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Common Lisp implementation running on the JVM
;;; compiler-pass2.lisp
;;;
;;; Copyright (C) 2003-2008 Peter Graves
;;; Copyright (C) 2008 Ville Voutilainen
;;; $Id$
;;;
;;; This program is free software; you can redistribute it and/or
;;; modify it under the terms of the GNU General Public License
;;; as published by the Free Software Foundation; either version 2
;;; of the License, or (at your option) any later version.
;;;
;;; This program is distributed in the hope that it will be useful,
;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;;; GNU General Public License for more details.
;;;
;;; You should have received a copy of the GNU General Public License
;;; along with this program; if not, write to the Free Software
;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
;;;
;;; As a special exception, the copyright holders of this library give you
;;; permission to link this library with independent modules to produce an
;;; executable, regardless of the license terms of these independent
;;; modules, and to copy and distribute the resulting executable under
;;; terms of your choice, provided that you also meet, for each linked
;;; independent module, the terms and conditions of the license of that
;;; module. An independent module is a module which is not derived from
;;; or based on this library. If you modify this library, you may extend
;;; this exception to your version of the library, but you are not
;;; obligated to do so. If you do not wish to do so, delete this
;;; exception statement from your version.
(in-package "JVM")
(eval-when (:compile-toplevel :load-toplevel :execute)
(require "LOOP")
(require "FORMAT")
(require "CLOS")
(require "PRINT-OBJECT")
(require "COMPILER-TYPES")
(require "KNOWN-FUNCTIONS")
(require "KNOWN-SYMBOLS")
(require "DUMP-FORM")
(require "JVM-INSTRUCTIONS")
(require "JVM-CLASS-FILE")
(require "JVM")
(require "COMPILER-PASS1")
(require "JAVA"))
(declaim (inline pool-name pool-string pool-name-and-type
pool-class pool-field pool-method pool-int
pool-float pool-long pool-double))
(declaim (special *memory-class-loader*))
(declaim (inline pool-name pool-name-and-type pool-string
pool-field pool-method pool-int pool-float pool-long
pool-double add-exception-handler))
(defun pool-name (name)
(pool-add-utf8 *pool* name))
(defun pool-name-and-type (name type)
(pool-add-name/type *pool* name type))
(defun pool-class (name)
(pool-add-class *pool* name))
(defun pool-string (string)
(pool-add-string *pool* string))
(defun pool-field (class-name field-name type-name)
(pool-add-field-ref *pool* class-name field-name type-name))
(defun pool-method (class-name method-name type-name)
(pool-add-method-ref *pool* class-name method-name type-name))
(defun pool-int (int)
(pool-add-int *pool* int))
(defun pool-float (float)
(pool-add-float *pool* float))
(defun pool-long (long)
(pool-add-long *pool* long))
(defun pool-double (double)
(pool-add-double *pool* double))
(defun add-exception-handler (start end handler type)
(code-add-exception-handler *current-code-attribute*
start end handler type))
(defknown emit-push-nil () t)
(declaim (inline emit-push-nil))
(defun emit-push-nil ()
(emit-getstatic +lisp+ "NIL" +lisp-symbol+))
(defknown emit-push-nil-symbol () t)
(declaim (inline emit-push-nil-symbol))
(defun emit-push-nil-symbol ()
(emit-getstatic +lisp-nil+ "NIL" +lisp-symbol+))
(defknown emit-push-t () t)
(declaim (inline emit-push-t))
(defun emit-push-t ()
(emit-getstatic +lisp+ "T" +lisp-symbol+))
(defknown emit-push-false (t) t)
(defun emit-push-false (representation)
(declare (optimize speed (safety 0)))
(ecase representation
(:boolean
(emit 'iconst_0))
((nil)
(emit-push-nil))))
(defknown emit-push-true (t) t)
(defun emit-push-true (representation)
(declare (optimize speed (safety 0)))
(ecase representation
(:boolean
(emit 'iconst_1))
((nil)
(emit-push-t))))
(defknown emit-push-constant-int (fixnum) t)
(defun emit-push-constant-int (n)
(case n
(-1
(emit 'iconst_m1))
(0
(emit 'iconst_0))
(1
(emit 'iconst_1))
(2
(emit 'iconst_2))
(3
(emit 'iconst_3))
(4
(emit 'iconst_4))
(5
(emit 'iconst_5))
(t
(if (<= -128 n 127)
(emit 'bipush n)
(if (<= -32768 n 32767)
(emit 'sipush n)
(emit 'ldc (pool-int n)))))))
(defknown emit-push-constant-long (integer) t)
(defun emit-push-constant-long (n)
(case n
(0 (emit 'lconst_0))
(1 (emit 'lconst_1))
(t
(emit 'ldc2_w (pool-long n)))))
(defknown emit-push-constant-float (single-float) t)
(defun emit-push-constant-float (n)
(case n
(0.0s0 (emit 'fconst_0))
(1.0s0 (emit 'fconst_1))
(2.0s0 (emit 'fconst_2))
(t (emit 'ldc (pool-float n)))))
(defknown emit-push-constant-double (double-float) t)
(defun emit-push-constant-double (n)
(case n
(0.0d0 (emit 'dconst_0))
(1.0d0 (emit 'dconst_1))
(t (emit 'ldc2_w (pool-double n)))))
(defknown emit-dup (symbol) t)
(defun emit-dup (representation &key (past nil past-supplied-p))
"Emits the 'dup' instruction required to duplicate `representation'.
If `past' is specified, the newly duplicated value is inserted on the
stack past the top-most value, which is assumed to be of the representation
passed in `past'."
(emit
(nth (if past-supplied-p
(representation-size past) 0)
(ecase (representation-size representation)
(1 '(dup dup_x1 dup_x2))
(2 '(dup2 dup2_x1 dup2_x2))))))
(defknown emit-swap (symbol symbol) t)
(defun emit-swap (rep1 rep2)
"Swaps 2 values on the stack,
the top-most value's representation being 'rep1'."
(let ((r1-size (representation-size rep1))
(r2-size (representation-size rep2)))
(cond ((and (= 1 r1-size)
(= 1 r2-size))
(emit 'swap))
((and (= 1 r1-size)
(= 2 r2-size))
(emit 'dup2_x1)
(emit 'pop2))
((and (= 2 r1-size)
(= 1 r2-size))
(emit 'dup_x2)
(emit 'pop))
((and (= 2 r1-size)
(= 2 r2-size))
(emit 'dup2_x2)
(emit 'pop2)))))
(declaim (ftype (function * t) emit-invokestatic))
(defun emit-invokestatic (class-name method-name arg-types return-type)
(let* ((stack-effect (apply #'descriptor-stack-effect return-type arg-types))
(index (pool-add-method-ref *pool* class-name
method-name (cons return-type arg-types)))
(instruction (%emit 'invokestatic index)))
(setf (instruction-stack instruction) stack-effect)))
(declaim (ftype (function t string) pretty-java-class))
(defun pretty-java-class (class)
(cond ((equal class +lisp-object+)
"LispObject")
((equal class +lisp-symbol+)
"Symbol")
((equal class +lisp-thread+)
"LispThread")
(t
class)))
(defknown emit-invokevirtual (t t t t) t)
(defun emit-invokevirtual (class-name method-name arg-types return-type)
(let* ((stack-effect (apply #'descriptor-stack-effect return-type arg-types))
(index (pool-add-method-ref *pool* class-name
method-name (cons return-type arg-types)))
(instruction (%emit 'invokevirtual index)))
(declare (type (signed-byte 8) stack-effect))
(let ((explain *explain*))
(when (and explain (memq :java-calls explain))
(unless (string= method-name "execute")
(format t "; call to ~A ~A.~A(~{~A~^,~})~%"
(pretty-java-type return-type)
(pretty-java-class class-name)
method-name
(mapcar 'pretty-java-type arg-types)))))
(setf (instruction-stack instruction) (1- stack-effect))))
(defknown emit-invokespecial-init (string list) t)
(defun emit-invokespecial-init (class-name arg-types)
(let* ((stack-effect (apply #'descriptor-stack-effect :void arg-types))
(index (pool-add-method-ref *pool* class-name
"" (cons nil arg-types)))
(instruction (%emit 'invokespecial index)))
(declare (type (signed-byte 8) stack-effect))
(setf (instruction-stack instruction) (1- stack-effect))))
(defknown pretty-java-type (t) string)
(defun pretty-java-type (type)
(let ((arrayp nil)
(pretty-string nil))
(when (and (stringp type)
(> (length type) 0)
(char= (char type 0) #\[))
(setf arrayp t
type (subseq type 1)))
(setf pretty-string
(cond ((equal type +lisp-object+)
"LispObject")
((equal type +lisp-symbol+)
"Symbol")
((equal type +lisp-thread+)
"LispThread")
((equal type :char)
"char")
((equal type :int)
"int")
((equal type :boolean)
"boolean")
((or (null type)
(eq type :void))
"void")
(t
type)))
(when arrayp
(setf pretty-string (concatenate 'string pretty-string "[]")))
pretty-string))
(declaim (inline emit-getstatic emit-putstatic))
(defknown emit-getstatic (t t t) t)
(defun emit-getstatic (class-name field-name type)
(let ((index (pool-add-field-ref *pool* class-name field-name type)))
(%emit 'getstatic index)))
(defknown emit-putstatic (t t t) t)
(defun emit-putstatic (class-name field-name type)
(let ((index (pool-add-field-ref *pool* class-name field-name type)))
(%emit 'putstatic index)))
(declaim (inline emit-getfield emit-putfield))
(defknown emit-getfield (t t t) t)
(defun emit-getfield (class-name field-name type)
(let* ((index (pool-add-field-ref *pool* class-name field-name type)))
(%emit 'getfield index)))
(defknown emit-putfield (t t t) t)
(defun emit-putfield (class-name field-name type)
(let* ((index (pool-add-field-ref *pool* class-name field-name type)))
(%emit 'putfield index)))
(defknown emit-new (t) t)
(declaim (inline emit-new emit-anewarray emit-checkcast emit-instanceof))
(defun emit-new (class-name)
(%emit 'new (pool-class class-name)))
(defknown emit-anewarray (t) t)
(defun emit-anewarray (class-name)
(apply #'%emit 'anewarray (u2 (pool-class class-name))))
(defknown emit-checkcast (t) t)
(defun emit-checkcast (class-name)
(apply #'%emit 'checkcast (list (pool-class class-name))))
(defknown emit-instanceof (t) t)
(defun emit-instanceof (class-name)
(apply #'%emit 'instanceof (list (pool-class class-name))))
(defvar type-representations '((:int fixnum)
(:long (integer #.most-negative-java-long
#.most-positive-java-long))
(:float single-float)
(:double double-float)
(:char base-char character)
(:boolean boolean)
)
"Lists the widest Lisp types to be stored in each of the Java primitives
supported (and used) by the compiler.")
(defun type-representation (the-type)
"Converts a type specification or compiler type into a representation."
(when (null the-type)
(return-from type-representation))
(do* ((types type-representations (cdr types)))
((endp types) nil)
(do* ((type-list (cdr (car types)) (cdr type-list))
(type (car type-list) (car type-list)))
((endp type-list))
(when (or (subtypep the-type type)
(compiler-subtypep the-type (make-compiler-type type)))
(return-from type-representation (caar types))))))
(defknown emit-unbox-boolean () t)
(defun emit-unbox-boolean ()
(emit-instanceof +lisp-nil+)
(emit 'iconst_1)
(emit 'ixor)) ;; 1 -> 0 && 0 -> 1: in other words, negate the low bit
(defknown emit-unbox-character () t)
(defun emit-unbox-character ()
(cond ((> *safety* 0)
(emit-invokestatic +lisp-character+ "getValue"
(lisp-object-arg-types 1) :char))
(t
(emit-checkcast +lisp-character+)
(emit-getfield +lisp-character+ "value" :char))))
;; source type /
;; targets :boolean :char :int :long :float :double
(defvar rep-conversion `((NIL . #( ,#'emit-unbox-boolean
,#'emit-unbox-character
"intValue" "longValue"
"floatValue" "doubleValue"))
(:boolean . #( NIL :err :err :err :err :err))
(:char . #( 1 NIL :err :err :err :err))
(:int . #( 1 :err NIL i2l i2f i2d))
(:long . #( 1 :err l2i NIL l2f l2d))
(:float . #( 1 :err :err :err NIL f2d))
(:double . #( 1 :err :err :err d2f NIL)))
"Contains a table with operations to be performed to do
internal representation conversion.")
(defvar rep-classes
`((:boolean . ,+lisp-object+)
(:char . ,+lisp-character+)
(:int . ,+lisp-integer+)
(:long . ,+lisp-integer+)
(:float . ,+lisp-single-float+)
(:double . ,+lisp-double-float+))
"Lists the class on which to call the `getInstance' method on,
when converting the internal representation to a LispObject.")
(defun convert-representation (in out)
"Converts the value on the stack in the `in' representation
to a value on the stack in the `out' representation."
(when (eql in out)
;; no-op
(return-from convert-representation))
(when (null out)
;; Convert back to a lisp object
(when in
(let ((class (cdr (assoc in rep-classes))))
(emit-invokestatic class "getInstance" (list in) class)))
(return-from convert-representation))
(let* ((in-map (cdr (assoc in rep-conversion)))
(op-num (position out '(:boolean :char :int :long :float :double)))
(op (aref in-map op-num)))
(when op
;; Convert from one internal representation into another
(assert (neq op :err))
(cond ((eql op 1)
(emit-move-from-stack nil in)
(emit 'iconst_1))
((functionp op)
(funcall op))
((stringp op)
(emit-invokevirtual +lisp-object+ op nil out))
(t
(emit op))))))
(defvar common-representations '((:int :long :long)
(:int :float :double)
(:int :double :double)
(:float :int :double)
(:float :double :double)
(:double :int :double)
(:double :float :double))
"Representations to convert unequal representations to, in order
to get the correct (exact where required) comparisons.")
(defun common-representation (rep1 rep2)
(when (eq rep1 rep2)
(return-from common-representation rep1))
(do* ((remaining common-representations (cdr remaining))
(rep (car remaining) (car remaining)))
((endp remaining))
(destructuring-bind
(r1 r2 result) rep
(when (and (eq rep1 r1) (eq rep2 r2))
(return-from common-representation result)))))
;; Index of local variable used to hold the current thread.
(defvar *thread* nil)
(defvar *initialize-thread-var* nil)
(defun maybe-initialize-thread-var ()
(when *initialize-thread-var*
(emit-invokestatic +lisp-thread+ "currentThread" nil +lisp-thread+)
(astore *thread*)
(setf *initialize-thread-var* nil)))
(defknown ensure-thread-var-initialized () t)
(declaim (inline ensure-thread-var-initialized))
(defun ensure-thread-var-initialized ()
(setf *initialize-thread-var* t))
(defknown emit-push-current-thread () t)
(defun emit-push-current-thread ()
(declare (optimize speed))
(ensure-thread-var-initialized)
(aload *thread*))
(defun variable-local-p (variable)
"Return non-NIL if `variable' is a local variable.
Special variables are not considered local."
(or (variable-register variable) ;; either register or index
(variable-index variable))) ;; is non-nil for local variables
(defun emit-load-local-variable (variable)
"Loads a local variable in the top stack position."
(aver (variable-local-p variable))
(if (variable-register variable)
(aload (variable-register variable))
(progn
(aload (compiland-argument-register *current-compiland*))
(emit-push-constant-int (variable-index variable))
(emit 'aaload))))
(defun emit-push-variable-name (variable)
(emit-load-externalized-object (variable-name variable)))
(defknown generate-instanceof-type-check-for-variable (t t) t)
(defun generate-instanceof-type-check-for-variable (variable expected-type)
"Generate a type check for `variable'.
The stack pointer is returned to the position from
before the emitted code: the code is 'stack-neutral'."
(declare (type symbol expected-type))
(unless (variable-local-p variable)
(return-from generate-instanceof-type-check-for-variable))
(let ((instanceof-class (ecase expected-type
(SYMBOL +lisp-symbol+)
(CHARACTER +lisp-character+)
(CONS +lisp-cons+)
(HASH-TABLE +lisp-hash-table+)
(FIXNUM +lisp-fixnum+)
(STREAM +lisp-stream+)
(STRING +lisp-abstract-string+)
(VECTOR +lisp-abstract-vector+)))
(expected-type-java-symbol-name (case expected-type
(HASH-TABLE "HASH_TABLE")
(t
(symbol-name expected-type))))
(LABEL1 (gensym)))
(emit-load-local-variable variable)
(emit-instanceof instanceof-class)
(emit 'ifne LABEL1)
(emit-load-local-variable variable)
(emit-getstatic +lisp-symbol+ expected-type-java-symbol-name
+lisp-symbol+)
(emit-invokestatic +lisp+ "type_error"
(lisp-object-arg-types 2) +lisp-object+)
(emit 'areturn) ; Needed for JVM stack consistency.
(label LABEL1))
t)
(defun find-type-for-type-check (declared-type)
(if (eq declared-type :none) nil
(or
(when (fixnum-type-p declared-type) 'FIXNUM)
(find-if #'(lambda (type) (eq type declared-type))
'(SYMBOL CHARACTER CONS HASH-TABLE))
(find-if #'(lambda (type) (subtypep declared-type type))
'(STRING VECTOR STREAM)))))
(defknown generate-type-check-for-variable (t) t)
(defun generate-type-check-for-variable (variable)
(let ((type-to-use
(find-type-for-type-check (variable-declared-type variable))))
(when type-to-use
(generate-instanceof-type-check-for-variable variable type-to-use))))
(defknown maybe-generate-type-check (t) t)
(defun maybe-generate-type-check (variable)
(unless (or (zerop *safety*)
(variable-special-p variable)
;###
(eq (variable-representation variable) :int))
(let ((declared-type (variable-declared-type variable)))
(unless (eq declared-type :none)
(unless (subtypep (derive-type (variable-initform variable)) declared-type)
(generate-type-check-for-variable variable))))))
(defknown generate-type-checks-for-variables (list) t)
(defun generate-type-checks-for-variables (variables)
(unless (zerop *safety*)
(dolist (variable variables)
(unless (variable-special-p variable)
(generate-type-check-for-variable variable)))
t))
(defun generate-arg-count-check (arity)
(aver (fixnump arity))
(aver (not (minusp arity)))
(aver (not (null (compiland-argument-register *current-compiland*))))
(let ((label1 (gensym)))
(aload (compiland-argument-register *current-compiland*))
(emit 'arraylength)
(emit-push-constant-int arity)
(emit 'if_icmpeq label1)
(aload 0) ; this
(emit-invokevirtual *this-class* "argCountError" nil nil)
(label label1)))
(defun maybe-generate-interrupt-check ()
(unless (> *speed* *safety*)
(let ((label1 (gensym)))
(emit-getstatic +lisp+ "interrupted" :boolean)
(emit 'ifeq label1)
(emit-invokestatic +lisp+ "handleInterrupt" nil nil)
(label label1))))
(defknown single-valued-p (t) t)
(defun single-valued-p (form)
(cond ((node-p form)
(cond ((tagbody-node-p form)
t)
((block-node-p form)
(and (single-valued-p (car (last (node-form form))))
;; return-from value forms
(every #'single-valued-p
(block-return-value-forms form))))
((or (flet-node-p form)
(labels-node-p form)
(let/let*-node-p form)
(m-v-b-node-p form)
(progv-node-p form)
(locally-node-p form)
(synchronized-node-p form))
(single-valued-p (car (last (node-form form)))))
((unwind-protect-node-p form)
(single-valued-p (second (node-form form))))
((catch-node-p form)
nil)
((jump-node-p form)
(single-valued-p (node-form form)))
((exception-protected-node-p form)
(single-valued-p (exception-protected-form form)))
(t
(assert (not "SINGLE-VALUED-P unhandled NODE-P branch")))))
((var-ref-p form)
t)
((atom form)
t)
(t
(let ((op (%car form))
result-type
compiland)
(assert (not (member op '(LET LET* FLET LABELS TAGBODY CATCH
MULTIPLE-VALUE-BIND
UNWIND-PROTECT BLOCK PROGV
LOCALLY))))
(cond ((eq op 'IF)
(and (single-valued-p (third form))
(single-valued-p (fourth form))))
((eq op 'PROGN)
(single-valued-p (car (last form))))
((memq op '(AND OR))
(every #'single-valued-p (cdr form)))
((eq op 'RETURN-FROM)
(single-valued-p (third form)))
((memq op '(THE TRULY-THE))
(single-valued-p (third form)))
((setf result-type
(or (function-result-type op)
(and (proclaimed-ftype op)
(ftype-result-type (proclaimed-ftype op)))))
(cond ((eq result-type '*)
nil)
((atom result-type)
t)
((eq (%car result-type) 'VALUES)
(= (length result-type) 2))
(t
t)))
((and (setf compiland *current-compiland*)
(eq op (compiland-name compiland)))
(compiland-%single-valued-p compiland))
(t
nil))))))
(defknown emit-clear-values () t)
(defun emit-clear-values ()
(declare (optimize speed (safety 0)))
(ensure-thread-var-initialized)
(emit 'clear-values *thread*))
(defknown maybe-emit-clear-values (&rest t) t)
(defun maybe-emit-clear-values (&rest forms)
(declare (optimize speed))
(dolist (form forms)
(unless (single-valued-p form)
(ensure-thread-var-initialized)
(emit 'clear-values *thread*)
(return))))
(defun compile-forms-and-maybe-emit-clear-values (&rest forms-and-compile-args)
(let ((forms-for-emit-clear
(loop for (form arg1 arg2) on forms-and-compile-args by #'cdddr
do (compile-form form arg1 arg2)
collecting form)))
(apply #'maybe-emit-clear-values forms-for-emit-clear)))
(declaim (special *saved-operands* *operand-representations*))
(defmacro with-operand-accumulation ((&body argument-accumulation-body)
&body call-body)
"Macro used to operand-stack-safely collect arguments in the
`argument-accumulation-body' to be available on the stack upon entry of the
`call-body'. The argument-accumulation-body code may not assume arguments
are actually on the stack while accumulating.
This macro closes over a code-generating block. Operands can be collected
using the `accumulate-operand', `compile-operand', `emit-variable-operand'
and `emit-load-externalized-object-operand'."
`(let (*saved-operands*
*operand-representations*
(*register* *register*)
) ;; hmm can we do this?? either body
;; could allocate registers ...
,@argument-accumulation-body
(load-saved-operands)
,@call-body))
(defmacro accumulate-operand ((representation &key unsafe-p)
&body body)
"Macro used to collect a single operand.
This macro closes over a code-generating block. The generated code should
leave a single operand on the stack, with representation `representation'.
The value `unsafe-p', when provided, is an expression evaluated at run time
to indicate if the body is opstack unsafe."
`(progn
,@(when unsafe-p
`((when ,unsafe-p
(save-existing-operands))))
,@body
(save-operand ,representation)))
(defun load-saved-operands ()
"Load any operands which have been saved into registers
back onto the stack in preparation of the execution of the opcode."
(mapcar #'emit-push-register
(reverse *saved-operands*)
(reverse *operand-representations*)))
(defun save-existing-operands ()
"If any operands have been compiled to the stack,
save them in registers."
(when (null *saved-operands*)
(dolist (representation *operand-representations*)
(let ((register (allocate-register representation)))
(push register *saved-operands*)
(emit-move-from-stack register representation)))
(setf *saved-operands* (nreverse *saved-operands*))))
(defun save-operand (representation)
"Saves an operand from the stack (with `representation') to
a register and updates associated operand collection variables."
(push representation *operand-representations*)
(when *saved-operands*
(let ((register (allocate-register representation)))
(push register *saved-operands*)
(emit-move-from-stack register representation))))
(defun compile-operand (form representation &optional cast)
"Compiles `form' into `representation', storing the resulting value
on the operand stack, if it's safe to do so. Otherwise stores the value
in a register"
(let ((unsafe (or *saved-operands*
(some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks form)))))
(when (and unsafe (null *saved-operands*))
(save-existing-operands))
(compile-form form 'stack representation)
(when cast
(emit-checkcast cast))
(when unsafe
(let ((register (allocate-register representation)))
(push register *saved-operands*)
(emit-move-from-stack register representation)))
(push representation *operand-representations*)))
(defun emit-variable-operand (variable)
"Pushes a variable onto the operand stack, if it's safe to do so. Otherwise
stores the value in a register."
(push (variable-representation variable) *operand-representations*)
(cond
((and *saved-operands*
(variable-register variable))
;; we're in 'safe mode' and the variable is in a register,
;; instead of binding a new register, just load the existing one
(push (variable-register variable) *saved-operands*))
(t
(emit-push-variable variable)
(when *saved-operands* ;; safe-mode
(let ((register (allocate-register (variable-representation variable))))
(push register *saved-operands*)
(emit-move-from-stack register (variable-representation variable)))))))
(defun emit-register-operand (register representation)
(push representation *operand-representations*)
(cond (*saved-operands*
(push register *saved-operands*))
(t
(emit-push-register register representation))))
(defun emit-thread-operand ()
(ensure-thread-var-initialized)
(emit-register-operand *thread* nil))
(defun emit-load-externalized-object-operand (object)
(push nil *operand-representations*)
(emit-load-externalized-object object)
(when *saved-operands* ;; safe-mode
(let ((register (allocate-register nil)))
(push register *saved-operands*)
(emit 'astore register))))
(defknown emit-unbox-fixnum () t)
(defun emit-unbox-fixnum ()
(declare (optimize speed))
(cond ((= *safety* 3)
(emit-invokestatic +lisp-fixnum+ "getValue"
(lisp-object-arg-types 1) :int))
(t
(emit-checkcast +lisp-fixnum+)
(emit-getfield +lisp-fixnum+ "value" :int))))
(defknown emit-unbox-long () t)
(defun emit-unbox-long ()
(emit-invokestatic +lisp-bignum+ "longValue"
(lisp-object-arg-types 1) :long))
(defknown emit-unbox-float () t)
(defun emit-unbox-float ()
(declare (optimize speed))
(cond ((= *safety* 3)
(emit-invokestatic +lisp-single-float+ "getValue"
(lisp-object-arg-types 1) :float))
(t
(emit-checkcast +lisp-single-float+)
(emit-getfield +lisp-single-float+ "value" :float))))
(defknown emit-unbox-double () t)
(defun emit-unbox-double ()
(declare (optimize speed))
(cond ((= *safety* 3)
(emit-invokestatic +lisp-double-float+ "getValue"
(lisp-object-arg-types 1) :double))
(t
(emit-checkcast +lisp-double-float+)
(emit-getfield +lisp-double-float+ "value" :double))))
(defknown fix-boxing (t t) t)
(defun fix-boxing (required-representation derived-type)
"Generate code to convert a boxed LispObject on the stack to the specified
representation, based on the derived type of the LispObject."
(cond ((null required-representation)) ; Nothing to do.
((eq required-representation :int)
(cond ((and (fixnum-type-p derived-type)
(< *safety* 3))
(emit-checkcast +lisp-fixnum+)
(emit-getfield +lisp-fixnum+ "value" :int))
(t
(emit-invokevirtual +lisp-object+ "intValue" nil :int))))
((eq required-representation :char)
(emit-unbox-character))
((eq required-representation :boolean)
(emit-unbox-boolean))
((eq required-representation :long)
(emit-invokevirtual +lisp-object+ "longValue" nil :long))
((eq required-representation :float)
(emit-invokevirtual +lisp-object+ "floatValue" nil :float))
((eq required-representation :double)
(emit-invokevirtual +lisp-object+ "doubleValue" nil :double))
(t (assert nil))))
(defknown emit-move-from-stack (t &optional t) t)
(defun emit-move-from-stack (target &optional representation)
(declare (optimize speed))
(cond ((null target)
(ecase representation
((:long :double)
(emit 'pop2))
((NIL :int :boolean :char :float)
(emit 'pop))))
((eq target 'stack)) ; Nothing to do.
((fixnump target)
;; A register.
(emit (ecase representation
((:int :boolean :char)
'istore)
(:long 'lstore)
(:float 'fstore)
(:double 'dstore)
((nil) 'astore))
target))
(t
(sys::%format t "emit-move-from-stack general case~%")
(aver nil))))
(defknown emit-push-register (t &optional t) t)
(defun emit-push-register (source &optional representation)
(declare (optimize speed))
(assert (fixnump source))
(emit (ecase representation
((:int :boolean :char)
'iload)
(:long 'lload)
(:float 'fload)
(:double 'dload)
((nil) 'aload))
source))
;; Expects value on stack.
(defknown emit-invoke-method (t t t) t)
(defun emit-invoke-method (method-name target representation)
(emit-invokevirtual +lisp-object+ method-name nil +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
;; "In addition to situations for which the standard specifies that conditions
;; of type WARNING must or might be signaled, warnings might be signaled in
;; situations where the compiler can determine that the consequences are
;; undefined or that a run-time error will be signaled. Examples of this
;; situation are as follows: violating type declarations, altering or assigning
;; the value of a constant defined with DEFCONSTANT, calling built-in Lisp
;; functions with a wrong number of arguments or malformed keyword argument
;; lists, and using unrecognized declaration specifiers." (3.2.5)
(defun check-number-of-args (form n &optional minimum)
(declare (type fixnum n))
(let* ((op (car form))
(args (cdr form))
(ok (if minimum
(>= (length args) n)
(= (length args) n))))
(declare (type boolean ok))
(unless ok
(funcall (if (eq (symbol-package op) +cl-package+)
#'compiler-warn ; See above!
#'compiler-style-warn)
"Wrong number of arguments for ~A (expected~:[~; at least~] ~D, but received ~D)."
op minimum n (length args)))
ok))
(defknown check-arg-count (t fixnum) t)
(defun check-arg-count (form n)
(check-number-of-args form n))
(declaim (ftype (function (t fixnum) t) check-min-args))
(defun check-min-args (form n)
(check-number-of-args form n t))
(defun emit-constructor-lambda-name (lambda-name)
(cond ((and lambda-name (symbolp lambda-name) (symbol-package (truly-the symbol lambda-name)))
(emit 'ldc (pool-string (symbol-name (truly-the symbol lambda-name))))
(emit 'ldc (pool-string (package-name (symbol-package (truly-the symbol lambda-name)))))
(emit-invokestatic +lisp+ "internInPackage"
(list +java-string+ +java-string+)
+lisp-symbol+))
(t
;; No name.
(emit-push-nil))))
(defun emit-constructor-lambda-list (lambda-list)
(if lambda-list
(serialize-object lambda-list)
(emit-push-nil)))
(defun emit-read-from-string (object)
(emit-constructor-lambda-list object))
(defun make-constructor (class lambda-name args)
(let* ((*compiler-debug* nil)
(method (make-jvm-method :constructor :void nil
:flags '(:public)))
;; We don't normally need to see debugging output for constructors.
(super (class-file-superclass class))
opt-params-register
key-params-register
req-count
rest-p
keys-p
more-keys-p
alp-register)
(with-code-to-method (class method)
(allocate-register nil)
(unless (eq super +lisp-compiled-primitive+)
(multiple-value-bind
(req opt key key-p rest
allow-other-keys-p)
(parse-lambda-list args)
(setf rest-p rest
more-keys-p allow-other-keys-p
keys-p key-p
req-count (length req))
(macrolet
((parameters-to-array ((param params register class) &body body)
(let ((count-sym (gensym)))
`(progn
(emit-push-constant-int (length ,params))
(emit-anewarray ,class)
(astore (setf ,register *registers-allocated*))
(allocate-register nil)
(do* ((,count-sym 0 (1+ ,count-sym))
(,params ,params (cdr ,params))
(,param (car ,params) (car ,params)))
((endp ,params))
(declare (ignorable ,param))
(aload ,register)
(emit-push-constant-int ,count-sym)
(emit-new ,class)
(emit 'dup)
,@body
(emit 'aastore))))))
(parameters-to-array (param opt opt-params-register
+alp-optional-parameter+)
(if (null (third param)) ;; supplied-p or not?
(emit 'iconst_0)
(emit 'iconst_1))
(emit-read-from-string (second param)) ;; initform
(emit-invokespecial-init +alp-optional-parameter+
(list :boolean +lisp-object+)))
(parameters-to-array (param key key-params-register
+alp-keyword-parameter+)
(if (null (third param)) ;; supplied-p or not?
(emit 'iconst_0)
(emit 'iconst_1))
(emit-read-from-string (second param)) ;; initform
(let ((keyword (fourth param)))
(if (keywordp keyword)
(progn
(emit 'ldc (pool-string (symbol-name keyword)))
(emit-invokestatic +lisp+ "internKeyword"
(list +java-string+) +lisp-symbol+))
;; symbol is not really a keyword; yes, that's allowed!
(progn
(emit 'ldc (pool-string (symbol-name keyword)))
(emit 'ldc (pool-string
(package-name (symbol-package keyword))))
(emit-invokestatic +lisp+ "internInPackage"
(list +java-string+ +java-string+)
+lisp-symbol+))))
(emit-invokespecial-init +alp-keyword-parameter+
(list :boolean +lisp-object+
+lisp-symbol+))))))
(aload 0) ;; this
(cond ((eq super +lisp-compiled-primitive+)
(emit-constructor-lambda-name lambda-name)
(emit-constructor-lambda-list args)
(emit-invokespecial-init super (lisp-object-arg-types 2)))
((equal super +lisp-compiled-closure+)
;;### only needs EQ when SUPER is guaranteed to be CLASS-NAME
(emit-new +argument-list-processor+)
(emit 'dup)
(emit 'dup)
(astore (setf alp-register (allocate-register nil)))
(emit 'aconst_null)
(emit-push-int req-count)
(aload opt-params-register)
(aload key-params-register)
(if keys-p
(emit 'iconst_1)
(emit 'iconst_0))
(if more-keys-p
(emit 'iconst_1)
(emit 'iconst_0))
(if rest-p
(emit-push-t)
(emit 'aconst_null))
(emit-invokespecial-init +argument-list-processor+
(list
+lisp-operator+
:int
(class-array +alp-optional-parameter+)
(class-array +alp-keyword-parameter+)
:boolean
:boolean
+lisp-symbol+))
(emit-invokespecial-init super
(list +argument-list-processor+))
(aload alp-register)
(aload 0)
(emit-invokevirtual +argument-list-processor+
"setFunction"
(list +lisp-operator+) nil))
(t
(sys::%format t "unhandled superclass ~A for ~A~%"
super
(abcl-class-file-class-name class))
(aver nil))))
method))
(defun make-static-initializer (class)
(let ((*compiler-debug* nil)
(method (make-jvm-method :static-initializer
:void nil :flags '(:public :static))))
;; We don't normally need to see debugging output for .
(with-code-to-method (class method)
method)))
(defvar *source-line-number* nil)
(defun finish-class (class stream)
"Finalizes the `class' and writes the result to `stream'.
The compiler calls this function to indicate it doesn't want to
extend the class any further."
(with-code-to-method (class (abcl-class-file-constructor class))
(emit 'return))
(with-code-to-method (class (abcl-class-file-static-initializer class))
(if (= 0 (length *code*))
(class-remove-method class (abcl-class-file-static-initializer class))
(emit 'return)))
(when *compiler-debug*
(print "; Writing class file ")
(print (abcl-class-file-class-name class))
(terpri))
(finalize-class-file class)
(write-class-file class stream))
(defknown declare-field (t t t) t)
(defun declare-field (name descriptor)
(let ((field (make-field name descriptor :flags '(:final :static))))
(class-add-field *class-file* field)))
(defknown sanitize (symbol) string)
(defun sanitize (symbol)
(declare (type symbol symbol))
(declare (optimize speed))
(let* ((input (symbol-name symbol))
(output (make-array (length input) :fill-pointer 0 :element-type 'character)))
(dotimes (i (length input))
(declare (type fixnum i))
(let ((c (char-upcase (char input i))))
(cond ((<= #.(char-code #\A) (char-code c) #.(char-code #\Z))
(vector-push c output))
((<= #.(char-code #\0) (char-code c) #.(char-code #\9))
(vector-push c output))
((eql c #\-)
(vector-push #\_ output)))))
(when (plusp (length output))
output)))
(defvar *declare-inline* nil)
(defmacro declare-with-hashtable (declared-item hashtable hashtable-var
item-var &body body)
`(let* ((,hashtable-var ,hashtable)
(,item-var (gethash1 ,declared-item ,hashtable-var)))
(declare (type hash-table ,hashtable-var))
(unless ,item-var
,@body)
,item-var))
;; The protocol of the serialize-* functions is to serialize
;; the type to which they apply and emit code which leaves the
;; restored object on the stack.
;; The functions may generate only Java code, or decide to defer
;; some of the process of restoring the object to the reader. The
;; latter is generally applicable to more complex structures.
;; This way, the serialize-* functions can be used to depend on
;; each other to serialize nested constructs. They are also the
;; building blocks of the EMIT-LOAD-EXTERNALIZED-OBJECT function,
;; which is called from the compiler.
(defun serialize-integer (n)
"Generates code to restore a serialized integer."
(cond((<= 0 n 255)
(emit-getstatic +lisp-fixnum+ "constants" +lisp-fixnum-array+)
(emit-push-constant-int n)
(emit 'aaload))
((<= most-negative-fixnum n most-positive-fixnum)
(emit-push-constant-int n)
(emit-invokestatic +lisp-fixnum+ "getInstance"
'(:int) +lisp-fixnum+))
((<= most-negative-java-long n most-positive-java-long)
(emit-push-constant-long n)
(emit-invokestatic +lisp-bignum+ "getInstance"
'(:long) +lisp-integer+))
(t
(let* ((*print-base* 10)
(s (with-output-to-string (stream) (dump-form n stream))))
(emit 'ldc (pool-string s))
(emit-push-constant-int 10)
(emit-invokestatic +lisp-bignum+ "getInstance"
(list +java-string+ :int) +lisp-integer+)))))
(defun serialize-character (c)
"Generates code to restore a serialized character."
(emit-push-constant-int (char-code c))
(emit-invokestatic +lisp-character+ "getInstance" '(:char)
+lisp-character+))
(defun serialize-float (s)
"Generates code to restore a serialized single-float."
(emit-new +lisp-single-float+)
(emit 'dup)
(emit 'ldc (pool-float s))
(emit-invokespecial-init +lisp-single-float+ '(:float)))
(defun serialize-double (d)
"Generates code to restore a serialized double-float."
(emit-new +lisp-double-float+)
(emit 'dup)
(emit 'ldc2_w (pool-double d))
(emit-invokespecial-init +lisp-double-float+ '(:double)))
(defun serialize-string (string)
"Generate code to restore a serialized string."
(cond
((< (length string) #xFFFF)
(emit-new +lisp-simple-string+)
(emit 'dup)
(emit 'ldc (pool-string string))
(emit-invokespecial-init +lisp-simple-string+ (list +java-string+)))
(t
(serialize-object string))))
(defun serialize-package (pkg)
"Generate code to restore a serialized package."
(emit 'ldc (pool-string (concatenate 'string "#.(CL:FIND-PACKAGE \""
(package-name pkg) "\")")))
(emit-invokestatic +lisp+ "readObjectFromString"
(list +java-string+) +lisp-object+))
(defun compiland-external-constant-resource-name (compiland)
(let ((resource-number (compiland-next-resource compiland))
(pathname (abcl-class-file-pathname (compiland-class-file compiland))))
(incf (compiland-next-resource compiland))
(make-pathname :name (format nil "~A_~D"
(pathname-name pathname) resource-number)
:type "clc"
:defaults pathname)))
(defun serialize-object (object)
"Generate code to restore a serialized object which is not of any
of the other types."
(let ((s (with-output-to-string (stream)
(dump-form object stream))))
(cond
((< (length s) #xFFFF) ;; maximum string size in class file
(emit 'ldc (pool-string s))
(emit-invokestatic +lisp+ "readObjectFromString"
(list +java-string+) +lisp-object+))
(t
;; get a 'class literal' for this class
(emit 'ldc_w (pool-class *this-class*))
(let ((pathname
(compiland-external-constant-resource-name *current-compiland*)))
(with-open-file (f pathname
:direction :output
:if-exists :supersede
:if-does-not-exist :create)
(write-string s f))
(emit 'ldc (pool-string
(namestring (make-pathname :name (pathname-name pathname)
:type (pathname-type pathname)
:version nil)))))
(emit-invokevirtual +java-class+ "getResourceAsStream"
(list +java-string+)
+java-io-input-stream+)
(emit-invokestatic +lisp+ "readObjectFromStream"
(list +java-io-input-stream+)
+lisp-object+)))))
(defun serialize-symbol (symbol)
"Generate code to restore a serialized symbol."
(multiple-value-bind
(name class)
(lookup-known-symbol symbol)
(cond
(name
(emit-getstatic class name +lisp-symbol+))
((null (symbol-package symbol))
(emit-push-constant-int (dump-uninterned-symbol-index symbol))
(emit-invokestatic +lisp-load+ "getUninternedSymbol" '(:int)
+lisp-object+)
(emit-checkcast +lisp-symbol+))
((keywordp symbol)
(emit 'ldc (pool-string (symbol-name symbol)))
(emit-invokestatic +lisp+ "internKeyword"
(list +java-string+) +lisp-symbol+))
(t
(emit 'ldc (pool-string (symbol-name symbol)))
(emit 'ldc (pool-string (package-name (symbol-package symbol))))
(emit-invokestatic +lisp+ "internInPackage"
(list +java-string+ +java-string+)
+lisp-symbol+)))))
(defvar serialization-table
`((integer "INT" ,#'eql ,#'serialize-integer ,+lisp-integer+)
(character "CHR" ,#'eql ,#'serialize-character ,+lisp-character+)
(single-float "FLT" ,#'eql ,#'serialize-float ,+lisp-single-float+)
(double-float "DBL" ,#'eql ,#'serialize-double ,+lisp-double-float+)
(string "STR" ,#'equal ,#'serialize-string
,+lisp-abstract-string+) ;; because of (not compile-file)
(package "PKG" ,#'eq ,#'serialize-package ,+lisp-object+)
(symbol "SYM" ,#'eq ,#'serialize-symbol ,+lisp-symbol+)
(T "OBJ" ,#'eq ,#'serialize-object ,+lisp-object+))
"A list of 5-element lists. The elements of the sublists mean:
1. The type of the value to be serialized
2. The string to be used as a field prefix
3. The function to be used to determine equality (coalescing or not)
4. The function to dispatch serialization to
5. The type of the field to save the serialized result to")
(defknown emit-load-externalized-object (t &optional t) string)
(defun emit-load-externalized-object (object &optional cast)
"Externalizes `object' for use in a FASL.
Returns the name of the field (in `*this-class*') from which
the value of the object can be loaded. Objects may be coalesced based
on the equality indicator in the `serialization-table'.
Code to restore the serialized object is inserted into the current method or
the constructor if `*declare-inline*' is non-nil.
"
;; TODO: rewrite to become EMIT-LOAD-EXTERNALIZED-OBJECT which
;; - instead of returning the name of the field - returns the type
;; of the field it just loaded (to allow casting and what not).
;; The function should still do what it does today: de-serialize the
;; object and storing its value.
(destructuring-bind
(type prefix similarity-fn dispatch-fn field-type)
(assoc-if #'(lambda (x)
(typep object x))
serialization-table)
(declare (ignore type)) ;; the type has been used in the selection process
(when (not *file-compilation*) ;; in-memory compilation wants object EQ-ness
(setf similarity-fn #'eq))
(let ((existing (assoc object *externalized-objects* :test similarity-fn)))
(when existing
(emit-getstatic *this-class* (cdr existing) field-type)
(when cast
(emit-checkcast cast))
(return-from emit-load-externalized-object field-type)))
;; We need to set up the serialized value
(let ((field-name (symbol-name (gensym prefix))))
(declare-field field-name field-type)
(push (cons object field-name) *externalized-objects*)
(cond
((not *file-compilation*)
(with-code-to-method
(*class-file* (abcl-class-file-static-initializer *class-file*))
(remember field-name object)
(emit 'ldc (pool-string field-name))
(emit-invokestatic +lisp+ "recall"
(list +java-string+) +lisp-object+)
(when (not (eq field-type +lisp-object+))
(emit-checkcast field-type))
(emit-putstatic *this-class* field-name field-type)))
(*declare-inline*
(funcall dispatch-fn object)
(emit-putstatic *this-class* field-name field-type))
(t
(with-code-to-method
(*class-file* (abcl-class-file-static-initializer *class-file*))
(funcall dispatch-fn object)
(emit-putstatic *this-class* field-name field-type))))
(emit-getstatic *this-class* field-name field-type)
(when cast
(emit-checkcast cast))
field-type)))
(defknown declare-function (symbol &optional setf) string)
(defun declare-function (symbol &optional setf)
(declare (type symbol symbol))
(declare-with-hashtable
symbol *declared-functions* ht f
(setf f (symbol-name (if setf (gensym "SETF") (gensym "FUN"))))
(let ((s (sanitize symbol)))
(when s
(setf f (concatenate 'string f "_" s))))
(declare-field f +lisp-object+)
(multiple-value-bind
(name class)
(lookup-known-symbol symbol)
;; This is a work-around for the fact that
;; EMIT-LOAD-EXTERNALIZED-OBJECT can't be used due to the fact that
;; here we won't know where to send the code yet (the LET
;; selects between *code* and *static-code*, while
;; EMIT-LOAD-EXTERNALIZED-OBJECT wants to modify those specials too
(unless name
(setf name (if *file-compilation*
(declare-object-as-string symbol)
(declare-object symbol))
class *this-class*))
(with-code-to-method (*class-file*
(if *declare-inline* *method*
(abcl-class-file-constructor *class-file*)))
(if (eq class *this-class*)
(progn ;; generated by the DECLARE-OBJECT*'s above
(emit-getstatic class name +lisp-object+)
(emit-checkcast +lisp-symbol+))
(emit-getstatic class name +lisp-symbol+))
(emit-invokevirtual +lisp-symbol+
(if setf
"getSymbolSetfFunctionOrDie"
"getSymbolFunctionOrDie")
nil +lisp-object+)
;; make sure we're not cacheing a proxied function
;; (AutoloadedFunctionProxy) by allowing it to resolve itself
(emit-invokevirtual +lisp-object+
"resolve" nil +lisp-object+)
(emit-putstatic *this-class* f +lisp-object+)
(setf (gethash symbol ht) f))
f)))
(defknown declare-setf-function (name) string)
(defun declare-setf-function (name)
(declare-function (cadr name) t))
(defun local-function-class-and-field (local-function)
(let ((local-function-parent-compiland
(compiland-parent (local-function-compiland local-function))))
(values (abcl-class-file-class-name
(compiland-class-file local-function-parent-compiland))
(local-function-field local-function))))
(defknown declare-local-function (local-function) string)
(defun declare-local-function (local-function)
(let ((class-name (abcl-class-file-class-name
(compiland-class-file
(local-function-compiland local-function))))
(field-name (local-function-field local-function)))
(with-code-to-method
(*class-file* (abcl-class-file-static-initializer *class-file*))
;; fixme *declare-inline*
(declare-field field-name +lisp-object+)
(emit-new class-name)
(emit 'dup)
(emit-invokespecial-init class-name '())
(emit-putstatic *this-class* field-name +lisp-object+))))
(defknown declare-object-as-string (t) string)
(defun declare-object-as-string (obj)
;; TODO: replace with emit-load-externalized-object
;; just replacing won't work however:
;; field identification in Java includes the field type
;; and we're not letting the caller know about the type of
;; field we're creating in emit-load-externalized-object.
;; The solution is to rewrite externalize-object to
;; EMIT-LOAD-EXTERNALIZED-OBJECT, which serializes *and*
;; emits the right loading code (not just de-serialization anymore)
(let ((g (symbol-name (gensym "OBJSTR")))
(s (with-output-to-string (stream) (dump-form obj stream))))
(with-code-to-method
(*class-file*
(if *declare-inline* *method*
(abcl-class-file-static-initializer *class-file*)))
;; strings may contain evaluated bits which may depend on
;; previous statements
(declare-field g +lisp-object+)
(emit 'ldc (pool-string s))
(emit-invokestatic +lisp+ "readObjectFromString"
(list +java-string+) +lisp-object+)
(emit-putstatic *this-class* g +lisp-object+))
g))
(defun declare-load-time-value (obj)
(let ((g (symbol-name (gensym "LTV")))
(s (with-output-to-string (stream) (dump-form obj stream))))
(with-code-to-method
(*class-file*
(if *declare-inline* *method*
(abcl-class-file-static-initializer *class-file*)))
;; The readObjectFromString call may require evaluation of
;; lisp code in the string (think #.() syntax), of which the outcome
;; may depend on something which was declared inline
(declare-field g +lisp-object+)
(emit 'ldc (pool-string s))
(emit-invokestatic +lisp+ "readObjectFromString"
(list +java-string+) +lisp-object+)
(emit-invokestatic +lisp+ "loadTimeValue"
(lisp-object-arg-types 1) +lisp-object+)
(emit-putstatic *this-class* g +lisp-object+))
g))
(declaim (ftype (function (t) string) declare-object))
(defun declare-object (obj)
"Stores the object OBJ in the object-lookup-table,
loading the object value into a field upon class-creation time.
The field type of the object is specified by OBJ-REF."
(let ((g (symbol-name (gensym "OBJ"))))
;; fixme *declare-inline*?
(remember g obj)
(with-code-to-method
(*class-file* (abcl-class-file-static-initializer *class-file*))
(declare-field g +lisp-object+)
(emit 'ldc (pool-string g))
(emit-invokestatic +lisp+ "recall"
(list +java-string+) +lisp-object+)
(emit-putstatic *this-class* g +lisp-object+))
g))
(defknown compile-constant (t t t) t)
(defun compile-constant (form target representation)
(unless target
(return-from compile-constant))
(ecase representation
(:int
(cond ((fixnump form)
(emit-push-constant-int form))
((integerp form)
(emit-load-externalized-object form)
(emit-invokevirtual +lisp-object+ "intValue" nil :int))
(t
(sys::%format t "compile-constant int representation~%")
(assert nil)))
(emit-move-from-stack target representation)
(return-from compile-constant))
(:long
(cond ((<= most-negative-java-long form most-positive-java-long)
(emit-push-constant-long form))
((integerp form)
(emit-load-externalized-object form)
(emit-invokevirtual +lisp-object+ "longValue" nil :long))
(t
(sys::%format t "compile-constant long representation~%")
(assert nil)))
(emit-move-from-stack target representation)
(return-from compile-constant))
(:char
(cond ((characterp form)
(emit-push-constant-int (char-code form))
(emit-move-from-stack target representation)
(return-from compile-constant))
(t
(sys::%format t "compile-constant :char representation~%")
(assert nil))))
(:boolean
(emit (if form 'iconst_1 'iconst_0))
(emit-move-from-stack target representation)
(return-from compile-constant))
(:float
(cond ((integerp form)
(emit-push-constant-float (coerce form 'single-float)))
((typep form 'single-float)
(emit-push-constant-float form))
((typep form 'double-float)
(emit-push-constant-double form)
(emit 'd2f))
(t
(sys::%format t "compile-constant :float representation~%")
(assert nil)))
(emit-move-from-stack target representation)
(return-from compile-constant))
(:double
(cond ((or (integerp form)
(typep form 'single-float))
(emit-push-constant-double (coerce form 'double-float)))
((typep form 'double-float)
(emit-push-constant-double form))
(t
(sys::%format t "compile-constant :double representation~%")
(assert nil)))
(emit-move-from-stack target representation)
(return-from compile-constant))
((NIL)))
(cond ((or (numberp form)
(typep form 'single-float)
(typep form 'double-float)
(characterp form)
(stringp form)
(packagep form)
(pathnamep form)
(arrayp form)
(structure-object-p form)
(standard-object-p form)
(java:java-object-p form))
(emit-load-externalized-object form))
(t
(if *file-compilation*
(error "COMPILE-CONSTANT unhandled case ~S" form)
(emit-load-externalized-object form))))
(emit-move-from-stack target representation))
(defparameter *unary-operators* nil)
(defun initialize-unary-operators ()
(let ((ht (make-hash-table :test 'eq)))
(dolist (pair '((ABS "ABS")
(CADDR "caddr")
(CADR "cadr")
(CDDR "cddr")
(CDR "cdr")
(CLASS-OF "classOf")
(COMPLEXP "COMPLEXP")
(DENOMINATOR "DENOMINATOR")
(FIRST "car")
(SYS::%LENGTH "LENGTH")
(NREVERSE "nreverse")
(NUMERATOR "NUMERATOR")
(REST "cdr")
(REVERSE "reverse")
(SECOND "cadr")
(SIMPLE-STRING-P "SIMPLE_STRING_P")
(STRING "STRING")
(THIRD "caddr")))
(setf (gethash (%car pair) ht) (%cadr pair)))
(setf *unary-operators* ht)))
(initialize-unary-operators)
(defknown install-p2-handler * t)
(defun install-p2-handler (symbol &optional handler)
(declare (type symbol symbol))
(let ((handler (or handler
(find-symbol (concatenate 'string "COMPILE-" (symbol-name symbol)) 'jvm))))
(unless (and handler (fboundp handler))
(error "Handler not found: ~S" handler))
(setf (get symbol 'p2-handler) handler)))
(defparameter *predicates* (make-hash-table :test 'eq))
(defun define-predicate (name boxed-method-name unboxed-method-name)
(setf (gethash name *predicates*) (cons boxed-method-name unboxed-method-name))
(install-p2-handler name 'p2-predicate))
(defmacro define-inlined-function (name params preamble-and-test &body body)
(let* ((test (second preamble-and-test))
(preamble (and test (first preamble-and-test)))
(test (or test (first preamble-and-test))))
`(defun ,name ,params
,preamble
(unless ,test
(compile-function-call ,@params)
(return-from ,name))
,@body)))
(defknown p2-predicate (t t t) t)
(define-inlined-function p2-predicate (form target representation)
((= (length form) 2))
(let* ((op (car form))
(info (gethash op *predicates*))
(boxed-method-name (car info))
(unboxed-method-name (cdr info)))
(cond ((and boxed-method-name unboxed-method-name)
(let ((arg (cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(ecase representation
(:boolean
(emit-invokevirtual +lisp-object+
unboxed-method-name
nil :boolean))
((NIL)
(emit-invokevirtual +lisp-object+
boxed-method-name
nil +lisp-object+)))
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation)))))
(define-predicate 'constantp "CONSTANTP" "constantp")
(define-predicate 'endp "ENDP" "endp")
(define-predicate 'evenp "EVENP" "evenp")
(define-predicate 'floatp "FLOATP" "floatp")
(define-predicate 'integerp "INTEGERP" "integerp")
(define-predicate 'listp "LISTP" "listp")
(define-predicate 'minusp "MINUSP" "minusp")
(define-predicate 'numberp "NUMBERP" "numberp")
(define-predicate 'oddp "ODDP" "oddp")
(define-predicate 'plusp "PLUSP" "plusp")
(define-predicate 'rationalp "RATIONALP" "rationalp")
(define-predicate 'realp "REALP" "realp")
(declaim (ftype (function (t t t t) t) compile-function-call-1))
(defun compile-function-call-1 (op args target representation)
(let ((arg (first args)))
(when (eq op '1+)
(p2-plus (list '+ arg 1) target representation)
(return-from compile-function-call-1 t))
(when (eq op '1-)
(p2-minus (list '- arg 1) target representation)
(return-from compile-function-call-1 t))
(let ((s (gethash1 op (the hash-table *unary-operators*))))
(cond (s
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invoke-method s target representation)
t)
(t
nil)))))
(defparameter *binary-operators* nil)
(defun initialize-binary-operators ()
(let ((ht (make-hash-table :test 'eq)))
(dolist (pair '((EQL "EQL")
(EQUAL "EQUAL")
(+ "add")
(- "subtract")
(/ "divideBy")
(* "multiplyBy")
(< "IS_LT")
(<= "IS_LE")
(> "IS_GT")
(>= "IS_GE")
( = "IS_E")
(/= "IS_NE")
(ASH "ash")
(AREF "AREF")
(SIMPLE-TYPEP "typep")
(RPLACA "RPLACA")
(RPLACD "RPLACD")))
(setf (gethash (%car pair) ht) (%cadr pair)))
(setf *binary-operators* ht)))
(initialize-binary-operators)
(defun compile-binary-operation (op args target representation)
(let ((arg1 (car args))
(arg2 (cadr args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2))
(emit-invokevirtual +lisp-object+ op
(lisp-object-arg-types 1) +lisp-object+))
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(declaim (ftype (function (t t t t) t) compile-function-call-2))
(defun compile-function-call-2 (op args target representation)
(let ((translation (gethash1 op (the hash-table *binary-operators*))))
(when translation
(compile-binary-operation translation args target representation))))
(declaim (ftype (function (t) t) fixnum-or-unboxed-variable-p))
(defun fixnum-or-unboxed-variable-p (arg)
(or (fixnump arg)
(unboxed-fixnum-variable arg)))
(declaim (ftype (function (t) t) emit-push-int))
(defun emit-push-int (arg)
(if (fixnump arg)
(emit-push-constant-int arg)
(let ((variable (unboxed-fixnum-variable arg)))
(if variable
(emit 'iload (variable-register variable))
(progn
(sys::%format t "emit-push-int~%")
(aver nil))))))
(declaim (ftype (function (t) t) emit-push-long))
(defun emit-push-long (arg)
(cond ((eql arg 0)
(emit 'lconst_0))
((eql arg 1)
(emit 'lconst_1))
((fixnump arg)
(emit-push-constant-int arg)
(emit 'i2l))
(t
(let ((variable (unboxed-fixnum-variable arg)))
(aver (not (null variable)))
(aver (not (null (variable-register variable))))
(emit 'iload (variable-register variable))
(emit 'i2l)))))
(defknown p2-eq/neq (t t t) t)
(define-inlined-function p2-eq/neq (form target representation)
((aver (or (null representation) (eq representation :boolean)))
(check-arg-count form 2))
(let* ((op (%car form))
(args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2))
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit (if (eq op 'EQ) 'if_acmpne 'if_acmpeq) LABEL1)
(emit-push-true representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-false representation)
(label LABEL2)))
(emit-move-from-stack target representation))
t)
(defun emit-ifne-for-eql (representation instruction-type)
(emit-invokevirtual +lisp-object+ "eql" instruction-type :boolean)
(convert-representation :boolean representation))
(defknown p2-eql (t t t) t)
(define-inlined-function p2-eql (form target representation)
((aver (or (null representation) (eq representation :boolean)))
(check-arg-count form 2))
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (fixnum-type-p type1)
(fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(let ((label1 (gensym))
(label2 (gensym)))
(emit 'if_icmpeq label1)
(emit-push-false representation)
(emit 'goto label2)
(label label1)
(emit-push-true representation)
(label label2)))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-ifne-for-eql representation '(:int)))
((fixnum-type-p type1)
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-ifne-for-eql representation '(:int)))
((eq type2 'CHARACTER)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :char)
(maybe-emit-clear-values arg1 arg2)))
(emit-ifne-for-eql representation '(:char)))
((eq type1 'CHARACTER)
(with-operand-accumulation
((compile-operand arg1 :char)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-ifne-for-eql representation '(:char)))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(ecase representation
(:boolean
(emit-invokevirtual +lisp-object+ "eql"
(lisp-object-arg-types 1) :boolean))
((NIL)
(emit-invokevirtual +lisp-object+ "EQL"
(lisp-object-arg-types 1) +lisp-object+)))))
(emit-move-from-stack target representation)))
(defknown p2-memq (t t t) t)
(define-inlined-function p2-memq (form target representation)
((check-arg-count form 2))
(cond ((eq representation :boolean)
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokestatic +lisp+ "memq"
(lisp-object-arg-types 2) :boolean)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
(defknown p2-memql (t t t) t)
(define-inlined-function p2-memql (form target representation)
((check-arg-count form 2))
(cond ((eq representation :boolean)
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(type1 (derive-compiler-type arg1)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(cond ((eq type1 'SYMBOL) ; FIXME
(emit-invokestatic +lisp+ "memq"
(lisp-object-arg-types 2) :boolean))
(t
(emit-invokestatic +lisp+ "memql"
(lisp-object-arg-types 2) :boolean)))
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
(defun p2-gensym (form target representation)
(cond ((and (null representation) (null (cdr form)))
(emit-push-current-thread)
(emit-invokestatic +lisp+ "gensym"
(list +lisp-thread+) +lisp-symbol+)
(emit-move-from-stack target))
(t
(compile-function-call form target representation))))
;; get symbol indicator &optional default => value
(defun p2-get (form target representation)
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(arg3 (third args)))
(case (length args)
((2 3)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(when arg3
(compile-operand arg3 nil))
(maybe-emit-clear-values arg1 arg2 arg3)))
(emit-invokestatic +lisp+ "get"
(lisp-object-arg-types (if arg3 3 2))
+lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compiler-warn "Wrong number of arguments for ~A (expected 2 or 3, but received ~D)."
'GET (length args))
(compile-function-call form target representation)))))
;; getf plist indicator &optional default => value
(defun p2-getf (form target representation)
(let* ((args (cdr form))
(arg-count (length args)))
(case arg-count
((2 3)
(let ((arg1 (first args))
(arg2 (second args))
(arg3 (third args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(compile-operand arg3 nil)
(maybe-emit-clear-values arg1 arg2 arg3)))
(emit-invokestatic +lisp+ "getf"
(lisp-object-arg-types 3) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation)))))
;; gethash key hash-table &optional default => value, present-p
(defun p2-gethash (form target representation)
(cond ((and (eq (car form) 'GETHASH1)
(= (length form) 3)
(eq (derive-type (%caddr form)) 'HASH-TABLE))
(let ((key-form (%cadr form))
(ht-form (%caddr form)))
(with-operand-accumulation
((compile-operand ht-form nil +lisp-hash-table+)
(compile-operand key-form nil)
(maybe-emit-clear-values ht-form key-form)))
(emit-invokevirtual +lisp-hash-table+ "gethash1"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
;; puthash key hash-table new-value &optional default => value
(defun p2-puthash (form target representation)
(cond ((and (= (length form) 4)
(eq (derive-type (%caddr form)) 'HASH-TABLE))
(let ((key-form (%cadr form))
(ht-form (%caddr form))
(value-form (fourth form)))
(with-operand-accumulation
((compile-operand ht-form nil +lisp-hash-table+)
(compile-operand key-form nil)
(compile-operand value-form nil)
(maybe-emit-clear-values ht-form key-form value-form)))
(cond (target
(emit-invokevirtual +lisp-hash-table+ "puthash"
(lisp-object-arg-types 2) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(emit-invokevirtual +lisp-hash-table+ "put"
(lisp-object-arg-types 2) nil)))))
(t
(compile-function-call form target representation))))
(defvar *functions-defined-in-current-file* nil)
(defun inline-ok (name)
(declare (optimize speed))
(cond ((notinline-p name)
nil)
((built-in-function-p name)
t)
((memq name *functions-defined-in-current-file*)
t)
(t
nil)))
(defknown process-args (t t) t)
(defun process-args (args stack)
"Compiles forms specified as function call arguments.
The results are either accumulated on the stack or in an array
in order to call the relevant `execute' form. The function call
itself is *not* compiled by this function."
(when args
(let ((numargs (length args)))
(let ((must-clear-values nil)
(unsafe-args (some-nested-block #'node-opstack-unsafe-p
(mapcan #'find-enclosed-blocks
args))))
(declare (type boolean must-clear-values))
(cond ((and unsafe-args
(<= numargs call-registers-limit))
(let ((*register* *register*)
operand-registers)
(dolist (stack-item stack)
(let ((register (allocate-register nil)))
(push register operand-registers)
(emit-move-from-stack register stack-item)))
(setf operand-registers (reverse operand-registers))
(dolist (arg args)
(push (allocate-register nil) operand-registers)
(compile-form arg (car operand-registers) nil)
(unless must-clear-values
(unless (single-valued-p arg)
(setf must-clear-values t))))
(dolist (register (nreverse operand-registers))
(aload register))))
((<= numargs call-registers-limit)
(dolist (arg args)
(compile-form arg 'stack nil)
(unless must-clear-values
(unless (single-valued-p arg)
(setf must-clear-values t)))))
(t
(let* ((*register* *register*) ;; ### FIXME: this doesn't work, but why not?
(array-register (allocate-register nil))
saved-stack)
(when unsafe-args
(dolist (stack-item stack)
(let ((register (allocate-register nil)))
(push register saved-stack)
(emit-move-from-stack register stack-item))))
(emit-push-constant-int numargs)
(emit-anewarray +lisp-object+)
;; be operand stack safe by not accumulating
;; any arguments on the stack.
;;
;; The overhead of storing+loading the array register
;; at the beginning and ending is small: there are at
;; least nine parameters to be calculated.
(astore array-register)
(let ((i 0))
(dolist (arg args)
(cond
((not (some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks arg)))
(aload array-register)
(emit-push-constant-int i)
(compile-form arg 'stack nil))
(t
(compile-form arg 'stack nil)
(aload array-register)
(emit 'swap)
(emit-push-constant-int i)
(emit 'swap)))
(emit 'aastore) ; store value in array
(unless must-clear-values
(unless (single-valued-p arg)
(setf must-clear-values t)))
(incf i))
(when unsafe-args
(mapcar #'emit-push-register
saved-stack
(reverse stack)))
(aload array-register)))))
(when must-clear-values
(emit-clear-values)))))
t)
(defknown lisp-object-arg-types (fixnum) list)
(let ((table (make-array 10)))
(dotimes (i 10)
(declare (type fixnum i))
(setf (aref table i) (make-list i :initial-element +lisp-object+)))
(defun lisp-object-arg-types (n)
(declare (type fixnum n))
(declare (optimize speed (safety 0)))
(if (< n 10)
(aref table n)
(make-list n :initial-element +lisp-object+))))
(declaim (ftype (function (t) t) emit-call-execute))
(defun emit-call-execute (numargs)
(let ((arg-types (if (<= numargs call-registers-limit)
(lisp-object-arg-types numargs)
(list +lisp-object-array+)))
(return-type +lisp-object+))
(emit-invokevirtual +lisp-object+ "execute" arg-types return-type)))
(declaim (ftype (function (t) t) emit-call-thread-execute))
(defun emit-call-thread-execute (numargs)
(let ((arg-types (if (<= numargs call-registers-limit)
(lisp-object-arg-types (1+ numargs))
(list +lisp-object+ +lisp-object-array+)))
(return-type +lisp-object+))
(emit-invokevirtual +lisp-thread+ "execute" arg-types return-type)))
(defknown compile-function-call (t t t) t)
(defun compile-function-call (form target representation)
(let ((op (car form))
(args (cdr form)))
(declare (type symbol op))
(when (find-local-function op)
(return-from compile-function-call
(compile-local-function-call form target representation)))
(when (and (boundp '*defined-functions*) (boundp '*undefined-functions*))
(unless (or (fboundp op)
(eq op (compiland-name *current-compiland*))
(memq op *defined-functions*)
(proclaimed-ftype op))
(pushnew op *undefined-functions*)))
(let ((numargs (length args)))
(case numargs
(1
(when (compile-function-call-1 op args target representation)
(return-from compile-function-call)))
(2
(when (compile-function-call-2 op args target representation)
(return-from compile-function-call))))
(let ((explain *explain*))
(when (and explain (memq :calls explain))
(let ((package (symbol-package op)))
(when (or (eq package +cl-package+) (eq package (find-package "SYSTEM")))
(format t "; full call to ~S~%" op)))))
(when (or (<= *speed* *debug*) *require-stack-frame*)
(emit-push-current-thread))
(cond ((and (eq op (compiland-name *current-compiland*))
(null (compiland-parent *current-compiland*)))
; recursive call
(if (notinline-p op)
(emit-load-externalized-object op)
(aload 0)))
(t
(emit-load-externalized-object op)))
(process-args args
(if (or (<= *speed* *debug*) *require-stack-frame*)
'(nil nil) '(nil)))
(if (or (<= *speed* *debug*) *require-stack-frame*)
(emit-call-thread-execute numargs)
(emit-call-execute numargs))
(fix-boxing representation (derive-compiler-type form))
(emit-move-from-stack target representation))))
(defun compile-call (args stack)
"Compiles a function call.
Depending on the `*speed*' and `*debug*' settings, a stack frame
is registered (or not)."
(let ((numargs (length args)))
(cond ((> *speed* *debug*)
(process-args args stack)
(emit-call-execute numargs))
(t
(emit-push-current-thread)
(emit 'swap) ; Stack: thread function
(process-args args (list* (car stack) nil (cdr stack)))
(emit-call-thread-execute numargs)))))
(define-source-transform funcall (&whole form fun &rest args)
(cond ((> *debug* *speed*)
form)
((and (consp fun)
(eq (%car fun) 'FUNCTION)
(symbolp (cadr fun)))
`(,(cadr fun) ,@args))
((and (consp fun)
(eq (%car fun) 'QUOTE))
(let ((sym (cadr fun)))
(if (and (symbolp sym)
(eq (symbol-package (truly-the symbol sym)) +cl-package+)
(not (special-operator-p sym))
(not (macro-function sym)))
`(,(cadr fun) ,@args)
form)))
(t
form)))
(define-source-transform mapcar (&whole form function &rest lists)
(cond ((or (> *debug* *speed*)
(> *space* *speed*))
form)
((= (length lists) 1)
(let ((list (gensym))
(result (gensym))
(temp (gensym)))
`(let* ((,list ,(car lists))
(,result (list nil))
(,temp ,result))
(loop
(when (null ,list)
(return (cdr ,result)))
(rplacd ,temp (setf ,temp (list (funcall ,function (car ,list)))))
(setf ,list (cdr ,list))))))
(t
form)))
(define-source-transform mapc (&whole form function &rest lists)
(cond ((or (> *debug* *speed*)
(> *space* *speed*))
form)
((= (length lists) 1)
(let ((list (gensym))
(result (gensym)))
`(let* ((,list ,(car lists))
(,result ,list))
(loop
(when (null ,list)
(return ,result))
(funcall ,function (car ,list))
(setf ,list (%cdr ,list))))))
(t
form)))
(defknown p2-funcall (t t t) t)
(defun p2-funcall (form target representation)
(unless (> (length form) 1)
(compiler-warn "Wrong number of arguments for ~A." (car form))
(compile-function-call form target representation)
(return-from p2-funcall))
(when (> *debug* *speed*)
(return-from p2-funcall (compile-function-call form target representation)))
(compile-forms-and-maybe-emit-clear-values (cadr form) 'stack nil)
(compile-call (cddr form) '(nil))
(fix-boxing representation nil)
(emit-move-from-stack target))
(defun duplicate-closure-array (compiland)
(let* ((*register* *register*)
(register (allocate-register nil)))
(aload (compiland-closure-register compiland)) ;; src
(emit-push-constant-int 0) ;; srcPos
(emit-push-constant-int (length *closure-variables*))
(emit-anewarray +lisp-closure-binding+) ;; dest
(emit 'dup)
(astore register) ;; save dest value
(emit-push-constant-int 0) ;; destPos
(emit-push-constant-int (length *closure-variables*)) ;; length
(emit-invokestatic +java-system+ "arraycopy"
(list +java-object+ :int
+java-object+ :int :int) nil)
(aload register))) ;; reload dest value
(defun emit-load-local-function (local-function)
(when (eq *current-compiland* (local-function-compiland local-function))
(aload 0)
(return-from emit-load-local-function))
(multiple-value-bind
(class field)
(local-function-class-and-field local-function)
(emit-getstatic class field +lisp-object+))
(when *closure-variables*
(emit-checkcast +lisp-compiled-closure+)
(duplicate-closure-array *current-compiland*)
(emit-invokestatic +lisp+ "makeCompiledClosure"
(list +lisp-object+ +closure-binding-array+)
+lisp-object+)))
(defknown compile-local-function-call (t t t) t)
(defun compile-local-function-call (form target representation)
"Compiles a call to a function marked as `*child-p*'; a local function.
Functions this applies to can be FLET, LABELS, LAMBDA or NAMED-LAMBDA.
Note: DEFUN implies a named lambda."
(let* ((op (car form))
(args (cdr form))
(local-function (find-local-function op))
(*register* *register*))
(cond
((local-function-environment local-function)
(assert (local-function-references-allowed-p local-function))
(assert (not *file-compilation*))
(emit-load-externalized-object
(local-function-environment local-function)
+lisp-environment+)
(emit-load-externalized-object (local-function-name local-function))
(emit-invokevirtual +lisp-environment+ "lookupFunction"
(list +lisp-object+)
+lisp-object+))
(t
(dformat t "compile-local-function-call default case~%")
(emit-load-local-function local-function)))
(process-args args '(nil))
(emit-call-execute (length args))
(fix-boxing representation nil)
(emit-move-from-stack target representation))
t)
;; < <= > >= =
(defvar comparison-ops '(< <= > >= =))
(defvar comparison-ins
'((:int . #(if_icmpge if_icmpgt if_icmple if_icmplt if_icmpne))
(:long . #((lcmp ifge) (lcmp ifgt) (lcmp ifle)
(lcmp iflt) (lcmp ifne)))
(:float . #((fcmpg ifge) (fcmpg ifgt) (fcmpl ifle)
(fcmpl iflt) (fcmpl ifne)))
(:double . #((dcmpg ifge) (dcmpg ifgt) (dcmpl ifle)
(dcmpl iflt) (dcmpl ifne))))
"Instructions to be generated upon each comparison operation,
given a specific common representation.")
(defun emit-numeric-comparison (op representation false-LABEL)
(let* ((pos (position op comparison-ops))
(ops-table (cdr (assoc representation comparison-ins)))
(ops (aref ops-table pos)))
(if (listp ops)
(progn
(emit (car ops))
(emit (cadr ops) false-LABEL))
(emit ops false-LABEL))))
;; Note that /= is not transitive, so we don't handle it here.
(defknown p2-numeric-comparison (t t t) t)
(defun p2-numeric-comparison (form target representation)
(aver (or (null representation) (eq representation :boolean)))
(let ((op (car form))
(args (%cdr form)))
(case (length args)
(2
(let* ((arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2))
(common-rep (common-representation (type-representation type1)
(type-representation type2))))
(cond ((and (integerp arg1) (integerp arg2))
(let ((result (funcall op arg1 arg2)))
(if result
(emit-push-true representation)
(emit-push-false representation)))
(emit-move-from-stack target representation)
(return-from p2-numeric-comparison))
(common-rep
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(with-operand-accumulation
((compile-operand arg1 common-rep)
(compile-operand arg2 common-rep)
(maybe-emit-clear-values arg1 arg2))
(emit-numeric-comparison op common-rep LABEL1)
(emit-push-true representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-false representation)
(label LABEL2)))
(emit-move-from-stack target representation)
(return-from p2-numeric-comparison))
((fixnump arg2)
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-push-constant-int arg2)
(emit-invokevirtual +lisp-object+
(case op
(< "isLessThan")
(<= "isLessThanOrEqualTo")
(> "isGreaterThan")
(>= "isGreaterThanOrEqualTo")
(= "isEqualTo"))
'(:int)
:boolean)
;; Java boolean on stack here
(convert-representation :boolean representation)
(emit-move-from-stack target representation)
(return-from p2-numeric-comparison)))))
(3
(when (dolist (arg args t)
(unless (fixnum-type-p (derive-compiler-type arg))
(return nil)))
(let* ((arg1 (%car args))
(arg2 (%cadr args))
(arg3 (%caddr args))
(test (case op
(< 'if_icmpge)
(<= 'if_icmpgt)
(> 'if_icmple)
(>= 'if_icmplt)
(= 'if_icmpne)))
(LABEL1 (gensym))
(LABEL2 (gensym))
;; If we do both tests, we need to use the arg2 value twice,
;; so we store that value in a temporary register.
(*register* *register*)
(arg2-register
(unless (and (or (node-constant-p arg2)
(var-ref-p arg2))
(node-constant-p arg3))
(allocate-register nil)))
(arg3-register
(unless (node-constant-p arg3) (allocate-register nil))))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(when arg3-register
(compile-operand arg3 :int))
(maybe-emit-clear-values arg1 arg2 arg3))
(when arg3-register
(emit 'istore arg3-register))
(when arg2-register
(emit 'dup)
(emit 'istore arg2-register)))
;; First test.
(emit test LABEL1)
;; Second test.
(cond (arg2-register
(emit 'iload arg2-register))
(t
(compile-form arg2 'stack :int)))
(cond (arg3-register
(emit 'iload arg3-register))
(t
(compile-form arg3 'stack :int)))
(emit test LABEL1)
(emit-push-true representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-false representation)
(label LABEL2)
(emit-move-from-stack target representation)
(return-from p2-numeric-comparison))))))
;; Still here?
(compile-function-call form target representation))
(defparameter *p2-test-handlers* nil)
(defun p2-test-handler (op)
(gethash1 op (the hash-table *p2-test-handlers*)))
(defun initialize-p2-test-handlers ()
(let ((ht (make-hash-table :test 'eq)))
(dolist (pair '(
(/= p2-test-/=)
(< p2-test-numeric-comparison)
(<= p2-test-numeric-comparison)
(= p2-test-numeric-comparison)
(> p2-test-numeric-comparison)
(>= p2-test-numeric-comparison)
(AND p2-test-and)
(OR p2-test-or)
(ATOM p2-test-atom)
(BIT-VECTOR-P p2-test-bit-vector-p)
(CHAR= p2-test-char=)
(CHARACTERP p2-test-characterp)
(CONSP p2-test-consp)
(CONSTANTP p2-test-constantp)
(ENDP p2-test-endp)
(EQ p2-test-eq)
(NEQ p2-test-neq)
(EQL p2-test-eql)
(EQUAL p2-test-equality)
(EQUALP p2-test-equality)
(EVENP p2-test-evenp)
(FIXNUMP p2-test-fixnump)
(FLOATP p2-test-floatp)
(INTEGERP p2-test-integerp)
(LISTP p2-test-listp)
(MEMQ p2-test-memq)
(MEMQL p2-test-memql)
(MINUSP p2-test-minusp)
(NOT p2-test-not/null)
(NULL p2-test-not/null)
(NUMBERP p2-test-numberp)
(PACKAGEP p2-test-packagep)
(ODDP p2-test-oddp)
(PLUSP p2-test-plusp)
(RATIONALP p2-test-rationalp)
(REALP p2-test-realp)
(SIMPLE-TYPEP p2-test-simple-typep)
(SIMPLE-VECTOR-P p2-test-simple-vector-p)
(SPECIAL-OPERATOR-P p2-test-special-operator-p)
(SPECIAL-VARIABLE-P p2-test-special-variable-p)
(STRINGP p2-test-stringp)
(SYMBOLP p2-test-symbolp)
(VECTORP p2-test-vectorp)
(ZEROP p2-test-zerop)
))
(setf (gethash (%car pair) ht) (%cadr pair)))
(setf *p2-test-handlers* ht)))
(initialize-p2-test-handlers)
(defknown negate-jump-condition (t) t)
(defun negate-jump-condition (jump-instruction)
(ecase jump-instruction
('if_acmpeq 'if_acmpne)
('if_acmpne 'if_acmpeq)
('ifeq 'ifne)
('ifne 'ifeq)
('iflt 'ifge)
('ifge 'iflt)
('ifgt 'ifle)
('ifle 'ifgt)
('if_icmpeq 'if_icmpne)
('if_icmpne 'if_icmpeq)
('if_icmplt 'if_icmpge)
('if_icmpge 'if_icmplt)
('if_icmpgt 'if_icmple)
('if_icmple 'if_icmpgt)))
(defknown emit-test-jump (t t t) t)
(defun emit-test-jump (jump success-label failure-label)
(cond
(failure-label
(emit jump failure-label)
(when success-label
(emit 'goto success-label)))
(t
(emit (negate-jump-condition jump) success-label)))
t)
(defknown p2-test-predicate (t t) t)
(defun p2-test-predicate (form java-predicate success-label failure-label)
(when (check-arg-count form 1)
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invokevirtual +lisp-object+ java-predicate nil :boolean)
(emit-test-jump 'ifeq success-label failure-label))))
(declaim (ftype (function (t t t t) t) p2-test-instanceof-predicate))
(defun p2-test-instanceof-predicate (form java-class
success-label failure-label)
(when (check-arg-count form 1)
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-instanceof java-class)
(emit-test-jump 'ifeq success-label failure-label))))
(defun p2-test-bit-vector-p (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-abstract-bit-vector+
success-label failure-label))
(defun p2-test-characterp (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-character+
success-label failure-label))
;; constantp form &optional environment => generalized-boolean
(defun p2-test-constantp (form success-label failure-label)
(when (= (length form) 2)
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invokevirtual +lisp-object+ "constantp" nil :boolean)
(emit-test-jump 'ifeq success-label failure-label))))
(defun p2-test-endp (form success-label failure-label)
(p2-test-predicate form "endp" success-label failure-label))
(defmacro p2-test-integer-predicate ((form predicate
success-label failure-label)
&body instructions)
(let ((tmpform (gensym)))
`(let ((,tmpform ,form))
(when (check-arg-count ,tmpform 1)
(let ((arg (%cadr ,tmpform)))
(cond ((fixnum-type-p (derive-compiler-type arg))
(compile-forms-and-maybe-emit-clear-values arg 'stack :int)
,@instructions)
(t
(p2-test-predicate ,tmpform ,predicate
,success-label ,failure-label))))))))
(defun p2-test-evenp (form success-label failure-label)
(p2-test-integer-predicate (form "evenp" success-label failure-label)
(emit-push-constant-int 1)
(emit 'iand)
(emit-test-jump 'ifne success-label failure-label)))
(defun p2-test-oddp (form success-label failure-label)
(p2-test-integer-predicate (form "oddp" success-label failure-label)
(emit-push-constant-int 1)
(emit 'iand)
(emit-test-jump 'ifeq success-label failure-label)))
(defun p2-test-floatp (form success-label failure-label)
(p2-test-predicate form "floatp" success-label failure-label))
(defun p2-test-integerp (form success-label failure-label)
(p2-test-predicate form "integerp" success-label failure-label))
(defun p2-test-listp (form success-label failure-label)
(when (check-arg-count form 1)
(let* ((arg (%cadr form))
(arg-type (derive-compiler-type arg)))
(cond ((memq arg-type '(CONS LIST NULL))
(compile-forms-and-maybe-emit-clear-values arg nil nil)
:consequent)
((neq arg-type t)
(compile-forms-and-maybe-emit-clear-values arg nil nil)
:alternate)
(t
(p2-test-predicate form "listp" success-label failure-label))))))
(defun p2-test-minusp (form success-label failure-label)
(p2-test-integer-predicate (form "minusp" success-label failure-label)
(emit-test-jump 'ifge success-label failure-label)))
(defun p2-test-plusp (form success-label failure-label)
(p2-test-integer-predicate (form "plusp" success-label failure-label)
(emit-test-jump 'ifle success-label failure-label)))
(defun p2-test-zerop (form success-label failure-label)
(p2-test-integer-predicate (form "zerop" success-label failure-label)
(emit-test-jump 'ifne success-label failure-label)))
(defun p2-test-numberp (form success-label failure-label)
(p2-test-predicate form "numberp" success-label failure-label))
(defun p2-test-packagep (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-package+
success-label failure-label))
(defun p2-test-rationalp (form success-label failure-label)
(p2-test-predicate form "rationalp" success-label failure-label))
(defun p2-test-realp (form success-label failure-label)
(p2-test-predicate form "realp" success-label failure-label))
(defun p2-test-special-operator-p (form success-label failure-label)
(p2-test-predicate form "isSpecialOperator" success-label failure-label))
(defun p2-test-special-variable-p (form success-label failure-label)
(p2-test-predicate form "isSpecialVariable" success-label failure-label))
(defun p2-test-symbolp (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-symbol+ success-label failure-label))
(defun p2-test-consp (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-cons+ success-label failure-label))
(defun p2-test-atom (form success-label failure-label)
;; The test below is a negative test, so, reverse the labels for failure and success
(p2-test-instanceof-predicate form +lisp-cons+ failure-label success-label))
(defun p2-test-fixnump (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-fixnum+ success-label failure-label))
(defun p2-test-stringp (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-abstract-string+
success-label failure-label))
(defun p2-test-vectorp (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-abstract-vector+
success-label failure-label))
(defun p2-test-simple-vector-p (form success-label failure-label)
(p2-test-instanceof-predicate form +lisp-simple-vector+
success-label failure-label))
(defknown compile-test-form (t) t)
(defun compile-test-form (test-form success-label failure-label)
(when (consp test-form)
(let* ((op (%car test-form))
(handler (p2-test-handler op))
(result (and handler (funcall handler test-form success-label
failure-label))))
(when result
(return-from compile-test-form result))))
(cond ((eq test-form t)
:consequent)
((eq (derive-compiler-type test-form) 'BOOLEAN)
(compile-forms-and-maybe-emit-clear-values test-form 'stack :boolean)
(emit-test-jump 'ifeq success-label failure-label))
(t
(compile-forms-and-maybe-emit-clear-values test-form 'stack nil)
(emit-push-nil)
(emit-test-jump 'if_acmpeq success-label failure-label))))
(defun p2-test-not/null (form success-label failure-label)
(when (check-arg-count form 1)
(let* ((arg (%cadr form))
(result (compile-test-form arg failure-label success-label)))
(case result
(:consequent :alternate)
(:alternate :consequent)
(t result)))))
(defun p2-test-char= (form success-label failure-label)
(when (= (length form) 3) ;; only optimize the "exactly 2 arguments" case
(let* ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 :char)
(compile-operand arg2 :char)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump 'if_icmpne success-label failure-label))))
(defun p2-test-eq (form success-label failure-label)
(when (check-arg-count form 2)
(let ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump 'if_acmpne success-label failure-label))))
(defun p2-test-or (form success-label failure-label)
(let ((args (cdr form)))
(case (length args)
(0
:alternate)
(1
(compile-test-form (%car args) success-label failure-label))
(t
(loop
with local-success-label = (or success-label (gensym))
for arg in args
for result = (compile-test-form arg local-success-label nil)
when (eq :consequent result)
do (progn
(emit 'goto local-success-label)
(loop-finish))
finally (progn
(when failure-label
(emit 'goto failure-label))
(unless (eq success-label local-success-label)
(label local-success-label))
(return t)))))))
(defun p2-test-and (form success-label failure-label)
(let ((args (cdr form)))
(case (length args)
(0
:consequent)
(1
(compile-test-form (%car args) success-label failure-label))
(t
(loop
with local-fail-label = (or failure-label (gensym))
for arg in args
for result = (compile-test-form arg nil local-fail-label)
when (eq :alternate result)
do (progn
(emit 'goto local-fail-label)
(loop-finish))
finally (progn
(when success-label
(emit 'goto success-label))
(unless (eq failure-label local-fail-label)
(label local-fail-label))
(return t)))))))
(defun p2-test-neq (form success-label failure-label)
(p2-test-eq form failure-label success-label))
(defun p2-test-eql (form success-label failure-label)
(when (check-arg-count form 2)
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (fixnum-type-p type1) (fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump 'if_icmpne success-label failure-label))
((and (eq type1 'CHARACTER) (eq type2 'CHARACTER))
(with-operand-accumulation
((compile-operand arg1 :char)
(compile-operand arg2 :char)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump 'if_icmpne success-label failure-label))
((eq type2 'CHARACTER)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :char)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "eql" '(:char) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
((eq type1 'CHARACTER)
(with-operand-accumulation
((compile-operand arg1 :char)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-invokevirtual +lisp-object+ "eql" '(:char) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "eql" '(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
((fixnum-type-p type1)
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-invokevirtual +lisp-object+ "eql" '(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "eql"
(lisp-object-arg-types 1) :boolean)
(emit-test-jump 'ifeq success-label failure-label))))))
(defun p2-test-equality (form success-label failure-label)
(when (check-arg-count form 2)
(let* ((op (%car form))
(translated-op (ecase op
(EQUAL "equal")
(EQUALP "equalp")))
(arg1 (%cadr form))
(arg2 (%caddr form)))
(cond ((fixnum-type-p (derive-compiler-type arg2))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+
translated-op
'(:int) :boolean))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+
translated-op
(lisp-object-arg-types 1) :boolean)))
(emit-test-jump 'ifeq success-label failure-label))))
(defun p2-test-simple-typep (form success-label failure-label)
(when (check-arg-count form 2)
(let ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "typep"
(lisp-object-arg-types 1) +lisp-object+)
(emit-push-nil)
(emit-test-jump 'if_acmpeq success-label failure-label))))
(defun p2-test-memq (form success-label failure-label)
(when (check-arg-count form 2)
(let ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokestatic +lisp+ "memq"
(lisp-object-arg-types 2) :boolean)
(emit-test-jump 'ifeq success-label failure-label))))
(defun p2-test-memql (form success-label failure-label)
(when (check-arg-count form 2)
(let ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokestatic +lisp+ "memql"
(lisp-object-arg-types 2) :boolean)
(emit-test-jump 'ifeq success-label failure-label))))
(defun p2-test-/= (form success-label failure-label)
(when (= (length form) 3)
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (numberp arg1) (numberp arg2))
(if (/= arg1 arg2) :consequent :alternate))
((and (fixnum-type-p type1)
(fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump 'if_icmpeq success-label failure-label))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "isNotEqualTo" '(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
((fixnum-type-p type1)
;; FIXME Compile the args in reverse order and avoid the swap if
;; either arg is a fixnum or a lexical variable.
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-invokevirtual +lisp-object+ "isNotEqualTo" '(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "isNotEqualTo"
(lisp-object-arg-types 1) :boolean)
(emit-test-jump 'ifeq success-label failure-label))))))
(defun p2-test-numeric-comparison (form success-label failure-label)
(when (check-min-args form 1)
(when (= (length form) 3)
(let* ((op (%car form))
(args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (fixnump arg1) (fixnump arg2))
(if (funcall op arg1 arg2) :consequent :alternate))
((and (fixnum-type-p type1) (fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-test-jump (ecase op
(< 'if_icmpge)
(<= 'if_icmpgt)
(> 'if_icmple)
(>= 'if_icmplt)
(= 'if_icmpne))
success-label failure-label))
((and (java-long-type-p type1) (java-long-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :long)
(compile-operand arg2 :long)
(maybe-emit-clear-values arg1 arg2)))
(emit 'lcmp)
(emit-test-jump (ecase op
(< 'ifge)
(<= 'ifgt)
(> 'ifle)
(>= 'iflt)
(= 'ifne))
success-label failure-label))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+
(ecase op
(< "isLessThan")
(<= "isLessThanOrEqualTo")
(> "isGreaterThan")
(>= "isGreaterThanOrEqualTo")
(= "isEqualTo"))
'(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
((fixnum-type-p type1)
;; FIXME We can compile the args in reverse order and avoid
;; the swap if either arg is a fixnum or a lexical variable.
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-invokevirtual +lisp-object+
(ecase op
(< "isGreaterThan")
(<= "isGreaterThanOrEqualTo")
(> "isLessThan")
(>= "isLessThanOrEqualTo")
(= "isEqualTo"))
'(:int) :boolean)
(emit-test-jump 'ifeq success-label failure-label))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+
(ecase op
(< "isLessThan")
(<= "isLessThanOrEqualTo")
(> "isGreaterThan")
(>= "isGreaterThanOrEqualTo")
(= "isEqualTo"))
(lisp-object-arg-types 1) :boolean)
(emit-test-jump 'ifeq success-label failure-label)))))))
(defknown p2-if (t t t) t)
(defun p2-if (form target representation)
(let* ((test (second form))
(consequent (third form))
(alternate (fourth form))
(LABEL1 (gensym))
(LABEL2 (gensym)))
(let ((result (compile-test-form test nil LABEL1)))
(case result
(:consequent
(compile-form consequent target representation))
(:alternate
(compile-form alternate target representation))
(t
(compile-form consequent target representation)
(emit 'goto LABEL2)
(label LABEL1)
(compile-form alternate target representation)
(label LABEL2))))))
(defun compile-multiple-value-list (form target representation)
(emit-clear-values)
(compile-form (second form) 'stack nil)
(emit-invokestatic +lisp+ "multipleValueList"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target))
(defun compile-multiple-value-prog1 (form target representation)
(let ((first-subform (cadr form))
(subforms (cddr form))
(result-register (allocate-register nil))
(values-register (allocate-register nil)))
;; Make sure there are no leftover values from previous calls.
(emit-clear-values)
(compile-form first-subform result-register nil)
;; Save multiple values returned by first subform.
(emit-push-current-thread)
(emit-getfield +lisp-thread+ "_values" +lisp-object-array+)
(astore values-register)
(compile-progn-body subforms nil nil)
;; Restore multiple values returned by first subform.
(emit-push-current-thread)
(aload values-register)
(emit-putfield +lisp-thread+ "_values" +lisp-object-array+)
;; Result.
(aload result-register)
(fix-boxing representation nil)
(emit-move-from-stack target)))
(defun compile-multiple-value-call (form target representation)
;; FIXME What if we're called with a non-NIL representation?
(aver (null representation))
(case (length form)
(1
(error "Wrong number of arguments for MULTIPLE-VALUE-CALL."))
(2
(compile-form (second form) 'stack nil)
(emit-invokestatic +lisp+ "coerceToFunction"
(lisp-object-arg-types 1) +lisp-object+)
(emit-invokevirtual +lisp-object+ "execute" nil +lisp-object+))
(3
(let* ((*register* *register*)
(function-register (allocate-register nil)))
(compile-form (second form) function-register nil)
(compile-form (third form) 'stack nil)
(aload function-register)
(emit-push-current-thread)
(emit-invokestatic +lisp+ "multipleValueCall1"
(list +lisp-object+ +lisp-object+ +lisp-thread+)
+lisp-object+)))
(t
;; The general case.
(let* ((*register* *register*)
(function-register (allocate-register nil))
(values-register (allocate-register nil)))
(compile-form (second form) 'stack nil)
(emit-invokestatic +lisp+ "coerceToFunction"
(lisp-object-arg-types 1) +lisp-object+)
(emit-move-from-stack function-register)
(emit 'aconst_null)
(astore values-register)
(dolist (values-form (cddr form))
(compile-form values-form 'stack nil)
(emit-push-current-thread)
(emit 'swap)
(aload values-register)
(emit-invokevirtual +lisp-thread+ "accumulateValues"
(list +lisp-object+ +lisp-object-array+)
+lisp-object-array+)
(astore values-register)
(maybe-emit-clear-values values-form))
(aload function-register)
(aload values-register)
(emit-invokevirtual +lisp-object+ "dispatch"
(list +lisp-object-array+) +lisp-object+))))
(fix-boxing representation nil)
(emit-move-from-stack target))
(defknown unused-variable (t) t)
(defun unused-variable (variable)
(unless (or (variable-ignore-p variable)
(variable-ignorable-p variable))
(compiler-style-warn "The variable ~S is defined but never used."
(variable-name variable))))
(defknown check-for-unused-variables (list) t)
(defun check-for-unused-variables (list)
(dolist (variable list)
(when (and (not (variable-special-p variable))
(zerop (variable-reads variable))
(zerop (variable-writes variable)))
(unused-variable variable))))
(declaim (ftype (function (t) t) emit-new-closure-binding))
(defun emit-new-closure-binding (variable)
""
(emit-new +lisp-closure-binding+) ;; value c-b
(emit 'dup_x1) ;; c-b value c-b
(emit 'swap) ;; c-b c-b value
(emit-invokespecial-init +lisp-closure-binding+
(list +lisp-object+)) ;; c-b
(aload (compiland-closure-register *current-compiland*))
;; c-b array
(emit 'swap) ;; array c-b
(emit-push-constant-int (variable-closure-index variable))
;; array c-b int
(emit 'swap) ; array index value
(emit 'aastore))
;; Generates code to bind variable to value at top of runtime stack.
(declaim (ftype (function (t) t) compile-binding))
(defun compile-binding (variable)
(cond ((variable-register variable)
(astore (variable-register variable)))
((variable-special-p variable)
(emit-push-current-thread)
(emit 'swap)
(emit-push-variable-name variable)
(emit 'swap)
(emit-invokevirtual +lisp-thread+ "bindSpecial"
(list +lisp-symbol+ +lisp-object+)
+lisp-special-binding+)
(if (variable-binding-register variable)
(astore (variable-binding-register variable))
(emit 'pop)))
((variable-closure-index variable) ;; stack:
(emit-new-closure-binding variable))
(t
(sys::%format t "compile-binding~%")
(aver nil))))
(defknown compile-progn-body (t t &optional t) t)
(defun compile-progn-body (body target &optional representation)
(cond ((null body)
(when target
(emit-push-nil)
(emit-move-from-stack target)))
(t
(loop
with clear-values = nil
for tail on body
for form = (car tail)
do (cond
((null (cdr tail))
;; Last form.
(when clear-values
(emit-clear-values))
(compile-form form target representation)
(return))
(t
;; Not the last form.
(compile-form form nil nil)
(unless clear-values
(unless (single-valued-p form)
(setq clear-values t))))))))
t)
(defun restore-dynamic-environment (register)
(emit-push-current-thread)
(aload register)
(emit-invokevirtual +lisp-thread+ "resetSpecialBindings"
(list +lisp-special-bindings-mark+) nil)
)
(defun save-dynamic-environment (register)
(emit-push-current-thread)
(emit-invokevirtual +lisp-thread+ "markSpecialBindings"
nil +lisp-special-bindings-mark+)
(astore register)
)
(defun p2-m-v-b-node (block target)
(let* ((*register* *register*)
(form (m-v-b-form block))
(*visible-variables* *visible-variables*)
(vars (second form))
(bind-special-p nil)
(variables (m-v-b-vars block)))
(dolist (variable variables)
(let ((special-p (variable-special-p variable)))
(cond (special-p
(setf bind-special-p t))
(t
(unless (variable-closure-index variable)
(setf (variable-register variable)
(allocate-register nil)))))))
;; If we're going to bind any special variables...
(when bind-special-p
(dformat t "p2-m-v-b-node lastSpecialBinding~%")
;; Save current dynamic environment.
(setf (m-v-b-environment-register block) (allocate-register nil))
(save-dynamic-environment (m-v-b-environment-register block)))
;; Make sure there are no leftover values from previous calls.
(emit-clear-values)
;; Bind the variables.
(aver (= (length vars) (length variables)))
(cond ((= (length vars) 1)
(compile-forms-and-maybe-emit-clear-values (third form) 'stack nil)
(compile-binding (car variables)))
(t
(let* ((*register* *register*)
(result-register (allocate-register nil))
(values-register (allocate-register nil))
(LABEL1 (gensym))
(LABEL2 (gensym)))
;; Store primary value from values form in result register.
(compile-form (third form) result-register nil)
;; Store values from values form in values register.
(emit-push-current-thread)
(emit-getfield +lisp-thread+ "_values" +lisp-object-array+)
(emit-move-from-stack values-register)
;; Did we get just one value?
(aload values-register)
(emit 'ifnull LABEL1)
;; Reaching here, we have multiple values (or no values at all).
;; We need the slow path if we have more variables than values.
(aload values-register)
(emit 'arraylength)
(emit-push-constant-int (length vars))
(emit 'if_icmplt LABEL1)
;; Reaching here, we have enough values for all the variables.
;; We can use the values we have. This is the fast path.
(aload values-register)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-current-thread)
(aload result-register)
(emit-push-constant-int (length vars))
(emit-invokevirtual +lisp-thread+ "getValues"
(list +lisp-object+ :int) +lisp-object-array+)
;; Values array is now on the stack at runtime.
(label LABEL2)
(let ((index 0))
(dolist (variable variables)
(when (< index (1- (length vars)))
(emit 'dup))
(emit-push-constant-int index)
(incf index)
(emit 'aaload)
;; Value is on the runtime stack at this point.
(compile-binding variable)))
(maybe-emit-clear-values (third form)))))
;; Make the variables visible for the body forms.
(dolist (variable variables)
(push variable *visible-variables*))
(dolist (variable (m-v-b-free-specials block))
(push variable *visible-variables*))
;; Body.
(with-saved-compiler-policy
(process-optimization-declarations (cdddr form))
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body (cdddr form) target)))
(when bind-special-p
(restore-dynamic-environment (m-v-b-environment-register block)))))
(defun propagate-vars (block)
(let ((removed '()))
(dolist (variable (let-vars block))
(unless (or (variable-special-p variable)
(variable-closure-index variable))
(when (eql (variable-writes variable) 0)
;; There are no writes to the variable.
(let ((initform (variable-initform variable)))
(cond ((var-ref-p initform)
(let ((source-var (var-ref-variable initform)))
(cond ((null source-var)
(aver (var-ref-constant-p initform))
(let ((value (var-ref-constant-value initform)))
(dolist (ref (variable-references variable))
(aver (eq (var-ref-variable ref) variable))
(setf (var-ref-variable ref) nil
(var-ref-constant-p ref) t
(var-ref-constant-value ref) value))))
(t
(unless (or (variable-special-p source-var)
(variable-used-non-locally-p source-var))
(when (eql (variable-writes source-var) 0)
;; We can eliminate the variable.
;; FIXME This may no longer be true when we start tracking writes!
(aver (= (variable-reads variable)
(length (variable-references variable))))
(dolist (ref (variable-references variable))
(aver (eq (var-ref-variable ref) variable))
(setf (var-ref-variable ref) source-var))
;; Check for DOTIMES limit variable.
(when (get (variable-name variable)
'sys::dotimes-limit-variable-p)
(let* ((symbol (get (variable-name variable)
'sys::dotimes-index-variable-name))
(index-variable (find-variable symbol (let-vars block))))
(when index-variable
(setf (get (variable-name index-variable)
'sys::dotimes-limit-variable-name)
(variable-name source-var)))))
(push variable removed)))))))
((fixnump initform)
(dolist (ref (variable-references variable))
(aver (eq (var-ref-variable ref) variable))
(setf (var-ref-variable ref) nil
(var-ref-constant-p ref) t
(var-ref-constant-value ref) initform))
(push variable removed)))))))
(when removed
(dolist (variable removed)
(setf (let-vars block) (remove variable (let-vars block)))))))
(defun derive-variable-representation (variable block
&key (type nil type-supplied-p))
(when (not (null (variable-representation variable)))
;; representation already derived
(return-from derive-variable-representation))
(when type-supplied-p
(setf (variable-declared-type variable) type))
(when (or (variable-closure-index variable)
(variable-index variable))
;; variables in one of the arrays cannot be represented
;; other than by the boxed representation LispObject
(return-from derive-variable-representation))
(let ((type (variable-declared-type variable)))
(when (and (eq (variable-declared-type variable) :none)
(eql (variable-writes variable) 0))
(variable-derived-type variable))
(cond ((neq type :none)
(setf (variable-representation variable)
(type-representation type))
(unless (memq (variable-representation variable) '(:int :long))
;; We don't support unboxed variables other than INT and LONG (yet)
(setf (variable-representation variable) NIL)))
((zerop (variable-writes variable))
(when (eq :none (variable-derived-type variable))
(setf (variable-derived-type variable)
(derive-compiler-type (variable-initform variable))))
(let ((derived-type (variable-derived-type variable)))
(setf (variable-derived-type variable) derived-type)
(setf (variable-representation variable)
(type-representation derived-type))
(unless (memq (variable-representation variable) '(:int :long))
;; We don't support unboxed variables other than INT and LONG (yet)
(setf (variable-representation variable) NIL))))
((and block
(get (variable-name variable) 'sys::dotimes-index-variable-p))
;; DOTIMES index variable.
(let* ((name (get (variable-name variable)
'sys::dotimes-limit-variable-name))
(limit-variable (and name
(or (find-variable name
(let-vars block))
(find-visible-variable name)))))
(when limit-variable
(derive-variable-representation limit-variable block)
(setf (variable-representation variable)
(variable-representation limit-variable))
(let ((limit-type (variable-derived-type limit-variable)))
(when (integer-type-p limit-type)
(setf (variable-derived-type variable)
(%make-integer-type 0 (integer-type-high limit-type)))))))))))
(defun allocate-variable-register (variable)
(setf (variable-register variable)
(allocate-register (variable-representation variable))))
(defun emit-move-to-variable (variable)
(let ((representation (variable-representation variable)))
(cond ((variable-register variable)
(emit (ecase (variable-representation variable)
((:int :boolean :char)
'istore)
(:long 'lstore)
(:float 'fstore)
(:double 'dstore)
((nil) 'astore))
(variable-register variable)))
((variable-index variable)
(aload (compiland-argument-register *current-compiland*))
(emit-swap representation nil)
(emit-push-constant-int (variable-index variable))
(emit-swap representation :int)
(emit 'aastore))
((variable-closure-index variable)
(aload (compiland-closure-register *current-compiland*))
(emit-push-constant-int (variable-closure-index variable))
(emit 'aaload)
(emit-swap representation nil)
(emit-putfield +lisp-closure-binding+ "value" +lisp-object+))
((variable-environment variable)
(assert (not *file-compilation*))
(emit-load-externalized-object (variable-environment variable)
+lisp-environment+)
(emit 'swap)
(emit-push-variable-name variable)
(emit 'swap)
(emit-invokevirtual +lisp-environment+ "rebind"
(list +lisp-symbol+ +lisp-object+)
nil))
(t
(assert nil)))))
(defun emit-push-variable (variable)
(cond ((variable-register variable)
(emit (ecase (variable-representation variable)
((:int :boolean :char)
'iload)
(:long 'lload)
(:float 'fload)
(:double 'dload)
((nil) 'aload))
(variable-register variable)))
((variable-index variable)
(aload (compiland-argument-register *current-compiland*))
(emit-push-constant-int (variable-index variable))
(emit 'aaload))
((variable-closure-index variable)
(aload (compiland-closure-register *current-compiland*))
(emit-push-constant-int (variable-closure-index variable))
(emit 'aaload)
(emit-getfield +lisp-closure-binding+ "value" +lisp-object+))
((variable-environment variable)
(assert (not *file-compilation*))
(emit-load-externalized-object (variable-environment variable)
+lisp-environment+)
(emit-push-variable-name variable)
(emit-invokevirtual +lisp-environment+ "lookup"
(list +lisp-object+)
+lisp-object+))
(t
(assert nil))))
(defknown p2-let-bindings (t) t)
(defun p2-let-bindings (block)
(dolist (variable (let-vars block))
(unless (or (variable-special-p variable)
(variable-closure-index variable)
(zerop (variable-reads variable)))
(aver (null (variable-register variable)))
(setf (variable-register variable) t)))
(let (must-clear-values
temporary-storage)
(declare (type boolean must-clear-values))
;; Evaluate each initform. If the variable being bound is special, allocate
;; a temporary register for the result; LET bindings must be done in
;; parallel, so we can't modify any specials until all the initforms have
;; been evaluated. Note that we can't just push the values on the stack
;; because we'll lose JVM stack consistency if there is a non-local
;; transfer of control from one of the initforms.
(dolist (variable (let-vars block))
(let* ((initform (variable-initform variable))
(unused-p (and (not (variable-special-p variable))
;; If it's never read, we don't care about writes.
(zerop (variable-reads variable)))))
(cond (unused-p
(compile-form initform nil nil)) ; for effect
(t
(cond (initform
(when (eq (variable-register variable) t)
(derive-variable-representation variable block))
(compile-form initform 'stack
(variable-representation variable))
(unless must-clear-values
(unless (single-valued-p initform)
(setf must-clear-values t))))
(t
;; No initform.
(emit-push-nil)))
(when (eq (variable-register variable) t)
;; Now allocate the register.
(allocate-variable-register variable))
(when (variable-special-p variable)
(setf (variable-binding-register variable)
(allocate-register nil)))
(cond ((variable-special-p variable)
(let ((temp-register (allocate-register nil)))
;; FIXME: this permanently allocates a register
;; which has only a single local use
(push (cons temp-register variable)
temporary-storage)
(emit-move-from-stack temp-register)))
((variable-representation variable)
(emit-move-to-variable variable))
(t
(compile-binding variable)))))))
(when must-clear-values
(emit-clear-values))
;; Now that all the initforms have been evaluated, move the results from
;; the temporary registers (if any) to their proper destinations.
(dolist (temp temporary-storage)
(aload (car temp))
(compile-binding (cdr temp))))
;; Now make the variables visible.
(dolist (variable (let-vars block))
(push variable *visible-variables*))
t)
(defknown p2-let*-bindings (t) t)
(defun p2-let*-bindings (block)
(let ((must-clear-values nil))
(declare (type boolean must-clear-values))
;; Generate code to evaluate initforms and bind variables.
(dolist (variable (let-vars block))
(let* ((initform (variable-initform variable))
(unused-p (and (not (variable-special-p variable))
(zerop (variable-reads variable))
(zerop (variable-writes variable))))
(boundp nil))
(declare (type boolean unused-p boundp))
(macrolet ((update-must-clear-values ()
`(unless must-clear-values
(unless (single-valued-p initform)
(setf must-clear-values t)))))
(cond ((and (variable-special-p variable)
(eq initform (variable-name variable)))
;; The special case of binding a special to its current value.
(emit-push-current-thread)
(emit-push-variable-name variable)
(emit-invokevirtual +lisp-thread+
"bindSpecialToCurrentValue"
(list +lisp-symbol+)
+lisp-special-binding+)
(if (variable-binding-register variable)
(astore (variable-binding-register variable))
(emit 'pop))
(setf boundp t))
((and (not (variable-special-p variable))
(zerop (variable-reads variable)))
;; We don't have to bind it if we never read it.
(compile-form initform nil nil) ; for effect
(update-must-clear-values)
(setf boundp t))
((null initform)
(cond ((and (null (variable-closure-index variable))
(not (variable-special-p variable))
(eq (variable-declared-type variable) 'BOOLEAN))
(setf (variable-representation variable) :boolean)
(setf (variable-register variable)
(allocate-register nil))
(emit 'iconst_0)
(emit 'istore (variable-register variable))
(setf boundp t))
(t
(emit-push-nil))))
(t
(cond (unused-p
(compile-form initform nil nil) ; for effect
(update-must-clear-values)
(setf boundp t))
((and (null (variable-closure-index variable))
(not (variable-special-p variable)))
(when (and (eq (variable-declared-type variable) :none)
(eql (variable-writes variable) 0))
(setf (variable-derived-type variable)
(derive-compiler-type initform)))
(derive-variable-representation variable block)
(allocate-variable-register variable)
(compile-form initform 'stack
(variable-representation variable))
(update-must-clear-values)
(emit-move-to-variable variable)
(setf boundp t))
(t
(compile-form initform 'stack nil)
(update-must-clear-values))))))
(unless (or boundp (variable-special-p variable))
(unless (or (variable-closure-index variable)
(variable-register variable))
(setf (variable-register variable)
(allocate-register nil))))
(push variable *visible-variables*)
(unless boundp
(when (variable-special-p variable)
(setf (variable-binding-register variable)
(allocate-register nil)))
(compile-binding variable))
(maybe-generate-type-check variable)))
(when must-clear-values
(emit-clear-values)))
t)
(defun p2-let/let*-node (block target representation)
(let* (
(*register* *register*)
(form (let-form block))
(*visible-variables* *visible-variables*)
(specialp nil))
;; Walk the variable list looking for special bindings and unused lexicals.
(dolist (variable (let-vars block))
(cond ((variable-special-p variable)
(setf specialp t))
((zerop (variable-reads variable))
(unused-variable variable))))
;; If there are any special bindings...
(when specialp
;; We need to save current dynamic environment.
(setf (let-environment-register block) (allocate-register nil))
(save-dynamic-environment (let-environment-register block)))
(propagate-vars block)
(ecase (car form)
(LET
(p2-let-bindings block))
(LET*
(p2-let*-bindings block)))
;; Make declarations of free specials visible.
(dolist (variable (let-free-specials block))
(push variable *visible-variables*))
;; Body of LET/LET*.
(with-saved-compiler-policy
(process-optimization-declarations (cddr form))
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body (cddr form) target representation)))
(when specialp
(restore-dynamic-environment (let-environment-register block)))))
(defknown p2-locally-node (t t t) t)
(defun p2-locally-node (block target representation)
(with-saved-compiler-policy
(let* ((body (cdr (locally-form block)))
(*visible-variables* (append (locally-free-specials block)
*visible-variables*))
(*blocks* (cons block *blocks*)))
(process-optimization-declarations body)
(compile-progn-body body target representation))))
(defknown p2-tagbody-node (t t) t)
(defun p2-tagbody-node (block target)
(let* ((*blocks* (cons block *blocks*))
(*visible-tags* *visible-tags*)
(*register* *register*)
(form (tagbody-form block))
(body (cdr form))
(BEGIN-BLOCK (gensym "F"))
(END-BLOCK (gensym "U"))
(RETHROW (gensym "T"))
(EXIT (gensym "E"))
(must-clear-values nil)
(specials-register (when (tagbody-non-local-go-p block)
(allocate-register nil))))
;; Scan for tags.
(dolist (tag (tagbody-tags block))
(push tag *visible-tags*))
(when (tagbody-id-variable block)
;; we have a block variable; that should be a closure variable
(assert (not (null (variable-closure-index (tagbody-id-variable block)))))
(emit-new +lisp-object+)
(emit 'dup)
(emit-invokespecial-init +lisp-object+ '())
(emit-new-closure-binding (tagbody-id-variable block)))
(when (tagbody-non-local-go-p block)
(save-dynamic-environment specials-register))
(label BEGIN-BLOCK)
(do* ((rest body (cdr rest))
(subform (car rest) (car rest)))
((null rest))
(cond ((or (symbolp subform) (integerp subform))
(let ((tag (find subform (tagbody-tags block) :key #'tag-name
:test #'eql)))
(unless tag
(error "COMPILE-TAGBODY: tag not found: ~S~%" subform))
(when (tag-used tag)
(label (tag-label tag)))))
(t
(compile-form subform nil nil)
(unless must-clear-values
(setf must-clear-values
(not (single-valued-p subform)))))))
(label END-BLOCK)
(emit 'goto EXIT)
(when (tagbody-non-local-go-p block)
; We need a handler to catch non-local GOs.
(let* ((HANDLER (gensym "H"))
(EXTENT-EXIT-HANDLER (gensym "HE"))
(*register* *register*)
(go-register (allocate-register nil))
(tag-register (allocate-register nil)))
(label HANDLER)
;; The Go object is on the runtime stack. Stack depth is 1.
(emit 'dup)
(astore go-register)
;; Get the tag.
(emit-getfield +lisp-go+ "tagbody" +lisp-object+) ; Stack depth is still 1.
(emit-push-variable (tagbody-id-variable block))
(emit 'if_acmpne RETHROW) ;; Not this TAGBODY
(aload go-register)
(emit-getfield +lisp-go+ "tag" +lisp-object+) ; Stack depth is still 1.
(astore tag-register)
(restore-dynamic-environment specials-register)
;; Don't actually generate comparisons for tags
;; to which there is no non-local GO instruction
(dolist (tag (remove-if-not #'tag-used-non-locally
(tagbody-tags block)))
(aload tag-register)
(emit-load-externalized-object (tag-label tag))
;; Jump if EQ.
(emit 'if_acmpeq (tag-label tag)))
(label RETHROW)
;; Not found. Re-throw Go.
(aload go-register)
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (tagbody-id-variable block))
(emit 'athrow)
(label EXTENT-EXIT-HANDLER)
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (tagbody-id-variable block))
(emit 'athrow)
;; Finally...
(add-exception-handler BEGIN-BLOCK END-BLOCK HANDLER +lisp-go+)
(add-exception-handler BEGIN-BLOCK END-BLOCK EXTENT-EXIT-HANDLER nil)))
(label EXIT)
(when (tagbody-non-local-go-p block)
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (tagbody-id-variable block)))
(when must-clear-values
(emit-clear-values))
;; TAGBODY returns NIL.
(when target
(emit-push-nil)
(emit-move-from-stack target)))
)
(defknown p2-go (t t t) t)
(defun p2-go (form target representation)
;; FIXME What if we're called with a non-NIL representation?
(declare (ignore target representation))
(let* ((node form)
(form (node-form form))
(name (cadr form))
(tag (jump-target-tag node))
(tag-block (when tag (jump-target-block node))))
(unless tag
(error "p2-go: tag not found: ~S" name))
(when (and (eq (tag-compiland tag) *current-compiland*)
(not (enclosed-by-protected-block-p tag-block)))
;; Local case with local transfer of control
;; Note: Local case with non-local transfer of control handled below
(when (and (tagbody-needs-environment-restoration tag-block)
(enclosed-by-environment-setting-block-p tag-block))
;; If there's a dynamic environment to restore, do it.
(restore-dynamic-environment (environment-register-to-restore tag-block)))
(maybe-generate-interrupt-check)
(emit 'goto (tag-label tag))
(return-from p2-go))
;; Non-local GO.
(emit-push-variable (tagbody-id-variable tag-block))
(emit-load-externalized-object (tag-label tag)) ; Tag.
(emit-invokestatic +lisp+ "nonLocalGo" (lisp-object-arg-types 2)
+lisp-object+)
;; Following code will not be reached, but is needed for JVM stack
;; consistency.
(emit 'areturn)))
(defknown p2-atom (t t t) t)
(define-inlined-function p2-atom (form target representation)
((aver (or (null representation) (eq representation :boolean)))
(check-arg-count form 1))
(compile-forms-and-maybe-emit-clear-values (cadr form) 'stack nil)
(emit-instanceof +lisp-cons+)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'ifeq LABEL1)
(ecase representation
(:boolean
(emit 'iconst_0))
((nil)
(emit-push-nil)))
(emit 'goto LABEL2)
(label LABEL1)
(ecase representation
(:boolean
(emit 'iconst_1))
((nil)
(emit-push-t)))
(label LABEL2)
(emit-move-from-stack target representation)))
(defknown p2-instanceof-predicate (t t t t) t)
(defun p2-instanceof-predicate (form target representation java-class)
(unless (check-arg-count form 1)
(compile-function-call form target representation)
(return-from p2-instanceof-predicate))
(let ((arg (%cadr form)))
(cond ((null target)
(compile-forms-and-maybe-emit-clear-values arg nil nil))
(t
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-instanceof java-class)
(convert-representation :boolean representation)
(emit-move-from-stack target representation)))))
(defun p2-bit-vector-p (form target representation)
(p2-instanceof-predicate form target representation +lisp-abstract-bit-vector+))
(defun p2-characterp (form target representation)
(p2-instanceof-predicate form target representation +lisp-character+))
(defun p2-consp (form target representation)
(p2-instanceof-predicate form target representation +lisp-cons+))
(defun p2-fixnump (form target representation)
(p2-instanceof-predicate form target representation +lisp-fixnum+))
(defun p2-packagep (form target representation)
(p2-instanceof-predicate form target representation +lisp-package+))
(defun p2-readtablep (form target representation)
(p2-instanceof-predicate form target representation +lisp-readtable+))
(defun p2-simple-vector-p (form target representation)
(p2-instanceof-predicate form target representation +lisp-simple-vector+))
(defun p2-stringp (form target representation)
(p2-instanceof-predicate form target representation +lisp-abstract-string+))
(defun p2-symbolp (form target representation)
(p2-instanceof-predicate form target representation +lisp-symbol+))
(defun p2-vectorp (form target representation)
(p2-instanceof-predicate form target representation +lisp-abstract-vector+))
(define-inlined-function p2-coerce-to-function (form target representation)
((check-arg-count form 1))
(compile-forms-and-maybe-emit-clear-values (%cadr form) 'stack nil)
(emit-invokestatic +lisp+ "coerceToFunction"
(lisp-object-arg-types 1) +lisp-object+)
(emit-move-from-stack target))
(defun p2-block-node (block target representation)
(unless (block-node-p block)
(sys::%format t "type-of block = ~S~%" (type-of block))
(aver (block-node-p block)))
(let* ((*blocks* (cons block *blocks*))
(*register* *register*)
(BEGIN-BLOCK (gensym "F"))
(END-BLOCK (gensym "U"))
(BLOCK-EXIT (block-exit block))
(specials-register (when (block-non-local-return-p block)
(allocate-register nil))))
(setf (block-target block) target)
(when (block-id-variable block)
;; we have a block variable; that should be a closure variable
(assert (not (null (variable-closure-index (block-id-variable block)))))
(emit-new +lisp-object+)
(emit 'dup)
(emit-invokespecial-init +lisp-object+ '())
(emit-new-closure-binding (block-id-variable block)))
(dformat t "*all-variables* = ~S~%"
(mapcar #'variable-name *all-variables*))
(when (block-non-local-return-p block)
(save-dynamic-environment specials-register))
(label BEGIN-BLOCK) ; Start of protected range, for non-local returns
;; Implicit PROGN.
(compile-progn-body (cddr (block-form block)) target)
(label END-BLOCK) ; End of protected range, for non-local returns
(when (block-non-local-return-p block)
;; We need a handler to catch non-local RETURNs.
(emit 'goto BLOCK-EXIT) ; Jump over handler, when inserting one
(let ((HANDLER (gensym "H"))
(EXTENT-EXIT-HANDLER (gensym "HE"))
(THIS-BLOCK (gensym)))
(label HANDLER)
;; The Return object is on the runtime stack. Stack depth is 1.
(emit 'dup) ; Stack depth is 2.
(emit-getfield +lisp-return+ "tag" +lisp-object+) ; Still 2.
(emit-push-variable (block-id-variable block))
;; If it's not the block we're looking for...
(emit 'if_acmpeq THIS-BLOCK) ; Stack depth is 1.
;; Not the tag we're looking for.
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (block-id-variable block))
(emit 'athrow)
(label EXTENT-EXIT-HANDLER)
;; Not the tag we're looking for.
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (block-id-variable block))
(emit 'athrow)
(label THIS-BLOCK)
(restore-dynamic-environment specials-register)
(emit-getfield +lisp-return+ "result" +lisp-object+)
(emit-move-from-stack target) ; Stack depth is 0.
;; Finally...
(add-exception-handler BEGIN-BLOCK END-BLOCK HANDLER +lisp-return+)
(add-exception-handler BEGIN-BLOCK END-BLOCK EXTENT-EXIT-HANDLER nil)))
(label BLOCK-EXIT)
(when (block-id-variable block)
(emit 'aconst_null) ;; load null value
(emit-move-to-variable (block-id-variable block)))
(fix-boxing representation nil)))
(defknown p2-return-from (t t t) t)
(defun p2-return-from (form target representation)
;; FIXME What if we're called with a non-NIL representation?
(declare (ignore target representation))
(let* ((node form)
(form (node-form form))
(name (second form))
(result-form (third form))
(block (jump-target-block node)))
(when (null block)
(error "No block named ~S is currently visible." name))
(let ((compiland *current-compiland*))
(when (eq (block-compiland block) compiland)
;; Local case. Is the RETURN nested inside an UNWIND-PROTECT which is
;; inside the block we're returning from?
(unless (enclosed-by-protected-block-p block)
(emit-clear-values)
(compile-form result-form (block-target block) nil)
(when (and (block-needs-environment-restoration block)
(enclosed-by-environment-setting-block-p block))
(restore-dynamic-environment (environment-register-to-restore block)))
(emit 'goto (block-exit block))
(return-from p2-return-from))))
;; Non-local RETURN.
(aver (block-non-local-return-p block))
(emit-clear-values)
(with-operand-accumulation
((emit-variable-operand (block-id-variable block))
(emit-load-externalized-object-operand (block-name block))
(compile-operand result-form nil))
(emit-invokestatic +lisp+ "nonLocalReturn" (lisp-object-arg-types 3)
+lisp-object+))
;; Following code will not be reached, but is needed for JVM stack
;; consistency.
(emit 'areturn)))
(defun emit-car/cdr (arg target representation field)
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invoke-method field target representation))
(define-inlined-function p2-car (form target representation)
((check-arg-count form 1))
(let ((arg (%cadr form)))
(cond ((and (null target) (< *safety* 3))
(compile-form arg target nil))
((and (consp arg) (eq (%car arg) 'cdr) (= (length arg) 2))
(compile-forms-and-maybe-emit-clear-values (second arg) 'stack nil)
(emit-invoke-method "cadr" target representation))
(t
(emit-car/cdr arg target representation "car")))))
(define-inlined-function p2-cdr (form target representation)
((check-arg-count form 1))
(let ((arg (%cadr form)))
(emit-car/cdr arg target representation "cdr")))
(define-inlined-function p2-cons (form target representation)
((check-arg-count form 2))
(let* ((args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(cons-register (when (some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks args))
(allocate-register nil))))
(emit-new +lisp-cons+)
(if cons-register
(astore cons-register)
(emit 'dup))
(with-operand-accumulation
((when cons-register
(emit-register-operand cons-register nil))
(compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokespecial-init +lisp-cons+ (lisp-object-arg-types 2))
(when cons-register
(emit-push-register cons-register nil))
(emit-move-from-stack target)))
(defun compile-progn (form target representation)
(compile-progn-body (cdr form) target)
(fix-boxing representation nil))
(defun p2-eval-when (form target representation)
(cond ((or (memq :execute (cadr form))
(memq 'eval (cadr form)))
(compile-progn-body (cddr form) target)
(fix-boxing representation nil))
(t
(emit-push-nil)
(emit-move-from-stack target))))
(defun p2-load-time-value (form target representation)
(cond (*file-compilation*
(emit-getstatic *this-class*
(declare-load-time-value (second form)) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-constant (eval (second form)) target representation))))
(defun p2-progv-node (block target representation)
(let* ((form (progv-form block))
(symbols-form (cadr form))
(values-form (caddr form))
(*register* *register*)
(environment-register
(setf (progv-environment-register block) (allocate-register nil))))
(with-operand-accumulation
((compile-operand symbols-form nil)
(compile-operand values-form nil))
(unless (and (single-valued-p symbols-form)
(single-valued-p values-form))
(emit-clear-values))
(save-dynamic-environment environment-register)
;; Compile call to Lisp.progvBindVars().
(emit-push-current-thread)
(emit-invokestatic +lisp+ "progvBindVars"
(list +lisp-object+ +lisp-object+ +lisp-thread+) nil))
;; Implicit PROGN.
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body (cdddr form) target representation))
(restore-dynamic-environment environment-register)))
(defun p2-quote (form target representation)
(aver (or (null representation) (eq representation :boolean)))
(let ((obj (second form)))
(cond ((null obj)
(when target
(emit-push-false representation)
(emit-move-from-stack target representation)))
((eq representation :boolean)
(emit 'iconst_1)
(emit-move-from-stack target representation))
((symbolp obj)
(emit-load-externalized-object obj)
(emit-move-from-stack target representation))
((listp obj)
(emit-load-externalized-object obj)
(emit-move-from-stack target representation))
((constantp obj)
(compile-constant obj target representation))
(t
(compiler-unsupported "COMPILE-QUOTE: unsupported case: ~S" form)))))
(define-inlined-function p2-rplacd (form target representation)
((check-arg-count form 2))
(let* ((args (cdr form))
(*register* *register*)
(target-register (allocate-register nil)))
(with-operand-accumulation
((accumulate-operand (nil
:unsafe-p (some-nested-block
#'node-opstack-unsafe-p
(find-enclosed-blocks (first args))))
(compile-form (first args) 'stack nil)
(when target-register
(emit 'dup)
(astore target-register)))
(compile-operand (second args) nil)))
(maybe-emit-clear-values (car args) (cadr args))
(emit-invokevirtual +lisp-object+
"setCdr"
(lisp-object-arg-types 1)
nil)
(when target-register
(aload target-register)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
(define-inlined-function p2-set-car/cdr (form target representation)
((check-arg-count form 2))
(let* ((op (%car form))
(args (%cdr form))
(*register* *register*)
(target-register (when target (allocate-register nil))))
(with-operand-accumulation
((compile-operand (%car args) nil)
(accumulate-operand (nil
:unsafe-p (some-nested-block
#'node-opstack-unsafe-p
(find-enclosed-blocks (cadr args))))
(compile-form (%cadr args) 'stack nil)
(when target-register
(emit 'dup)
(astore target-register)))
(maybe-emit-clear-values (car args) (cadr args))))
(emit-invokevirtual +lisp-object+
(if (eq op 'sys:set-car) "setCar" "setCdr")
(lisp-object-arg-types 1)
nil)
(when target-register
(aload target-register)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
(defun compile-declare (form target representation)
(declare (ignore form representation))
(when target
(emit-push-nil)
(emit-move-from-stack target)))
(defun compile-local-function (local-function)
(let* ((compiland (local-function-compiland local-function))
(pathname (funcall *pathnames-generator*))
(class-file (make-abcl-class-file :pathname pathname))
(stream (unless *file-compilation*
(sys::%make-byte-array-output-stream))))
(setf (compiland-class-file compiland) class-file)
(with-open-stream (f (or stream
(open pathname :direction :output
:element-type '(unsigned-byte 8)
:if-exists :supersede)))
(with-class-file class-file
(compile-to-jvm-class compiland)
(finish-class (compiland-class-file compiland) f)))
(when stream
(let ((bytes (sys::%get-output-stream-bytes stream)))
(sys::put-memory-function *memory-class-loader*
(class-name-internal
(abcl-class-file-class-name
(compiland-class-file compiland)))
bytes)))))
(defknown p2-flet-node (t t t) t)
(defun p2-flet-node (block target representation)
(let* ((form (flet-form block))
(*local-functions* *local-functions*)
(*visible-variables* *visible-variables*)
(local-functions (cadr form))
(body (cddr form)))
(dolist (local-function local-functions)
(compile-local-function local-function))
(dolist (local-function local-functions)
(push local-function *local-functions*))
(dolist (special (flet-free-specials block))
(push special *visible-variables*))
(with-saved-compiler-policy
(process-optimization-declarations body)
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body body target representation)))))
(defknown p2-labels-node (t t t) t)
(defun p2-labels-node (block target representation)
(let* ((form (labels-form block))
(*local-functions* *local-functions*)
(*visible-variables* *visible-variables*)
(local-functions (cadr form))
(body (cddr form)))
(dolist (local-function local-functions)
(push local-function *local-functions*))
(dolist (local-function local-functions)
(compile-local-function local-function))
(dolist (special (labels-free-specials block))
(push special *visible-variables*))
(with-saved-compiler-policy
(process-optimization-declarations body)
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body body target representation)))))
(defun p2-lambda (local-function target)
(compile-local-function local-function)
(emit-load-local-function local-function)
(emit-move-from-stack target))
(defknown p2-function (t t t) t)
(defun p2-function (form target representation)
;; FIXME What if we're called with a non-NIL representation?
(declare (ignore representation))
(let ((name (second form))
local-function)
(cond
((symbolp name)
(dformat t "p2-function case 1~%")
(cond
((setf local-function (find-local-function name))
(dformat t "p2-function 1~%")
(emit-load-local-function local-function)
(emit-move-from-stack target))
((inline-ok name)
;; ### FASLATONCE: when compiling fasl functions after the
;; full fasl has been processed, forward referenced functions
;; may not be available during the load process
;; This case is particularly triggered with circular referencing
;; functions, both marked as 'notinline'
(emit-getstatic *this-class*
(declare-function name) +lisp-object+)
(emit-move-from-stack target))
(t
(emit-load-externalized-object name)
(emit-invokevirtual +lisp-object+ "getSymbolFunctionOrDie"
nil +lisp-object+)
(emit-move-from-stack target))))
((and (consp name) (eq (%car name) 'SETF))
(dformat t "p2-function case 2~%")
;; FIXME Need to check for NOTINLINE declaration!
(cond
((setf local-function (find-local-function name))
(dformat t "p2-function 1~%")
(emit-load-local-function local-function))
((and (member name *functions-defined-in-current-file* :test #'equal)
(not (notinline-p name)))
;; ### FASLATONCE: when compiling fasl functions after the
;; full fasl has been processed, forward referenced functions
;; may not be available during the load process
;; This case is particularly triggered with circular referencing
;; functions, both marked as 'notinline'
(emit-getstatic *this-class*
(declare-setf-function name) +lisp-object+)
(emit-move-from-stack target))
((and (null *file-compilation*)
(fboundp name)
(fdefinition name))
(emit-load-externalized-object (fdefinition name))
(emit-move-from-stack target))
(t
(emit-load-externalized-object (cadr name))
(emit-invokevirtual +lisp-symbol+
"getSymbolSetfFunctionOrDie"
nil +lisp-object+)
(emit-move-from-stack target))))
((local-function-p name)
(dformat t "p2-function case 3~%")
(p2-lambda name target))
(t
(compiler-unsupported "p2-function: unsupported case: ~S" form)))))
(defknown p2-ash (t t t) t)
(define-inlined-function p2-ash (form target representation)
((check-arg-count form 2))
(let* ((args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2))
(low2 (and (fixnum-type-p type2) (integer-type-low type2)))
(high2 (and (fixnum-type-p type2) (integer-type-high type2)))
(constant-shift (fixnum-constant-value type2))
(result-type (derive-compiler-type form)))
(cond ((and (integerp arg1) (integerp arg2))
(compile-constant (ash arg1 arg2) target representation))
((and constant-shift
;; ishl/ishr only use the low five bits of the mask.
(<= -31 constant-shift 31)
(fixnum-type-p type1)
(fixnum-type-p result-type))
(compile-form arg1 'stack :int)
(cond ((plusp constant-shift)
(compile-form arg2 'stack :int)
(maybe-emit-clear-values arg1 arg2)
(emit 'ishl))
((minusp constant-shift)
(cond ((fixnump arg2)
(emit-push-constant-int (- arg2)))
(t
(compile-form arg2 'stack :int)
(emit 'ineg)))
(maybe-emit-clear-values arg1 arg2)
(emit 'ishr))
((zerop constant-shift)
(compile-form arg2 nil nil))) ; for effect
(convert-representation :int representation)
(emit-move-from-stack target representation))
((and constant-shift
;; lshl/lshr only use the low six bits of the mask.
(<= -63 constant-shift 63)
(java-long-type-p type1)
(java-long-type-p result-type))
(compile-form arg1 'stack :long)
(cond ((plusp constant-shift)
(compile-form arg2 'stack :int)
(maybe-emit-clear-values arg1 arg2)
(emit 'lshl))
((minusp constant-shift)
(cond ((fixnump arg2)
(emit-push-constant-int (- arg2)))
(t
(compile-form arg2 'stack :int)
(emit 'ineg)))
(maybe-emit-clear-values arg1 arg2)
(emit 'lshr))
((zerop constant-shift)
(compile-form arg2 nil nil))) ; for effect
(convert-representation :long representation)
(emit-move-from-stack target representation))
((and (fixnum-type-p type1)
low2 high2 (<= -31 low2 high2 0)) ; Negative shift.
(compile-forms-and-maybe-emit-clear-values arg1 'stack :int
arg2 'stack :int)
(emit 'ineg)
(emit 'ishr)
(convert-representation :int representation)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(cond ((and low2 high2 (<= 0 low2 high2 63) ; Non-negative shift.
(java-long-type-p type1)
(java-long-type-p result-type))
(compile-forms-and-maybe-emit-clear-values arg1 'stack :long
arg2 'stack :int)
(emit 'lshl)
(convert-representation :long representation))
((and low2 high2 (<= -63 low2 high2 0) ; Negative shift.
(java-long-type-p type1)
(java-long-type-p result-type))
(compile-forms-and-maybe-emit-clear-values arg1 'stack :long
arg2 'stack :int)
(emit 'ineg)
(emit 'lshr)
(convert-representation :long representation))
(t
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil
arg2 'stack :int)
(emit-invokevirtual +lisp-object+ "ash" '(:int) +lisp-object+)
(fix-boxing representation result-type)))
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-logand (t t t) t)
(defun p2-logand (form target representation)
(let* ((args (cdr form)))
(case (length args)
(2
(let* ((arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2))
(result-type (derive-compiler-type form)))
(cond ((and (integerp arg1) (integerp arg2))
(compile-constant (logand arg1 arg2) target representation))
((and (integer-type-p type1) (eql arg2 0))
(compile-forms-and-maybe-emit-clear-values arg1 nil nil)
(compile-constant 0 target representation))
((eql (fixnum-constant-value type1) -1)
(compile-forms-and-maybe-emit-clear-values arg1 nil nil
arg2 target representation))
((eql (fixnum-constant-value type2) -1)
(let ((target-register
(if (or (not (eq target 'stack))
(not (some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks arg2))))
target
(allocate-register representation))))
(compile-form arg1 target-register representation)
(compile-form arg2 nil nil)
(when (and (eq target 'stack)
(not (eq target-register 'stack)))
(emit-push-register target-register))
(maybe-emit-clear-values arg1 arg2)))
((and (fixnum-type-p type1) (fixnum-type-p type2))
;; Both arguments are fixnums.
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit 'iand)
(convert-representation :int representation)
(emit-move-from-stack target representation))
((or (and (fixnum-type-p type1) (member type2 '(:long :int))
(compiler-subtypep type1 'unsigned-byte))
(and (fixnum-type-p type2) (member type1 '(:long :int))
(compiler-subtypep type2 'unsigned-byte)))
;; One of the arguments is a positive fixnum.
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit 'iand)
(convert-representation :int representation)
(emit-move-from-stack target representation))
((and (java-long-type-p type1) (java-long-type-p type2))
;; Both arguments are longs.
(with-operand-accumulation
((compile-operand arg1 :long)
(compile-operand arg2 :long)
(maybe-emit-clear-values arg1 arg2)))
(emit 'land)
(convert-representation :long representation)
(emit-move-from-stack target representation))
((or (and (java-long-type-p type1) (member type2 '(:long :int))
(compiler-subtypep type1 'unsigned-byte))
(and (java-long-type-p type2) (member type1 '(:long :int))
(compiler-subtypep type2 'unsigned-byte)))
;; One of the arguments is a positive long.
(with-operand-accumulation
((compile-operand arg1 :long)
(compile-operand arg2 :long)
(maybe-emit-clear-values arg1 arg2)))
(emit 'land)
(convert-representation :long representation)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGAND" '(:int) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
((fixnum-type-p type1)
;; arg1 is a fixnum, but arg2 is not
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
;; swap args
(emit 'swap)
(emit-invokevirtual +lisp-object+ "LOGAND" '(:int) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGAND"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation)))))
(t
(compile-function-call form target representation)))))
(defknown p2-logior (t t t) t)
(defun p2-logior (form target representation)
(let ((args (cdr form)))
(case (length args)
(0
(compile-constant 0 target representation))
(1
(let ((arg (%car args)))
(compile-forms-and-maybe-emit-clear-values arg target representation)))
(2
(let* ((arg1 (%car args))
(arg2 (%cadr args))
type1 type2 result-type)
(when (and (integerp arg1) (integerp arg2))
(compile-constant (logior arg1 arg2) target representation)
(return-from p2-logior t))
(when (integerp arg1)
(setf arg1 (%cadr args)
arg2 (%car args)))
(setf type1 (derive-compiler-type arg1)
type2 (derive-compiler-type arg2)
result-type (derive-compiler-type form))
(cond ((and (fixnum-constant-value type1) (fixnum-constant-value type2))
(compile-constant (logior (fixnum-constant-value type1)
(fixnum-constant-value type2))
target representation))
((and (fixnum-type-p type1) (fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit 'ior)
(convert-representation :int representation)
(emit-move-from-stack target representation))
((and (eql (fixnum-constant-value type1) 0) (< *safety* 3))
(compile-forms-and-maybe-emit-clear-values arg1 nil nil
arg2 target representation))
((and (eql (fixnum-constant-value type2) 0) (< *safety* 3))
(let ((target-register
(if (or (not (eq target 'stack))
(not (some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks arg2))))
target
(allocate-register representation))))
(compile-form arg1 target-register representation)
(compile-form arg2 nil nil)
(when (and (eq target 'stack)
(not (eq target-register 'stack)))
(emit-push-register target-register))
(maybe-emit-clear-values arg1 arg2)))
((or (eq representation :long)
(and (java-long-type-p type1) (java-long-type-p type2)))
(with-operand-accumulation
((compile-operand arg1 :long)
(compile-operand arg2 :long)
(maybe-emit-clear-values arg1 arg2)))
(emit 'lor)
(convert-representation :long representation)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGIOR" '(:int) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
((fixnum-type-p type1)
;; arg1 is of fixnum type, but arg2 is not
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
;; swap args
(emit 'swap)
(emit-invokevirtual +lisp-object+ "LOGIOR" '(:int) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGIOR"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation)))))
(t
;; (logior a b c d ...) => (logior a (logior b c d ...))
(let ((new-form `(logior ,(car args) (logior ,@(cdr args)))))
(p2-logior new-form target representation))))))
(defknown p2-logxor (t t t) t)
(defun p2-logxor (form target representation)
(let* ((args (cdr form))
(len (length args)))
(case len
(0
(compile-constant 0 target representation))
(1
(let ((arg (%car args)))
(compile-forms-and-maybe-emit-clear-values arg target representation)))
(2
(let* ((arg1 (%car args))
(arg2 (%cadr args))
type1 type2 result-type)
(when (and (integerp arg1) (integerp arg2))
(compile-constant (logxor arg1 arg2) target representation)
(return-from p2-logxor))
(when (integerp arg1)
(setf arg1 (%cadr args)
arg2 (%car args)))
(setf type1 (derive-compiler-type arg1)
type2 (derive-compiler-type arg2)
result-type (derive-compiler-type form))
(cond ((or (eq representation :int)
(and (fixnum-type-p type1) (fixnum-type-p type2)))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit 'ixor)
(convert-representation :int representation))
((and (java-long-type-p type1) (java-long-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :long)
(compile-operand arg2 :long)
(maybe-emit-clear-values arg1 arg2)))
(emit 'lxor)
(convert-representation :long representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGXOR" '(:int) +lisp-object+)
(fix-boxing representation result-type))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "LOGXOR"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation result-type)))
(emit-move-from-stack target representation)))
(t
;; (logxor a b c d ...) => (logxor a (logxor b c d ...))
(let ((new-form `(logxor ,(car args) (logxor ,@(cdr args)))))
(p2-logxor new-form target representation))))))
(defknown p2-lognot (t t t) t)
(define-inlined-function p2-lognot (form target representation)
((check-arg-count form 1))
(cond ((and (fixnum-type-p (derive-compiler-type form)))
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack :int)
(emit 'iconst_m1)
(emit 'ixor)
(convert-representation :int representation)
(emit-move-from-stack target representation)))
(t
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil))
(emit-invokevirtual +lisp-object+ "LOGNOT" nil +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
;; %ldb size position integer => byte
(defknown p2-%ldb (t t t) t)
(define-inlined-function p2-%ldb (form target representation)
((check-arg-count form 3))
(let* ((args (cdr form))
(size-arg (%car args))
(position-arg (%cadr args))
(arg3 (%caddr args))
(size-type (derive-compiler-type size-arg))
(position-type (derive-compiler-type position-arg))
(size (fixnum-constant-value size-type))
(position (fixnum-constant-value position-type)))
;; FIXME Inline the case where all args are of fixnum type.
;; FIXME Add LispObject.ldb(), returning a Java int, for the case where we
;; need an unboxed fixnum result.
(cond ((eql size 0)
(compile-forms-and-maybe-emit-clear-values size-arg nil nil
position-arg nil nil
arg3 nil nil)
(compile-constant 0 target representation))
((and size position)
(cond ((<= (+ position size) 31)
(compile-forms-and-maybe-emit-clear-values size-arg nil nil
position-arg nil nil
arg3 'stack :int)
(unless (zerop position)
(emit-push-constant-int position)
(emit 'ishr))
(emit-push-constant-int (1- (expt 2 size))) ; mask
(emit 'iand)
(convert-representation :int representation)
(emit-move-from-stack target representation))
((<= (+ position size) 63)
(compile-forms-and-maybe-emit-clear-values size-arg nil nil
position-arg nil nil
arg3 'stack :long)
(unless (zerop position)
(emit-push-constant-int position)
(emit 'lshr))
(cond ((<= size 31)
(emit 'l2i)
(emit-push-constant-int (1- (expt 2 size)))
(emit 'iand)
(convert-representation :int representation))
(t
(emit-push-constant-long (1- (expt 2 size))) ; mask
(emit 'land)
(convert-representation :long representation)))
(emit-move-from-stack target representation))
(t
(compile-forms-and-maybe-emit-clear-values arg3 'stack nil)
(emit-push-constant-int size)
(emit-push-constant-int position)
(emit-invokevirtual +lisp-object+ "LDB" '(:int :int) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
((and (fixnum-type-p size-type)
(fixnum-type-p position-type))
(with-operand-accumulation
((compile-operand size-arg :int)
(compile-operand position-arg :int)
(compile-operand arg3 nil)
(maybe-emit-clear-values size-arg position-arg arg3)))
(emit 'dup_x2) ;; use not supported by emit-dup: 3 values involved
(emit 'pop)
(emit-invokevirtual +lisp-object+ "LDB" '(:int :int) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-mod (t t t) t)
(define-inlined-function p2-mod (form target representation)
((check-arg-count form 2))
(let* ((args (cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (eq representation :int)
(fixnum-type-p type1)
(fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokestatic +lisp+ "mod" '(:int :int) :int)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "MOD" '(:int) +lisp-object+)
(fix-boxing representation nil) ; FIXME use derived result type
(emit-move-from-stack target representation))
(t
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+ "MOD"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil) ; FIXME use derived result type
(emit-move-from-stack target representation)))))
(defknown p2-zerop (t t t) t)
(define-inlined-function p2-zerop (form target representation)
((aver (or (null representation) (eq representation :boolean)))
(check-arg-count form 1))
(let* ((arg (cadr form))
(type (derive-compiler-type arg)))
(cond ((fixnum-type-p type)
(compile-forms-and-maybe-emit-clear-values arg 'stack :int)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'ifne LABEL1)
(ecase representation
(:boolean
(emit 'iconst_1))
((nil)
(emit-push-t)))
(emit 'goto LABEL2)
(label LABEL1)
(ecase representation
(:boolean
(emit 'iconst_0))
((nil)
(emit-push-nil)))
(label LABEL2)
(emit-move-from-stack target representation)))
((java-long-type-p type)
(compile-forms-and-maybe-emit-clear-values arg 'stack :long)
(emit 'lconst_0)
(emit 'lcmp)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'ifne LABEL1)
(emit-push-true representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-false representation)
(label LABEL2)
(emit-move-from-stack target representation)))
(t
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invoke-method "ZEROP" target representation)))))
;; find-class symbol &optional errorp environment => class
(defknown p2-find-class (t t t) t)
(defun p2-find-class (form target representation)
(let* ((args (cdr form))
(arg-count (length args))
(arg1 (first args))
class)
(when (and (<= 1 arg-count 2) ; no environment arg
(consp arg1)
(= (length arg1) 2)
(eq (first arg1) 'QUOTE)
(symbolp (second arg1))
(eq (symbol-package (second arg1)) (find-package "CL"))
(setf class (find-class (second arg1) nil)))
(compile-constant class target representation)
(return-from p2-find-class))
(case arg-count
(1
;; errorp is true
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-push-constant-int 1) ; errorp
(emit-invokestatic +lisp-class+ "findClass"
(list +lisp-object+ :boolean) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(2
(let ((arg2 (second args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :boolean)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokestatic +lisp-class+ "findClass"
(list +lisp-object+ :boolean) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation)))))
;; vector-push-extend new-element vector &optional extension => new-index
(defun p2-vector-push-extend (form target representation)
(let* ((args (cdr form))
(arg-count (length args))
(arg1 (first args))
(arg2 (second args)))
(case arg-count
(2
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)))
(maybe-emit-clear-values arg1 arg2)
(emit 'swap)
(cond (target
(emit-invokevirtual +lisp-object+ "VECTOR_PUSH_EXTEND"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(emit-invokevirtual +lisp-object+ "vectorPushExtend"
(lisp-object-arg-types 1) nil))))
(t
(compile-function-call form target representation)))))
(defknown p2-std-slot-value (t t t) t)
(define-inlined-function p2-std-slot-value (form target representation)
((check-arg-count form 2))
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)))
(maybe-emit-clear-values arg1 arg2)
(emit-invokevirtual +lisp-object+ "SLOT_VALUE"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
;; set-std-slot-value instance slot-name new-value => new-value
(defknown p2-set-std-slot-value (t t t) t)
(define-inlined-function p2-set-std-slot-value (form target representation)
((check-arg-count form 3))
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(arg3 (third args))
(*register* *register*)
(value-register (when target (allocate-register nil))))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)
(compile-operand arg3 nil)))
(when value-register
(emit 'dup)
(astore value-register))
(maybe-emit-clear-values arg1 arg2 arg3)
(emit-invokevirtual +lisp-object+ "setSlotValue"
(lisp-object-arg-types 2) nil)
(when value-register
(aload value-register)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
(defknown p2-stream-element-type (t t t) t)
(define-inlined-function p2-stream-element-type (form target representation)
((check-arg-count form 1))
(let ((arg (%cadr form)))
(cond ((eq (derive-compiler-type arg) 'STREAM)
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-checkcast +lisp-stream+)
(emit-invokevirtual +lisp-stream+ "getElementType"
nil +lisp-object+)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
;; write-8-bits byte stream => nil
(defknown p2-write-8-bits (t t t) t)
(define-inlined-function p2-write-8-bits (form target representation)
((check-arg-count form 2))
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (compiler-subtypep type1 '(UNSIGNED-BYTE 8))
(eq type2 'STREAM))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil +lisp-stream+)))
(maybe-emit-clear-values arg1 arg2)
(emit 'swap)
(emit-invokevirtual +lisp-stream+ "_writeByte" '(:int) nil)
(when target
(emit-push-nil)
(emit-move-from-stack target)))
((fixnum-type-p type1)
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)))
(maybe-emit-clear-values arg1 arg2)
(emit-invokestatic +lisp+ "writeByte"
(list :int +lisp-object+) nil)
(when target
(emit-push-nil)
(emit-move-from-stack target)))
(t
(compile-function-call form target representation)))))
(defun p2-read-line (form target representation)
(let* ((args (cdr form))
(len (length args)))
(case len
(1
(let* ((arg1 (%car args))
(type1 (derive-compiler-type arg1)))
(cond ((compiler-subtypep type1 'stream)
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-checkcast +lisp-stream+)
(emit-push-constant-int 1)
(emit-push-nil)
(emit-invokevirtual +lisp-stream+ "readLine"
(list :boolean +lisp-object+) +lisp-object+)
(emit-move-from-stack target))
(t
(compile-function-call form target representation)))))
(2
(let* ((arg1 (%car args))
(type1 (derive-compiler-type arg1))
(arg2 (%cadr args)))
(cond ((and (compiler-subtypep type1 'stream) (null arg2))
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-checkcast +lisp-stream+)
(emit-push-constant-int 0)
(emit-push-nil)
(emit-invokevirtual +lisp-stream+ "readLine"
(list :boolean +lisp-object+) +lisp-object+)
(emit-move-from-stack target)
)
(t
(compile-function-call form target representation)))))
(t
(compile-function-call form target representation)))))
(defmacro define-derive-type-handler (op lambda-list &body body)
(let ((name (intern (concatenate 'string "DERIVE-TYPE-" (symbol-name op)))))
`(progn
(defknown ,name (t) t)
(defun ,name ,lambda-list ,@body)
(setf (get ',op 'derive-type-handler) ',name))))
(define-derive-type-handler aref (form)
(let* ((args (cdr form))
(array-arg (car args))
(array-type (normalize-type (derive-type array-arg)))
(result-type t))
(cond ((and (consp array-type)
(memq (%car array-type) '(ARRAY SIMPLE-ARRAY VECTOR)))
(let ((element-type (second array-type)))
(unless (eq element-type '*)
(setf result-type element-type))))
((and (consp array-type)
(memq (%car array-type) '(STRING SIMPLE-STRING)))
(setf result-type 'CHARACTER)))
result-type))
(define-derive-type-handler fixnump (form)
(if (fixnum-type-p (derive-compiler-type (cadr form)))
+true-type+
'BOOLEAN))
(define-derive-type-handler setq (form)
(if (= (length form) 3)
(derive-compiler-type (third form))
t))
(defknown derive-type-logior/logxor (t) t)
(defun derive-type-logior/logxor (form)
(let ((op (car form))
(args (cdr form))
(result-type +integer-type+))
(case (length args)
(0
(setf result-type (make-integer-type '(INTEGER 0 0))))
(1
(setf result-type (derive-compiler-type (car args))))
(2
(let ((type1 (derive-compiler-type (%car args)))
(type2 (derive-compiler-type (%cadr args))))
(cond ((and (compiler-subtypep type1 'unsigned-byte)
(compiler-subtypep type2 'unsigned-byte))
(let ((high1 (integer-type-high type1))
(high2 (integer-type-high type2)))
(cond ((and high1 high2)
(let ((length (integer-length (max high1 high2))))
(setf result-type
(make-compiler-type (list 'INTEGER 0
(1- (expt 2 length)))))))
(t
(setf result-type (make-compiler-type 'unsigned-byte))))))
((and (fixnum-type-p type1)
(fixnum-type-p type2))
(setf result-type (make-compiler-type 'fixnum))))))
(t
(setf result-type (derive-type-logior/logxor
`(,op ,(car args) (,op ,@(cdr args)))))))
result-type))
(defknown derive-type-logand (t) t)
(defun derive-type-logand (form)
(let ((args (cdr form)))
(case (length args)
(0
(make-integer-type '(INTEGER -1 -1)))
(1
(let ((type (derive-compiler-type (%car args))))
(if (integer-type-p type)
type
(make-integer-type 'INTEGER))))
(2
(dformat t "derive-type-logand 2-arg case~%")
(let* ((type1 (derive-compiler-type (%car args)))
(type2 (derive-compiler-type (%cadr args)))
low1 high1 low2 high2 result-low result-high result-type)
(when (integer-type-p type1)
(setf low1 (integer-type-low type1)
high1 (integer-type-high type1)))
(when (integer-type-p type2)
(setf low2 (integer-type-low type2)
high2 (integer-type-high type2)))
(cond ((and low1 low2 (>= low1 0) (>= low2 0))
;; Both arguments are non-negative.
(dformat t "both args are non-negative~%")
(setf result-low 0)
(setf result-high (if (and high1 high2)
(min high1 high2)
(or high1 high2))))
((and low1 (>= low1 0))
;; arg1 is non-negative
(dformat t "arg1 is non-negative~%")
(setf result-low 0)
(setf result-high high1))
((and low2 (>= low2 0))
;; arg2 is non-negative
(dformat t "arg2 is non-negative~%")
(setf result-low 0)
(setf result-high high2)))
(dformat t "result-low = ~S~%" result-low)
(dformat t "result-high = ~S~%" result-high)
(setf result-type (make-integer-type (list 'INTEGER result-low result-high)))
(dformat t "result-type = ~S~%" result-type)
result-type))
(t
(make-integer-type 'INTEGER)))))
(declaim (ftype (function (t) t) derive-type-lognot))
(defun derive-type-lognot (form)
(let (arg-type)
(if (and (= (length form) 2)
(fixnum-type-p (setf arg-type (derive-compiler-type (%cadr form)))))
(let* ((arg-low (integer-type-low arg-type))
(arg-high (integer-type-high arg-type))
(result-low (if arg-high (lognot arg-high) nil))
(result-high (if arg-low (lognot arg-low) nil)))
(make-integer-type (list 'INTEGER result-low result-high)))
+integer-type+)))
;; mod number divisor
(declaim (ftype (function (t) t) derive-type-mod))
(defun derive-type-mod (form)
(if (= (length form) 3)
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (integer-type-p type1) (fixnum-type-p type2))
'FIXNUM)
(t
t)))
t))
(defknown derive-type-coerce (t) t)
(defun derive-type-coerce (form)
(if (= (length form) 3)
(let ((type-form (%caddr form)))
(if (and (consp type-form) (eq (%car type-form) 'QUOTE) (= (length type-form) 2))
(%cadr type-form)
t))
t))
(defknown derive-type-copy-seq (t) t)
(defun derive-type-copy-seq (form)
(if (= (length form) 2)
(let ((type (derive-compiler-type (second form))))
(case type
((STRING SIMPLE-STRING)
(make-compiler-type type))
(t
t)))
t))
(defknown derive-type-integer-length (t) t)
(defun derive-type-integer-length (form)
(when (= (length form) 2)
(let ((type (make-integer-type (derive-type (%cadr form)))))
(when type
(let ((low (integer-type-low type))
(high (integer-type-high type)))
(when (and (integerp low) (integerp high))
(return-from derive-type-integer-length
(list 'INTEGER 0
(max (integer-length low) (integer-length high)))))))))
(list 'INTEGER 0 '*))
(defknown derive-type-%ldb (t) t)
(defun derive-type-%ldb (form)
(when (= (length form) 4)
(let* ((args (cdr form))
(size-arg (first args)))
(when (fixnump size-arg)
(return-from derive-type-%ldb (list 'INTEGER 0 (1- (expt 2 size-arg)))))))
(list 'INTEGER 0 '*))
(defmacro define-int-bounds-derivation (name (low1 high1 low2 high2)
&body body)
"Associates an integer-bounds calculation function with a numeric
operator `name', assuming 2 integer arguments."
`(setf (get ',name 'int-bounds)
#'(lambda (,low1 ,high1 ,low2 ,high2)
(declare (ignorable ,low1 ,high1 ,low2 ,high2))
,@body)))
(defun derive-integer-type (op type1 type2)
"Derives the composed integer type of operation `op' given integer
types `type1' and `type2'."
(let ((low1 (integer-type-low type1))
(high1 (integer-type-high type1))
(low2 (integer-type-low type2))
(high2 (integer-type-high type2))
(op-fn (get op 'int-bounds)))
(assert op-fn)
(multiple-value-bind
(low high non-int-p)
(funcall op-fn low1 high1 low2 high2)
(if non-int-p
non-int-p
(%make-integer-type low high)))))
(defvar numeric-op-type-derivation
`(((+ - *)
(integer integer ,#'derive-integer-type)
(integer single-float single-float)
(integer double-float double-float)
(single-float integer single-float)
(single-float double-float double-float)
(double-float integer double-float)
(double-float single-float double-float))
((/)
(integer single-float single-float)
(integer double-float double-float)
(single-float integer single-float)
(single-float double-float double-float)
(double-float integer double-float)
(double-float single-float double-float))
((ash)
(integer integer ,#'derive-integer-type))
((min max)
(integer integer ,#'derive-integer-type)
(integer single-float single-float)
(integer double-float double-float)
(single-float double-float double-float)
(double-float single-float double-float)))
"Table used to derive the return type of a numeric operation,
based on the types of the arguments.")
(defun derive-type-numeric-op (op &rest types)
"Returns the result type of the numeric operation `op' and the types
of the operation arguments given in `types'."
(let ((types-table
(cdr (assoc op numeric-op-type-derivation :test #'member))))
(assert types-table)
(flet ((match (type1 type2)
(do* ((remaining-types types-table (cdr remaining-types)))
((endp remaining-types)
;; when we don't find a matching type, return T
T)
(destructuring-bind
(t1 t2 result-type)
(car remaining-types)
(when (and (or (subtypep type1 t1)
(compiler-subtypep type1 t1))
(or (subtypep type2 t2)
(compiler-subtypep type2 t2)))
(return-from match
(if (functionp result-type)
(funcall result-type op type1 type2)
result-type)))))))
(let ((type1 (car types))
(type2 (cadr types)))
(when (and (eq type1 type2)
(memq type1 '(SINGLE-FLOAT DOUBLE-FLOAT)))
(return-from derive-type-numeric-op type1))
(match type1 type2)))))
(defvar zero-integer-type (%make-integer-type 0 0)
"Integer type representing the 0 (zero)
value for use with derive-type-minus and derive-type-plus.")
(define-int-bounds-derivation - (low1 high1 low2 high2)
(values (when (and low1 high2) ;; low1 or high2 undefined: no lower bound
(if low2
(min (- low1 low2)
(- low1 high2))
;; low2 undefined: no effect on lower bound
(- low1 high2)))
(when (and high1 low2) ;; high1 or low2 undefined: no upper bound
(if high2
(max (- high1 low2)
(- high1 high2))
;; high2 undefined: no effect on upper bound
(- high1 low2)))))
(defun derive-compiler-types (args op)
(flet ((combine (x y)
(derive-type-numeric-op op x y)))
(reduce #'combine (cdr args) :key #'derive-compiler-type
:initial-value (derive-compiler-type (car args)))))
(defknown derive-type-minus (t) t)
(defun derive-type-minus (form)
(let ((op (car form))
(args (cdr form)))
(case (length args)
(1 (derive-type-numeric-op (car form)
zero-integer-type
(derive-compiler-type (%car args))))
(2 (derive-compiler-types args op)))))
(define-int-bounds-derivation + (low1 high1 low2 high2)
(values (and low1 low2 (+ low1 low2))
(and high1 high2 (+ high1 high2))))
(defknown derive-type-plus (t) t)
(defun derive-type-plus (form)
(let ((op (car form))
(args (cdr form)))
(if (null args)
zero-integer-type
(derive-compiler-types args op))))
(define-int-bounds-derivation * (low1 high1 low2 high2)
(cond ((or (null low1) (null low2))
(values nil nil))
((or (null high1) (null high2))
(values (if (or (minusp low1) (minusp low2))
(- (* (abs low1) (abs low2)))
(* low1 low2))
nil))
((or (minusp low1) (minusp low2))
(let ((max (* (max (abs low1) (abs high1))
(max (abs low2) (abs high2)))))
(values (- max) max)))
(t
(values (* low1 low2) (* high1 high2)))))
(defvar one-integer-type (%make-integer-type 1 1)
"Integer type representing the value 1 (one)
for use with derive-type-times.")
(defun derive-type-times (form)
(let ((op (car form))
(args (cdr form)))
(if (null args)
one-integer-type
(derive-compiler-types args op))))
(define-int-bounds-derivation max (low1 high1 low2 high2)
(values (or (when (and low1 low2) (max low1 low2)) low1 low2)
; if either maximum is unbound, their maximum is unbound
(when (and high1 high2) (max high1 high2))))
(declaim (ftype (function (t) t) derive-type-max))
(defun derive-type-max (form)
(let ((op (car form))
(args (cdr form)))
(derive-compiler-types args op)))
(define-int-bounds-derivation min (low1 high1 low2 high2)
(values (when (and low1 low2) (min low1 low2))
; if either minimum is unbound, their minimum is unbound
(or (when (and high1 high2) (min high1 high2)) high1 high2)))
(defknown derive-type-min (t) t)
(defun derive-type-min (form)
(let ((op (car form))
(args (cdr form)))
(derive-compiler-types args op)))
;; read-char &optional input-stream eof-error-p eof-value recursive-p => char
(declaim (ftype (function (t) t) derive-type-read-char))
(defun derive-type-read-char (form)
(if (< (length form) 3) ; no EOF-ERROR-P arg
'CHARACTER
t))
(define-int-bounds-derivation ash (low1 high1 low2 high2)
(when (and low1 high1 low2 high2)
(cond
((and (>= low1 0) (>= high1 0) (>= low2 0) (>= high2 0))
;; Everything is non-negative.
(values (ash low1 low2)
(unless (<= 64 high2)
(ash high1 high2))))
((and (>= low1 0) (>= high1 0) (<= low2 0) (<= high2 0))
;; Negative (or zero) second argument.
(values (ash low1 low2)
(ash high1 high2))))))
;; ash integer count => shifted-integer
(defknown derive-type-ash (t) t)
(defun derive-type-ash (form)
(derive-type-numeric-op (car form)
(derive-compiler-type (cadr form))
(derive-compiler-type (caddr form))))
(defknown derive-type (t) t)
(defun derive-type (form)
(cond ((consp form)
(let* ((op (%car form))
(handler (and (symbolp op) (get op 'derive-type-handler))))
(if handler
(funcall handler form)
(case op
(ASH
(derive-type-ash form))
((CHAR SCHAR)
'CHARACTER)
(COERCE
(derive-type-coerce form))
(COPY-SEQ
(derive-type-copy-seq form))
(INTEGER-LENGTH
(derive-type-integer-length form))
(%LDB
(derive-type-%ldb form))
(LENGTH
'(INTEGER 0 #.(1- most-positive-fixnum)))
(LOGAND
(derive-type-logand form))
(LOGNOT
(derive-type-lognot form))
((LOGIOR LOGXOR)
(derive-type-logior/logxor form))
(MOD
(derive-type-mod form))
(-
(derive-type-minus form))
(1-
(derive-type-minus (list '- (cadr form) 1)))
(+
(derive-type-plus form))
(1+
(derive-type-plus (list '+ (cadr form) 1)))
(*
(derive-type-times form))
(MAX
(derive-type-max form))
(MIN
(derive-type-min form))
(READ-CHAR
(derive-type-read-char form))
((THE TRULY-THE)
(second form))
(t
(let ((type (or (function-result-type op)
(ftype-result-type (proclaimed-ftype op)))))
(if (eq type '*)
t
type)))))))
((null form)
'NULL)
((integerp form)
(list 'INTEGER form form))
((typep form 'single-float)
'SINGLE-FLOAT)
((typep form 'double-float)
'DOUBLE-FLOAT)
((characterp form)
'CHARACTER)
((stringp form)
'STRING)
((arrayp form)
(type-of form))
((variable-p form)
(cond ((neq (variable-declared-type form) :none)
(variable-declared-type form))
((neq (variable-derived-type form) :none)
(variable-derived-type form))
(t
t)))
((var-ref-p form)
(cond ((var-ref-constant-p form)
(derive-type (var-ref-constant-value form)))
(t
(let ((variable (var-ref-variable form)))
(cond ((variable-special-p variable)
(or (proclaimed-type (variable-name variable))
t))
((neq (variable-declared-type variable) :none)
(variable-declared-type variable))
((neq (variable-derived-type variable) :none)
(variable-derived-type variable))
((= 0 (variable-writes variable))
(derive-type (variable-initform variable)))
(t
t))))))
((symbolp form)
(cond ((keywordp form)
'SYMBOL)
((eq form t)
t)
((and (special-variable-p form)
(constantp form))
(derive-type (symbol-value form)))
(t
(let ((variable (find-visible-variable form)))
(if variable
(derive-type variable)
t)))))
((node-p form)
(let ((result t))
;;; ### FIXME
#|
the statements below used to work, maybe ...
We need more thought here.
(cond ((and (block-node-p form)
(equal (block-name form) '(LET)))
;; (format t "derive-type LET/LET* node case~%")
(let* ((forms (cddr (node-form form)))
(last-form (car (last forms)))
(derived-type (derive-compiler-type last-form)))
;; (unless (eq derived-type t)
;; (let ((*print-structure* nil))
;; (format t "last-form = ~S~%" last-form))
;; (format t "derived-type = ~S~%" derived-type)
;; )
(setf result derived-type)))
((and (block-node-p form)
(symbolp (block-name form)))
(unless (block-return-p form)
(let* ((forms (cddr (block-form form)))
(last-form (car (last forms)))
(derived-type (derive-compiler-type last-form)))
;; (unless (eq derived-type t)
;; (let ((*print-structure* nil))
;; (format t "last-form = ~S~%" last-form))
;; (format t "derived-type = ~S~%" derived-type)
;; )
(setf result derived-type))))) |#
result))
(t
t)))
(defun derive-compiler-type (form)
(make-compiler-type (derive-type form)))
;; delete item sequence &key from-end test test-not start end count key
(defknown p2-delete (t t t) t)
(defun p2-delete (form target representation)
(unless (notinline-p 'delete)
(when (= (length form) 3)
;; No keyword arguments.
(let* ((args (cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-type arg1))
(type2 (derive-type arg2))
(test (if (memq type1 '(SYMBOL NULL)) 'eq 'eql)))
(cond ((subtypep type2 'VECTOR)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil +lisp-abstract-vector+)))
(maybe-emit-clear-values arg1 arg2)
(emit 'swap)
(emit-invokevirtual +lisp-abstract-vector+
(if (eq test 'eq) "deleteEq" "deleteEql")
(lisp-object-arg-types 1) +lisp-object+)
(emit-move-from-stack target)
(return-from p2-delete t))
(t
(setf (car form) (if (eq test 'eq) 'delete-eq 'delete-eql)))))))
(compile-function-call form target representation))
(define-inlined-function p2-length (form target representation)
((check-arg-count form 1))
(let ((arg (cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(ecase representation
(:int
(emit-invokevirtual +lisp-object+ "length" nil :int))
((:long :float :double)
(emit-invokevirtual +lisp-object+ "length" nil :int)
(convert-representation :int representation))
(:boolean
;; FIXME We could optimize this all away in unsafe calls.
(emit-invokevirtual +lisp-object+ "length" nil :int)
(emit 'pop)
(emit 'iconst_1))
(:char
(sys::%format t "p2-length: :char case~%")
(aver nil))
((nil)
(emit-invokevirtual +lisp-object+ "LENGTH" nil +lisp-object+)))
(emit-move-from-stack target representation)))
(defun cons-for-list/list* (form target representation &optional list-star-p)
(let* ((args (cdr form))
(length (length args))
(cons-heads (if list-star-p
(butlast args 1)
args)))
(cond ((and (not (some-nested-block #'node-opstack-unsafe-p
(find-enclosed-blocks args)))
(>= 4 length 1))
(dolist (cons-head cons-heads)
(emit-new +lisp-cons+)
(emit 'dup)
(compile-form cons-head 'stack nil))
(if list-star-p
(compile-form (first (last args)) 'stack nil)
(progn
(emit-invokespecial-init
+lisp-cons+ (lisp-object-arg-types 1))
(pop cons-heads))) ; we've handled one of the args, so remove it
(dolist (cons-head cons-heads)
(declare (ignore cons-head))
(emit-invokespecial-init
+lisp-cons+ (lisp-object-arg-types 2)))
(if list-star-p
(progn
(apply #'maybe-emit-clear-values args)
(emit-move-from-stack target representation))
(progn
(unless (every 'single-valued-p args)
(emit-clear-values))
(emit-move-from-stack target))))
(t
(compile-function-call form target representation)))))
(defun p2-list (form target representation)
(cons-for-list/list* form target representation))
(defun p2-list* (form target representation)
(cons-for-list/list* form target representation t))
(define-inlined-function compile-nth (form target representation)
((check-arg-count form 2))
(let* ((index-form (second form))
(list-form (third form))
(index-type (derive-compiler-type index-form)))
(unless (fixnum-type-p index-type)
(compile-function-call form target representation)
(return-from compile-nth))
(with-operand-accumulation
((compile-operand index-form :int)
(compile-operand list-form nil)
(maybe-emit-clear-values index-form list-form))
(emit 'swap)
(emit-invokevirtual +lisp-object+ "NTH" '(:int) +lisp-object+))
(fix-boxing representation nil) ; FIXME use derived result type
(emit-move-from-stack target representation)))
(defun p2-times (form target representation)
(case (length form)
(1 (compile-constant 1 target representation))
(2 (compile-form (cadr form) target representation))
(3
(let* ((args (cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
result-type result-rep value)
(when (fixnump arg1)
(rotatef arg1 arg2))
(setf result-type (derive-compiler-type form)
result-rep (type-representation result-type))
(cond ((and (numberp arg1) (numberp arg2))
(dformat t "p2-times case 1~%")
(compile-constant (* arg1 arg2) target representation))
((setf value (fixnum-constant-value result-type))
(dformat t "p2-times case 1a~%")
(compile-constant value target representation))
(result-rep
(with-operand-accumulation
((compile-operand arg1 result-rep)
(compile-operand arg2 result-rep)
(maybe-emit-clear-values arg1 arg2))
(emit (case result-rep
(:int 'imul)
(:long 'lmul)
(:float 'fmul)
(:double 'dmul)
(t
(sys::format t "p2-times: unsupported rep case")))))
(convert-representation result-rep representation)
(emit-move-from-stack target representation))
((fixnump arg2)
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-push-int arg2)
(emit-invokevirtual +lisp-object+ "multiplyBy" '(:int) +lisp-object+)
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
(t
(dformat t "p2-times case 4~%")
(compile-binary-operation "multiplyBy" args target representation)))))
(t
(dformat t "p2-times case 5~%")
(p2-times `(,(car form) (,(car form) ,(second form) ,(third form))
,@(nthcdr 3 form)) target representation))))
(defknown p2-min/max (t t t) t)
(defun p2-min/max (form target representation)
(case (length form)
(1 (error 'program-error "Wrong number of arguments for ~A." (car form)))
(2 (compile-form (cadr form) target representation))
(3 (let* ((op (%car form))
(args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(*register* *register*))
(when (null target)
;; compile for effect
(compile-forms-and-maybe-emit-clear-values arg1 nil nil
arg2 nil nil)
(return-from p2-min/max))
(when (notinline-p op)
(compile-function-call form target representation)
(return-from p2-min/max))
(let ((type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((and (java-long-type-p type1) (java-long-type-p type2))
(let* ((common-rep (if (and (fixnum-type-p type1)
(fixnum-type-p type2))
:int :long))
(LABEL1 (gensym))
(LABEL2 (gensym))
(arg1-register (allocate-register common-rep))
(arg2-register (allocate-register common-rep)))
(compile-form arg1 arg1-register common-rep)
(compile-form arg2 'stack common-rep)
(emit-dup common-rep)
(emit-move-from-stack arg2-register common-rep)
(emit-push-register arg1-register common-rep)
;; note: we've now reversed the arguments on the stack!
(emit-numeric-comparison (if (eq op 'max) '<= '>=)
common-rep LABEL1)
(emit-push-register arg1-register common-rep)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-register arg2-register common-rep)
(label LABEL2)
(convert-representation common-rep representation)
(emit-move-from-stack target representation)))
(t
(let* ((arg1-register (allocate-register nil))
(arg2-register (allocate-register nil)))
(compile-form arg1 arg1-register nil)
(compile-form arg2 'stack nil)
(emit-dup nil)
(astore arg2-register)
(emit-push-register arg1-register nil)
(emit-invokevirtual +lisp-object+
(if (eq op 'max)
"isLessThanOrEqualTo"
"isGreaterThanOrEqualTo")
(lisp-object-arg-types 1) :boolean)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'ifeq LABEL1)
(emit-push-register arg1-register nil)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-register arg2-register nil)
(label LABEL2))
(fix-boxing representation nil)
(emit-move-from-stack target representation)))))))
(t
(p2-min/max `(,(car form) (,(car form) ,(second form) ,(third form))
,@(nthcdr 3 form)) target representation))))
(defun p2-plus (form target representation)
(case (length form)
(1
(compile-constant 0 target representation))
(2
(compile-form (cadr form) target representation))
(3
(let* ((args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2))
(result-type (derive-compiler-type form))
(result-rep (type-representation result-type)))
(cond ((and (numberp arg1) (numberp arg2))
(compile-constant (+ arg1 arg2) target representation))
((and (numberp arg1) (eql arg1 0))
(compile-forms-and-maybe-emit-clear-values arg1 nil nil
arg2 'stack representation)
(emit-move-from-stack target representation))
((and (numberp arg2) (eql arg2 0))
(compile-forms-and-maybe-emit-clear-values arg1 'stack representation
arg2 nil nil)
(emit-move-from-stack target representation))
(result-rep
(with-operand-accumulation
((compile-operand arg1 result-rep)
(compile-operand arg2 result-rep)
(maybe-emit-clear-values arg1 arg2))
(emit (case result-rep
(:int 'iadd)
(:long 'ladd)
(:float 'fadd)
(:double 'dadd)
(t
(sys::format
t "p2-plus: Unexpected result-rep ~S for form ~S."
result-rep form)
(assert nil)))))
(convert-representation result-rep representation)
(emit-move-from-stack target representation))
((eql arg2 1)
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-invoke-method "incr" target representation))
((eql arg1 1)
(compile-forms-and-maybe-emit-clear-values arg2 'stack nil)
(emit-invoke-method "incr" target representation))
((or (fixnum-type-p type1) (fixnum-type-p type2))
(with-operand-accumulation
((compile-operand arg1 (when (fixnum-type-p type1) :int))
(compile-operand arg2 (when (null (fixnum-type-p type1))
:int))
(maybe-emit-clear-values arg1 arg2))
(when (fixnum-type-p type1)
(emit 'swap))
(emit-invokevirtual +lisp-object+ "add"
'(:int) +lisp-object+))
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
(t
(compile-binary-operation "add" args target representation)))))
(t
;; (+ a b c) => (+ (+ a b) c)
(let ((new-form `(+ (+ ,(second form) ,(third form)) ,@(nthcdr 3 form))))
(p2-plus new-form target representation)))))
(defun p2-minus (form target representation)
(case (length form)
(1
;; generates "Insufficient arguments" error
(compile-function-call form target representation))
(2
(let* ((arg (%cadr form))
(type (derive-compiler-type form))
(type-rep (type-representation type)))
(cond ((numberp arg)
(compile-constant (- arg) 'stack representation)
(emit-move-from-stack target representation))
(type-rep
(compile-form arg 'stack type-rep)
(emit (case type-rep
(:int 'ineg)
(:long 'lneg)
(:float 'fneg)
(:double 'dneg)
(t
(sys::format t
"p2-minus: unsupported rep (~S) for '~S'~%"
type-rep form)
(assert nil))))
(convert-representation type-rep representation)
(emit-move-from-stack target representation))
(t
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invokevirtual +lisp-object+ "negate"
nil +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))))
(3
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(type2 (derive-compiler-type arg2))
(result-type (derive-compiler-type form))
(result-rep (type-representation result-type)))
(cond ((and (numberp arg1) (numberp arg2))
(compile-constant (- arg1 arg2) target representation))
(result-rep
(with-operand-accumulation
((compile-operand arg1 result-rep)
(compile-operand arg2 result-rep)
(maybe-emit-clear-values arg1 arg2))
(emit (case result-rep
(:int 'isub)
(:long 'lsub)
(:float 'fsub)
(:double 'dsub)
(t
(sys::%format t "p2-minus sub-instruction (rep: ~S); form: ~S~%"
result-rep form)
(assert nil)))))
(convert-representation result-rep representation)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2))
(emit-invokevirtual +lisp-object+
"subtract"
'(:int) +lisp-object+))
(fix-boxing representation result-type)
(emit-move-from-stack target representation))
(t
(compile-binary-operation "subtract" args target representation)))))
(t
(let ((new-form `(- (- ,(second form) ,(third form)) ,@(nthcdr 3 form))))
(p2-minus new-form target representation)))))
;; char/schar string index => character
(defknown p2-char/schar (t t t) t)
(define-inlined-function p2-char/schar (form target representation)
((check-arg-count form 2))
(let* ((op (%car form))
(args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2)))
(cond ((or (and (eq representation :char)
(zerop *safety*))
(and (eq representation :char)
(or (eq op 'CHAR) (< *safety* 3))
(compiler-subtypep type1 'STRING)
(fixnum-type-p type2)))
(with-operand-accumulation
((compile-operand arg1 nil +lisp-abstract-string+)
(compile-operand arg2 :int)))
(maybe-emit-clear-values arg1 arg2)
(emit-invokevirtual +lisp-abstract-string+ "charAt"
'(:int) :char)
(emit-move-from-stack target representation))
((fixnum-type-p type2)
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2)))
(emit-invokevirtual +lisp-object+
(symbol-name op) ;; "CHAR" or "SCHAR"
'(:int) +lisp-object+)
(when (eq representation :char)
(emit-unbox-character))
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
;; set-char/schar string index character => character
(defknown p2-set-char/schar (t t t) t)
(define-inlined-function p2-set-char/schar (form target representation)
((check-arg-count form 3))
(let* ((op (%car form))
(args (%cdr form))
(arg1 (first args))
(arg2 (second args))
(arg3 (third args))
(type1 (derive-compiler-type arg1))
(type2 (derive-compiler-type arg2))
(type3 (derive-compiler-type arg3)))
(cond ((and (< *safety* 3)
(or (null representation) (eq representation :char))
(compiler-subtypep type1 'STRING)
(fixnum-type-p type2)
(compiler-subtypep type3 'CHARACTER))
(let* ((*register* *register*)
(value-register (when target (allocate-register nil)))
(class (if (eq op 'SCHAR)
+lisp-simple-string+
+lisp-abstract-string+)))
(with-operand-accumulation
((compile-operand arg1 nil class)
(compile-operand arg2 :int)
(accumulate-operand (:char
:unsafe-p (some-nested-block
#'node-opstack-unsafe-p
(find-enclosed-blocks arg3)))
(compile-form arg3 'stack :char)
(when target
(emit 'dup)
(emit-move-from-stack value-register :char)))))
(maybe-emit-clear-values arg1 arg2 arg3)
(emit-invokevirtual class "setCharAt" '(:int :char) nil)
(when target
(emit 'iload value-register)
(convert-representation :char representation)
(emit-move-from-stack target representation))))
(t
(compile-function-call form target representation)))))
(defun p2-svref (form target representation)
(cond ((and (check-arg-count form 2)
(neq representation :char)) ; FIXME
(let ((arg1 (%cadr form))
(arg2 (%caddr form)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 :int)))
(maybe-emit-clear-values arg1 arg2)
(emit-invokevirtual +lisp-object+ "SVREF" '(:int) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
(defun p2-svset (form target representation)
(cond ((check-arg-count form 3)
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(arg3 (fourth form))
(*register* *register*)
(value-register (when target (allocate-register nil))))
(with-operand-accumulation
((compile-operand arg1 nil) ;; vector
(compile-operand arg2 :int) ;; intex
(compile-operand arg3 nil) ;; new value
))
(when value-register
(emit 'dup)
(emit-move-from-stack value-register nil))
(maybe-emit-clear-values arg1 arg2 arg3)
(emit-invokevirtual +lisp-object+ "svset" (list :int +lisp-object+) nil)
(when value-register
(aload value-register)
(emit-move-from-stack target nil))))
(t
(compile-function-call form target representation))))
(defun p2-truncate (form target representation)
(let ((args (cdr form))
arg1
arg2)
(case (length args)
(1
(setf arg1 (%car args)
arg2 1))
(2
(setf arg1 (%car args)
arg2 (%cadr args)))
(t
(compiler-warn "Wrong number of arguments for ~A (expected 1 or 2, but received ~D)."
'truncate (length args))
(compile-function-call form target representation)
(return-from p2-truncate)))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg2 nil)))
(maybe-emit-clear-values arg1 arg2)
(emit-invokevirtual +lisp-object+ "truncate"
(lisp-object-arg-types 1) +lisp-object+)
(fix-boxing representation nil) ; FIXME use derived result type
(emit-move-from-stack target representation)))
(defun p2-elt (form target representation)
(cond ((and (check-arg-count form 2)
(fixnum-type-p (derive-compiler-type (third form)))
(neq representation :char)) ; FIXME
(with-operand-accumulation
((compile-operand (second form) nil)
(compile-operand (third form) :int)
(maybe-emit-clear-values (second form) (third form))))
(emit-invokevirtual +lisp-object+ "elt" '(:int) +lisp-object+)
(fix-boxing representation nil) ; FIXME use derived result type
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation))))
(defun p2-aref (form target representation)
;; We only optimize the 2-arg case.
(case (length form)
(3
(let* ((arg1 (%cadr form))
(arg2 (%caddr form))
(type1 (derive-compiler-type arg1)))
(with-operand-accumulation
((compile-operand arg1 nil
(when (compiler-subtypep type1 'string)
+lisp-abstract-string+))
(compile-operand arg2 :int)
(maybe-emit-clear-values arg1 arg2))
(ecase representation
(:int
(emit-invokevirtual +lisp-object+ "aref" '(:int) :int))
(:long
(emit-invokevirtual +lisp-object+ "aref_long" '(:int) :long))
(:char
(cond ((compiler-subtypep type1 'string)
(emit-invokevirtual +lisp-abstract-string+
"charAt" '(:int) :char))
(t
(emit-invokevirtual +lisp-object+
"AREF" '(:int) +lisp-object+)
(emit-unbox-character))))
((nil :float :double :boolean)
;;###FIXME for float and double, we probably want
;; separate java methods to retrieve the values.
(emit-invokevirtual +lisp-object+ "AREF" '(:int) +lisp-object+)
(convert-representation nil representation))))
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
(defun p2-aset (form target representation)
;; We only optimize the 3-arg case.
(cond ((= (length form) 4)
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(arg3 (third args))
(type3 (derive-compiler-type arg3))
(*register* *register*)
(value-register (unless (null target) (allocate-register nil))))
(with-operand-accumulation
(
;; array
(compile-operand arg1 nil)
;; index
(compile-operand arg2 :int)
;; value
(accumulate-operand
((when (fixnum-type-p type3) :int)
:unsafe-p (some-nested-block
#'node-opstack-unsafe-p
(find-enclosed-blocks arg3)))
(cond ((fixnum-type-p type3)
(compile-form arg3 'stack :int)
(when value-register
(emit 'dup)
(emit-move-from-stack value-register :int)))
(t
(compile-form arg3 'stack nil)
(when value-register
(emit 'dup)
(emit-move-from-stack value-register nil)))))))
(maybe-emit-clear-values arg1 arg2 arg3)
(cond ((fixnum-type-p type3)
(emit-invokevirtual +lisp-object+ "aset" '(:int :int) nil))
(t
(emit-invokevirtual +lisp-object+ "aset"
(list :int +lisp-object+) nil)))
(when value-register
(cond ((fixnum-type-p type3)
(emit 'iload value-register)
(convert-representation :int representation))
(t
(aload value-register)
(fix-boxing representation type3)))
(emit-move-from-stack target representation))))
(t
(compile-function-call form target representation))))
(defknown p2-structure-ref (t t t) t)
(define-inlined-function p2-structure-ref (form target representation)
((check-arg-count form 2))
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args)))
(cond ((and (fixnump arg2)
(null representation))
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(case arg2
(0
(emit-invokevirtual +lisp-object+ "getSlotValue_0"
nil +lisp-object+))
(1
(emit-invokevirtual +lisp-object+ "getSlotValue_1"
nil +lisp-object+))
(2
(emit-invokevirtual +lisp-object+ "getSlotValue_2"
nil +lisp-object+))
(3
(emit-invokevirtual +lisp-object+ "getSlotValue_3"
nil +lisp-object+))
(t
(emit-push-constant-int arg2)
(emit-invokevirtual +lisp-object+ "getSlotValue"
'(:int) +lisp-object+)))
(emit-move-from-stack target representation))
((fixnump arg2)
(compile-forms-and-maybe-emit-clear-values arg1 'stack nil)
(emit-push-constant-int arg2)
(ecase representation
(:int
(emit-invokevirtual +lisp-object+ "getFixnumSlotValue"
'(:int) :int))
((nil :char :long :float :double)
(emit-invokevirtual +lisp-object+ "getSlotValue"
'(:int) +lisp-object+)
;; (convert-representation NIL NIL) is a no-op
(convert-representation nil representation))
(:boolean
(emit-invokevirtual +lisp-object+ "getSlotValueAsBoolean"
'(:int) :boolean)))
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-structure-set (t t t) t)
(define-inlined-function p2-structure-set (form target representation)
((check-arg-count form 3))
(let* ((args (cdr form))
(arg1 (first args))
(arg2 (second args))
(arg3 (third args)))
(cond ((and (fixnump arg2)
(<= 0 arg2 3))
(let* ((*register* *register*)
(value-register (when target (allocate-register nil))))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg3 nil)))
(when value-register
(emit 'dup)
(astore value-register))
(maybe-emit-clear-values arg1 arg3)
(emit-invokevirtual +lisp-object+
(format nil "setSlotValue_~D" arg2)
(lisp-object-arg-types 1) nil)
(when value-register
(aload value-register)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
((fixnump arg2)
(let* ((*register* *register*)
(value-register (when target (allocate-register nil))))
(with-operand-accumulation
((compile-operand arg1 nil)
(compile-operand arg3 nil)))
(maybe-emit-clear-values arg1 arg3)
(when value-register
(emit 'dup)
(astore value-register))
(emit-push-constant-int arg2)
(emit 'swap) ;; prevent the integer
;; from being pushed, saved and restored
(emit-invokevirtual +lisp-object+ "setSlotValue"
(list :int +lisp-object+) nil)
(when value-register
(aload value-register)
(fix-boxing representation nil)
(emit-move-from-stack target representation))))
(t
(compile-function-call form target representation)))))
(define-inlined-function p2-not/null (form target representation)
((aver (or (null representation) (eq representation :boolean)))
(check-arg-count form 1))
(let ((arg (second form)))
(cond ((null arg)
(emit-push-true representation))
((node-constant-p arg)
(emit-push-false representation))
((and (consp arg)
(memq (%car arg) '(NOT NULL)))
(compile-forms-and-maybe-emit-clear-values (second arg) 'stack nil)
(emit-push-nil)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'if_acmpeq LABEL1)
(emit-push-true representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-false representation)
(label LABEL2)))
((eq representation :boolean)
(compile-forms-and-maybe-emit-clear-values arg 'stack :boolean)
(emit 'iconst_1)
(emit 'ixor))
((eq (derive-compiler-type arg) 'BOOLEAN)
(compile-forms-and-maybe-emit-clear-values arg 'stack :boolean)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'ifeq LABEL1)
(emit-push-nil)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-t)
(label LABEL2)))
(t
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit-push-nil)
(emit 'if_acmpeq LABEL1)
(emit-push-nil)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-t)
(label LABEL2)))))
(emit-move-from-stack target representation))
(define-inlined-function p2-nthcdr (form target representation)
((check-arg-count form 2))
(let* ((args (%cdr form))
(arg1 (%car args))
(arg2 (%cadr args)))
(cond ((fixnum-type-p (derive-compiler-type arg1))
(with-operand-accumulation
((compile-operand arg1 :int)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2)))
(emit 'swap)
(emit-invokevirtual +lisp-object+ "nthcdr" '(:int) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defun p2-and (form target representation)
(aver (or (null representation) (eq representation :boolean)))
(let ((args (cdr form)))
(case (length args)
(0
(emit-push-true representation)
(emit-move-from-stack target representation))
(1
(compile-form (%car args) target representation))
(t
(let ((FAIL (gensym))
(DONE (gensym))
(butlast-args (butlast args)))
(loop
for form in butlast-args
do (compile-form form 'stack nil)
do (emit-push-nil)
do (emit 'if_acmpeq FAIL))
(apply #'maybe-emit-clear-values butlast-args)
(compile-form (car (last args)) target representation)
(emit 'goto DONE)
(label FAIL)
(apply #'maybe-emit-clear-values butlast-args)
(emit-push-false representation)
(emit-move-from-stack target representation)
(label DONE))))))
(defknown p2-or (t t t) t)
(defun p2-or (form target representation)
(let ((args (cdr form)))
(case (length args)
(0
(emit-push-false representation)
(emit-move-from-stack target representation))
(1
(compile-form (%car args) target representation))
(t
(let ((SUCCESS (gensym))
(DONE (gensym))
(butlast-args (butlast args)))
(loop
for form in butlast-args
do (compile-form form 'stack nil)
do (emit 'dup) ;; leave value on the stack for SUCCESS to use
do (emit-push-nil)
do (emit 'if_acmpne SUCCESS)
do (emit 'pop))
(apply #'maybe-emit-clear-values butlast-args)
(compile-form (car (last args)) target representation)
(emit 'goto DONE)
(label SUCCESS)
(fix-boxing representation nil) ;; value is still on the stack
(emit-move-from-stack target representation)
(apply #'maybe-emit-clear-values butlast-args)
(label DONE))))))
(defun p2-values (form target representation)
(let* ((args (cdr form))
(len (length args)))
(case len
(0
(emit-push-current-thread)
(emit-invokevirtual +lisp-thread+ "setValues" nil +lisp-object+)
(emit-move-from-stack target))
(1
(let ((arg (%car args)))
(compile-forms-and-maybe-emit-clear-values arg target representation)))
(2
(let ((arg1 (%car args))
(arg2 (%cadr args)))
(cond ((and (eq arg1 t)
(eq arg2 t))
(emit-push-current-thread)
(emit-push-t)
(emit 'dup))
((and (eq arg1 nil)
(eq arg2 nil))
(emit-push-current-thread)
(emit-push-nil)
(emit 'dup))
(t
(with-operand-accumulation
((emit-thread-operand)
(compile-operand arg1 nil)
(compile-operand arg2 nil)
(maybe-emit-clear-values arg1 arg2))))))
(emit-invokevirtual +lisp-thread+
"setValues"
(lisp-object-arg-types len)
+lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target))
((3 4)
(with-operand-accumulation
((emit-thread-operand)
(dolist (arg args)
(compile-operand arg nil))))
(when (notevery #'single-valued-p args)
(emit-clear-values))
(emit-invokevirtual +lisp-thread+
"setValues"
(lisp-object-arg-types len)
+lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target))
(t
(compile-function-call form target representation)))))
(defun compile-special-reference (variable target representation)
(let ((name (variable-name variable)))
(when (constantp name)
(let ((value (symbol-value name)))
(when (or (null *file-compilation*)
(stringp value)
(numberp value)
(packagep value))
(compile-constant value target representation)
(return-from compile-special-reference))))
(unless (and (variable-binding-register variable)
(eq (variable-compiland variable) *current-compiland*)
(not (enclosed-by-runtime-bindings-creating-block-p
(variable-block variable))))
(emit-load-externalized-object name))
(cond ((constantp name)
;; "... a reference to a symbol declared with DEFCONSTANT always
;; refers to its global value."
(emit-invokevirtual +lisp-symbol+ "getSymbolValue"
nil +lisp-object+))
((and (variable-binding-register variable)
(eq (variable-compiland variable) *current-compiland*)
(not (enclosed-by-runtime-bindings-creating-block-p
(variable-block variable))))
(aload (variable-binding-register variable))
(emit-getfield +lisp-special-binding+ "value"
+lisp-object+))
(t
(emit-push-current-thread)
(emit-invokevirtual +lisp-symbol+ "symbolValue"
(list +lisp-thread+) +lisp-object+)))
(fix-boxing representation nil)
(emit-move-from-stack target representation)))
(defknown compile-var-ref (t t t) t)
(defun compile-var-ref (ref target representation)
(when target
(if (var-ref-constant-p ref)
(compile-constant (var-ref-constant-value ref) target representation)
(let ((variable (var-ref-variable ref)))
(cond ((variable-special-p variable)
(compile-special-reference variable target representation))
((or (variable-representation variable)
(variable-register variable)
(variable-closure-index variable)
(variable-index variable)
(variable-environment variable))
(emit-push-variable variable)
(convert-representation (variable-representation variable)
representation)
(emit-move-from-stack target representation))
(t
(sys::%format t "compile-var-ref general case~%")
(aver nil)))))))
(defun p2-set (form target representation)
(cond ((and (check-arg-count form 2)
(eq (derive-type (%cadr form)) 'SYMBOL))
(with-operand-accumulation
((emit-thread-operand)
(compile-operand (%cadr form) nil +lisp-symbol+)
(compile-operand (%caddr form) nil)))
(maybe-emit-clear-values (%cadr form) (%caddr form))
(emit-invokevirtual +lisp-thread+ "setSpecialVariable"
(list +lisp-symbol+ +lisp-object+) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation))))
(defknown p2-setq (t t t) t)
(defun p2-setq (form target representation)
(unless (= (length form) 3)
(assert (not "p2-setq should receive exactly 2 arguments!")))
(let* ((name (%cadr form))
(variable (find-visible-variable name))
(value-form (%caddr form)))
(when (or (null variable)
(variable-special-p variable))
;; We're setting a special variable.
(cond ((and variable
(variable-binding-register variable)
(eq (variable-compiland variable) *current-compiland*)
(not (enclosed-by-runtime-bindings-creating-block-p
(variable-block variable))))
;; choose this compilation order to prevent
;; with-operand-accumulation
(compile-forms-and-maybe-emit-clear-values value-form 'stack nil)
(emit 'dup)
(aload (variable-binding-register variable))
(emit 'swap)
(emit-putfield +lisp-special-binding+ "value"
+lisp-object+))
((and (consp value-form)
(eq (first value-form) 'CONS)
(= (length value-form) 3)
(var-ref-p (third value-form))
(eq (variable-name (var-ref-variable (third value-form)))
name))
(with-operand-accumulation
((emit-thread-operand)
(emit-load-externalized-object-operand name)
(compile-operand (second value-form) nil)
(maybe-emit-clear-values (second value-form)))
(emit-invokevirtual +lisp-thread+ "pushSpecial"
(list +lisp-symbol+ +lisp-object+)
+lisp-object+)))
(t
(unless (symbolp name)
(error 'program-error
"First argument to SETQ is not a symbol in ~S"
form))
(with-operand-accumulation
((emit-thread-operand)
(emit-load-externalized-object-operand name)
(compile-operand value-form nil)
(maybe-emit-clear-values value-form))
(emit-invokevirtual +lisp-thread+ "setSpecialVariable"
(list +lisp-symbol+ +lisp-object+)
+lisp-object+))))
(fix-boxing representation nil)
(emit-move-from-stack target representation)
(return-from p2-setq))
(when (zerop (variable-reads variable))
;; If we never read the variable, we don't have to set it.
(cond (target
(compile-forms-and-maybe-emit-clear-values value-form 'stack nil)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-form value-form nil nil)))
(return-from p2-setq))
;; Optimize the (INCF X) case.
(let ((incf-p nil))
(when (and (eq (variable-representation variable) :int)
(consp value-form))
(let ((op (car value-form))
(len (length value-form)))
(case op
(1+
(when (= len 2)
(let ((arg (cadr value-form)))
(when (and (var-ref-p arg) (eq (var-ref-variable arg) variable))
(setf incf-p t)))))
(+
(when (= len 3)
(let ((arg1 (second value-form))
(arg2 (third value-form)))
(when (eql arg1 1)
(setf arg1 arg2 arg2 1)) ;; (+ 1 X) => (+ X 1)
(when (eql arg2 1)
(when (and (var-ref-p arg1) (eq (var-ref-variable arg1) variable))
(setf incf-p t)))))))))
(when incf-p
(aver (variable-register variable))
(emit 'iinc (variable-register variable) 1)
(when target
(emit 'iload (variable-register variable))
(convert-representation :int representation)
(emit-move-from-stack target representation))
(return-from p2-setq)))
(cond ((and (eq (variable-representation variable) :int)
(or (equal value-form (list '1+ (variable-name variable)))
(equal value-form (list '+ (variable-name variable) 1))
(equal value-form (list '+ 1 (variable-name variable)))))
;; FIXME This is the old (INCF X) case. We should be able to remove
;; this case once the new code is stable.
(emit 'iinc (variable-register variable) 1)
(when target
(convert-representation :int representation)
(emit-move-from-stack target representation)))
((and (eq (variable-representation variable) :int)
(or (equal value-form (list '1- (variable-name variable)))
(equal value-form (list '- (variable-name variable) 1))))
(dformat t "p2-setq decf :int case~%")
(emit 'iinc (variable-register variable) -1)
(when target
(convert-representation :int representation)
(emit-move-from-stack target representation)))
(t
(let ((rep (variable-representation variable)))
(dformat t "p2-setq ~A case value-form = ~S~%" rep value-form)
(compile-forms-and-maybe-emit-clear-values value-form 'stack rep)
(when target
(emit-dup rep))
(emit-move-to-variable variable)
(when target
(convert-representation rep representation)
(emit-move-from-stack target representation)))))))
(defun p2-sxhash (form target representation)
(cond ((check-arg-count form 1)
(let ((arg (%cadr form)))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-invokevirtual +lisp-object+ "sxhash" nil :int)
(convert-representation :int representation)
(emit-move-from-stack target representation)))
(t
(compile-function-call form target representation))))
(defknown p2-symbol-name (t t t) t)
(define-inlined-function p2-symbol-name (form target representation)
((check-arg-count form 1))
(let ((arg (%cadr form)))
(cond ((and (eq (derive-compiler-type arg) 'SYMBOL) (< *safety* 3))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-checkcast +lisp-symbol+)
(emit-getfield +lisp-symbol+ "name" +lisp-simple-string+)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-symbol-package (t t t) t)
(define-inlined-function p2-symbol-package (form target representation)
((check-arg-count form 1))
(let ((arg (%cadr form)))
(cond ((and (eq (derive-compiler-type arg) 'SYMBOL) (< *safety* 3))
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-checkcast +lisp-symbol+)
(emit-invokevirtual +lisp-symbol+ "getPackage"
nil +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-symbol-value (t t t) t)
(defun p2-symbol-value (form target representation)
(when (check-arg-count form 1)
(let ((arg (%cadr form)))
(when (eq (derive-compiler-type arg) 'SYMBOL)
(compile-forms-and-maybe-emit-clear-values arg 'stack nil)
(emit-checkcast +lisp-symbol+)
(emit-push-current-thread)
(emit-invokevirtual +lisp-symbol+ "symbolValue"
(list +lisp-thread+) +lisp-object+)
(fix-boxing representation nil)
(emit-move-from-stack target representation)
(return-from p2-symbol-value))))
;; Otherwise...
(compile-function-call form target representation))
(defknown generate-instanceof-type-check-for-value (t) t)
(defun generate-instanceof-type-check-for-value (expected-type)
;; The value to be checked is on the stack.
(declare (type symbol expected-type))
(let ((instanceof-class (ecase expected-type
(SYMBOL +lisp-symbol+)
(CHARACTER +lisp-character+)
(CONS +lisp-cons+)
(HASH-TABLE +lisp-hash-table+)
(FIXNUM +lisp-fixnum+)
(STREAM +lisp-stream+)
(STRING +lisp-abstract-string+)
(VECTOR +lisp-abstract-vector+)))
(expected-type-java-symbol-name (case expected-type
(HASH-TABLE "HASH_TABLE")
(t
(symbol-name expected-type))))
(LABEL1 (gensym)))
(emit 'dup)
(emit-instanceof instanceof-class)
(emit 'ifne LABEL1)
(emit-getstatic +lisp-symbol+ expected-type-java-symbol-name +lisp-symbol+)
(emit-invokestatic +lisp+ "type_error"
(lisp-object-arg-types 2) +lisp-object+)
(label LABEL1))
t)
(declaim (ftype (function (t) t) generate-type-check-for-value))
(defun generate-type-check-for-value (declared-type)
(let ((type-to-use (find-type-for-type-check declared-type)))
(when type-to-use
(generate-instanceof-type-check-for-value type-to-use))))
(defun p2-the (form target representation)
(let ((type-form (second form))
(value-form (third form)))
(cond ((and (subtypep type-form 'FIXNUM)
(consp value-form)
(eq (car value-form) 'structure-ref))
;; Special case for structure slot references: getFixnumSlotValue()
;; signals an error if the slot's value is not a fixnum.
(compile-form value-form target representation))
((and (> *safety* 0)
(not (compiler-subtypep (derive-type value-form) type-form)))
(compile-form value-form 'stack nil)
(generate-type-check-for-value type-form)
;; The value is left on the stack here if the type check succeeded.
(fix-boxing representation nil)
(emit-move-from-stack target representation))
(t
(compile-form value-form target representation)))))
(defun p2-truly-the (form target representation)
(compile-form (third form) target representation))
(defknown p2-char-code (t t t) t)
(define-inlined-function p2-char-code (form target representation)
((check-arg-count form 1))
(let ((arg (second form)))
(cond ((characterp arg)
(compile-constant (char-code arg) target representation))
((and (< *safety* 3)
(eq (derive-compiler-type arg) 'character))
(compile-form arg 'stack :char)
;; we change the representation between the above and here
;; ON PURPOSE!
(convert-representation :int representation)
(emit-move-from-stack target representation))
(t
(compile-function-call form target representation)))))
(defknown p2-java-jclass (t t t) t)
(define-inlined-function p2-java-jclass (form target representation)
((and (= 2 (length form))
(stringp (cadr form))))
(let ((c (ignore-errors (java:jclass (cadr form)))))
(if c (compile-constant c target representation)
;; delay resolving the method to run-time; it's unavailable now
(compile-function-call form target representation))))
(defknown p2-java-jconstructor (t t t) t)
(define-inlined-function p2-java-jconstructor (form target representation)
((and (< 1 (length form))
(every #'stringp (cdr form))))
(let ((c (ignore-errors (apply #'java:jconstructor (cdr form)))))
(if c (compile-constant c target representation)
;; delay resolving the method to run-time; it's unavailable now
(compile-function-call form target representation))))
(defknown p2-java-jmethod (t t t) t)
(define-inlined-function p2-java-jmethod (form target representation)
((and (< 1 (length form))
(every #'stringp (cdr form))))
(let ((m (ignore-errors (apply #'java:jmethod (cdr form)))))
(if m (compile-constant m target representation)
;; delay resolving the method to run-time; it's unavailable now
(compile-function-call form target representation))))
#|(defknown p2-java-jcall (t t t) t)
(define-inlined-function p2-java-jcall (form target representation)
((and (> *speed* *safety*)
(< 1 (length form))
(eq 'jmethod (car (cadr form)))
(every #'stringp (cdr (cadr form)))))
(let ((m (ignore-errors (eval (cadr form)))))
(if m
(let ((must-clear-values nil)
(arg-types (raw-arg-types (jmethod-params m))))
(declare (type boolean must-clear-values))
(dolist (arg (cddr form))
(compile-form arg 'stack nil)
(unless must-clear-values
(unless (single-valued-p arg)
(setf must-clear-values t))))
(when must-clear-values
(emit-clear-values))
(dotimes (i (jarray-length raw-arg-types))
(push (jarray-ref raw-arg-types i) arg-types))
(emit-invokevirtual (jclass-name (jmethod-declaring-class m))
(jmethod-name m)
(nreverse arg-types)
(jmethod-return-type m)))
;; delay resolving the method to run-time; it's unavailable now
(compile-function-call form target representation))))|#
(defknown p2-char= (t t t) t)
(defun p2-char= (form target representation)
(let* ((args (cdr form))
(numargs (length args)))
(when (= numargs 0)
(compiler-warn "Wrong number of arguments for ~A." (car form))
(compile-function-call form target representation)
(return-from p2-char=))
(unless (= numargs 2)
(compile-function-call form target representation)
(return-from p2-char=))
(let ((arg1 (%car args))
(arg2 (%cadr args)))
(when (and (characterp arg1) (characterp arg2))
(cond ((eql arg1 arg2)
(emit-push-true representation))
(t
(emit-push-false representation)))
(emit-move-from-stack target representation)
(return-from p2-char=))
(cond ((characterp arg1)
;; prevent need for with-operand-accumulation: reverse args
(compile-forms-and-maybe-emit-clear-values arg2 'stack :char)
(emit-push-constant-int (char-code arg1)))
((characterp arg2)
(compile-forms-and-maybe-emit-clear-values arg1 'stack :char)
(emit-push-constant-int (char-code arg2)))
(t
(with-operand-accumulation
((compile-operand arg1 :char)
(compile-operand arg2 :char)
(maybe-emit-clear-values arg1 arg2)))))
(let ((LABEL1 (gensym))
(LABEL2 (gensym)))
(emit 'if_icmpeq LABEL1)
(emit-push-false representation)
(emit 'goto LABEL2)
(label LABEL1)
(emit-push-true representation)
(label LABEL2)
(emit-move-from-stack target representation)))))
(defknown p2-threads-synchronized-on (t t) t)
(defun p2-threads-synchronized-on (block target)
(let* ((form (synchronized-form block))
(*register* *register*)
(object-register (allocate-register nil))
(BEGIN-PROTECTED-RANGE (gensym "F"))
(END-PROTECTED-RANGE (gensym "U"))
(EXIT (gensym "E")))
(compile-form (cadr form) 'stack nil)
(emit-invokevirtual +lisp-object+ "lockableInstance" nil
+java-object+) ; value to synchronize
(emit 'dup)
(astore object-register)
(emit 'monitorenter)
(label BEGIN-PROTECTED-RANGE)
(let ((*blocks* (cons block *blocks*)))
(compile-progn-body (cddr form) target))
(emit 'goto EXIT)
(label END-PROTECTED-RANGE)
(aload object-register)
(emit 'monitorexit)
(emit 'athrow)
(label EXIT)
(aload object-register)
(emit 'monitorexit)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE
END-PROTECTED-RANGE nil)))
(defun p2-java-jrun-exception-protected (block target)
(let* ((form (exception-protected-form block))
(*register* *register*)
(*blocks* (cons block *blocks*))
(BEGIN-PROTECTED-RANGE (gensym "F"))
(END-PROTECTED-RANGE (gensym "U"))
(STACK-EXHAUST (gensym "S"))
(MEMORY-EXHAUST (gensym "M"))
(EXIT (gensym "E")))
(label BEGIN-PROTECTED-RANGE)
(compile-progn-body form target)
(emit 'goto EXIT)
(label END-PROTECTED-RANGE)
(label STACK-EXHAUST)
(emit 'pop)
(emit-invokestatic +lisp+ "stackError" nil +lisp-object+)
(emit 'areturn)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE
STACK-EXHAUST
+java-stack-overflow+)
(label MEMORY-EXHAUST)
(emit-invokestatic +lisp+ "memoryError" (list +java-out-of-memory+)
+lisp-object+)
(emit 'areturn)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE
MEMORY-EXHAUST
+java-out-of-memory+)
(label EXIT)))
(defknown p2-catch-node (t t) t)
(defun p2-catch-node (block target)
(let ((form (catch-form block)))
(when (= (length form) 2) ; (catch 'foo)
(when target
(emit-push-nil)
(emit-move-from-stack target))
(return-from p2-catch-node))
(let* ((*register* *register*)
(tag-register (allocate-register nil))
(BEGIN-PROTECTED-RANGE (gensym "F"))
(END-PROTECTED-RANGE (gensym "U"))
(THROW-HANDLER (gensym "H"))
(RETHROW (gensym))
(DEFAULT-HANDLER (gensym))
(EXIT (gensym "E"))
(specials-register (allocate-register nil)))
(compile-form (second form) tag-register nil) ; Tag.
(emit-push-current-thread)
(aload tag-register)
(emit-invokevirtual +lisp-thread+ "pushCatchTag"
(lisp-object-arg-types 1) nil)
(let ((*blocks* (cons block *blocks*)))
; Stack depth is 0.
(save-dynamic-environment specials-register)
(label BEGIN-PROTECTED-RANGE) ; Start of protected range.
(compile-progn-body (cddr form) target) ; Implicit PROGN.
(label END-PROTECTED-RANGE) ; End of protected range.
(emit 'goto EXIT)) ; Jump over handlers.
(label THROW-HANDLER) ; Start of handler for THROW.
;; The Throw object is on the runtime stack. Stack depth is 1.
(emit 'dup) ; Stack depth is 2.
(emit-getfield +lisp-throw+ "tag" +lisp-object+) ; Still 2.
(aload tag-register) ; Stack depth is 3.
;; If it's not the tag we're looking for, we branch to the start of the
;; catch-all handler, which will do a re-throw.
(emit 'if_acmpne RETHROW) ; Stack depth is 1.
(restore-dynamic-environment specials-register)
(emit-push-current-thread)
(emit-invokevirtual +lisp-throw+ "getResult"
(list +lisp-thread+) +lisp-object+)
(emit-move-from-stack target) ; Stack depth is 0.
(emit 'goto EXIT)
(label RETHROW) ; Start of handler for all other Throwables.
;; A Throwable object is on the runtime stack here. Stack depth is 1.
(emit-push-current-thread)
(emit-invokevirtual +lisp-thread+ "popCatchTag" nil nil)
(emit 'athrow) ; Re-throw.
(label DEFAULT-HANDLER) ; Start of handler for all other Throwables.
;; A Throwable object is on the runtime stack here. Stack depth is 1.
(emit-push-current-thread)
(emit-invokevirtual +lisp-thread+ "popCatchTag" nil nil)
(emit 'athrow) ; Re-throw.
(label EXIT)
;; Finally...
(emit-push-current-thread)
(emit-invokevirtual +lisp-thread+ "popCatchTag" nil nil)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE
THROW-HANDLER +lisp-throw+)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE
DEFAULT-HANDLER nil)))
t)
(defun p2-throw (form target representation)
(with-operand-accumulation
((emit-thread-operand)
(compile-operand (second form) nil) ; Tag.
(emit-clear-values) ; Do this unconditionally! (MISC.503)
(compile-operand (third form) nil)) ; Result.
(emit-invokevirtual +lisp-thread+ "throwToTag"
(lisp-object-arg-types 2) nil))
;; Following code will not be reached.
(when target
(ecase representation
((:int :boolean :char)
(emit 'iconst_0))
((nil)
(emit-push-nil)))
(emit-move-from-stack target)))
(defun p2-unwind-protect-node (block target)
(let ((form (unwind-protect-form block)))
(when (= (length form) 2) ; No cleanup form.
(compile-form (second form) target nil)
(return-from p2-unwind-protect-node))
;; The internal representation of UNWIND-PROTECT
;; as generated by P1-UNWIND-PROTECT differs a bit
;; from what the spec says; ours is:
;; (UNWIND-PROTECT protected-form (progn cleanup-forms) cleanup-forms),
;; because we need to compile the cleanup forms twice and
;; we can compile a p1 outcome only once.
;;
;; We used to use JSR and RET JVM instructions to prevent
;; duplication of output code. However, this led to JVM stack
;; inconsistency errors
;; (see http://trac.common-lisp.net/armedbear/ticket/21)
(let* ((protected-form (cadr form))
(unwinding-form (caddr form))
(cleanup-forms (cdddr form))
(*register* *register*)
(exception-register (allocate-register nil))
(result-register (allocate-register nil))
(values-register (allocate-register nil))
(specials-register (allocate-register nil))
(BEGIN-PROTECTED-RANGE (gensym "F"))
(END-PROTECTED-RANGE (gensym "U"))
(HANDLER (gensym "H"))
(EXIT (gensym "E")))
;; Make sure there are no leftover multiple return values from previous calls.
(emit-clear-values)
(let* ((*blocks* (cons block *blocks*)))
(save-dynamic-environment specials-register)
(label BEGIN-PROTECTED-RANGE)
(compile-form protected-form result-register nil)
(unless (single-valued-p protected-form)
(emit-push-current-thread)
(emit-getfield +lisp-thread+ "_values" +lisp-object-array+)
(astore values-register))
(label END-PROTECTED-RANGE))
(let ((*register* *register*))
(compile-form unwinding-form nil nil))
(when (single-valued-p protected-form)
;; otherwise, we'll load the values register below
(maybe-emit-clear-values unwinding-form))
(emit 'goto EXIT) ; Jump over handler.
(label HANDLER) ; Start of exception handler.
;; The Throwable object is on the runtime stack. Stack depth is 1.
(astore exception-register)
(emit-push-current-thread)
(emit-getfield +lisp-thread+ "_values" +lisp-object-array+)
(astore values-register)
(restore-dynamic-environment specials-register)
(let ((*register* *register*))
(compile-progn-body cleanup-forms nil nil))
(emit-push-current-thread)
(aload values-register)
(emit-putfield +lisp-thread+ "_values" +lisp-object-array+)
(aload exception-register)
(emit 'athrow) ; Re-throw exception.
(label EXIT)
;; Restore multiple values returned by protected form.
(unless (single-valued-p protected-form)
(emit-push-current-thread)
(aload values-register)
(emit-putfield +lisp-thread+ "_values" +lisp-object-array+))
;; Result.
(aload result-register)
(emit-move-from-stack target)
(add-exception-handler BEGIN-PROTECTED-RANGE
END-PROTECTED-RANGE HANDLER nil))))
(defknown compile-form (t t t) t)
(defun compile-form (form target representation)
(cond
((consp form)
(let* ((op (%car form))
(handler (and (symbolp op) (get op 'p2-handler))))
(cond
(handler
(funcall handler form target representation))
((symbolp op)
(cond
((special-operator-p op)
(dformat t "form = ~S~%" form)
(compiler-unsupported
"COMPILE-FORM: unsupported special operator ~S" op))
(t
(compile-function-call form target representation))))
((and (consp op) (eq (%car op) 'LAMBDA))
(aver (progn 'unexpected-lambda nil))
(let ((new-form (list* 'FUNCALL form)))
(compile-form new-form target representation)))
(t
(compiler-unsupported "COMPILE-FORM unhandled case ~S" form)))))
((symbolp form)
(cond
((null form)
(emit-push-false representation)
(emit-move-from-stack target representation))
((eq form t)
(emit-push-true representation)
(emit-move-from-stack target representation))
((keywordp form)
(ecase representation
(:boolean
(emit 'iconst_1))
((nil)
(emit-load-externalized-object form)))
(emit-move-from-stack target representation))
(t
;; Shouldn't happen.
(aver nil))))
((var-ref-p form)
(compile-var-ref form target representation))
((node-p form)
(cond
((jump-node-p form)
(let ((op (car (node-form form))))
(cond
((eq op 'go)
(p2-go form target representation))
((eq op 'return-from)
(p2-return-from form target representation))
(t
(assert (not "jump-node: can't happen"))))))
((block-node-p form)
(p2-block-node form target representation))
((let/let*-node-p form)
(p2-let/let*-node form target representation))
((tagbody-node-p form)
(p2-tagbody-node form target)
(fix-boxing representation nil))
((unwind-protect-node-p form)
(p2-unwind-protect-node form target)
(fix-boxing representation nil))
((m-v-b-node-p form)
(p2-m-v-b-node form target)
(fix-boxing representation nil))
((flet-node-p form)
(p2-flet-node form target representation))
((labels-node-p form)
(p2-labels-node form target representation))
((locally-node-p form)
(p2-locally-node form target representation))
((catch-node-p form)
(p2-catch-node form target)
(fix-boxing representation nil))
((progv-node-p form)
(p2-progv-node form target representation))
((synchronized-node-p form)
(p2-threads-synchronized-on form target)
(fix-boxing representation nil))
((protected-node-p form)
(p2-java-jrun-exception-protected form target)
(fix-boxing representation nil))
(t
(aver (not "Can't happen")))))
((constantp form)
(compile-constant form target representation))
(t
(compiler-unsupported "COMPILE-FORM unhandled case ~S" form)))
t)
(defmacro with-open-class-file ((var class-file) &body body)
`(with-open-file (,var (abcl-class-file-pathname ,class-file)
:direction :output
:element-type '(unsigned-byte 8)
:if-exists :supersede)
,@body))
(defknown p2-compiland-process-type-declarations (list) t)
(defun p2-compiland-process-type-declarations (body)
(flet ((process-declaration (name type)
(let ((variable (find-visible-variable name)))
(when variable
(setf (variable-declared-type variable) type)))))
(dolist (subform body)
(unless (and (consp subform) (eq (%car subform) 'DECLARE))
(return))
(let ((decls (%cdr subform)))
(dolist (decl decls)
(case (car decl)
(TYPE
(let ((type (make-compiler-type (cadr decl))))
(dolist (name (cddr decl))
(process-declaration name type))))
((IGNORE IGNORABLE)
(process-ignore/ignorable (%car decl) (%cdr decl) *visible-variables*))
((DYNAMIC-EXTENT FTYPE INLINE NOTINLINE OPTIMIZE SPECIAL)
;; Nothing to do here.
)
(t
(let ((type (make-compiler-type (car decl))))
(dolist (name (cdr decl))
(process-declaration name type)))))))))
t)
(defknown p2-compiland-unbox-variable (variable) t)
(defun p2-compiland-unbox-variable (variable)
(let ((register (variable-register variable)))
(when (and register
(not (variable-special-p variable))
(not (variable-used-non-locally-p variable))
(null (compiland-children *current-compiland*)))
(when (memq (type-representation (variable-declared-type variable))
'(:int :long))
(emit-push-variable variable)
(derive-variable-representation variable nil)
(when (< 1 (representation-size (variable-representation variable)))
(allocate-variable-register variable))
(convert-representation nil (variable-representation variable))
(emit-move-to-variable variable))))
t)
(defun assign-field-name (local-function)
(setf (local-function-field local-function)
(symbol-name (gensym "LFUN"))))
(defknown p2-compiland (t) t)
(defun p2-compiland (compiland method)
(let* ((p1-result (compiland-p1-result compiland))
(class-file (compiland-class-file compiland))
(*this-class* (abcl-class-file-class class-file))
(closure-args (intersection *closure-variables*
(compiland-arg-vars compiland)))
(local-closure-vars
(find compiland *closure-variables* :key #'variable-compiland))
(body (cddr p1-result))
(*child-p* (not (null (compiland-parent compiland))))
(*visible-variables* *visible-variables*)
(*thread* nil)
(*initialize-thread-var* nil)
(*current-compiland* compiland))
(with-code-to-method (class-file method)
(setf *register* 1 ;; register 0: "this" pointer
*registers-allocated* 1)
(when (fixnump *source-line-number*)
(let ((table (make-line-numbers-attribute)))
(code-add-attribute *current-code-attribute* table)
(line-numbers-add-line table 0 *source-line-number*)))
(dolist (local-function (compiland-children compiland))
(assign-field-name local-function))
(dolist (var (compiland-arg-vars compiland))
(push var *visible-variables*))
(dolist (var (compiland-free-specials compiland))
(push var *visible-variables*))
(when *using-arg-array*
(setf (compiland-argument-register compiland) (allocate-register nil)))
;; Assign indices or registers, depending on where the args are
;; located: the arg-array or the call-stack
(let ((index 0))
(dolist (variable (compiland-arg-vars compiland))
(aver (null (variable-register variable)))
(aver (null (variable-index variable)))
(if *using-arg-array*
(setf (variable-index variable) index)
(setf (variable-register variable) (allocate-register nil)))
(incf index)))
;; Reserve the next available slot for the thread register.
(setf *thread* (allocate-register nil))
(when *closure-variables*
(setf (compiland-closure-register compiland) (allocate-register nil))
(dformat t "p2-compiland 2 closure register = ~S~%"
(compiland-closure-register compiland)))
(when *closure-variables*
(if (not *child-p*)
(progn
;; if we're the ultimate parent: create the closure array
(emit-push-constant-int (length *closure-variables*))
(emit-anewarray +lisp-closure-binding+))
(progn
(aload 0)
(emit-getfield +lisp-compiled-closure+ "ctx"
+closure-binding-array+)
(when local-closure-vars
;; in all other cases, it gets stored in the register below
(emit 'astore (compiland-closure-register compiland))
(duplicate-closure-array compiland)))))
;; Move args from their original registers to the closure variables array
(when (or closure-args
(and *closure-variables* (not *child-p*)))
(dformat t "~S moving arguments to closure array~%"
(compiland-name compiland))
(dotimes (i (length *closure-variables*))
;; Loop over all slots, setting their value
;; unconditionally if we're the parent creating it (using null
;; values if no real value is available)
;; or selectively if we're a child binding certain slots.
(let ((variable (find i closure-args
:key #'variable-closure-index
:test #'eql)))
(when (or (not *child-p*) variable)
;; we're the parent, or we have a variable to set.
(emit 'dup) ; array
(emit-push-constant-int i)
(emit-new +lisp-closure-binding+)
(emit 'dup)
(cond
((null variable)
(assert (not *child-p*))
(emit 'aconst_null))
((variable-register variable)
(assert (not (eql (variable-register variable)
(compiland-closure-register compiland))))
(aload (variable-register variable))
(setf (variable-register variable) nil))
((variable-index variable)
(aload (compiland-argument-register compiland))
(emit-push-constant-int (variable-index variable))
(emit 'aaload)
(setf (variable-index variable) nil))
(t
(assert (not "Can't happen!!"))))
(emit-invokespecial-init +lisp-closure-binding+
(list +lisp-object+))
(emit 'aastore)))))
(when *closure-variables*
(aver (not (null (compiland-closure-register compiland))))
(astore (compiland-closure-register compiland))
(dformat t "~S done moving arguments to closure array~%"
(compiland-name compiland)))
;; If applicable, move args from arg array to registers.
(when *using-arg-array*
(dolist (variable (compiland-arg-vars compiland))
(unless (or (variable-special-p variable)
(null (variable-index variable)) ;; not in the array anymore
(< (+ (variable-reads variable)
(variable-writes variable)) 2))
(let ((register (allocate-register nil)))
(aload (compiland-argument-register compiland))
(emit-push-constant-int (variable-index variable))
(emit 'aaload)
(astore register)
(setf (variable-register variable) register)
(setf (variable-index variable) nil)))))
(with-saved-compiler-policy
(process-optimization-declarations body)
(p2-compiland-process-type-declarations body)
(generate-type-checks-for-variables (compiland-arg-vars compiland))
;; Unbox variables.
(dolist (variable (compiland-arg-vars compiland))
(p2-compiland-unbox-variable variable))
;; Establish dynamic bindings for any variables declared special.
(when (some #'variable-special-p (compiland-arg-vars compiland))
;; Save the dynamic environment
(setf (compiland-environment-register compiland)
(allocate-register nil))
(save-dynamic-environment (compiland-environment-register compiland))
(dolist (variable (compiland-arg-vars compiland))
(when (variable-special-p variable)
(setf (variable-binding-register variable) (allocate-register nil))
(emit-push-current-thread)
(emit-push-variable-name variable)
(cond ((variable-register variable)
(aload (variable-register variable))
(setf (variable-register variable) nil))
((variable-index variable)
(aload (compiland-argument-register compiland))
(emit-push-constant-int (variable-index variable))
(emit 'aaload)
(setf (variable-index variable) nil)))
(emit-invokevirtual +lisp-thread+ "bindSpecial"
(list +lisp-symbol+ +lisp-object+)
+lisp-special-binding+)
(astore (variable-binding-register variable)))))
(compile-progn-body body 'stack))
(when (compiland-environment-register compiland)
(restore-dynamic-environment (compiland-environment-register compiland)))
(unless *code*
(emit-push-nil))
(emit 'areturn)
;; Warn if any unused args. (Is this the right place?)
(check-for-unused-variables (compiland-arg-vars compiland))
(dolist (local-function (compiland-children compiland))
(when (compiland-class-file (local-function-compiland local-function))
(declare-local-function local-function)))
;; Go back and fill in prologue.
(let ((code *code*))
(setf *code* ())
(let ((arity (compiland-arity compiland)))
(when (and arity
*using-arg-array*)
(generate-arg-count-check arity)))
(when *hairy-arglist-p*
(aload 0) ; this
(aver (not (null (compiland-argument-register compiland))))
(aload (compiland-argument-register compiland)) ; arg vector
(emit 'aconst_null) ;; no thread arg required:
;; there's no non-constant initform or special
;; which might require the thread
(emit-invokevirtual *this-class* "processArgs"
(list +lisp-object-array+ +lisp-thread+)
+lisp-object-array+)
(astore (compiland-argument-register compiland)))
(maybe-initialize-thread-var)
(setf *code* (nconc code *code*)))))
t)
(defun compile-to-jvm-class (compiland)
"Returns ?what? ### a jvm class-file object?"
(let* ((class-file (compiland-class-file compiland))
(args (cadr (compiland-p1-result compiland)))
(*hairy-arglist-p* (or (memq '&KEY args)
(memq '&OPTIONAL args)
(memq '&REST args)))
(*using-arg-array* (or *hairy-arglist-p*
(< call-registers-limit (length args)))))
(setf (abcl-class-file-superclass class-file)
(if (or *hairy-arglist-p*
(and (not (null (compiland-parent compiland)))
*closure-variables*))
+lisp-compiled-closure+
+lisp-compiled-primitive+))
(unless *hairy-arglist-p*
(setf (compiland-arity compiland)
(length args)))
;; Static initializer
(let ((clinit (make-static-initializer class-file)))
(setf (abcl-class-file-static-initializer class-file) clinit)
(class-add-method class-file clinit))
;; Constructor
(let ((constructor
(make-constructor class-file (compiland-name compiland) args)))
(setf (abcl-class-file-constructor class-file) constructor)
(class-add-method class-file constructor))
;; Main method
(let* ((method-arg-types (if *using-arg-array*
(list +lisp-object-array+)
(lisp-object-arg-types (length args))))
(method (make-jvm-method "execute" +lisp-object+ method-arg-types
:flags '(:final :public))))
(class-add-method class-file method)
(p2-compiland compiland method))))
(defun p2-with-inline-code (form target representation)
;;form = (with-inline-code (&optional target-var repr-var) ...body...)
(destructuring-bind (&optional target-var repr-var) (cadr form)
(eval `(let (,@(when target-var `((,target-var ,target)))
,@(when repr-var `((,repr-var ,representation))))
,@(cddr form)))))
(defun compile-1 (compiland stream)
(let ((*all-variables* nil)
(*closure-variables* nil)
(*undefined-variables* nil)
(*local-functions* nil))
(p1-compiland compiland)
;; *all-variables* doesn't contain variables which
;; are in an enclosing lexical environment (variable-environment)
;; so we don't need to filter them out
(setf *closure-variables*
(remove-if #'variable-special-p
(remove-if-not #'variable-used-non-locally-p
*all-variables*)))
(let ((i 0))
(dolist (var (reverse *closure-variables*))
(setf (variable-closure-index var) i)
(dformat t "var = ~S closure index = ~S~%" (variable-name var)
(variable-closure-index var))
(incf i)))
;; Assert that we're not refering to any variables
;; we're not allowed to use
(assert (= 0
(length (remove-if (complement #'variable-references)
(remove-if #'variable-references-allowed-p
*visible-variables*)))))
;; Pass 2.
(with-class-file (compiland-class-file compiland)
(compile-to-jvm-class compiland)
(finish-class (compiland-class-file compiland) stream))))
(defvar *compiler-error-bailout*)
(defun make-compiler-error-form (form condition)
`(lambda ,(cadr form)
(error 'program-error :format-control "Program error while compiling ~a" :format-arguments
(if ,condition
(list (apply 'format nil ,(slot-value condition 'sys::format-control) ',(slot-value condition 'sys::format-arguments)))
(list "a form")))))
(defun compile-defun (name form environment filespec stream *declare-inline*)
"Compiles a lambda expression `form'. If `filespec' is NIL,
a random Java class name is generated, if it is non-NIL, it's used
to derive a Java class name from.
Returns the a abcl-class-file structure containing the description of the
generated class."
(aver (eq (car form) 'LAMBDA))
(catch 'compile-defun-abort
(flet ((compiler-bailout (&optional condition)
(let ((class-file (make-abcl-class-file :pathname filespec))
(error-form (make-compiler-error-form form condition)))
(compile-1 (make-compiland :name name
:lambda-expression error-form
:class-file class-file)
stream)
class-file)))
(let* ((class-file (make-abcl-class-file :pathname filespec))
(*compiler-error-bailout* #'compiler-bailout)
(*compile-file-environment* environment)
(precompiled-form (pre:precompile-form form t environment)))
(compile-1 (make-compiland :name name
:lambda-expression precompiled-form
:class-file class-file)
stream)
class-file))))
(defvar *catch-errors* t)
(defvar *last-error-context* nil)
(defun note-error-context ()
(let ((context *compiler-error-context*))
(when (and context (neq context *last-error-context*))
(fresh-line *error-output*)
(princ "; in " *error-output*)
(let ((*print-length* 2)
(*print-level* 2)
(*print-pretty* nil))
(prin1 context *error-output*))
(terpri *error-output*)
(terpri *error-output*)
(setf *last-error-context* context))))
(defvar *resignal-compiler-warnings* nil
"Bind this to t inside slime compilation")
(defun handle-warning (condition)
(cond (*resignal-compiler-warnings*
(signal condition))
(t
(unless *suppress-compiler-warnings*
(fresh-line *error-output*)
(note-error-context)
(format *error-output* "; Caught ~A:~%; ~A~2%"
(type-of condition) condition))
(muffle-warning))))
(defun handle-compiler-error (condition)
(fresh-line *error-output*)
(note-error-context)
(format *error-output* "; Caught ERROR:~%; ~A~2%" condition)
(throw 'compile-defun-abort (funcall *compiler-error-bailout* condition)))
(defvar *in-compilation-unit* nil)
(defmacro with-compilation-unit (options &body body)
`(%with-compilation-unit (lambda () ,@body) ,@options))
(defun %with-compilation-unit (fn &key override)
(if (and *in-compilation-unit* (not override))
(funcall fn)
(let ((style-warnings 0)
(warnings 0)
(errors 0)
(*defined-functions* nil)
(*undefined-functions* nil)
(*in-compilation-unit* t))
(unwind-protect
(handler-bind ((style-warning #'(lambda (c)
(incf style-warnings)
(handle-warning c)))
(warning #'(lambda (c)
(incf warnings)
(handle-warning c)))
(compiler-error #'(lambda (c)
(incf errors)
(handle-compiler-error c))))
(funcall fn))
(unless (or (and *suppress-compiler-warnings* (zerop errors))
(and (zerop (+ errors warnings style-warnings))
(null *undefined-functions*)))
(format *error-output*
"~%; Compilation unit finished~%")
(unless (zerop errors)
(format *error-output*
"; Caught ~D ERROR condition~P~%"
errors errors))
(unless *suppress-compiler-warnings*
(unless (zerop warnings)
(format *error-output*
"; Caught ~D WARNING condition~P~%"
warnings warnings))
(unless (zerop style-warnings)
(format *error-output*
"; Caught ~D STYLE-WARNING condition~P~%"
style-warnings style-warnings))
(when *undefined-functions*
(format *error-output*
"; The following functions were used but not defined:~%")
(dolist (name *undefined-functions*)
(format *error-output* "; ~S~%" name))))
(terpri *error-output*))))))
(defun %jvm-compile (name definition expr env)
;; This function is part of the call chain from COMPILE, but
;; not COMPILE-FILE
(let* (compiled-function
(*memory-class-loader* (sys::make-memory-class-loader)))
(with-compilation-unit ()
(with-saved-compiler-policy
(setf compiled-function
(with-open-stream (s (sys::%make-byte-array-output-stream))
(let* ((class-file (compile-defun name expr env nil s nil))
(bytes (progn
(finish-output s)
(sys::%get-output-stream-bytes s)))
(class-name (class-name-internal
(abcl-class-file-class-name class-file))))
(sys::put-memory-function *memory-class-loader*
class-name bytes)
(sys::get-memory-function *memory-class-loader*
class-name))))))
(when (and name (functionp compiled-function))
(sys::set-function-definition name compiled-function definition))
(or name compiled-function)))
(defun jvm-compile (name &optional definition)
;; This function is part of the call chain from COMPILE, but
;; not COMPILE-FILE
(unless definition
(resolve name) ;; Make sure the symbol has been resolved by the autoloader
(setf definition (fdefinition name)))
(when (compiled-function-p definition)
(return-from jvm-compile (values (or name definition) nil nil)))
(let ((catch-errors *catch-errors*)
(warnings-p nil)
(failure-p nil)
(*package* (or (and name (symbol-package name)) *package*))
(expression definition)
(*file-compilation* nil)
(*visible-variables* nil)
(*local-functions* nil)
(*pathnames-generator* (constantly nil))
environment)
(unless (and (consp definition) (eq (car definition) 'LAMBDA))
(let ((function definition))
(when (typep definition 'mop:funcallable-standard-object)
(setf function (mop::funcallable-instance-function function)))
(multiple-value-setq
(expression environment)
(function-lambda-expression function))))
(unless expression
(error "Can't find a definition for ~S." definition))
(when environment
(dolist (var (reverse (environment-all-variables environment)))
;; We need to add all variables, even symbol macros,
;; because the latter may shadow other variables by the same name
;; The precompiler should have resolved all symbol-macros, so
;; later we assert we didn't get any references to the symbol-macro.
(push (make-variable :name (if (symbolp var) var (car var))
:special-p (symbolp var)
:environment environment
:references-allowed-p
(not (sys:symbol-macro-p (cdr var)))
:compiland NIL) *visible-variables*))
(dolist (fun (reverse (environment-all-functions environment)))
(push (make-local-function :name (car fun)
:references-allowed-p
(not (macro-function-p (cdr fun)))
:environment environment)
*local-functions*)))
(handler-bind
((compiler-unsupported-feature-error
#'(lambda (c)
(when catch-errors
(fresh-line)
(sys::%format t "; UNSUPPORTED FEATURE: ~A~%" c)
(sys::%format t "; Unable to compile ~S.~%"
(or name "top-level form"))
(return-from jvm-compile
(sys:precompile name definition)))))
(style-warning
#'(lambda (c) (declare (ignore c))
(setf warnings-p t) nil))
((or warning compiler-error)
#'(lambda (c) (declare (ignore c))
(setf warnings-p t
failure-p t)
nil)))
(values (%jvm-compile name definition expression environment)
warnings-p failure-p))))
(defvar *file-compilation* nil)
(defvar *pathnames-generator* #'make-temp-file)
(defun compile (name &optional definition)
(jvm-compile name definition))
(defmacro with-file-compilation (&body body)
`(let ((*file-compilation* t)
(*pathnames-generator* #'sys::next-classfile))
,@body))
(defun initialize-p2-handlers ()
(mapc #'install-p2-handler '(declare
multiple-value-call
multiple-value-list
multiple-value-prog1
nth
progn))
(install-p2-handler '%ldb 'p2-%ldb)
(install-p2-handler '* 'p2-times)
(install-p2-handler '+ 'p2-plus)
(install-p2-handler '- 'p2-minus)
(install-p2-handler '< 'p2-numeric-comparison)
(install-p2-handler '<= 'p2-numeric-comparison)
(install-p2-handler '= 'p2-numeric-comparison)
(install-p2-handler '> 'p2-numeric-comparison)
(install-p2-handler '>= 'p2-numeric-comparison)
(install-p2-handler 'and 'p2-and)
(install-p2-handler 'aref 'p2-aref)
(install-p2-handler 'aset 'p2-aset)
(install-p2-handler 'ash 'p2-ash)
(install-p2-handler 'atom 'p2-atom)
(install-p2-handler 'bit-vector-p 'p2-bit-vector-p)
(install-p2-handler 'car 'p2-car)
(install-p2-handler 'cdr 'p2-cdr)
(install-p2-handler 'char 'p2-char/schar)
(install-p2-handler 'char-code 'p2-char-code)
(install-p2-handler 'java:jclass 'p2-java-jclass)
(install-p2-handler 'java:jconstructor 'p2-java-jconstructor)
(install-p2-handler 'java:jmethod 'p2-java-jmethod)
; (install-p2-handler 'java:jcall 'p2-java-jcall)
(install-p2-handler 'char= 'p2-char=)
(install-p2-handler 'characterp 'p2-characterp)
(install-p2-handler 'coerce-to-function 'p2-coerce-to-function)
(install-p2-handler 'cons 'p2-cons)
(install-p2-handler 'sys::backq-cons 'p2-cons)
(install-p2-handler 'consp 'p2-consp)
(install-p2-handler 'delete 'p2-delete)
(install-p2-handler 'elt 'p2-elt)
(install-p2-handler 'eq 'p2-eq/neq)
(install-p2-handler 'eql 'p2-eql)
(install-p2-handler 'eval-when 'p2-eval-when)
(install-p2-handler 'find-class 'p2-find-class)
(install-p2-handler 'fixnump 'p2-fixnump)
(install-p2-handler 'funcall 'p2-funcall)
(install-p2-handler 'function 'p2-function)
(install-p2-handler 'gensym 'p2-gensym)
(install-p2-handler 'get 'p2-get)
(install-p2-handler 'getf 'p2-getf)
(install-p2-handler 'gethash 'p2-gethash)
(install-p2-handler 'gethash1 'p2-gethash)
(install-p2-handler 'go 'p2-go)
(install-p2-handler 'if 'p2-if)
(install-p2-handler 'sys::%length 'p2-length)
(install-p2-handler 'list 'p2-list)
(install-p2-handler 'sys::backq-list 'p2-list)
(install-p2-handler 'list* 'p2-list*)
(install-p2-handler 'sys::backq-list* 'p2-list*)
(install-p2-handler 'load-time-value 'p2-load-time-value)
(install-p2-handler 'logand 'p2-logand)
(install-p2-handler 'logior 'p2-logior)
(install-p2-handler 'lognot 'p2-lognot)
(install-p2-handler 'logxor 'p2-logxor)
(install-p2-handler 'max 'p2-min/max)
(install-p2-handler 'memq 'p2-memq)
(install-p2-handler 'memql 'p2-memql)
(install-p2-handler 'min 'p2-min/max)
(install-p2-handler 'mod 'p2-mod)
(install-p2-handler 'neq 'p2-eq/neq)
(install-p2-handler 'not 'p2-not/null)
(install-p2-handler 'nthcdr 'p2-nthcdr)
(install-p2-handler 'null 'p2-not/null)
(install-p2-handler 'or 'p2-or)
(install-p2-handler 'packagep 'p2-packagep)
(install-p2-handler 'puthash 'p2-puthash)
(install-p2-handler 'quote 'p2-quote)
(install-p2-handler 'read-line 'p2-read-line)
(install-p2-handler 'readtablep 'p2-readtablep)
(install-p2-handler 'return-from 'p2-return-from)
(install-p2-handler 'rplacd 'p2-rplacd)
(install-p2-handler 'schar 'p2-char/schar)
(install-p2-handler 'set 'p2-set)
(install-p2-handler 'set-car 'p2-set-car/cdr)
(install-p2-handler 'set-cdr 'p2-set-car/cdr)
(install-p2-handler 'set-char 'p2-set-char/schar)
(install-p2-handler 'set-schar 'p2-set-char/schar)
(install-p2-handler 'set-std-slot-value 'p2-set-std-slot-value)
(install-p2-handler 'setq 'p2-setq)
(install-p2-handler 'simple-vector-p 'p2-simple-vector-p)
(install-p2-handler 'std-slot-value 'p2-std-slot-value)
(install-p2-handler 'stream-element-type 'p2-stream-element-type)
(install-p2-handler 'stringp 'p2-stringp)
(install-p2-handler 'structure-ref 'p2-structure-ref)
(install-p2-handler 'structure-set 'p2-structure-set)
(install-p2-handler 'svref 'p2-svref)
(install-p2-handler 'svset 'p2-svset)
(install-p2-handler 'sxhash 'p2-sxhash)
(install-p2-handler 'symbol-name 'p2-symbol-name)
(install-p2-handler 'symbol-package 'p2-symbol-package)
(install-p2-handler 'symbol-value 'p2-symbol-value)
(install-p2-handler 'symbolp 'p2-symbolp)
(install-p2-handler 'the 'p2-the)
(install-p2-handler 'throw 'p2-throw)
(install-p2-handler 'truly-the 'p2-truly-the)
(install-p2-handler 'truncate 'p2-truncate)
(install-p2-handler 'values 'p2-values)
(install-p2-handler 'vectorp 'p2-vectorp)
(install-p2-handler 'vector-push-extend 'p2-vector-push-extend)
(install-p2-handler 'write-8-bits 'p2-write-8-bits)
(install-p2-handler 'zerop 'p2-zerop)
(install-p2-handler 'with-inline-code 'p2-with-inline-code)
t)
(initialize-p2-handlers)
(defvar sys:*enable-autocompile*)
(defun sys:autocompile (function)
(when sys:*enable-autocompile*
(let ((sys:*enable-autocompile* nil))
(values (compile nil function)))))
(setf sys:*enable-autocompile* t)
(provide "COMPILER-PASS2")