######################################################################## # 2024 September 25 # # The author disclaims copyright to this source code. In place of # a legal notice, here is a blessing: # # * May you do good and not evil. # * May you find forgiveness for yourself and forgive others. # * May you share freely, never taking more than you give. # ######################################################################## # Routines for Steve Bennett's autosetup which are common to trees # managed in and around the umbrella of the SQLite project. # # This file was initially derived from one used in the libfossil # project, authored by the same person who ported it here, and this is # noted here only as an indication that there are no licensing issues # despite this code having a handful of near-twins running around a # handful of third-party source trees. # ######################################################################## # # Design notes: # # - Symbols with a suffix of _ are intended for internal use within # this file, and are not part of the API which auto.def files should # rely on. # # - By and large, autosetup prefers to update global state with the # results of feature checks, e.g. whether the compiler supports flag # --X. In this developer's opinion that (A) causes more confusion # than it solves[^1] and (B) adds an unnecessary layer of "voodoo" # between the autosetup user and its internals. This module, in # contrast, instead injects the results of its own tests into # well-defined variables and leaves the integration of those values # to the caller's discretion. # # [1]: As an example: testing for the -rpath flag, using # cc-check-flags, can break later checks which use # [cc-check-function-in-lib ...] because the resulting -rpath flag # implicitly becomes part of those tests. In the case of an rpath # test, downstream tests may not like the $prefix/lib path added by # the rpath test. To avoid such problems, we avoid (intentionally) # updating global state via feature tests. ######################################################################## ######################################################################## # $proj_ is an internal-use-only array for storing whatever generic # internal stuff we need stored. array set proj_ {} set proj_(isatty) [isatty? stdout] proc proj-warn {msg} { puts stderr [proj-bold "WARNING: $msg"] } proc proj-fatal {msg} { show-notices puts stderr [proj-bold "ERROR: $msg"] exit 1 } ######################################################################## # Kind of like a C assert if uplevel (eval) of $script is false, # triggers a fatal error. proc proj-assert {script} { if {1 == [get-env proj-assert 0]} { msg-result [proj-bold "asserting: [string trim $script]"] } if {![uplevel 1 $script]} { proj-fatal "Assertion failed: $script" } } ######################################################################## # If this function believes that the current console might support # ANSI escape sequences then this returns $str wrapped in a sequence # to bold that text, else it returns $str as-is. proc proj-bold {str} { if {$::autosetup(iswin) || !$::proj_(isatty)} { return $str } return "\033\[1m${str}\033\[0m" } ######################################################################## # Takes a multi-line message and emits it with consistent indentation # using [user-notice] (which means its rendering will (A) go to stderr # and (B) be delayed until the next time autosetup goes to output a # message). # # If its first argument is -error then it renders the message # immediately and then exits. proc proj-indented-notice {args} { set fErr "" if {"-error" eq [lindex $args 0]} { set args [lassign $args fErr] } set lines [split [join $args] \n] foreach line $lines { user-notice " [string trimleft $line]" } if {"" ne $fErr} { show-notices exit 1 } } ######################################################################## # Returns 1 if cross-compiling, else 0. proc proj-is-cross-compiling {} { return [expr {[get-define host] ne [get-define build]}] } ######################################################################## # proj-lshift_ shifts $count elements from the list named $listVar # and returns them as a new list. On empty input, returns "". # # Modified slightly from: https://wiki.tcl-lang.org/page/lshift proc proj-lshift_ {listVar {count 1}} { upvar 1 $listVar l if {![info exists l]} { # make the error message show the real variable name error "can't read \"$listVar\": no such variable" } if {![llength $l]} { # error Empty return "" } set r [lrange $l 0 [incr count -1]] set l [lreplace $l [set l 0] $count] return $r } ######################################################################## # Expects to receive string input, which it splits on newlines, strips # out any lines which begin with an number of whitespace followed by a # '#', and returns a value containing the [append]ed results of each # remaining line with a \n between each. proc proj-strip-hash-comments_ {val} { set x {} foreach line [split $val \n] { if {![string match "#*" [string trimleft $line]]} { append x $line \n } } return $x } ######################################################################## # A proxy for cc-check-function-in-lib which "undoes" any changes that # routine makes to the LIBS define. Returns the result of # cc-check-function-in-lib. proc proj-check-function-in-lib {function libs {otherlibs {}}} { set found 0 define-push {LIBS} { set found [cc-check-function-in-lib $function $libs $otherlibs] } return $found } ######################################################################## # Searches for $header in a combination of dirs and subdirs, specified # by the -dirs {LIST} and -subdirs {LIST} flags (each of which have # sane defaults). Returns either the first matching dir or an empty # string. The return value does not contain the filename part. proc proj-search-for-header-dir {header args} { set subdirs {include} set dirs {/usr /usr/local /mingw} # Debatable: # if {![proj-is-cross-compiling]} { # lappend dirs [get-define prefix] # } while {[llength $args]} { switch -exact -- [lindex $args 0] { -dirs { set args [lassign $args - dirs] } -subdirs { set args [lassign $args - subdirs] } default { proj-fatal "Unhandled argument: $args" } } } foreach dir $dirs { foreach sub $subdirs { if {[file exists $dir/$sub/$header]} { return "$dir/$sub" } } } return "" } ######################################################################## # Usage: proj-find-executable-path ?-v? binaryName # # Works similarly to autosetup's [find-executable-path $binName] but: # # - If the first arg is -v, it's verbose about searching, else it's quiet. # # Returns the full path to the result or an empty string. proc proj-find-executable-path {args} { set binName $args set verbose 0 if {[lindex $args 0] eq "-v"} { set verbose 1 set args [lassign $args - binName] msg-checking "Looking for $binName ... " } set check [find-executable-path $binName] if {$verbose} { if {"" eq $check} { msg-result "not found" } else { msg-result $check } } return $check } ######################################################################## # Uses [proj-find-executable-path $binName] to (verbosely) search for # a binary, sets a define (see below) to the result, and returns the # result (an empty string if not found). # # The define'd name is: if defName is empty then "BIN_X" is used, # where X is the upper-case form of $binName with any '-' characters # replaced with '_'. proc proj-bin-define {binName {defName {}}} { set check [proj-find-executable-path -v $binName] if {"" eq $defName} { set defName "BIN_[string toupper [string map {- _} $binName]]" } define $defName $check return $check } ######################################################################## # Usage: proj-first-bin-of bin... # # Looks for the first binary found of the names passed to this # function. If a match is found, the full path to that binary is # returned, else "" is returned. # # Despite using cc-path-progs to do the search, this function clears # any define'd name that function stores for the result (because the # caller has no sensible way of knowing which result it was unless # they pass only a single argument). proc proj-first-bin-of {args} { set rc "" foreach b $args { set u [string toupper $b] # Note that cc-path-progs defines $u to false if it finds no match. if {[cc-path-progs $b]} { set rc [get-define $u] } undefine $u if {"" ne $rc} break } return $rc } ######################################################################## # Returns 1 if the user specifically provided the given configure # flag, else 0. This can be used to distinguish between options which # have a default value and those which were explicitly provided by the # user, even if the latter is done in a way which uses the default # value. # # For example, with a configure flag defined like: # # { foo-bar:=baz => {its help text} } # # This function will, when passed foo-bar, return 1 only if the user # passes --foo-bar to configure, even if that invocation would resolve # to the default value of baz. If the user does not explicitly pass in # --foo-bar (with or without a value) then this returns 0. proc proj-opt-was-provided {key} { dict exists $::autosetup(optset) $key } ######################################################################## # Force-set autosetup option $flag to $val. The value can be fetched # later with [opt-val], [opt-bool], and friends. # # Returns $val. proc proj-opt-set {flag {val 1}} { global autosetup if {$flag ni $::autosetup(options)} { # We have to add this to autosetup(options) or else future calls # to [opt-bool $flag] will fail validation of $flag. lappend ::autosetup(options) $flag } dict set ::autosetup(optset) $flag $val return $val } ######################################################################## # Returns 1 if $val appears to be a truthy value, else returns # 0. Truthy values are any of {1 on enabled yes} proc proj-val-truthy {val} { expr {$val in {1 on enabled yes}} } ######################################################################## # Returns 1 if [opt-val $flag] appears to be a truthy value or # [opt-bool $flag] is true. See proj-val-truthy. proc proj-opt-truthy {flag} { if {[proj-val-truthy [opt-val $flag]]} { return 1 } set rc 0 catch { # opt-bool will throw if $flag is not a known boolean flag set rc [opt-bool $flag] } return $rc } ######################################################################## # If [proj-opt-truthy $flag] is true, eval $then, else eval $else. proc proj-if-opt-truthy {boolFlag thenScript {elseScript {}}} { if {[proj-opt-truthy $boolFlag]} { uplevel 1 $thenScript } else { uplevel 1 $elseScript } } ######################################################################## # If [proj-opt-truthy $flag] then [define $def $iftrue] else [define # $def $iffalse]. If $msg is not empty, output [msg-checking $msg] and # a [msg-results ...] which corresponds to the result. Returns 1 if # the opt-truthy check passes, else 0. proc proj-define-if-opt-truthy {flag def {msg ""} {iftrue 1} {iffalse 0}} { if {"" ne $msg} { msg-checking "$msg " } set rcMsg "" set rc 0 if {[proj-opt-truthy $flag]} { define $def $iftrue set rc 1 } else { define $def $iffalse } switch -- [proj-val-truthy [get-define $def]] { 0 { set rcMsg no } 1 { set rcMsg yes } } if {"" ne $msg} { msg-result $rcMsg } return $rc } ######################################################################## # Args: [-v] optName defName {descr {}} # # Checks [proj-opt-truthy $optName] and calls [define $defName X] # where X is 0 for false and 1 for true. descr is an optional # [msg-checking] argument which defaults to $defName. Returns X. # # If args[0] is -v then the boolean semantics are inverted: if # the option is set, it gets define'd to 0, else 1. Returns the # define'd value. proc proj-opt-define-bool {args} { set invert 0 if {[lindex $args 0] eq "-v"} { set invert 1 set args [lrange $args 1 end] } set optName [proj-lshift_ args] set defName [proj-lshift_ args] set descr [proj-lshift_ args] if {"" eq $descr} { set descr $defName } set rc 0 msg-checking "$descr ... " if {[proj-opt-truthy $optName]} { if {0 eq $invert} { set rc 1 } else { set rc 0 } } elseif {0 ne $invert} { set rc 1 } msg-result $rc define $defName $rc return $rc } ######################################################################## # Check for module-loading APIs (libdl/libltdl)... # # Looks for libltdl or dlopen(), the latter either in -ldl or built in # to libc (as it is on some platforms). Returns 1 if found, else # 0. Either way, it `define`'s: # # - HAVE_LIBLTDL to 1 or 0 if libltdl is found/not found # - HAVE_LIBDL to 1 or 0 if dlopen() is found/not found # - LDFLAGS_MODULE_LOADER one of ("-lltdl", "-ldl", or ""), noting # that -ldl may legally be empty on some platforms even if # HAVE_LIBDL is true (indicating that dlopen() is available without # extra link flags). LDFLAGS_MODULE_LOADER also gets "-rdynamic" appended # to it because otherwise trying to open DLLs will result in undefined # symbol errors. # # Note that if it finds LIBLTDL it does not look for LIBDL, so will # report only that is has LIBLTDL. proc proj-check-module-loader {} { msg-checking "Looking for module-loader APIs... " if {99 ne [get-define LDFLAGS_MODULE_LOADER 99]} { if {1 eq [get-define HAVE_LIBLTDL 0]} { msg-result "(cached) libltdl" return 1 } elseif {1 eq [get-define HAVE_LIBDL 0]} { msg-result "(cached) libdl" return 1 } # else: wha??? } set HAVE_LIBLTDL 0 set HAVE_LIBDL 0 set LDFLAGS_MODULE_LOADER "" set rc 0 puts "" ;# cosmetic kludge for cc-check-XXX if {[cc-check-includes ltdl.h] && [cc-check-function-in-lib lt_dlopen ltdl]} { set HAVE_LIBLTDL 1 set LDFLAGS_MODULE_LOADER "-lltdl -rdynamic" msg-result " - Got libltdl." set rc 1 } elseif {[cc-with {-includes dlfcn.h} { cctest -link 1 -declare "extern char* dlerror(void);" -code "dlerror();"}]} { msg-result " - This system can use dlopen() without -ldl." set HAVE_LIBDL 1 set LDFLAGS_MODULE_LOADER "" set rc 1 } elseif {[cc-check-includes dlfcn.h]} { set HAVE_LIBDL 1 set rc 1 if {[cc-check-function-in-lib dlopen dl]} { msg-result " - dlopen() needs libdl." set LDFLAGS_MODULE_LOADER "-ldl -rdynamic" } else { msg-result " - dlopen() not found in libdl. Assuming dlopen() is built-in." set LDFLAGS_MODULE_LOADER "-rdynamic" } } define HAVE_LIBLTDL $HAVE_LIBLTDL define HAVE_LIBDL $HAVE_LIBDL define LDFLAGS_MODULE_LOADER $LDFLAGS_MODULE_LOADER return $rc } ######################################################################## # Sets all flags which would be set by proj-check-module-loader to # empty/falsy values, as if those checks had failed to find a module # loader. Intended to be called in place of that function when # a module loader is explicitly not desired. proc proj-no-check-module-loader {} { define HAVE_LIBDL 0 define HAVE_LIBLTDL 0 define LDFLAGS_MODULE_LOADER "" } ######################################################################## # Opens the given file, reads all of its content, and returns it. proc proj-file-content {fname} { set fp [open $fname r] set rc [read $fp] close $fp return $rc } ######################################################################## # Returns the contents of the given file as an array of lines, with # the EOL stripped from each input line. proc proj-file-content-list {fname} { set fp [open $fname r] set rc {} while { [gets $fp line] >= 0 } { lappend rc $line } return $rc } ######################################################################## # Checks the compiler for compile_commands.json support. If passed an # argument it is assumed to be the name of an autosetup boolean config # which controls whether to run/skip this check. # # Returns 1 if supported, else 0. Defines MAKE_COMPILATION_DB to "yes" # if supported, "no" if not. # # This test has a long history of false positive results because of # compilers reacting differently to the -MJ flag. proc proj-check-compile-commands {{configOpt {}}} { msg-checking "compile_commands.json support... " if {"" ne $configOpt && ![proj-opt-truthy $configOpt]} { msg-result "explicitly disabled" define MAKE_COMPILATION_DB no return 0 } else { if {[cctest -lang c -cflags {/dev/null -MJ} -source {}]} { # This test reportedly incorrectly succeeds on one of # Martin G.'s older systems. drh also reports a false # positive on an unspecified older Mac system. msg-result "compiler supports compile_commands.json" define MAKE_COMPILATION_DB yes return 1 } else { msg-result "compiler does not support compile_commands.json" define MAKE_COMPILATION_DB no return 0 } } } ######################################################################## # Runs the 'touch' command on one or more files, ignoring any errors. proc proj-touch {filename} { catch { exec touch {*}$filename } } ######################################################################## # Usage: # # proj-make-from-dot-in ?-touch? filename(s)... # # Uses [make-template] to create makefile(-like) file(s) $filename # from $filename.in but explicitly makes the output read-only, to # avoid inadvertent editing (who, me?). # # If the first argument is -touch then the generated file is touched # to update its timestamp. This can be used as a workaround for # cases where (A) autosetup does not update the file because it was # not really modified and (B) the file *really* needs to be updated to # please the build process. # # Failures when running chmod or touch are silently ignored. proc proj-make-from-dot-in {args} { set filename $args set touch 0 if {[lindex $args 0] eq "-touch"} { set touch 1 set filename [lrange $args 1 end] } foreach f $filename { set f [string trim $f] catch { exec chmod u+w $f } make-template $f.in $f if {$touch} { proj-touch $f } catch { exec chmod -w $f } } } ######################################################################## # Checks for the boolean configure option named by $flagname. If set, # it checks if $CC seems to refer to gcc. If it does (or appears to) # then it defines CC_PROFILE_FLAG to "-pg" and returns 1, else it # defines CC_PROFILE_FLAG to "" and returns 0. # # Note that the resulting flag must be added to both CFLAGS and # LDFLAGS in order for binaries to be able to generate "gmon.out". In # order to avoid potential problems with escaping, space-containing # tokens, and interfering with autosetup's use of these vars, this # routine does not directly modify CFLAGS or LDFLAGS. proc proj-check-profile-flag {{flagname profile}} { #puts "flagname=$flagname ?[proj-opt-truthy $flagname]?" if {[proj-opt-truthy $flagname]} { set CC [get-define CC] regsub {.*ccache *} $CC "" CC # ^^^ if CC="ccache gcc" then [exec] treats "ccache gcc" as a # single binary name and fails. So strip any leading ccache part # for this purpose. if { ![catch { exec $CC --version } msg]} { if {[string first gcc $CC] != -1} { define CC_PROFILE_FLAG "-pg" return 1 } } } define CC_PROFILE_FLAG "" return 0 } ######################################################################## # Returns 1 if this appears to be a Windows environment (MinGw, # Cygwin, MSys), else returns 0. The optional argument is the name of # an autosetup define which contains platform name info, defaulting to # "host" (meaning, somewhat counterintuitively, the target system, not # the current host). The other legal value is "build" (the build # machine, i.e. the local host). If $key == "build" then some # additional checks may be performed which are not applicable when # $key == "host". proc proj-looks-like-windows {{key host}} { global autosetup switch -glob -- [get-define $key] { *-*-ming* - *-*-cygwin - *-*-msys { return 1 } } if {$key eq "build"} { # These apply only to the local OS, not a cross-compilation target, # as the above check potentially can. if {$::autosetup(iswin)} { return 1 } if {[find-an-executable cygpath] ne "" || $::tcl_platform(os)=="Windows NT"} { return 1 } } return 0 } ######################################################################## # Looks at either the 'host' (==compilation target platform) or # 'build' (==the being-built-on platform) define value and returns if # if that value seems to indicate that it represents a Mac platform, # else returns 0. # # TODO: have someone verify whether this is correct for the # non-Linux/BSD platforms. proc proj-looks-like-mac {{key host}} { switch -glob -- [get-define $key] { *apple* { return 1 } default { return 0 } } } ######################################################################## # Checks autosetup's "host" and "build" defines to see if the build # host and target are Windows-esque (Cygwin, MinGW, MSys). If the # build environment is then BUILD_EXEEXT is [define]'d to ".exe", else # "". If the target, a.k.a. "host", is then TARGET_EXEEXT is # [define]'d to ".exe", else "". proc proj-exe-extension {} { set rH "" set rB "" if {[proj-looks-like-windows host]} { set rH ".exe" } if {[proj-looks-like-windows build]} { set rB ".exe" } define BUILD_EXEEXT $rB define TARGET_EXEEXT $rH } ######################################################################## # Works like proj-exe-extension except that it defines BUILD_DLLEXT # and TARGET_DLLEXT to one of (.so, ,dll, .dylib). # # Trivia: for .dylib files, the linker needs the -dynamiclib flag # instead of -shared. # # TODO: have someone verify whether this is correct for the # non-Linux/BSD platforms. proc proj-dll-extension {} { proc inner {key} { switch -glob -- [get-define $key] { *apple* { return ".dylib" } *-*-ming* - *-*-cygwin - *-*-msys { return ".dll" } default { return ".so" } } } define BUILD_DLLEXT [inner build] define TARGET_DLLEXT [inner host] } ######################################################################## # Static-library counterpart of proj-dll-extension. Defines # BUILD_LIBEXT and TARGET_LIBEXT to the conventional static library # extension for the being-built-on resp. the target platform. proc proj-lib-extension {} { proc inner {key} { switch -glob -- [get-define $key] { *-*-ming* - *-*-cygwin - *-*-msys { return ".lib" } default { return ".a" } } } define BUILD_LIBEXT [inner build] define TARGET_LIBEXT [inner host] } ######################################################################## # Calls all of the proj-*-extension functions. proc proj-file-extensions {} { proj-exe-extension proj-dll-extension proj-lib-extension } ######################################################################## # Expects a list of file names. If any one of them does not exist in # the filesystem, it fails fatally with an informative message. # Returns the last file name it checks. If the first argument is -v # then it emits msg-checking/msg-result messages for each file. proc proj-affirm-files-exist {args} { set rc "" set verbose 0 if {[lindex $args 0] eq "-v"} { set verbose 1 set args [lrange $args 1 end] } foreach f $args { if {$verbose} { msg-checking "Looking for $f ... " } if {![file exists $f]} { user-error "not found: $f" } if {$verbose} { msg-result "" } set rc $f } return rc } ######################################################################## # Emscripten is used for doing in-tree builds of web-based WASM stuff, # as opposed to WASI-based WASM or WASM binaries we import from other # places. This is only set up for Unix-style OSes and is untested # anywhere but Linux. # # Defines the following: # # - EMSDK_HOME = top dir of the emsdk or "". It looks for # --with-emsdk=DIR or the $EMSDK environment variable. # - EMSDK_ENV = path to EMSDK_HOME/emsdk_env.sh or "" # - BIN_EMCC = $EMSDK_HOME/upstream/emscripten/emcc or "" # - HAVE_EMSDK = 0 or 1 (this function's return value) # # Returns 1 if EMSDK_ENV is found, else 0. If EMSDK_HOME is not empty # but BIN_EMCC is then emcc was not found in the EMSDK_HOME, in which # case we have to rely on the fact that sourcing $EMSDK_ENV from a # shell will add emcc to the $PATH. proc proj-check-emsdk {} { set emsdkHome [opt-val with-emsdk] define EMSDK_HOME "" define EMSDK_ENV "" define BIN_EMCC "" msg-checking "Emscripten SDK? " if {$emsdkHome eq ""} { # Fall back to checking the environment. $EMSDK gets set by # sourcing emsdk_env.sh. set emsdkHome [get-env EMSDK ""] } set rc 0 if {$emsdkHome ne ""} { define EMSDK_HOME $emsdkHome set emsdkEnv "$emsdkHome/emsdk_env.sh" if {[file exists $emsdkEnv]} { msg-result "$emsdkHome" define EMSDK_ENV $emsdkEnv set rc 1 set emcc "$emsdkHome/upstream/emscripten/emcc" if {[file exists $emcc]} { define BIN_EMCC $emcc } } else { msg-result "emsdk_env.sh not found in $emsdkHome" } } else { msg-result "not found" } define HAVE_EMSDK $rc return $rc } ######################################################################## # Tries various approaches to handling the -rpath link-time # flag. Defines LDFLAGS_RPATH to that/those flag(s) or an empty # string. Returns 1 if it finds an option, else 0. # # Achtung: we have seen platforms which report that a given option # checked here will work but then fails at build-time, and the current # order of checks reflects that. proc proj-check-rpath {} { set rc 1 set lp "[get-define prefix]/lib" # If we _don't_ use cc-with {} here (to avoid updating the global # CFLAGS or LIBS or whatever it is that cc-check-flags updates) then # downstream tests may fail because the resulting rpath gets # implicitly injected into them. cc-with {} { if {[cc-check-flags "-rpath $lp"]} { define LDFLAGS_RPATH "-rpath $lp" } elseif {[cc-check-flags "-Wl,-rpath,$lp"]} { define LDFLAGS_RPATH "-Wl,-rpath,$lp" } elseif {[cc-check-flags "-Wl,-rpath -Wl,$lp"]} { define LDFLAGS_RPATH "-Wl,-rpath -Wl,$lp" } elseif {[cc-check-flags -Wl,-R$lp]} { define LDFLAGS_RPATH "-Wl,-R$lp" } else { define LDFLAGS_RPATH "" set rc 0 } } return $rc } ######################################################################## # Internal helper for proj-dump-defs-json. Expects to be passed a # [define] name and the variadic $args which are passed to # proj-dump-defs-json. If it finds a pattern match for the given # $name in the various $args, it returns the type flag for that $name, # e.g. "-str" or "-bare", else returns an empty string. proc proj-defs-type_ {name spec} { foreach {type patterns} $spec { foreach pattern $patterns { if {[string match $pattern $name]} { return $type } } } return "" } ######################################################################## # Internal helper for proj-defs-format_: returns a JSON-ish quoted # form of the given (JSON) string-type values. proc proj-quote-str_ {value} { return \"[string map [list \\ \\\\ \" \\\"] $value]\" } ######################################################################## # An internal impl detail of proj-dump-defs-json. Requires a data # type specifier, as used by make-config-header, and a value. Returns # the formatted value or the value $::proj_(defs-skip) if the caller # should skip emitting that value. set proj_(defs-skip) "-proj-defs-format_ sentinel" proc proj-defs-format_ {type value} { switch -exact -- $type { -bare { # Just output the value unchanged } -none { set value $::proj_(defs-skip) } -str { set value [proj-quote-str_ $value] } -auto { # Automatically determine the type if {![string is integer -strict $value]} { set value [proj-quote-str_ $value] } } -array { set ar {} foreach v $value { set v [proj-defs-format_ -auto $v] if {$::proj_(defs-skip) ne $v} { lappend ar $v } } set value "\[ [join $ar {, }] \]" } "" { set value $::proj_(defs-skip) } default { proj-fatal "Unknown type in proj-dump-defs-json: $type" } } return $value } ######################################################################## # This function works almost identically to autosetup's # make-config-header but emits its output in JSON form. It is not a # fully-functional JSON emitter, and will emit broken JSON for # complicated outputs, but should be sufficient for purposes of # emitting most configure vars (numbers and simple strings). # # In addition to the formatting flags supported by make-config-header, # it also supports: # # -array {patterns...} # # Any defines matching the given patterns will be treated as a list of # values, each of which will be formatted as if it were in an -auto {...} # set, and the define will be emitted to JSON in the form: # # "ITS_NAME": [ "value1", ...valueN ] # # Achtung: if a given -array pattern contains values which themselves # contains spaces... # # define-append foo {"-DFOO=bar baz" -DBAR="baz barre"} # # will lead to: # # ["-DFOO=bar baz", "-DBAR=\"baz", "barre\""] # # Neither is especially satisfactory (and the second is useless), and # handling of such values is subject to change if any such values ever # _really_ need to be processed by our source trees. proc proj-dump-defs-json {file args} { file mkdir [file dirname $file] set lines {} lappend args -bare {SIZEOF_* HAVE_DECL_*} -auto HAVE_* foreach n [lsort [dict keys [all-defines]]] { set type [proj-defs-type_ $n $args] set value [proj-defs-format_ $type [get-define $n]] if {$::proj_(defs-skip) ne $value} { lappend lines "\"$n\": ${value}" } } set buf {} lappend buf [join $lines ",\n"] write-if-changed $file $buf { msg-result "Created $file" } } ######################################################################## # Expects a list of pairs of configure flags with the given names to # have been registered with autosetup, in this form: # # { alias1 => canonical1 # aliasN => canonicalN ... } # # The names must not have their leading -- part and must be in the # form which autosetup will expect for passing to [opt-val NAME] and # friends. # # Commend lines are permitted in the input. # # If [opt-val $hidden] has a value but [opt-val # $canonical] does not, it copies the former over the latter. If # $hidden has no value set, this is a no-op. If both have explicit # values a fatal usage error is triggered. # # Motivation: autosetup enables "hidden aliases" in [options] lists, # and elides the aliases from --help output but does no further # handling of them. For example, when --alias is a hidden alias of # --canonical and a user passes --alias=X, [opt-val canonical] returns # no value. i.e. the script must check both [opt-val alias] and # [opt-val canonical]. The intent here is that this function be # passed such mappings immediately after [options] is called, # to carry over any values from hidden aliases into their canonical # names, so that in the above example [opt-value canonical] will # return X if --alias=X is passed in. proc proj-xfer-options-aliases {mapping} { foreach {hidden - canonical} [proj-strip-hash-comments_ $mapping] { if {[proj-opt-was-provided $hidden]} { if {[proj-opt-was-provided $canonical]} { proj-fatal "both --$canonical and its alias --$hidden were used. Use only one or the other." } else { proj-opt-set $canonical [opt-val $hidden] } } } } ######################################################################## # Arguable/debatable... # # When _not_ cross-compiling and CC_FOR_BUILD is _not_ explcitely # specified, force CC_FOR_BUILD to be the same as CC, so that: # # ./configure CC=clang # # will use CC_FOR_BUILD=clang, instead of cc, for building in-tree # tools. This is based off of an email discussion and is thought to # be likely to cause less confusion than seeing 'cc' invocations # will when the user passes CC=clang. # # Sidebar: if we do this before the cc package is installed, it gets # reverted by that package. Ergo, the cc package init will tell the # user "Build C compiler...cc" shortly before we tell them: proc proj-redefine-cc-for-build {} { if {![proj-is-cross-compiling] && "nope" eq [get-env CC_FOR_BUILD "nope"] && [get-define CC] ne [get-define CC_FOR_BUILD]} { user-notice "Re-defining CC_FOR_BUILD to CC=[get-define CC]. To avoid this, explicitly pass CC_FOR_BUILD=..." define CC_FOR_BUILD [get-define CC] } }