;;; open-coding primitive procedures ;; Copyright (C) 2009, 2010, 2011, 2012 Free Software Foundation, Inc. ;;;; This library is free software; you can redistribute it and/or ;;;; modify it under the terms of the GNU Lesser General Public ;;;; License as published by the Free Software Foundation; either ;;;; version 3 of the License, or (at your option) any later version. ;;;; ;;;; This library 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 ;;;; Lesser General Public License for more details. ;;;; ;;;; You should have received a copy of the GNU Lesser General Public ;;;; License along with this library; if not, write to the Free Software ;;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA ;;; Code: (define-module (language tree-il primitives) #:use-module (system base pmatch) #:use-module (rnrs bytevectors) #:use-module (system base syntax) #:use-module (language tree-il) #:use-module (srfi srfi-4) #:use-module (srfi srfi-16) #:export (resolve-primitives! add-interesting-primitive! expand-primitives! effect-free-primitive? effect+exception-free-primitive? constructor-primitive? accessor-primitive? singly-valued-primitive? equality-primitive? bailout-primitive? negate-primitive)) ;; When adding to this, be sure to update *multiply-valued-primitives* ;; if appropriate. (define *interesting-primitive-names* '(apply @apply call-with-values @call-with-values call-with-current-continuation @call-with-current-continuation call/cc dynamic-wind @dynamic-wind values eq? eqv? equal? memq memv = < > <= >= zero? + * - / 1- 1+ quotient remainder modulo ash logand logior logxor lognot not pair? null? list? symbol? vector? string? struct? number? char? nil? complex? real? rational? inf? nan? integer? exact? inexact? even? odd? char=? char>? integer->char char->integer number->string string->number acons cons cons* list vector car cdr set-car! set-cdr! caar cadr cdar cddr caaar caadr cadar caddr cdaar cdadr cddar cdddr caaaar caaadr caadar caaddr cadaar cadadr caddar cadddr cdaaar cdaadr cdadar cdaddr cddaar cddadr cdddar cddddr vector-length vector-ref vector-set! variable-ref variable-set! variable-bound? fluid-ref fluid-set! @prompt call-with-prompt @abort abort-to-prompt make-prompt-tag throw error scm-error string-length string-ref string-set! struct-vtable make-struct struct-ref struct-set! bytevector-u8-ref bytevector-u8-set! bytevector-s8-ref bytevector-s8-set! u8vector-ref u8vector-set! s8vector-ref s8vector-set! bytevector-u16-ref bytevector-u16-set! bytevector-u16-native-ref bytevector-u16-native-set! bytevector-s16-ref bytevector-s16-set! bytevector-s16-native-ref bytevector-s16-native-set! u16vector-ref u16vector-set! s16vector-ref s16vector-set! bytevector-u32-ref bytevector-u32-set! bytevector-u32-native-ref bytevector-u32-native-set! bytevector-s32-ref bytevector-s32-set! bytevector-s32-native-ref bytevector-s32-native-set! u32vector-ref u32vector-set! s32vector-ref s32vector-set! bytevector-u64-ref bytevector-u64-set! bytevector-u64-native-ref bytevector-u64-native-set! bytevector-s64-ref bytevector-s64-set! bytevector-s64-native-ref bytevector-s64-native-set! u64vector-ref u64vector-set! s64vector-ref s64vector-set! bytevector-ieee-single-ref bytevector-ieee-single-set! bytevector-ieee-single-native-ref bytevector-ieee-single-native-set! bytevector-ieee-double-ref bytevector-ieee-double-set! bytevector-ieee-double-native-ref bytevector-ieee-double-native-set! f32vector-ref f32vector-set! f64vector-ref f64vector-set!)) (define (add-interesting-primitive! name) (hashq-set! *interesting-primitive-vars* (or (module-variable (current-module) name) (error "unbound interesting primitive" name)) name)) (define *interesting-primitive-vars* (make-hash-table)) (for-each add-interesting-primitive! *interesting-primitive-names*) (define *primitive-constructors* ;; Primitives that return a fresh object. '(acons cons cons* list vector make-struct make-struct/no-tail make-prompt-tag)) (define *primitive-accessors* ;; Primitives that are pure, but whose result depends on the mutable ;; memory pointed to by their operands. '(vector-ref car cdr memq memv struct-ref string-ref bytevector-u8-ref bytevector-s8-ref bytevector-u16-ref bytevector-u16-native-ref bytevector-s16-ref bytevector-s16-native-ref bytevector-u32-ref bytevector-u32-native-ref bytevector-s32-ref bytevector-s32-native-ref bytevector-u64-ref bytevector-u64-native-ref bytevector-s64-ref bytevector-s64-native-ref bytevector-ieee-single-ref bytevector-ieee-single-native-ref bytevector-ieee-double-ref bytevector-ieee-double-native-ref)) (define *effect-free-primitives* `(values eq? eqv? equal? = < > <= >= zero? ash logand logior logxor lognot + * - / 1- 1+ quotient remainder modulo not pair? null? list? symbol? vector? struct? string? number? char? nil complex? real? rational? inf? nan? integer? exact? inexact? even? odd? char=? char>? integer->char char->integer number->string string->number struct-vtable string-length vector-length ;; These all should get expanded out by expand-primitives!. caar cadr cdar cddr caaar caadr cadar caddr cdaar cdadr cddar cdddr caaaar caaadr caadar caaddr cadaar cadadr caddar cadddr cdaaar cdaadr cdadar cdaddr cddaar cddadr cdddar cddddr ,@*primitive-constructors* ,@*primitive-accessors*)) ;; Like *effect-free-primitives* above, but further restricted in that they ;; cannot raise exceptions. (define *effect+exception-free-primitives* '(values eq? eqv? equal? not pair? null? list? symbol? vector? struct? string? number? char? acons cons cons* list vector)) ;; Primitives that don't always return one value. (define *multiply-valued-primitives* '(apply @apply call-with-values @call-with-values call-with-current-continuation @call-with-current-continuation call/cc dynamic-wind @dynamic-wind values @prompt call-with-prompt @abort abort-to-prompt)) ;; Procedures that cause a nonlocal, non-resumable abort. (define *bailout-primitives* '(throw error scm-error)) ;; Negatable predicates. (define *negatable-primitives* '((even? . odd?) (exact? . inexact?) (< . >=) (> . <=) (char=?) (char>? . char<=?))) (define *equality-primitives* '(eq? eqv? equal?)) (define *effect-free-primitive-table* (make-hash-table)) (define *effect+exceptions-free-primitive-table* (make-hash-table)) (define *equality-primitive-table* (make-hash-table)) (define *multiply-valued-primitive-table* (make-hash-table)) (define *bailout-primitive-table* (make-hash-table)) (define *negatable-primitive-table* (make-hash-table)) (for-each (lambda (x) (hashq-set! *effect-free-primitive-table* x #t)) *effect-free-primitives*) (for-each (lambda (x) (hashq-set! *effect+exceptions-free-primitive-table* x #t)) *effect+exception-free-primitives*) (for-each (lambda (x) (hashq-set! *equality-primitive-table* x #t)) *equality-primitives*) (for-each (lambda (x) (hashq-set! *multiply-valued-primitive-table* x #t)) *multiply-valued-primitives*) (for-each (lambda (x) (hashq-set! *bailout-primitive-table* x #t)) *bailout-primitives*) (for-each (lambda (x) (hashq-set! *negatable-primitive-table* (car x) (cdr x)) (hashq-set! *negatable-primitive-table* (cdr x) (car x))) *negatable-primitives*) (define (constructor-primitive? prim) (memq prim *primitive-constructors*)) (define (accessor-primitive? prim) (memq prim *primitive-accessors*)) (define (effect-free-primitive? prim) (hashq-ref *effect-free-primitive-table* prim)) (define (effect+exception-free-primitive? prim) (hashq-ref *effect+exceptions-free-primitive-table* prim)) (define (equality-primitive? prim) (hashq-ref *equality-primitive-table* prim)) (define (singly-valued-primitive? prim) (not (hashq-ref *multiply-valued-primitive-table* prim))) (define (bailout-primitive? prim) (hashq-ref *bailout-primitive-table* prim)) (define (negate-primitive prim) (hashq-ref *negatable-primitive-table* prim)) (define (resolve-primitives! x mod) (define local-definitions (make-hash-table)) (let collect-local-definitions ((x x)) (record-case x (( name) (hashq-set! local-definitions name #t)) (( head tail) (collect-local-definitions head) (collect-local-definitions tail)) (else #f))) (post-order! (lambda (x) (record-case x (( src name) (and=> (and (not (hashq-ref local-definitions name)) (hashq-ref *interesting-primitive-vars* (module-variable mod name))) (lambda (name) (make-primitive-ref src name)))) (( src mod name public?) ;; for the moment, we're disabling primitive resolution for ;; public refs because resolve-interface can raise errors. (and=> (and=> (resolve-module mod) (if public? module-public-interface identity)) (lambda (m) (and=> (hashq-ref *interesting-primitive-vars* (module-variable m name)) (lambda (name) (make-primitive-ref src name)))))) (( src proc args) (and (primitive-ref? proc) (make-primcall src (primitive-ref-name proc) args))) (else #f))) x)) (define *primitive-expand-table* (make-hash-table)) (define (expand-primitives! x) (pre-order! (lambda (x) (record-case x (( src name args) (let ((expand (hashq-ref *primitive-expand-table* name))) (and expand (apply expand src args)))) (else #f))) x)) ;;; I actually did spend about 10 minutes trying to redo this with ;;; syntax-rules. Patches appreciated. ;;; (define-macro (define-primitive-expander sym . clauses) (define (inline-args args) (let lp ((in args) (out '())) (cond ((null? in) `(list ,@(reverse out))) ((symbol? in) `(cons* ,@(reverse out) ,in)) ((pair? (car in)) (lp (cdr in) (cons (if (eq? (caar in) 'quote) `(make-const src ,@(cdar in)) `(make-primcall src ',(caar in) ,(inline-args (cdar in)))) out))) ((symbol? (car in)) ;; assume it's locally bound (lp (cdr in) (cons (car in) out))) ((self-evaluating? (car in)) (lp (cdr in) (cons `(make-const src ,(car in)) out))) (else (error "what what" (car in)))))) (define (consequent exp) (cond ((pair? exp) (pmatch exp ((if ,test ,then ,else) `(if ,test ,(consequent then) ,(consequent else))) (else `(make-primcall src ',(car exp) ,(inline-args (cdr exp)))))) ((symbol? exp) ;; assume locally bound exp) ((number? exp) `(make-const src ,exp)) ((not exp) ;; failed match #f) (else (error "bad consequent yall" exp)))) `(hashq-set! *primitive-expand-table* ',sym (case-lambda ,@(let lp ((in clauses) (out '())) (if (null? in) (reverse (cons '(else #f) out)) (lp (cddr in) (cons `((src . ,(car in)) ,(consequent (cadr in))) out))))))) (define-primitive-expander zero? (x) (= x 0)) ;; FIXME: All the code that uses `const?' is redundant with `peval'. (define-primitive-expander + () 0 (x) (values x) (x y) (if (and (const? y) (let ((y (const-exp y))) (and (number? y) (exact? y) (= y 1)))) (1+ x) (if (and (const? y) (let ((y (const-exp y))) (and (number? y) (exact? y) (= y -1)))) (1- x) (if (and (const? x) (let ((x (const-exp x))) (and (number? x) (exact? x) (= x 1)))) (1+ y) (+ x y)))) (x y z . rest) (+ x (+ y z . rest))) (define-primitive-expander * () 1 (x) (values x) (x y z . rest) (* x (* y z . rest))) (define-primitive-expander - (x) (- 0 x) (x y) (if (and (const? y) (let ((y (const-exp y))) (and (number? y) (exact? y) (= y 1)))) (1- x) (- x y)) (x y z . rest) (- x (+ y z . rest))) (define-primitive-expander / (x) (/ 1 x) (x y z . rest) (/ x (* y z . rest))) (define-primitive-expander logior () 0 (x) (logior x 0) (x y) (logior x y) (x y z . rest) (logior x (logior y z . rest))) (define-primitive-expander logand () -1 (x) (logand x -1) (x y) (logand x y) (x y z . rest) (logand x (logand y z . rest))) (define-primitive-expander caar (x) (car (car x))) (define-primitive-expander cadr (x) (car (cdr x))) (define-primitive-expander cdar (x) (cdr (car x))) (define-primitive-expander cddr (x) (cdr (cdr x))) (define-primitive-expander caaar (x) (car (car (car x)))) (define-primitive-expander caadr (x) (car (car (cdr x)))) (define-primitive-expander cadar (x) (car (cdr (car x)))) (define-primitive-expander caddr (x) (car (cdr (cdr x)))) (define-primitive-expander cdaar (x) (cdr (car (car x)))) (define-primitive-expander cdadr (x) (cdr (car (cdr x)))) (define-primitive-expander cddar (x) (cdr (cdr (car x)))) (define-primitive-expander cdddr (x) (cdr (cdr (cdr x)))) (define-primitive-expander caaaar (x) (car (car (car (car x))))) (define-primitive-expander caaadr (x) (car (car (car (cdr x))))) (define-primitive-expander caadar (x) (car (car (cdr (car x))))) (define-primitive-expander caaddr (x) (car (car (cdr (cdr x))))) (define-primitive-expander cadaar (x) (car (cdr (car (car x))))) (define-primitive-expander cadadr (x) (car (cdr (car (cdr x))))) (define-primitive-expander caddar (x) (car (cdr (cdr (car x))))) (define-primitive-expander cadddr (x) (car (cdr (cdr (cdr x))))) (define-primitive-expander cdaaar (x) (cdr (car (car (car x))))) (define-primitive-expander cdaadr (x) (cdr (car (car (cdr x))))) (define-primitive-expander cdadar (x) (cdr (car (cdr (car x))))) (define-primitive-expander cdaddr (x) (cdr (car (cdr (cdr x))))) (define-primitive-expander cddaar (x) (cdr (cdr (car (car x))))) (define-primitive-expander cddadr (x) (cdr (cdr (car (cdr x))))) (define-primitive-expander cdddar (x) (cdr (cdr (cdr (car x))))) (define-primitive-expander cddddr (x) (cdr (cdr (cdr (cdr x))))) (define-primitive-expander cons* (x) (values x) (x y) (cons x y) (x y . rest) (cons x (cons* y . rest))) (define-primitive-expander acons (x y z) (cons (cons x y) z)) (define-primitive-expander apply (f a0 . args) (@apply f a0 . args)) (define-primitive-expander call-with-values (producer consumer) (@call-with-values producer consumer)) (define-primitive-expander call-with-current-continuation (proc) (@call-with-current-continuation proc)) (define-primitive-expander call/cc (proc) (@call-with-current-continuation proc)) (define-primitive-expander make-struct (vtable tail-size . args) (if (and (const? tail-size) (let ((n (const-exp tail-size))) (and (number? n) (exact? n) (zero? n)))) (make-struct/no-tail vtable . args) #f)) (define-primitive-expander u8vector-ref (vec i) (bytevector-u8-ref vec i)) (define-primitive-expander u8vector-set! (vec i x) (bytevector-u8-set! vec i x)) (define-primitive-expander s8vector-ref (vec i) (bytevector-s8-ref vec i)) (define-primitive-expander s8vector-set! (vec i x) (bytevector-s8-set! vec i x)) (define-primitive-expander u16vector-ref (vec i) (bytevector-u16-native-ref vec (* i 2))) (define-primitive-expander u16vector-set! (vec i x) (bytevector-u16-native-set! vec (* i 2) x)) (define-primitive-expander s16vector-ref (vec i) (bytevector-s16-native-ref vec (* i 2))) (define-primitive-expander s16vector-set! (vec i x) (bytevector-s16-native-set! vec (* i 2) x)) (define-primitive-expander u32vector-ref (vec i) (bytevector-u32-native-ref vec (* i 4))) (define-primitive-expander u32vector-set! (vec i x) (bytevector-u32-native-set! vec (* i 4) x)) (define-primitive-expander s32vector-ref (vec i) (bytevector-s32-native-ref vec (* i 4))) (define-primitive-expander s32vector-set! (vec i x) (bytevector-s32-native-set! vec (* i 4) x)) (define-primitive-expander u64vector-ref (vec i) (bytevector-u64-native-ref vec (* i 8))) (define-primitive-expander u64vector-set! (vec i x) (bytevector-u64-native-set! vec (* i 8) x)) (define-primitive-expander s64vector-ref (vec i) (bytevector-s64-native-ref vec (* i 8))) (define-primitive-expander s64vector-set! (vec i x) (bytevector-s64-native-set! vec (* i 8) x)) (define-primitive-expander f32vector-ref (vec i) (bytevector-ieee-single-native-ref vec (* i 4))) (define-primitive-expander f32vector-set! (vec i x) (bytevector-ieee-single-native-set! vec (* i 4) x)) (define-primitive-expander f32vector-ref (vec i) (bytevector-ieee-single-native-ref vec (* i 4))) (define-primitive-expander f32vector-set! (vec i x) (bytevector-ieee-single-native-set! vec (* i 4) x)) (define-primitive-expander f64vector-ref (vec i) (bytevector-ieee-double-native-ref vec (* i 8))) (define-primitive-expander f64vector-set! (vec i x) (bytevector-ieee-double-native-set! vec (* i 8) x)) (define-primitive-expander f64vector-ref (vec i) (bytevector-ieee-double-native-ref vec (* i 8))) (define-primitive-expander f64vector-set! (vec i x) (bytevector-ieee-double-native-set! vec (* i 8) x)) (hashq-set! *primitive-expand-table* '@dynamic-wind (case-lambda ((src pre expr post) (let ((PRE (gensym "pre-")) (POST (gensym "post-"))) (make-let src '(pre post) (list PRE POST) (list pre post) (make-dynwind src (make-lexical-ref #f 'pre PRE) (make-call #f (make-lexical-ref #f 'pre PRE) '()) expr (make-call #f (make-lexical-ref #f 'post POST) '()) (make-lexical-ref #f 'post POST))))))) (hashq-set! *primitive-expand-table* 'fluid-ref (case-lambda ((src fluid) (make-dynref src fluid)) (else #f))) (hashq-set! *primitive-expand-table* 'fluid-set! (case-lambda ((src fluid exp) (make-dynset src fluid exp)) (else #f))) (hashq-set! *primitive-expand-table* '@prompt (case-lambda ((src tag exp handler) (let ((args-sym (gensym))) (make-prompt src tag exp ;; If handler itself is a lambda, the inliner can do some ;; trickery here. (make-lambda-case (tree-il-src handler) '() #f 'args #f '() (list args-sym) (make-primcall #f 'apply (list handler (make-lexical-ref #f 'args args-sym))) #f)))) (else #f))) (hashq-set! *primitive-expand-table* 'call-with-prompt (case-lambda ((src tag thunk handler) (let ((handler-sym (gensym)) (args-sym (gensym))) (make-let src '(handler) (list handler-sym) (list handler) (make-prompt src tag (make-call #f thunk '()) ;; If handler itself is a lambda, the inliner can do some ;; trickery here. (make-lambda-case (tree-il-src handler) '() #f 'args #f '() (list args-sym) (make-primcall #f 'apply (list (make-lexical-ref #f 'handler handler-sym) (make-lexical-ref #f 'args args-sym))) #f))))) (else #f))) (hashq-set! *primitive-expand-table* '@abort (case-lambda ((src tag tail-args) (make-abort src tag '() tail-args)) (else #f))) (hashq-set! *primitive-expand-table* 'abort-to-prompt (case-lambda ((src tag . args) (make-abort src tag args (make-const #f '()))) (else #f)))