;; O Emacs, this is a -*- Lisp -*- file, despite appearance
;;
;; Copyright (c) 1991-2002, The Numerical Algorithms Group Ltd.
;; All rights reserved.
;;
;; Copyright (C) 2007-2012, Gabriel Dos Reis.
;; All rights reserved.
;;
;; Redistribution and use in source and binary forms, with or without
;; modification, are permitted provided that the following conditions are
;; met:
;;
;; - Redistributions of source code must retain the above copyright
;; notice, this list of conditions and the following disclaimer.
;;
;; - Redistributions in binary form must reproduce the above copyright
;; notice, this list of conditions and the following disclaimer in
;; the documentation and/or other materials provided with the
;; distribution.
;;
;; - Neither the name of The Numerical Algorithms Group Ltd. nor the
;; names of its contributors may be used to endorse or promote products
;; derived from this software without specific prior written permission.
;;
;; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
;; IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
;; TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
;; PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
;; OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
;; EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
;; PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
;; PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
;; LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
;; NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
;; SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
;;
;; -*- Abstract -*-
;;
;; This file defines the core of the system utilities for building
;; Boot and OpenAxiom executable. It essentially etablishes a namespace
;; (package AxiomCore) and defines some macros and functions
;; that need to be present during compilation and executable
;; image construction.
;;
(defpackage "AxiomCore"
#+:common-lisp (:use "COMMON-LISP")
#-:common-lisp (:use "LISP" "USER")
#+(and :SBCL :SB-THREAD) (:use "SB-THREAD")
#+(and :ECL :THREADS) (:use "MP")
#+(and :CLISP :MT) (:use "THREADS")
;; For GCL we need to explicitly use the DEFPACKAGE, otherwise the
;; image obtained from compiler link will not work. The root cause
;; is a non-ANSI compliant organization of GCL's implementation.
#+:gcl (:use "DEFPACKAGE")
;; Clozure CL sequesters most of its useful extensions, in particular
;; threads, in the CCL package.
;; #+:clozure (:use "CCL")
#+:clozure (:import-from "CCL"
external-call %get-cstring
with-pointer-to-ivector with-cstrs)
#+:clozure (:export "CCL"
external-call %get-cstring
with-pointer-to-ivector with-cstrs)
(:export "%Thing"
"%Void"
"%Boolean"
"%String"
"%Symbol"
"%Short"
"%Bit"
"%Byte"
"%Char"
"%Bignum"
"%Integer"
"%Number"
"%IntegerSection"
"%DoubleFloat"
"%Atom"
"%Maybe"
"%Pair"
"%Node"
"%List"
"%Vector"
"%BitVector"
"%SimpleArray"
;; Some common data structures
"makeTable" ; construct a hash table with a given comp function
"tableValue" ; value associated with a key in a table
"tableLength" ; number of entries in the table.
"tableRemove!" ; remove an entry from a table
"ref"
"deref"
;; IO
"$stdin"
"$stdout"
"$stdio"
"$InputStream"
"$OutputStream"
"$ErrorStream"
"inputBinaryFile"
"outputBinaryFile"
"inputTextFile"
"outputTextFile"
"closeFile"
"closeStream"
"eof?"
"prettyPrint"
"readLine"
"readExpr"
"readIntegerIfCan"
"formatToString"
"formatToStream"
"formatToStdout"
;; compiler data structures
"%Mode"
"%Sig"
"%Code"
"%Env"
"%Form"
"%Triple"
"%Shell"
;; functor data structures
"%FunctorData"
"%FunctorCoreData"
"%FunctorBytecode"
"%FunctorTemplate"
"%FunctorPredicateIndexTable"
"%FunctorOperatorDirectory"
"%FunctorCategoryTable"
"%FunctorAttributeTable"
"%FunctorDefaultTable"
"%FunctorLookupFunction"
"primitiveLoad"
"coreQuit"
"fatalError"
"internalError"
"coreError"
"errorCount"
"countError"
"resetErrorCount"
"warn"
"startCompileDuration"
"endCompileDuration"
"%ByteArray"
"makeByteArray"
"makeBitVector"
"makeString"
"mkVector"
"mkIntArray"
"listToString"
"maxIndex"
"%hasFeature"
"%systemOptions"
"%systemArguments"
"%sysInit"
"%basicSystemIsComplete"
"%algebraSystemIsComplete"
"%nothing"
"%nullStream"
"%nonNullStream"
"%escapeSequenceAverseHost?"
"%defaultReadAndLoadSettings"
"$hostPlatform"
"$buildPlatform"
"$targetPlatform"
"$faslType"
"$delayedFFI"
"$effectiveFaslType"
"$NativeModuleExt"
"$systemInstallationDirectory"
"$NativeTypeTable"
"$LispOptimizeOptions"
"$StandardLinking"
"$ECLVersionNumber"
"$FilesToRetain"
"$dynamicForeignFunctions"
"getOptionValue"
"getCommandLineArguments"
"$originalLispTopLevel"
"link"
"installDriver"
"associateRequestWithFileType"
"ensureTrailingSlash"
"getOutputPathname"
"loadPathname"
"loadFileIfPresent"
"compileLispFile"
"compileLispHandler"
"Option"
"systemRootDirectory"
"systemLibraryDirectory"
"userHomeDirectory"
"pathBasename"
"IMPORT-MODULE"
"bootImport"
"CONCAT"
"$EditorProgram"
"ident?"
;; numeric support
"fixnum?"
"double"
"%fNaN?"
))
(in-package "AxiomCore")
;;
;; -*- Basic data types -*-
;;
;; Type of nothing. Bottom of the abstract machine type lattice.
;; Since Lisp functions always returns something, we cannot
;; use the `nil' type specifier (the ideal answer). Second
;; best possibility is to have Void-returning functions
;; systematically return `nil'. However, until the Lisp
;; backend is fixed, we will use the interpretation that a
;; Void-returning function may return anything, but nobody cares.
;; Hence, the choice below which contradicts the very first line
;; of this description.
(deftype |%Void| () 't)
(deftype |%Thing| () 't)
(deftype |%Boolean| () 'boolean)
(deftype |%String| () 'string)
(deftype |%Symbol| () 'symbol)
(deftype |%Short| () 'fixnum)
(deftype |%Bit| () 'bit)
(deftype |%Byte| () '(unsigned-byte 8))
(deftype |%Char| () 'character)
(deftype |%Bignum| () 'bignum)
(deftype |%Integer| () 'integer)
(deftype |%IntegerSection| (n) `(integer ,n))
(deftype |%DoubleFloat| () 'double-float)
(deftype |%Number| () 'number)
(deftype |%Atom| () 'atom)
(deftype |%Maybe| (s) `(or null ,s))
(deftype |%Pair| (u v)
`(cons ,u ,v))
(deftype |%Node| (s)
`(cons ,s null))
(deftype |%List| (s)
`(or null (cons ,s)))
(deftype |%SimpleArray| (s) `(simple-array ,s))
(deftype |%Vector| (s) `(vector ,s))
(deftype |%BitVector| () '(simple-array bit))
(deftype |%Shell| () 'simple-vector)
(deftype |%Mode| () '(or symbol string cons))
(deftype |%Sig| () '(or symbol cons))
(deftype |%Code| () '(or |%Form| |%Char|))
(deftype |%Env| () '(or null cons))
(deftype |%Form| () '(or number symbol string cons))
(deftype |%Triple| ()
'(cons |%Code| (cons |%Mode| (cons |%Env| null))))
;; Functor templates
(deftype |%FunctorTemplate| ()
'simple-vector)
;; operator directory for functors.
(deftype |%FunctorOperatorDirectory| ()
'(simple-array (or symbol fixnum)))
;; List of (attribute . predicate-index) pairs for functors.
(deftype |%FunctorAttributeTable| ()
'list)
;; Lookup-function for functors. For most functors, they are
;; either lookupIncomplete or lookupComplete.
;; Historical functors have lookupInTable.
(deftype |%FunctorLookupFunction| ()
'|%Symbol|)
;; Functor predicate index table
(deftype |%FunctorPredicateIndexTable| ()
'(simple-array fixnum))
;; vector of categories a functor instantiation may belong to.
(deftype |%FunctorCategoryTable| ()
'(simple-array |%Form|))
;; vector of default category packages that a functor may implicitly use.
(deftype |%FunctorDefaultTable| ()
'(simple-array (|%Maybe| |%Constructor|)))
;; sequence of `byte codes' for a functor
(deftype |%FunctorBytecode| ()
'(simple-array fixnum))
;; PredicateIndex + DefaultTable + CategoryTable + Bytecode
(deftype |%FunctorCoreData| ()
'(cons |%FunctorPredicateIndexTable|
(cons |%FunctorDefaultTable|
(cons |%FunctorCategoryTable| |%FunctorBytecode|))))
;; The essential of what is needed to instantiate a functor.
;; This is the type of `infovec' properties of functors.
(deftype |%FunctorData| ()
'(cons |%FunctorTemplate|
(cons |%FunctorOperatorDirectory|
(cons |%FunctorAttributeTable|
(cons |%Thing|
(cons |%FunctorLookupFunction| null))))))
;;
;; -*- Configuration Constants -*-
;;
;; The canonical triplets for host, build, and target. For the moment,
;; they are all identical, for we don't support cross compilation yet.
(defconstant |$hostPlatform| "@host@")
(defconstant |$buildPlatform| "@build@")
(defconstant |$targetPlatform| "@target@")
;; How to invoke the host C++ compiler and linker flags
(defconstant oa-cxx "@CXX@")
(defconstant oa-ldflags "@LDFLAGS@")
;; The directory that contains the final installation directory, as
;; specified at configuration time (or in exoteric cases, as overriden
;; on the Make command line).
(defconstant |$systemInstallationDirectory|
"@open_axiom_installdir@/")
;; File kinds to retain.
(defconstant |$FilesToRetain|
'(@oa_keep_files@))
;; List of foreign function symbols to unload before saving the
;; Lisp image. This is meaningful only for those systems not
;; using standard linking and that delay FFI modules to runtime.
(defparameter |$dynamicForeignFunctions| nil)
;; Lisp compiler optimization settings.
(defconstant |$LispOptimizeOptions|
'(@oa_optimize_options@))
(proclaim '(optimize @oa_optimize_options@))
;; Enablig profiling of generated Lisp codes.
(eval-when (:compile-toplevel :load-toplevel :execute)
(defconstant |$EnableLispProfiling| @oa_enable_profiling@))
(eval-when (:compile-toplevel :load-toplevel :execute)
(progn #+(and :sbcl (not :win32)) (require :sb-sprof)))
;; Return true if the full OpenAxiom algebra system is completed
;; built.
(defun |%algebraSystemIsComplete| nil
(member :open-axiom-algebra-system *features*))
;; Return true if the basic OpenAxiom system is complete. This means
;; that we have a compiler and an interpreter, but not necessarily
;; the algebras.
(defun |%basicSystemIsComplete| nil
(or (|%algebraSystemIsComplete|)
(member :open-axiom-basic-system *features*)))
;; Return true if the Boot system is completely bootstrapped.
(defun boot-completed-p nil
(or (|%basicSystemIsComplete|)
(member :open-axiom-boot *features*)))
;;
;; -*- Hosting Lisp System -*-
;;
(eval-when (:compile-toplevel :load-toplevel :execute)
(progn
(setq *read-default-float-format* 'double-float)
(setq *load-verbose* nil)))
;; True means that the base Lisp system uses conventional C-style
;; program linking model, whereby programs are constructed by linking
;; separately compiled units. By constrast, many Lisp systems build
;; executable programs by loading FASLs into core and dumping the resulting
;; image on disk.
(defconstant |$StandardLinking|
(eq '@oa_standard_linking@ 'yes))
;; Almost every supported Lisp use dynamic link for FFI.
;; ECL's support is partial. GCL-2.6.x hasn't discovered it yet.
(defconstant |$useDynamicLink|
#+:ecl (member :dffi *features*)
#+:gcl nil
#-(or :ecl :gcl) t)
;; True if FFI modules were delayed till runtime.
(defconstant |$delayedFFI|
(eq '@oa_delay_ffi@ 'yes))
;; The top level read-eval-print loop function of the base
;; Lisp system we are using. This is a very brittle way
;; of achieving something conceptually simple.
(defconstant |$originalLispTopLevel|
#+:ecl #'si::top-level
#+:gcl #'si::top-level
#+:sbcl #'sb-impl::toplevel-init
#+clisp #'system::main-loop
#+:clozure nil ; don't know, kept private
)
;; Lisp source file extension.
(defconstant |$LispFileType| "lisp")
;; Extenstion of FASL files.
(defconstant |$faslType|
(pathname-type (compile-file-pathname "foo.lisp")))
(defconstant |$effectiveFaslType|
#+:ecl (pathname-type (compile-file-pathname "foo.lisp" :system-p t))
#-:ecl |$faslType|)
;; Extension of file containers for native shared libraries.
(defconstant |$NativeModuleExt|
(cond (|$useDynamicLink| "@SHREXT@")
(t ".@LIBEXT@")))
;; Return true if the host is escape sequence averse. This is notably
;; true on windows-based builds (win32 or win64)
(defun |%escapeSequenceAverseHost?| ()
(or (member :win32 *features*)
(member :windows *features*)))
;; Some default settings
(defmacro |%defaultReadAndLoadSettings| ()
`(eval-when (:compile-toplevel :load-toplevel :execute)
(progn
(setq *read-default-float-format* 'double-float)
(setq *load-verbose* nil))))
(defconstant |$EditorProgram| "@oa_editor@")
;; Token expression to indicate absence of value or bottom value.
;; This is also the bottom value of the Maybe domain.
(defconstant |%nothing| :|OpenAxiomNoValue|)
;; Token expression to indicate the end of a stream of values.
(defconstant |%nullStream| :|OpenAxiomNullStream|)
;; Token expression to indicate there are move to come in a stream of values.
(defconstant |%nonNullStream| :|OpenAxiomNonNullStream|)
;; Base name of the native core runtime library
(defconstant |$CoreLibName|
"open-axiom-core")
;; C runtime needed by the target system; e.g. -lm or -lwinsock
(defconstant |$ExtraRuntimeLibraries|
'(@oa_c_runtime_extra@))
(defun extra-runtime-libs nil
(if (boot-completed-p)
(append
(list (concatenate 'string "-L" (|systemLibraryDirectory|))
(concatenate 'string "-l" |$CoreLibName|))
|$ExtraRuntimeLibraries|)
|$ExtraRuntimeLibraries|))
#+:clisp
(eval-when (:compile-toplevel :load-toplevel :execute)
(progn
(setf custom:*ansi* t)
(setf custom:*floating-point-contagion-ansi* t)
(setf custom:*warn-on-floating-point-contagion* t)
(setf custom:*trace-indent* t)
(setf custom:*foreign-encoding*
(ext:make-encoding :charset charset:iso-8859-1))))
;; ECL is a moving target, especially, in its FII support. Track
;; versions as poor man safeguard to portability chaos.
(defconstant |$ECLVersionNumber|
#-:ecl -1
#+:ecl (let ((ver (find-symbol "+ECL-VERSION-NUMBER+" "EXT")))
(cond (ver (symbol-value ver))
(t -1))))
;; -*- Hash table -*-
(defmacro |makeTable| (cmp)
`(make-hash-table :test ,cmp))
(defmacro |tableValue| (ht k)
`(gethash ,k ,ht))
(defmacro |tableRemove!| (ht k)
`(remhash ,k ,ht))
(defmacro |tableLength| (ht)
`(hash-table-count ,ht))
;; -*- Reference -*-
(defmacro |ref| (v)
`(cons ,v nil))
(defmacro |deref| (r)
`(car ,r))
;; -*- File IO -*-
(defparameter |$stdout| *standard-output*)
(defparameter |$stdin| *standard-input*)
(defparameter |$stdio| *terminal-io*)
(defparameter |$InputStream| (make-synonym-stream '*standard-input*))
(defparameter |$OutputStream| (make-synonym-stream '*standard-output*))
(defparameter |$ErrorStream| (make-synonym-stream '*standard-output*))
(defun |inputBinaryFile| (f)
(open f
:direction :input
:element-type 'unsigned-byte
:if-does-not-exist nil))
(defun |outputBinaryFile| (f)
(open f
:direction :output
:element-type 'unsigned-byte
:if-exists :supersede))
(defun |inputTextFile| (f)
(open f
:direction :input
:if-does-not-exist nil))
(defun |outputTextFile| (f)
(open f
:direction :output
:if-exists :supersede))
(defun |closeFile| (f)
(close f))
(defmacro |closeStream| (s)
`(close ,s))
(defmacro |eof?| (s)
`(null (peek-char nil ,s nil nil nil)))
;; Read a line from the input text file. Quietly return
;; %nothing at end of file.
(defmacro |readLine| (f)
`(read-line ,f nil |%nothing|))
(defmacro |readByte| (f)
`(read-byte ,f nil |%nothing|))
(defmacro |readExpr| (f)
`(read ,f nil |%nothing|))
(defun |readIntegerIfCan| (s)
(let ((r (multiple-value-call #'cons (parse-integer s :junk-allowed t))))
(cond ((eql (cdr r) (length s)) (car r))
(t nil))))
;; Pretty-print a lisp form on a given output stream.
(defun |prettyPrint| (x &optional (s |$OutputStream|))
(let ((*print-pretty* t)
(*print-array* t)
(*print-circle* t)
(*print-length* nil)
(*print-level* nil))
(prin1 x s)))
(defmacro |formatToString| (&rest args)
`(format nil ,@args))
(defmacro |formatToStream| (&rest x)
`(format ,@x))
(defmacro |formatToStdout| (&rest args)
`(format |$stdout| ,@args))
;;
;; -*- OpenAxiom filesystem -*-
;;
(defconstant |$BootFileType| "boot")
(defconstant |$LibraryFileType| "spad")
(defconstant |$ScriptFileType| "input")
;; Canonalize source file extensions
(defun |getFileType|(file)
(let ((file-type (pathname-type file)))
(cond ((or (equal "clisp" file-type)
(equal "lsp" file-type))
|$LispFileType|)
(t file-type))))
;; Returns the root directory of the running system.
;; A directory specified on command line takes precedence
;; over directory specified at configuration time.
(defun |systemRootDirectory| nil
(let ((dir (assoc (|Option| "system") (|%systemOptions|))))
(if (not (null dir))
(|ensureTrailingSlash| (cdr dir))
|$systemInstallationDirectory|)))
;; Returns the directory containing the core runtime support
;; libraries, either as specified on command line, or as inferred
;; from the system root directory.
(defun |systemLibraryDirectory| nil
(let ((dir (assoc (|Option| "syslib") (|%systemOptions|))))
(if (not (null dir))
(|ensureTrailingSlash| (cdr dir))
(concatenate 'string (|systemRootDirectory|) "lib/"))))
(defmacro |userHomeDirectory| nil
(user-homedir-pathname))
;; Return the list of linkable fasls in in the directory `dir'.
(defun linkset-from (dir)
(mapcar #'(lambda(f) (concatenate 'string dir f))
(with-open-file (stream (concatenate 'string dir "linkset"))
(read stream t))))
;; Return a path to the the subdirectory `subdir' within the
;; OpenAxiom filesystem.
(defun system-subdirectory (subdir)
(concatenate 'string (|systemRootDirectory|) subdir))
;; Like linkset-from when `feature' in on the features list.
(defun linkset-from-if (dir feature)
(if (member feature *features*)
(linkset-from (system-subdirectory dir))
nil))
;; Return a complete list of fasls as appropriate for building
;; an executable program user thought consists only of `fasls'.
(defun complete-fasl-list-for-link (fasls)
(append (linkset-from-if "lisp/" :open-axiom-base-lisp)
(linkset-from-if "boot/" :open-axiom-boot)
(map 'list #'|compileFilePathname| fasls)))
;;
;; -*- OpenAxiom Driver Table -*-
;;
;; Global map from requests to drivers.
;; Ideally we want to handle
;; --help: just print a help menu and exit
;; --version: Print version information and exit
;; --system=
: specify as the root directory
;; --sysalg=: specify as directory containing algebras
;; --compile: boot or lisp files
;; --translate: boot files
;; --prologue=: Run just before the main entry point.
;; --make: boot, lisp, or fasl files
(defparameter |$driverTable|
(make-hash-table :test #'equal :size 10))
;; Look up the driver that can handle REQUEST. Returns nil when
;; no driver exists.
(defun |getDriver| (request)
(gethash request |$driverTable|))
;; Associate DRIVER with REQUEST.
;; There can exist at most one driver per request.
(defun |installDriver| (request driver)
(when (|getDriver| request)
(|internalError| "attempt to override driver"))
(setf (gethash request |$driverTable|) driver))
(defun |useFileType?| (request)
(get request 'use-file-type))
;; Register DRIVER for a REQUEST for a file with FILE-TYPE extension.
(defun |associateRequestWithFileType| (request file-type driver)
;; If a driver is already installed, it must be non-null.
;; We don't allow overriding at the moment.
(let ((key (cons request file-type)))
(unless (|useFileType?| request)
(setf (get request 'use-file-type) file-type))
(|installDriver| key driver)))
;;
;; -*- OpenAxiom Command Line Parsing -*-
;;
;; Return a symbol object represensing option named OPT, without leading
;; double dash (--).
(defun |Option| (opt)
(intern (string opt) (find-package "AxiomCore")))
;; Translate option value:
;; "no" -> nil
;; "yes" -> t
;; [0-9]+ -> integer value
;; otherwise -> input string unmolested
(defun translate-option-value (val)
(cond ((string= val "no") nil)
((string= val "yes") t)
(t (multiple-value-bind (ival idx)
(parse-integer val :junk-allowed t)
(cond ((null ival) val)
((eql idx (length val)) ival)
(t val))))))
;; Returns a pair (name . value) if OPTION if of the form "--name=value",
;; where name is a symbol and value is a string. Otherwise, if
;; OPTION is of the form "--name", returns the symbol name.
(defun |parseOption| (option)
(setq option (subseq option 2))
(let ((p (position #\= option)))
(if p
(cons (|Option| (subseq option 0 p))
(translate-option-value (subseq option (1+ p))))
(|Option| option))))
;; Returns the value specified for OPTION. Otherwise, return nil
(defun |getOptionValue| (opt &optional (options (|%systemOptions|)))
(let ((val (assoc (|Option| opt) options)))
(cond (val (cdr val))
(t nil))))
;; Walk through the command line arguments ARGV, separating options
;; of the form --opt or --opt=val into an a-list, and the rest
;; of the command line into a list. The processing stop as soon as
;; a non-option form is encountered. OPTIONS-SO-FAR accumulates the
;; the list of processed options.
(defun |processCommandLine| (argv options-so-far args-so-far)
(cond ((null argv)
;; no more command-line argument to process
(values options-so-far (nreverse args-so-far)))
((equal "--" (car argv))
;; end of command-line options
(values options-so-far (concatenate 'list
(nreverse args-so-far)
(cdr argv))))
((or (< (length (car argv)) 2)
(not (equal "--" (subseq (car argv) 0 2))))
;; not a command-line option
(|processCommandLine| (cdr argv)
options-so-far
(cons (car argv) args-so-far)))
(t (let ((option (|parseOption| (car argv))))
(cond ((symbolp option)
(|processCommandLine| (cdr argv)
(cons (cons option t)
options-so-far)
args-so-far))
((consp option)
(|processCommandLine| (cdr argv)
(cons option options-so-far)
args-so-far))
(t (|internalError|
(format nil "processCommandLine: unknown option ~S"
option))))))))
;;
;; -*- Building New Lisp Images -*-
;;
;; At many points, the build machinery makes new Lisp images that
;; are the results of augmenting a given Lisp image with new
;; Lisp files (either compiled or in source form). For most Lisp
;; implementations, this is done by loading the Lisp files in the
;; current image and dumping the result on disk as an executable.
(defun |getOutputPathname| (options)
(let ((output-option (assoc (|Option| "output") options)))
(when output-option
;; If an output file name was specified on the command line, it
;; is so relative to the current working directory. In
;; particular we want to prevent overly zelous SBCL to mess
;; around with the output file when we call compile-file-pathname.
;; The SBCL-specific hack below does not work all the time, but in
;; most cases, it is OK.
#+:sbcl (merge-pathnames (cdr output-option)
*default-pathname-defaults*)
#-:sbcl (cdr output-option))))
(defun |getMainEntryPoint| (options)
(|getOptionValue| (|Option| "main") options))
(defun |getPrologue| (options)
(let ((prologue (|getOptionValue| (|Option| "prologue") options)))
(if prologue (read-from-string prologue) nil)))
;; This is meaningful only for systems that delay FFI.
;; Unbind foreign function symbols in case delaying FFI modules
;; is needed. Indeed, these systems should not have references to
;; foreign symbols that cannot be guaranteed to work properly
;; when the saved image is restarted.
(defun unbind-foreign-function-symbols ()
(when |$delayedFFI|
(mapc #'(lambda (s)
(when (fboundp s)
(fmakunbound s)))
|$dynamicForeignFunctions|)))
;; Save current image on disk as executable and quit.
(defun |saveCore| (core-image &optional (entry-point nil))
;; When building the OpenAxiom system, and in many other cases I suspect,
;; the main entry point is some function in a package not known to
;; the Lisp system at compile time, so we have delayed the
;; evaluation of the entry point in a form of a suspension. At this
;; point we must have all data needed to complete the evaluation.
(when (consp entry-point)
(setq entry-point (apply (car entry-point)
(cdr entry-point))))
(unbind-foreign-function-symbols)
#+:sbcl (if (null entry-point)
(sb-ext::save-lisp-and-die core-image :executable t)
(sb-ext::save-lisp-and-die core-image
:toplevel entry-point
:executable t))
#+:gcl (progn
(when entry-point
(setq si::*top-level-hook* entry-point))
(system::save-system core-image))
#+:clisp (progn
(if entry-point
(ext::saveinitmem core-image
:init-function entry-point
:executable t
:norc t
:quiet t
)
(ext::saveinitmem core-image
:executable t
:norc t
))
(ext::quit))
#+:clozure (progn
(ccl:save-application core-image
:toplevel-function entry-point
:error-handler :quit
:prepend-kernel t)
(return-from |saveCore|))
(error "don't know how to save Lisp image"))
;; Load a module designated by `f'.
(defmacro |primitiveLoad| (f)
`(load ,f))
;;
;; -*- Program Termination -*-
;;
;; When working in batch mode, we need to return so-called `exit status'
;; to the calling shell. Common Lisp has no provision for that ---
;; not even exiting from the toplevel read-eval-print loop. Most
;; Lisp implementations provide an `exit' function as extensions, though
;; they don't agree on the exact spelling, therefore on the API.
;; The function |coreQuit| is our abstractions over those variabilties.
;; It takes an optional small integer value, the exit status code to
;; return to the calling shell. When no exit status code is specified,
;; it would return $0$, meaning that everything is OK.
(defun |coreQuit| (&optional (status 0))
#+:sbcl (sb-ext:quit :unix-status status)
#+:clisp (ext:quit status)
#+:gcl (si::bye status)
#+:ecl (ext:quit status)
#+:clozure (ccl:quit status)
#-(or :sbcl :clisp :gcl :ecl :clozure)
(error "`coreQuit' not implemented for this Lisp"))
;;
;; -*- Basic Diagnostic Routines -*-
;;
;; For the most basic batch stuff, we want:
;; (1) fatal error: output message and exit with nonzero status
;; (2) internal error: same. This is for use on reporting internal
;; consistency error.
(defun |diagnosticMessage|(prefix msg)
(let ((text (concatenate 'string prefix ": " msg)))
(write-line text *error-output*)))
;; Keep count of number of hard errors.
(defparameter |$errorCount| 0)
(defun |errorCount| nil
|$errorCount|)
(defun |countError| nil
(setq |$errorCount| (1+ |$errorCount|)))
(defun |resetErrorCount| nil
(setq |$errorCount| 0))
;; utils
;; GCL has a hard limit on the number of arguments for concatenate.
;; However, it has a specialized versions for catenating string
;; that seems immune to that hard limit. Specialized accordingly.
(defun |catenateStrings| (&rest l)
#+ :gcl (apply #'si::string-concatenate l)
#- :gcl (apply #'concatenate 'string l))
(defun concat (a b &rest l)
(cond ((bit-vector-p a)
(apply #'concatenate 'bit-vector a b l))
(t
(apply #'|catenateStrings|
(string a)
(string b)
(mapcar #'string l)))))
(defun |fatalError| (msg)
(|countError|)
(|diagnosticMessage| "fatal error" msg)
(|coreQuit| 1))
(defun |internalError| (msg)
(|countError|)
(|diagnosticMessage| "internal error" msg)
(|coreQuit| 1))
(defun |coreError| (msg)
(|countError|)
(|diagnosticMessage| "error"
(cond ((consp msg)
(reduce #'(lambda (x y)
(concatenate 'string x y))
msg :initial-value ""))
(t msg)))
nil)
(defun |warn| (msg)
(|diagnosticMessage| "warning"
(cond ((consp msg)
(reduce #'(lambda (x y)
(concatenate 'string x y))
msg :initial-value ""))
(t msg))))
;;
;; -*- Command Line Arguments -*-
(defparameter |$sysOpts| nil)
(defparameter |$sysArgs| nil)
(defun |%systemOptions| ()
|$sysOpts|)
(defun |%systemArguments| ()
|$sysArgs|)
;;
;; Ideally, we would just like to have a traditional command line
;; passing mechanism from the shell to the application. That
;; mechanism works fine with GCL. Some Lisp implementations such as
;; SBCL or CLISP will insist on processing the command lines. Some
;; such as CLISP will baffle when they hit an option they don't
;; understand. Which is silly. It seems like the only common ground,
;; as ever, is to go with the most annoying behaviour and penalize
;; the good "citizen", sensible, Lisp implementations interfaces.
;; Consequently, we have standardized on the the following practice:
;; always issue a double bash (--) after the command line, and afterwards
;; supply options and other arguments. The double dash has the effect
;; of dissuading the underlying lisp implementation of trying to
;; process whatever comes after as options.
;; Command line arguments: equivalent of traditional `argv[]' from
;; systems programming world.
(defun |getCommandLineArguments| nil
#-(or :gcl :sbcl :clisp :ecl :clozure)
(|fatalError| "don't know how to get command line args")
(let* ((all-args
#+:clozure ccl:*command-line-argument-list*
#+:ecl (ext:command-args)
#+:gcl si::*command-args*
#+:sbcl sb-ext::*posix-argv*
#+:clisp (coerce (ext::argv) 'list))
(args (member "--" all-args :test #'equal)))
(cons (car all-args) (if args (cdr args) args))))
;;
;; -*- Building Standalone Executable -*-
;;
;; Build a standalone excutable from LISP-FILES -- a list of
;; pathnames designating compiled source files (either FASLs, for
;; most Lisp systems, or object files for systems like ECL.)
;; ENTRY-POINT is the entry point of the program. If not supplied, or
;; if null, then the entry entry is supposed to be the top level
;; read-eval-print loop of original Lisp system.
;; Note, despite the name LISP-FILEs, we do not expect bare Lisp source
;; files here. We do insist on FASLs. There is no check for that at
;; this point. You have been warned.
(defun |link| (core-image lisp-files
&optional (entry-point nil) (prologue nil))
(if (and entry-point (stringp entry-point))
(setq entry-point `(read-from-string ,entry-point)))
#-:ecl
(progn
(mapcar #'(lambda (p) (|loadOrElse| p)) lisp-files)
(eval prologue)
(|saveCore| core-image entry-point))
#+:ecl
(let* ((compiler::*ld* oa-cxx)
(compiler::*ld-flags* (concatenate 'string
compiler::*ld-flags*
" " oa-ldflags)))
(progn
(unless entry-point
(setq entry-point #'si::top-level))
(c:build-program core-image
:lisp-files
(complete-fasl-list-for-link lisp-files)
:ld-flags (extra-runtime-libs)
:epilogue-code
`(progn
(pushnew :open-axiom-base-lisp *features*)
,prologue
(funcall ,entry-point)))
(|coreQuit|))))
;;
;; -*- Handling Command Line Arguments -*-
;;
(defun |handleRequest| (prog-name request options args)
(let ((driver (|getDriver| request)))
(when (null driver)
(|fatalError| (format nil "invalid option `--~a'" (string request))))
(funcall driver prog-name options args)))
(defun |hasHandler?| (request)
(or (|getDriver| request)
(|useFileType?| request)))
(defun run-driver (prog-name action options args)
(cond ((|useFileType?| (car action))
;; If the action is file-type dependent, make sure
;; we have at least one file.
(unless (not (null args))
(|coreError| "missing input files"))
(dolist (f args t)
(let* ((name (car action))
(file-type (or (|getFileType| f)
(|useFileType?| name)))
(request (cons name file-type)))
(unless (|handleRequest| prog-name request options f)
(return nil)))))
(t (|handleRequest| prog-name (car action) options args))))
(defun |handleCommandLine| (prog-name options args)
(when (or options args)
(let (action)
(dolist (opt options)
(cond ((stringp (cdr opt))
;; In general, nothing is to be done for option value
;; specifications, except when they require special handlers.
(when (|hasHandler?| (car opt))
(unless (|handleRequest| prog-name (car opt) options args)
(return nil))))
;; Don't allow for more than one driver request.
((|hasHandler?| (car opt))
(if (not (null action))
(|coreError| "multiple driver request")
(setq action opt)))))
;; By now, we hope to have figured out what action to perform.
(cond ((consp action)
(run-driver prog-name action options args))
(t nil)))))
;;
;; -*- --help Handler -*-
;;
;; Print help screen
(defun |printUsage| (prog-name)
(write-line "usage:")
(write-line
(concatenate 'string prog-name " -- [options] [files]"))
(write-line "option:")
(write-line " --help print this message")
(write-line " --system= set to the root directory of running system")
(write-line " --sysalg= set to the algebra directory of running system")
(write-line " --compile compile file")
(write-line " --output= set output file to ")
(write-line " --load-directory= use as search path for modules")
(write-line " --make create an executable"))
(defun |helpHandler|(prog-name options args)
(declare (ignore options args))
(|printUsage| prog-name)
(|coreQuit|))
(|installDriver| (|Option| "help") #'|helpHandler|)
;;
;; -*- --make Handler -*-
;;
(defun |makeHandler| (prog-name options args)
(declare (ignore prog-name))
(unless (> (length args) 0)
(|fatalError| "--make requires at least one file"))
(|link| (or (|getOutputPathname| options) "a.out")
args
(|getMainEntryPoint| options)
(|getPrologue| options))
(|coreQuit|))
(|installDriver| (|Option| "make") #'|makeHandler|)
;;
;; -*- --load-directory Handler -*-
;;
;; Remember value specified for the --load-dircetory option. Notice
;; that this is the direct handler for that option. Consequently, it
;; passed all three arguments: PROG-NAME OPTIONS ARGS. Only the second
;; argument is of interest.
(defun |recordLoadDirectory| (prog-name options args)
(declare (ignore prog-name args)
(special |$LoadDirectories|))
(let ((load-option (assoc (|Option| "load-directory") options)))
(unless load-option
(|internalError| "`recordLoadDirectory' called without option"))
(unless (cdr load-option)
(|fatalError| "--load-directory option without value"))
(pushnew (cdr load-option) |$LoadDirectories| :test #'equal)
))
(|installDriver| (|Option| "load-directory") #'|recordLoadDirectory|)
;;
;; -*- --compile Handler for Lisp Source Files -*-
;;
(declaim (inline |compileFilePathname|))
(defun |compileFilePathname| (file)
#-:ecl (compile-file-pathname file)
#+:ecl (compile-file-pathname file :type :object))
(defun |currentDirectoryName| nil
(let* ((dir (namestring (truename "")))
(n (1- (length dir))))
(if (char= (char dir n) #\/)
(subseq dir 0 n)
dir)))
;; Compile Lisp source files to target object code. Most of the time
;; this function is called externally to accomplish just that: compile
;; a Lisp file. So, by default, we exit the read-eval-print loop after
;; the task is done.
;;
;; NOTE: The Lisp system ECL has an interesting compilation and program
;; build model. It distinguishes between FASL files (results of
;; compilation usable as operand to LOAD) and object files (result of
;; compilation usable to build standalone programs). We are primarily
;; interested in producing compiled files that can be used to produce
;; standalone programs. Consequently we must convince ECL to produce
;; object files. Notice that when program components require that
;; previously compiled files be loaded in the startup environment,
;; the system will load the FASL file. So, we end up with a 2-step
;; compilation process for ECL:
;; (1) compile as object code;
;; (2) build a FASL from the result of (1).
(defun |compileLispFile| (file out-file)
;; When OUT-FILE does not have a specified parent directory, it is
;; implied that the compiled file is placed in the current directory.
;; This is a very common convention on traditional systems and
;; environments. However GCL would insist to pick the parent
;; directory from FILE, which clearly is bogus.
;; Consequently, we must convince GCL to do what we expected.
#+gcl (when (and (pathname-directory file)
(not (pathname-directory out-file)))
(setq out-file
(make-pathname :name (pathname-name out-file)
:type (pathname-type out-file)
:directory (list (|currentDirectoryName|)))))
(unwind-protect
(progn
(|startCompileDuration|)
(multiple-value-bind (result warning-p failure-p)
#-:ecl (compile-file file :output-file out-file)
#+:ecl (if |$EnableLispProfiling|
(compile-file file :output-file out-file :system-p t
:c-file t :h-file t)
(compile-file file :output-file out-file :system-p t))
#+:ecl
(let ((compiler::*ld* oa-cxx))
(if (and result (not failure-p)
(null (c::build-fasl (compile-file-pathname out-file)
:lisp-files `(,out-file)
:ld-flags (extra-runtime-libs))))
(setq result nil)))
(cond ((null result)
(|coreError| "compilation of Lisp code failed"))
(failure-p
;; Since we believe the source code must
;; be fixed, we don't want to leave
;; the generated FASL behing us, as that
;; would confuse both users and tools.
(delete-file result)
(|coreError| "Lisp code contained errors"))
(warning-p
(|warn| "Lisp code contained warnings")))
result))
(|endCompileDuration|)))
(defun |compileLispHandler| (prog-name options in-file)
(declare (ignore prog-name))
(let ((out-file (|compileFilePathname| (or (|getOutputPathname| options)
in-file))))
(|compileLispFile| in-file out-file)))
(|associateRequestWithFileType| (|Option| "compile") |$LispFileType|
#'|compileLispHandler|)
;;
;; -*- Predefined System Entry Point -*-
;;
;; The top level entry point to most saved Lisp image.
(defun |topLevel|()
(let ((*package* (find-package "AxiomCore"))
(command-args (|getCommandLineArguments|)))
(when (null command-args)
(|internalError| "empty command line args"))
;; Existing system programming practive, and POSIX, have it
;; that the first argument on the command line is the name
;; of the current instantiation of the program.
;; We require at least two arguments:
;; (0) the program name
;; (1) either one of --help or --version, or
;; a filename.
(multiple-value-bind
(options args) (|processCommandLine| (cdr command-args) nil nil)
(setq |$sysOpts| options)
(setq |$sysArgs| args)
;; Run the system-specific initialization.
(when (fboundp '|%sysInit|)
(funcall (symbol-function '|%sysInit|)))
(when (|handleCommandLine| (car command-args) options args)
(|coreQuit| (if (> (|errorCount|) 0) 1 0))))))
;;
;; -*- Filesystem Utilities -*-
;;
;; Make sure that directory name DIR ends with a slash.
(defun |ensureTrailingSlash| (dir)
(let ((l (length dir)))
(unless (> l 0)
(|fatalError| "null directory name"))
(if (char= (char dir (- l 1)) #\/)
dir
(concatenate 'string dir "/"))))
;; Return the basename (without extension) of a file.
(defun |pathBasename| (file)
(pathname-name file))
;;
;; -*- Modules in OpenAxiom -*-
;;
;; List of directories to search for FASLs.
(defparameter |$LoadDirectories| nil)
;; List of FASLs imported
(defparameter |$ImportedModules| nil)
;; Return true if MODULE is known to have been imported or loaded.
(defun |getModuleInternalSymbol| (module)
(intern module (find-package "AxiomCore")))
(defun |alreadyLoaded?| (module)
(get (|getModuleInternalSymbol| (namestring module))
'|AxiomCore.loaded|))
;; Remember that MODULE was imported or loaded.
(defun |noteUnitLoaded| (module)
(setf (get (|getModuleInternalSymbol| (namestring module))
'|AxiomCore.loaded|) t))
;; We are searching for MODULE (currently a FASL) in DIRECTORY. So, this
;; function returns a (tentative) pathname designating that module.
(defun |loadPathname| (module dir)
(setq dir (|ensureTrailingSlash| dir))
(make-pathname :directory (pathname-directory dir)
:name module
#-:ecl :type #-:ecl |$faslType|))
(defun |btxPthaname| (module dir)
(setq dir (|ensureTrailingSlash| dir))
(make-pathname :directory (pathname-directory dir)
:name module
:type "btx"))
(defun |loadFileIfPresent| (file)
(load file :if-does-not-exist nil))
(defun |loadIfPresent| (module)
(if (|alreadyLoaded?| module)
module
(when (|loadFileIfPresent| module)
(|noteUnitLoaded| module)
module)))
(defun |loadOrElse| (module)
(if (|alreadyLoaded?| module)
module
(when (load module :if-does-not-exist :error)
(|noteUnitLoaded| module)
module)))
(defun import-module-if-present (module dir)
(or (|loadIfPresent| (|btxPthaname| module dir))
(|loadIfPresent| (|loadPathname| module dir))))
(defun do-import-module (module directories)
(cond ((null directories)
(|fatalError|
(format nil
"module ~S not found in search path ~S"
module
|$LoadDirectories|)))
(t
(unless (import-module-if-present module (car directories))
(do-import-module module (cdr directories))))))
(defun |importModule| (module)
(do-import-module module |$LoadDirectories|))
(defmacro import-module (module)
`(progn (eval-when
#+:common-lisp (:compile-toplevel :load-toplevel :execute)
#-:common-lisp (compile load eval)
(if (compile-time-p)
(|importModule| ,module)))))
(defmacro |bootImport| (module)
`(|importModule| ,module))
;;
;; -*- Feature Tests in Boot -*-
;;
(defun |%hasFeature| (f)
(member f *features* :test #'eq))
(defun |startCompileDuration| nil
(push :open-axiom-compile-time *features*))
(defun |endCompileDuration| nil
(delete :open-axiom-compile-time *features*))
(defun compile-time-p nil
(member :open-axiom-compile-time *features*))
;; -*- Lisp Implementatiom-dependent Supports -*-
#+(and :sbcl (not :win32))
(require "sb-posix")
#+ :sbcl
(defun shoe-provide-module(name)
(load name)
(provide name))
#+ :sbcl
(eval-when (:load-toplevel :execute)
(pushnew #'shoe-provide-module sb-ext:*module-provider-functions*))
;; Return true if `x' designates an identifier.
(defun |ident?| (x)
(and (symbolp x)
(not (null x))))
;;
;; -*-* Numerics support -*-
;;
(defmacro |fixnum?| (x)
`(typep ,x 'fixnum))
(defmacro |%fNaN?| (x)
#+:sbcl `(sb-ext:float-nan-p ,x)
#+:ecl `(ext:float-nan-p ,x)
#-(or :sbcl :ecl) `(/= ,x ,x))
;; convert an integer to double-float
(defmacro |double| (x)
`(float ,x 1.0d0))
;;
;; -*- Native Datatype correspondance -*-
;;
(defmacro |maxIndex| (x)
`(1- (length ,x)))
;; Datatype for buffers mostly used for transmitting data between
;; the Lisp world and Native World.
(deftype |%ByteArray| ()
'(simple-array (unsigned-byte 8)))
(declaim (ftype (function (fixnum) |%ByteArray|) |makeByteArray|))
(defun |makeByteArray| (n)
(make-array n
:element-type '(unsigned-byte 8)
:initial-element 0))
(defmacro |makeBitVector| (n)
`(make-array ,n :element-type 'bit :initial-element 0))
(defun |makeString| (n &optional (c (code-char 0)))
(make-string n :initial-element c))
(defun |listToString| (l)
(let ((s (|makeString| (list-length l))))
(do ((i 0 (1+ i)))
((null l))
(setf (schar s i) (car l))
(setq l (cdr l)))
s))
(defmacro |mkVector| (n)
`(make-array ,n :initial-element nil))
(defmacro |mkIntArray| (n)
`(make-array ,n :initial-element 0))
;; native data type translation table
(defconstant |$NativeTypeTable|
'((|void| . @void_type@)
(|char| . @char_type@)
(|int| . @int_type@)
(|float| . @float_type@)
(|double| . @double_type@)
(|string| . @string_type@)))