop for m in (reverse manyraws) for i from 0 do ;; Compare the tagged reference values with raw reffer results. (destructuring-bind (j a b c d e) (manyraw-unraw-slot-just-for-variety m) (assert (eql i j)) (assert (= (manyraw-a m) a)) (assert (= (manyraw-b m) b)) (assert (= (manyraw-c m) c)) (assert (= (manyraw-d m) d)) (assert (= (manyraw-e m) e))) ;; Test the funny out-of-line OAOOM-style closures, too. (mapcar (lambda (fn value) (assert (= (funcall fn m) value))) (list #'manyraw-a #'manyraw-b #'manyraw-c #'manyraw-d #'manyraw-e) (cdr (manyraw-unraw-slot-just-for-variety m))))) (defstruct (manyraw-subclass (:include manyraw)) (stolperstein 0 :type (unsigned-byte 32))) ;;; create lots of manyraw objects, triggering GC every now and then (dotimes (y +n-manyraw+) (dotimes (x +m-manyraw+) (let ((a (random (expt 2 32))) (b (random most-positive-single-float)) (c (random most-positive-double-float)) (d (complex (random most-positive-single-float) (random most-positive-single-float))) (e (complex (random most-positive-double-float) (random most-positive-double-float)))) (push (funcall (if (zerop (mod x 3)) #'make-manyraw-subclass #'make-manyraw) :unraw-slot-just-for-variety (list (+ x (* y +m-manyraw+)) a b c d e) :a a :b b :c c :d d :e e) *manyraw*))) (room) (sb-ext:gc)) (with-test (:name :defstruct-raw-slot-gc) (check-manyraws *manyraw*)) ;;; try a full GC, too (sb-ext:gc :full t) (with-test (:name (:defstruct-raw-slot-gc :full)) (check-manyraws *manyraw*)) ;;; fasl dumper and loader also have special handling of raw slots, so ;;; dump all of them into a fasl (defmethod make-load-form ((self manyraw) &optional env) self env :sb-just-dump-it-normally) (with-open-file (s "tmp-defstruct.manyraw.lisp" :direction :output :if-exists :supersede) (write-string "(defun dumped-manyraws () '#.*manyraw*)" s)) (compile-file "tmp-defstruct.manyraw.lisp") (delete-file "tmp-defstruct.manyraw.lisp") ;;; nuke the objects and try another GC just to be extra careful (setf *manyraw* nil) (sb-ext:gc :full t) ;;; re-read the dumped structures and check them (load "tmp-defstruct.manyraw.fasl") (with-test (:name (:defstruct-raw-slot load)) (check-manyraws (dumped-manyraws))) ;;;; miscellaneous old bugs (defstruct ya-struct) (when (ignore-errors (or (ya-struct-p) 12)) (error "YA-STRUCT-P of no arguments should signal an error.")) (when (ignore-errors (or (ya-struct-p 'too 'many 'arguments) 12)) (error "YA-STRUCT-P of three arguments should signal an error.")) ;;; bug 210: Until sbcl-0.7.8.32 BOA constructors had SAFETY 0 ;;; declared inside on the theory that slot types were already ;;; checked, which bogusly suppressed unbound-variable and other ;;; checks within the evaluation of initforms. (defvar *bug210*) (defstruct (bug210a (:constructor bug210a ())) (slot *bug210*)) (defstruct bug210b (slot *bug210*)) ;;; Because of bug 210, this assertion used to fail. (assert (typep (nth-value 1 (ignore-errors (bug210a))) 'unbound-variable)) ;;; Even with bug 210, these assertions succeeded. (assert (typep (nth-value 1 (ignore-errors *bug210*)) 'unbound-variable)) (assert (typep (nth-value 1 (ignore-errors (make-bug210b))) 'unbound-variable)) ;;; In sbcl-0.7.8.53, DEFSTRUCT blew up in non-toplevel contexts ;;; because it implicitly assumed that EVAL-WHEN (COMPILE) stuff ;;; setting up compiler-layout information would run before the ;;; constructor function installing the layout was compiled. Make sure ;;; that doesn't happen again. (defun foo-0-7-8-53 () (defstruct foo-0-7-8-53 x (y :not))) (assert (not (find-class 'foo-0-7-8-53 nil))) (foo-0-7-8-53) (assert (find-class 'foo-0-7-8-53 nil)) (let ((foo-0-7-8-53 (make-foo-0-7-8-53 :x :s))) (assert (eq (foo-0-7-8-53-x foo-0-7-8-53) :s)) (assert (eq (foo-0-7-8-53-y foo-0-7-8-53) :not))) ;;; tests of behaviour of colliding accessors. (defstruct (bug127-foo (:conc-name bug127-baz-)) a) (assert (= (bug127-baz-a (make-bug127-foo :a 1)) 1)) (defstruct (bug127-bar (:conc-name bug127-baz-) (:include bug127-foo)) b) (assert (= (bug127-baz-a (make-bug127-bar :a 1 :b 2)) 1)) (assert (= (bug127-baz-b (make-bug127-bar :a 1 :b 2)) 2)) (assert (= (bug127-baz-a (make-bug127-foo :a 1)) 1)) (defun bug127-flurble (x) x) (defstruct bug127 flurble) (assert (= (bug127-flurble (make-bug127 :flurble 7)) 7)) (defstruct bug127-a b-c) (assert (= (bug127-a-b-c (make-bug127-a :b-c 9)) 9)) (defstruct (bug127-a-b (:include bug127-a)) c) (assert (= (bug127-a-b-c (make-bug127-a :b-c 9)) 9)) (assert (= (bug127-a-b-c (make-bug127-a-b :b-c 11 :c 13)) 11)) (defstruct (bug127-e (:conc-name bug127--)) foo) (assert (= (bug127--foo (make-bug127-e :foo 3)) 3)) (defstruct (bug127-f (:conc-name bug127--)) foo) (assert (= (bug127--foo (make-bug127-f :foo 3)) 3)) (assert (raises-error? (bug127--foo (make-bug127-e :foo 3)) type-error)) ;;; FIXME: should probably do the same tests on DEFSTRUCT :TYPE ;;; As noted by Paul Dietz for CMUCL, :CONC-NAME handling was a little ;;; too fragile: (defstruct (conc-name-syntax :conc-name) a-conc-name-slot) (assert (eq (a-conc-name-slot (make-conc-name-syntax :a-conc-name-slot 'y)) 'y)) ;;; and further :CONC-NAME NIL was being wrongly treated: (defpackage "DEFSTRUCT-TEST-SCRATCH") (defstruct (conc-name-nil :conc-name) defstruct-test-scratch::conc-name-nil-slot) (assert (= (defstruct-test-scratch::conc-name-nil-slot (make-conc-name-nil :conc-name-nil-slot 1)) 1)) (assert (raises-error? (conc-name-nil-slot (make-conc-name-nil)) undefined-function)) ;;; The named/typed predicates were a little fragile, in that they ;;; could throw errors on innocuous input: (defstruct (list-struct (:type list) :named) a-slot) (assert (list-struct-p (make-list-struct))) (assert (not (list-struct-p nil))) (assert (not (list-struct-p 1))) (defstruct (offset-list-struct (:type list) :named (:initial-offset 1)) a-slot) (assert (offset-list-struct-p (make-offset-list-struct))) (assert (not (offset-list-struct-p nil))) (assert (not (offset-list-struct-p 1))) (assert (not (offset-list-struct-p '(offset-list-struct)))) (assert (not (offset-list-struct-p '(offset-list-struct . 3)))) (defstruct (vector-struct (:type vector) :named) a-slot) (assert (vector-struct-p (make-vector-struct))) (assert (not (vector-struct-p nil))) (assert (not (vector-struct-p #()))) ;;; bug 3d: type safety with redefined type constraints on slots #+#.(cl:if (cl:eq sb-ext:*evaluator-mode* :compile) '(and) '(or)) (macrolet ((test (type) (let* ((base-name (intern (format nil "bug3d-~A" type))) (up-name (intern (format nil "~A-up" base-name))) (accessor (intern (format nil "~A-X" base-name))) (up-accessor (intern (format nil "~A-X" up-name))) (type-options (when type `((:type ,type))))) `(progn (defstruct (,base-name ,@type-options) x y) (defstruct (,up-name (:include ,base-name (x "x" :type simple-string) (y "y" :type simple-string)) ,@type-options)) (let ((ob (,(intern (format nil "MAKE-~A" up-name))))) (setf (,accessor ob) 0) (loop for decl in '(inline notinline) for fun = `(lambda (s) (declare (optimize (safety 3)) (,decl ,',up-accessor)) (,',up-accessor s)) do (assert (raises-error? (funcall (compile nil fun) ob) type-error)))))))) (test nil) (test list) (test vector)) (let* ((name (gensym)) (form `(defstruct ,name (x nil :type (or null (function (integer) (values number &optional foo))))))) (eval (copy-tree form)) (eval (copy-tree form))) ;;; 322: "DEFSTRUCT :TYPE LIST predicate and improper lists" ;;; reported by Bruno Haible sbcl-devel "various SBCL bugs" from CLISP ;;; test suite. (defstruct (bug-332a (:type list) (:initial-offset 5) :named)) (defstruct (bug-332b (:type list) (:initial-offset 2) :named (:include bug-332a))) (assert (not (bug-332b-p (list* nil nil nil nil nil 'foo73 nil 'tail)))) (assert (not (bug-332b-p 873257))) (assert (not (bug-332b-p '(1 2 3 4 5 x 1 2 bug-332a)))) (assert (bug-332b-p '(1 2 3 4 5 x 1 2 bug-332b))) ;;; Similar test for vectors, just for good measure. (defstruct (bug-332a-aux (:type vector) (:initial-offset 5) :named)) (defstruct (bug-332b-aux (:type vector) (:initial-offset 2) :named (:include bug-332a-aux))) (assert (not (bug-332b-aux-p #(1 2 3 4 5 x 1 premature-end)))) (assert (not (bug-332b-aux-p 873257))) (assert (not (bug-332b-aux-p #(1 2 3 4 5 x 1 2 bug-332a-aux)))) (assert (bug-332b-aux-p #(1 2 3 4 5 x 1 2 bug-332b-aux))) ;;; In sbcl-0.8.11.8 FBOUNDPness potential collisions of structure ;;; slot accessors signalled a condition at macroexpansion time, not ;;; when the code was actually compiled or loaded. (let ((defstruct-form '(defstruct bug-in-0-8-11-8 x))) (defun bug-in-0-8-11-8-x (z) (print "some unrelated thing")) (handler-case (macroexpand defstruct-form) (warning (c) (error "shouldn't warn just from macroexpansion here")))) ;;; bug 318 symptom no 1. (rest not fixed yet) (catch :ok (handler-bind ((error (lambda (c) ;; Used to cause stack-exhaustion (unless (typep c 'storage-condition) (throw :ok t))))) (eval '(progn (defstruct foo a) (setf (find-class 'foo) nil) (defstruct foo slot-1))))) ;;; bug 348, evaluation order of slot writer arguments. Fixed by Gabor ;;; Melis. (defstruct bug-348 x) (assert (eql -1 (let ((i (eval '-2)) (x (make-bug-348))) (funcall #'(setf bug-348-x) (incf i) (aref (vector x) (incf i))) (bug-348-x x)))) ;;; obsolete instance trapping ;;; ;;; FIXME: Both error conditions below should possibly be instances ;;; of the same class. (Putting this FIXME here, since this is the only ;;; place where they appear together.) (with-test (:name :obsolete-defstruct/print-object) (eval '(defstruct born-to-change)) (let ((x (make-born-to-change))) (handler-bind ((error 'continue)) (eval '(defstruct born-to-change slot))) (assert (eq :error (handler-case (princ-to-string x) (sb-pcl::obsolete-structure () :error)))))) (with-test (:name :obsolete-defstruct/typep) (eval '(defstruct born-to-change-2)) (let ((x (make-born-to-change-2))) (handler-bind ((error 'continue)) (eval '(defstruct born-to-change-2 slot))) (assert (eq :error2 (handler-case (typep x (find-class 'standard-class)) (sb-kernel:layout-invalid () :error2)))))) ;; EQUALP didn't work for structures with float slots (reported by ;; Vjacheslav Fyodorov). (defstruct raw-slot-equalp-bug (b 0s0 :type single-float) c (a 0d0 :type double-float)) (defstruct raw-slot-equalp-bug-2 (b (complex 1d0) :type (complex double-float)) (x (complex 1d0) :type (complex double-float)) c (a 1s0 :type single-float)) (with-test (:name :raw-slot-equalp) (assert (equalp (make-raw-slot-equalp-bug :a 1d0 :b 2s0) (make-raw-slot-equalp-bug :a 1d0 :b 2s0))) (assert (equalp (make-raw-slot-equalp-bug :a 1d0 :b 0s0) (make-raw-slot-equalp-bug :a 1d0 :b -0s0))) (assert (not (equalp (make-raw-slot-equalp-bug :a 1d0 :b 2s0) (make-raw-slot-equalp-bug :a 1d0 :b 3s0)))) (assert (not (equalp (make-raw-slot-equalp-bug :a 1d0 :b 2s0) (make-raw-slot-equalp-bug :a 2d0 :b 2s0)))) (assert (equalp (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 2s0) (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 2s0))) (assert (equalp (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 0s0) (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a -0s0))) (assert (not (equalp (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 2s0) (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 3s0)))) (assert (not (equalp (make-raw-slot-equalp-bug-2 :b (complex 1d0) :a 2s0) (make-raw-slot-equalp-bug-2 :b (complex 2d0) :a 2s0))))) ;;; Check that all slot types (non-raw and raw) can be initialized with ;;; constant arguments. (defstruct constant-arg-inits (a 42 :type t) (b 1 :type fixnum) (c 2 :type sb-vm:word) (d 3.0 :type single-float) (e 4.0d0 :type double-float) (f #c(5.0 5.0) :type (complex single-float)) (g #c(6.0d0 6.0d0) :type (complex double-float))) (defun test-constant-arg-inits () (let ((foo (make-constant-arg-inits))) (declare (dynamic-extent foo)) (assert (eql 42 (constant-arg-inits-a foo))) (assert (eql 1 (constant-arg-inits-b foo))) (assert (eql 2 (constant-arg-inits-c foo))) (assert (eql 3.0 (constant-arg-inits-d foo))) (assert (eql 4.0d0 (constant-arg-inits-e foo))) (assert (eql #c(5.0 5.0) (constant-arg-inits-f foo))) (assert (eql #c(6.0d0 6.0d0) (constant-arg-inits-g foo))))) (make-constant-arg-inits) ;;; bug reported by John Morrison, 2008-07-22 on sbcl-devel (defstruct (raw-slot-struct-with-unknown-init (:constructor make-raw-slot-struct-with-unknown-init ())) (x (#:unknown-function) :type double-float)) ;;; Some checks for the behavior of incompatibly redefining structure ;;; classes. We don't actually check that our detection of ;;; "incompatible" is comprehensive, only that if an incompatible ;;; definition is processed, we do various things. (defmacro with-files ((&rest vars) &body body) "Evaluate BODY with VARS bound to a number of filenames, then delete the files at the end." (let* ((paths (loop for var in vars as index upfrom 0 collect (make-pathname :case :common :name (format nil "DEFSTRUCT-REDEF-TEST-~D" index) :type "LISP"))) (binding-spec (mapcar (lambda (var path) `(,var ,path)) vars paths))) (labels ((frob (n) `((unwind-protect (progn ,@(if (plusp n) (frob (1- n)) body)) (delete-file ,(elt paths n)))))) `(let ,binding-spec ,@(frob (1- (length vars))))))) (defun noclobber (pathspec &rest forms) "Write FORMS to the file named by PATHSPEC, erroring if PATHSPEC already names an existing file." (with-open-file (*standard-output* pathspec :direction :output :if-exists :error) (print '(in-package "CL-USER")) (mapc #'print forms))) (defun compile-file-assert (file &optional (want-error-p t) (want-warning-p t)) "Compile FILE and assert some things about the results." (multiple-value-bind (fasl errors-p warnings-p) (compile-file file) (assert fasl) (assert (eq errors-p want-error-p)) (assert (eq warnings-p want-warning-p)) fasl)) (defun continue-from-incompatible-defstruct-error (error) "Invoke the CONTINUE restart for an incompatible DEFSTRUCT redefinition." ;; FIXME: want distinct error type for incompatible defstruct. (when (search "attempt to redefine" (simple-condition-format-control error)) (when (find-restart 'continue) (invoke-restart 'continue)))) (defun recklessly-continue-from-incompatible-defstruct-error (error) "Invoke the RECKLESSLY-CONTINUE restart for an incompatible DEFSTRUCT redefinition." ;; FIXME: want distinct error type for incompatible defstruct. (when (search "attempt to redefine" (simple-condition-format-control error)) (when (find-restart 'sb-kernel::recklessly-continue) (invoke-restart 'sb-kernel::recklessly-continue)))) (defun assert-is (predicate instance) (assert (funcall predicate instance))) (defun assert-invalid (predicate instance) (assert (typep (nth-value 1 (ignore-errors (funcall predicate instance))) 'sb-kernel::layout-invalid))) ;; Don't try to understand this macro; just look at its expansion. (defmacro with-defstruct-redefinition-test (name (&rest defstruct-form-bindings) (&rest path-form-specs) handler-function &body body) (labels ((make-defstruct-form (&key class-name super-name slots) (let* ((predicate-name (read-from-string (format nil "~A-p" class-name))) (constructor-name (read-from-string (format nil "make-~A" class-name)))) `(values '(defstruct (,class-name (:constructor ,constructor-name) ,@(when super-name `((:include ,super-name)))) ,@slots) ',constructor-name ',predicate-name))) (frob (bindspecs classno) (if bindspecs `((multiple-value-bind ,(first (first bindspecs)) ,(apply #'make-defstruct-form (rest (first bindspecs))) (declare (ignorable ,@(first (first bindspecs)))) ,@(frob (rest bindspecs) (1+ classno)))) `((with-files ,(mapcar #'first path-form-specs) ,@(mapcar (lambda (path-form) `(noclobber ,@path-form)) path-form-specs) (handler-bind ((simple-error ',handler-function)) ,@body)))))) `(with-test (:name ,name) ,(first (frob defstruct-form-bindings 0))))) ;; When eyeballing these, it's helpful to see when various things are ;; happening. (setq *compile-verbose* t *load-verbose* t) ;;; Tests begin. ;; Base case: recklessly-continue. (with-defstruct-redefinition-test :defstruct/recklessly (((defstruct ctor pred) :class-name redef-test-1 :slots (a)) ((defstruct*) :class-name redef-test-1 :slots (a b))) ((path1 defstruct) (path2 defstruct*)) recklessly-continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load path2) (assert-is pred instance))) ;; Base case: continue (i.e., invalidate instances). (with-defstruct-redefinition-test :defstruct/continue (((defstruct ctor pred) :class-name redef-test-2 :slots (a)) ((defstruct*) :class-name redef-test-2 :slots (a b))) ((path1 defstruct) (path2 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load path2) (assert-invalid pred instance))) ;; Compiling a file with an incompatible defstruct should emit a ;; warning and an error, but the fasl should be loadable. (with-defstruct-redefinition-test :defstruct/compile-file-should-warn (((defstruct) :class-name redef-test-3 :slots (a)) ((defstruct*) :class-name redef-test-3 :slots (a b))) ((path1 defstruct) (path2 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (load (compile-file-assert path2))) ;; After compiling a file with an incompatible DEFSTRUCT, load the ;; fasl and ensure that an old instance remains valid. (with-defstruct-redefinition-test :defstruct/compile-file-reckless (((defstruct ctor pred) :class-name redef-test-4 :slots (a)) ((defstruct*) :class-name redef-test-4 :slots (a b))) ((path1 defstruct) (path2 defstruct*)) recklessly-continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load (compile-file-assert path2)) (assert-is pred instance))) ;; After compiling a file with an incompatible DEFSTRUCT, load the ;; fasl and ensure that an old instance has become invalid. (with-defstruct-redefinition-test :defstruct/compile-file-continue (((defstruct ctor pred) :class-name redef-test-5 :slots (a)) ((defstruct*) :class-name redef-test-5 :slots (a b))) ((path1 defstruct) (path2 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load (compile-file-assert path2)) (assert-invalid pred instance))) ;;; Subclasses. ;; Ensure that recklessly continuing DT(expected)T to instances of ;; subclasses. (This is a case where recklessly continuing is ;; actually dangerous, but we don't care.) (with-defstruct-redefinition-test :defstruct/subclass-reckless (((defstruct ignore pred1) :class-name redef-test-6 :slots (a)) ((substruct ctor pred2) :class-name redef-test-6-sub :super-name redef-test-6 :slots (z)) ((defstruct*) :class-name redef-test-6 :slots (a b))) ((path1 defstruct substruct) (path2 defstruct* substruct)) recklessly-continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load (compile-file-assert path2)) (assert-is pred1 instance) (assert-is pred2 instance))) ;; Ensure that continuing invalidates instances of subclasses. (with-defstruct-redefinition-test :defstruct/subclass-continue (((defstruct) :class-name redef-test-7 :slots (a)) ((substruct ctor pred) :class-name redef-test-7-sub :super-name redef-test-7 :slots (z)) ((defstruct*) :class-name redef-test-7 :slots (a b))) ((path1 defstruct substruct) (path2 defstruct* substruct)) continue-from-incompatible-defstruct-error (load path1) (let ((instance (funcall ctor))) (load (compile-file-assert path2)) (assert-invalid pred instance))) ;; Reclkessly continuing doesn't invalidate instances of subclasses. (with-defstruct-redefinition-test :defstruct/subclass-in-other-file-reckless (((defstruct ignore pred1) :class-name redef-test-8 :slots (a)) ((substruct ctor pred2) :class-name redef-test-8-sub :super-name redef-test-8 :slots (z)) ((defstruct*) :class-name redef-test-8 :slots (a b))) ((path1 defstruct) (path2 substruct) (path3 defstruct*)) recklessly-continue-from-incompatible-defstruct-error (load path1) (load path2) (let ((instance (funcall ctor))) (load (compile-file-assert path3)) (assert-is pred1 instance) (assert-is pred2 instance))) ;; This is an icky case: when a subclass is defined in a separate ;; file, CONTINUE'ing from LOAD of a file containing an incompatible ;; superclass definition leaves the predicates and accessors into the ;; subclass in a bad way until the subclass form is evaluated. (with-defstruct-redefinition-test :defstruct/subclass-in-other-file-continue (((defstruct ignore pred1) :class-name redef-test-9 :slots (a)) ((substruct ctor pred2) :class-name redef-test-9-sub :super-name redef-test-9 :slots (z)) ((defstruct*) :class-name redef-test-9 :slots (a b))) ((path1 defstruct) (path2 substruct) (path3 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (load path2) (let ((instance (funcall ctor))) (load (compile-file-assert path3)) ;; At this point, the instance of the subclass will not count as ;; an instance of the superclass or of the subclass, but PRED2's ;; predicate will error with "an obsolete structure accessor ;; function was called". (assert-invalid pred1 instance) (format t "~&~A~%" (nth-value 1 (ignore-errors (funcall pred2 instance)))) ;; After loading PATH2, we'll get the desired LAYOUT-INVALID error. (load path2) (assert-invalid pred2 instance))) ;; Some other subclass wrinkles have to do with splitting definitions ;; accross files and compiling and loading things in a funny order. (with-defstruct-redefinition-test :defstruct/subclass-in-other-file-funny-operation-order-continue (((defstruct ignore pred1) :class-name redef-test-10 :slots (a)) ((substruct ctor pred2) :class-name redef-test-10-sub :super-name redef-test-10 :slots (z)) ((defstruct*) :class-name redef-test-10 :slots (a b))) ((path1 defstruct) (path2 substruct) (path3 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (load path2) (let ((instance (funcall ctor))) ;; First we clobber the compiler's layout for the superclass. (compile-file-assert path3) ;; Then we recompile the subclass definition (which generates a ;; warning about the compiled layout for the superclass being ;; incompatible with the loaded layout, because we haven't loaded ;; path3 since recompiling). (compile-file path2) ;; Ugh. I don't want to think about loading these in the wrong ;; order. (load (compile-file-pathname path3)) (load (compile-file-pathname path2)) (assert-invalid pred1 instance) (assert-invalid pred2 instance))) (with-defstruct-redefinition-test :defstruct/subclass-in-other-file-funny-operation-order-continue (((defstruct ignore pred1) :class-name redef-test-11 :slots (a)) ((substruct ctor pred2) :class-name redef-test-11-sub :super-name redef-test-11 :slots (z)) ((defstruct*) :class-name redef-test-11 :slots (a b))) ((path1 defstruct) (path2 substruct) (path3 defstruct*)) continue-from-incompatible-defstruct-error (load path1) (load path2) (let ((instance (funcall ctor))) ;; This clobbers the compiler's layout for REDEF-TEST-11. (compile-file-assert path3) ;; This recompiles REDEF-TEST-11-SUB, using the new REDEF-TEST-11 ;; compiler-layout. (load (compile-file-pathname path2)) ;; Note that because we haven't loaded PATH3, we haven't clobbered ;; the class's layout REDEF-TEST-11, so REDEF-11's predicate will ;; still work. That's probably bad. (assert-is pred1 instance) (assert-is pred2 instance))) (with-test (:name :raw-slot/circle-subst) ;; CIRCLE-SUBSTS used %INSTANCE-REF on raw slots (multiple-value-bind (list n) (eval '(progn (defstruct raw-slot/circle-subst (x 0.0 :type single-float)) (read-from-string "((#1=#S(raw-slot/circle-subst :x 2.7158911)))"))) (destructuring-bind ((struct)) list (assert (raw-slot/circle-subst-p struct)) (assert (eql 2.7158911 (raw-slot/circle-subst-x struct))) (assert (eql 45 n))))) (defstruct (bug-3b (:constructor make-bug-3b (&aux slot))) (slot nil :type string)) (with-test (:name :bug-3b) (handler-case (progn (bug-3b-slot (make-bug-3b)) (error "fail")) (type-error (e) (assert (eq 'string (type-error-expected-type e))) (assert (zerop (type-error-datum e)))))) (with-test (:name :defstruct-copier-typechecks-argument) (assert (not (raises-error? (copy-person (make-astronaut :name "Neil"))))) (assert (raises-error? (copy-astronaut (make-person :name "Fred"))))) (with-test (:name :bug-528807) (let ((*evaluator-mode* :compile)) (handler-bind ((style-warning #'error)) (eval `(defstruct (bug-528807 (:constructor make-528807 (&aux x))) (x nil :type fixnum)))))) (with-test (:name :bug-520607) (assert (raises-error? (eval '(defstruct (typed-struct (:type list) (:predicate typed-struct-p)) (a 42 :type fixnum))))) ;; NIL is ok, though. (eval '(defstruct (typed-struct (:type list) (:predicate nil)) (a 42 :type fixnum))) ;; So's empty. (eval '(defstruct (typed-struct2 (:type list) (:predicate)) (a 42 :type fixnum)))) (with-test (:name (:boa-supplied-p &optional)) (handler-bind ((warning #'error)) (eval `(defstruct (boa-supplied-p.1 (:constructor make-boa-supplied-p.1 (&optional (bar t barp)))) bar barp))) (let ((b1 (make-boa-supplied-p.1)) (b2 (make-boa-supplied-p.1 t))) (assert (eq t (boa-supplied-p.1-bar b1))) (assert (eq t (boa-supplied-p.1-bar b2))) (assert (eq nil (boa-supplied-p.1-barp b1))) (assert (eq t (boa-supplied-p.1-barp b2))))) (with-test (:name (:boa-supplied-p &key)) (handler-bind ((warning #'error)) (eval `(defstruct (boa-supplied-p.2 (:constructor make-boa-supplied-p.2 (&key (bar t barp)))) bar barp))) (let ((b1 (make-boa-supplied-p.2)) (b2 (make-boa-supplied-p.2 :bar t))) (assert (eq t (boa-supplied-p.2-bar b1))) (assert (eq t (boa-supplied-p.2-bar b2))) (assert (eq nil (boa-supplied-p.2-barp b1))) (assert (eq t (boa-supplied-p.2-barp b2))))) (defstruct structure-with-predicate) (defclass class-to-be-redefined () ()) (let ((x (make-instance 'class-to-be-redefined))) (defun function-trampoline (fun) (funcall fun x))) (with-test (:name (:struct-predicate :obsolete-instance)) (defclass class-to-be-redefined () ((a :initarg :a :initform 1))) (function-trampoline #'structure-with-predicate-p)) (with-test (:name (:defstruct :not-toplevel-silent)) (let ((sb-ext:*evaluator-mode* :compile)) (handler-bind ((warning #'error)) (eval `(let () (defstruct defstruct-no-warning-not-at-toplevel bar)))))) (with-test (:name :bug-941102) (let ((test `((defstruct bug-941102) (setf (find-class 'bug-941102-alias) (find-class 'bug-941102)) (setf (find-class 'bug-941102-alias) nil)))) (multiple-value-bind (warn fail) (ctu:file-compile test :load t) (assert (not warn)) (assert (not fail))) (multiple-value-bind (warn2 fail2) (ctu:file-compile test) (assert (not warn2)) (assert (not fail2))))) (with-test (:name (defstruct :constant-slot-names)) (defstruct defstruct-constant-slot-names t) (assert (= 3 (defstruct-constant-slot-names-t (make-defstruct-constant-slot-names :t 3)))))