PrusaSlicer-NonPlainar/deps/Boost/common.jam

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2021-03-22 13:35:49 +00:00
# Copyright 2003, 2005 Dave Abrahams
# Copyright 2005, 2006 Rene Rivera
# Copyright 2005 Toon Knapen
# Copyright 2002, 2003, 2004, 2005, 2006 Vladimir Prus
# Distributed under the Boost Software License, Version 1.0.
# (See accompanying file LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)
# Provides actions common to all toolsets, such as creating directories and
# removing files.
import os ;
import modules ;
import utility ;
import print ;
import type ;
import feature ;
import errors ;
import path ;
import sequence ;
import toolset ;
import virtual-target ;
import numbers ;
if [ MATCH (--debug-configuration) : [ modules.peek : ARGV ] ]
{
.debug-configuration = true ;
}
if [ MATCH (--show-configuration) : [ modules.peek : ARGV ] ]
{
.show-configuration = true ;
}
# Configurations
#
# The following class helps to manage toolset configurations. Each configuration
# has a unique ID and one or more parameters. A typical example of a unique ID
# is a condition generated by 'common.check-init-parameters' rule. Other kinds
# of IDs can be used. Parameters may include any details about the configuration
# like 'command', 'path', etc.
#
# A toolset configuration may be in one of the following states:
#
# - registered
# Configuration has been registered (e.g. explicitly or by auto-detection
# code) but has not yet been marked as used, i.e. 'toolset.using' rule has
# not yet been called for it.
# - used
# Once called 'toolset.using' rule marks the configuration as 'used'.
#
# The main difference between the states above is that while a configuration is
# 'registered' its options can be freely changed. This is useful in particular
# for autodetection code - all detected configurations may be safely overwritten
# by user code.
class configurations
{
import errors ;
rule __init__ ( )
{
}
# Registers a configuration.
#
# Returns 'true' if the configuration has been added and an empty value if
# it already exists. Reports an error if the configuration is 'used'.
#
rule register ( id )
{
if $(id) in $(self.used)
{
errors.error "common: the configuration '$(id)' is in use" ;
}
local retval ;
if ! $(id) in $(self.all)
{
self.all += $(id) ;
# Indicate that a new configuration has been added.
retval = true ;
}
return $(retval) ;
}
# Mark a configuration as 'used'.
#
# Returns 'true' if the state of the configuration has been changed to
# 'used' and an empty value if it the state has not been changed. Reports an
# error if the configuration is not known.
#
rule use ( id )
{
if ! $(id) in $(self.all)
{
errors.error "common: the configuration '$(id)' is not known" ;
}
local retval ;
if ! $(id) in $(self.used)
{
self.used += $(id) ;
# Indicate that the configuration has been marked as 'used'.
retval = true ;
}
return $(retval) ;
}
# Return all registered configurations.
#
rule all ( )
{
return $(self.all) ;
}
# Return all used configurations.
#
rule used ( )
{
return $(self.used) ;
}
# Returns the value of a configuration parameter.
#
rule get ( id : param )
{
return $(self.$(param).$(id)) ;
}
# Sets the value of a configuration parameter.
#
rule set ( id : param : value * )
{
self.$(param).$(id) = $(value) ;
}
}
# The rule for checking toolset parameters. Trailing parameters should all be
# parameter name/value pairs. The rule will check that each parameter either has
# a value in each invocation or has no value in each invocation. Also, the rule
# will check that the combination of all parameter values is unique in all
# invocations.
#
# Each parameter name corresponds to a subfeature. This rule will declare a
# subfeature the first time a non-empty parameter value is passed and will
# extend it with all the values.
#
# The return value from this rule is a condition to be used for flags settings.
#
rule check-init-parameters ( toolset requirement * : * )
{
local sig = $(toolset) ;
local condition = <toolset>$(toolset) ;
local subcondition ;
for local index in 2 3 4 5 6 7 8 9
{
local name = $($(index)[1]) ;
local value = $($(index)[2]) ;
if $(value)-is-not-empty
{
condition = $(condition)-$(value) ;
if $(.had-unspecified-value.$(toolset).$(name))
{
errors.user-error
"$(toolset) initialization: parameter '$(name)'"
"inconsistent" : "no value was specified in earlier"
"initialization" : "an explicit value is specified now" ;
}
# The below logic is for intel compiler. It calls this rule with
# 'intel-linux' and 'intel-win' as toolset, so we need to get the
# base part of toolset name. We can not pass 'intel' as toolset
# because in that case it will be impossible to register versionless
# intel-linux and intel-win toolsets of a specific version.
local t = $(toolset) ;
local m = [ MATCH "([^-]*)-" : $(toolset) ] ;
if $(m)
{
t = $(m[1]) ;
}
if ! $(.had-value.$(toolset).$(name))
{
if ! $(.declared-subfeature.$(t).$(name))
{
feature.subfeature toolset $(t) : $(name) : : propagated ;
.declared-subfeature.$(t).$(name) = true ;
}
.had-value.$(toolset).$(name) = true ;
}
feature.extend-subfeature toolset $(t) : $(name) : $(value) ;
subcondition += <toolset-$(t):$(name)>$(value) ;
}
else
{
if $(.had-value.$(toolset).$(name))
{
errors.user-error
"$(toolset) initialization: parameter '$(name)'"
"inconsistent" : "an explicit value was specified in an"
"earlier initialization" : "no value is specified now" ;
}
.had-unspecified-value.$(toolset).$(name) = true ;
}
sig = $(sig)$(value:E="")- ;
}
# We also need to consider requirements on the toolset as we can
# configure the same toolset multiple times with different options that
# are selected with the requirements.
if $(requirement)
{
sig = $(sig)$(requirement:J=,) ;
}
if $(sig) in $(.all-signatures)
{
local message =
"duplicate initialization of $(toolset) with the following parameters: " ;
for local index in 2 3 4 5 6 7 8 9
{
local p = $($(index)) ;
if $(p)
{
message += "$(p[1]) = $(p[2]:E=<unspecified>)" ;
}
}
message += "previous initialization at $(.init-loc.$(sig))" ;
errors.user-error
$(message[1]) : $(message[2]) : $(message[3]) : $(message[4]) :
$(message[5]) : $(message[6]) : $(message[7]) : $(message[8]) ;
}
.all-signatures += $(sig) ;
.init-loc.$(sig) = [ errors.nearest-user-location ] ;
# If we have a requirement, this version should only be applied under that
# condition. To accomplish this we add a toolset requirement that imposes
# the toolset subcondition, which encodes the version.
if $(requirement)
{
local r = <toolset>$(toolset) $(requirement) ;
r = $(r:J=,) ;
toolset.add-requirements "$(r):$(subcondition)" ;
}
# We add the requirements, if any, to the condition to scope the toolset
# variables and options to this specific version.
condition += $(requirement) ;
if $(.show-configuration)
{
ECHO "notice:" $(condition) ;
}
return $(condition:J=/) ;
}
# A helper rule to get the command to invoke some tool. If
# 'user-provided-command' is not given, tries to find binary named 'tool' in
# PATH and in the passed 'additional-path'. Otherwise, verifies that the first
# element of 'user-provided-command' is an existing program.
#
# This rule returns the command to be used when invoking the tool. If we can not
# find the tool, a warning is issued. If 'path-last' is specified, PATH is
# checked after 'additional-paths' when searching for 'tool'.
#
rule get-invocation-command-nodefault ( toolset : tool :
user-provided-command * : additional-paths * : path-last ? )
{
local command ;
if ! $(user-provided-command)
{
command = [ find-tool $(tool) : $(additional-paths) : $(path-last) ] ;
if ! $(command) && $(.debug-configuration)
{
ECHO "warning:" toolset $(toolset) "initialization:" can not find tool
$(tool) ;
ECHO "warning:" initialized from [ errors.nearest-user-location ] ;
}
}
else
{
command = [ check-tool $(user-provided-command) ] ;
if ! $(command) && $(.debug-configuration)
{
ECHO "warning:" toolset $(toolset) "initialization:" ;
ECHO "warning:" can not find user-provided command
'$(user-provided-command)' ;
ECHO "warning:" initialized from [ errors.nearest-user-location ] ;
}
}
return $(command) ;
}
# Same as get-invocation-command-nodefault, except that if no tool is found,
# returns either the user-provided-command, if present, or the 'tool' parameter.
#
rule get-invocation-command ( toolset : tool : user-provided-command * :
additional-paths * : path-last ? )
{
local result = [ get-invocation-command-nodefault $(toolset) : $(tool) :
$(user-provided-command) : $(additional-paths) : $(path-last) ] ;
if ! $(result)
{
if $(user-provided-command)
{
result = $(user-provided-command) ;
}
else
{
result = $(tool) ;
}
}
return $(result) ;
}
# Given an invocation command return the absolute path to the command. This
# works even if command has no path element and was found on the PATH.
#
rule get-absolute-tool-path ( command )
{
if $(command:D)
{
return $(command:D) ;
}
else
{
local m = [ GLOB [ modules.peek : PATH Path path ] : $(command)
$(command).exe ] ;
return $(m[1]:D) ;
}
}
# Attempts to find tool (binary) named 'name' in PATH and in 'additional-paths'.
# If found in PATH, returns 'name' and if found in additional paths, returns
# absolute name. If the tool is found in several directories, returns the first
# path found. Otherwise, returns an empty string. If 'path-last' is specified,
# PATH is searched after 'additional-paths'.
#
rule find-tool ( name : additional-paths * : path-last ? )
{
if $(name:D)
{
return [ check-tool-aux $(name) ] ;
}
local path = [ path.programs-path ] ;
local match = [ path.glob $(path) : $(name) $(name).exe ] ;
local additional-match = [ path.glob $(additional-paths) : $(name)
$(name).exe ] ;
local result ;
if $(path-last)
{
result = $(additional-match) ;
if ! $(result) && $(match)
{
result = $(name) ;
}
}
else
{
if $(match)
{
result = $(name) ;
}
else
{
result = $(additional-match) ;
}
}
if $(result)
{
return [ path.native $(result[1]) ] ;
}
}
# Checks if 'command' can be found either in path or is a full name to an
# existing file.
#
local rule check-tool-aux ( command )
{
if $(command:D)
{
if [ path.exists $(command) ]
# Both NT and Cygwin will run .exe files by their unqualified names.
|| ( [ os.on-windows ] && [ path.exists $(command).exe ] )
# Only NT will run .bat & .cmd files by their unqualified names.
|| ( ( [ os.name ] = NT ) && ( [ path.exists $(command).bat ] ||
[ path.exists $(command).cmd ] ) )
{
return $(command) ;
}
}
else
{
if [ GLOB [ modules.peek : PATH Path path ] : $(command) ]
{
return $(command) ;
}
}
}
# Checks that a tool can be invoked by 'command'. If command is not an absolute
# path, checks if it can be found in 'path'. If command is an absolute path,
# check that it exists. Returns 'command' if ok or empty string otherwise.
#
local rule check-tool ( xcommand + )
{
if [ check-tool-aux $(xcommand[1]) ] ||
[ check-tool-aux $(xcommand[-1]) ]
{
return $(xcommand) ;
}
}
# Handle common options for toolset, specifically sets the following flag
# variables:
# - CONFIG_COMMAND to $(command)
# - OPTIONS for compile to the value of <compileflags> in $(options)
# - OPTIONS for compile.c to the value of <cflags> in $(options)
# - OPTIONS for compile.c++ to the value of <cxxflags> in $(options)
# - OPTIONS for compile.asm to the value of <asmflags> in $(options)
# - OPTIONS for compile.fortran to the value of <fflags> in $(options)
# - OPTIONS for link to the value of <linkflags> in $(options)
#
rule handle-options ( toolset : condition * : command * : options * )
{
if $(.debug-configuration)
{
ECHO "notice:" will use '$(command)' for $(toolset), condition
$(condition:E=(empty)) ;
}
# The last parameter ('unchecked') says it is OK to set flags for another
# module.
toolset.flags $(toolset) CONFIG_COMMAND $(condition) : $(command)
: unchecked ;
toolset.flags $(toolset).compile OPTIONS $(condition) :
[ feature.get-values <compileflags> : $(options) ] : unchecked ;
toolset.flags $(toolset).compile.c OPTIONS $(condition) :
[ feature.get-values <cflags> : $(options) ] : unchecked ;
toolset.flags $(toolset).compile.c++ OPTIONS $(condition) :
[ feature.get-values <cxxflags> : $(options) ] : unchecked ;
toolset.flags $(toolset).compile.asm OPTIONS $(condition) :
[ feature.get-values <asmflags> : $(options) ] : unchecked ;
toolset.flags $(toolset).compile.fortran OPTIONS $(condition) :
[ feature.get-values <fflags> : $(options) ] : unchecked ;
toolset.flags $(toolset).link OPTIONS $(condition) :
[ feature.get-values <linkflags> : $(options) ] : unchecked ;
}
# Returns the location of the "program files" directory on a Windows platform.
#
rule get-program-files-dir ( )
{
local ProgramFiles = [ modules.peek : ProgramFiles ] ;
if $(ProgramFiles)
{
ProgramFiles = "$(ProgramFiles:J= )" ;
}
else
{
ProgramFiles = "c:\\Program Files" ;
}
return $(ProgramFiles) ;
}
if [ os.name ] = NT
{
NULL_DEVICE = "NUL" ;
IGNORE = "2>$(NULL_DEVICE) >$(NULL_DEVICE) & setlocal" ;
RM = del /f /q ;
CP = copy /b ;
LN ?= $(CP) ;
# Ugly hack to convince copy to set the timestamp of the destination to the
# current time by concatenating the source with a nonexistent file. Note
# that this requires /b (binary) as the default when concatenating files is
# /a (ascii).
WINDOWS-CP-HACK = "+ this-file-does-not-exist-A698EE7806899E69" ;
}
else if [ os.name ] = VMS
{
NULL_DEVICE = "NL:" ;
PIPE = PIPE ;
IGNORE = "2>$(NULL_DEVICE) >$(NULL_DEVICE)" ;
RM = DELETE /NOCONF ;
CP = COPY /OVERWRITE ;
LN = $(CP) ;
}
else
{
NULL_DEVICE = "/dev/null" ;
IGNORE = "2>$(NULL_DEVICE) >$(NULL_DEVICE)" ;
RM = rm -f ;
CP = cp ;
LN = ln ;
}
NULL_OUT = ">$(NULL_DEVICE)" ;
rule null-device ( )
{
return $(NULL_DEVICE) ;
}
rule rm-command ( )
{
return $(RM) ;
}
rule copy-command ( )
{
return $(CP) ;
}
if "\n" = "n"
{
# Escape characters not supported so use ugly hacks. Will not work on Cygwin
# - see below.
nl = "
" ;
q = "" ;
}
else
{
nl = "\n" ;
q = "\"" ;
}
rule newline-char ( )
{
return $(nl) ;
}
# Returns the command needed to set an environment variable on the current
# platform. The variable setting persists through all following commands and is
# visible in the environment seen by subsequently executed commands. In other
# words, on Unix systems, the variable is exported, which is consistent with the
# only possible behavior on Windows systems.
#
rule variable-setting-command ( variable : value )
{
if [ os.name ] = NT
{
return "set $(variable)=$(value)$(nl)" ;
}
else if [ os.name ] = VMS
{
return "$(variable) == $(q)$(value)$(q)$(nl)" ;
}
else
{
# If we do not have escape character support in bjam, the cod below
# blows up on CYGWIN, since the $(nl) variable holds a Windows new-line
# \r\n sequence that messes up the executed export command which then
# reports that the passed variable name is incorrect.
# But we have a check for cygwin in kernel/bootstrap.jam already.
return "$(variable)=$(q)$(value)$(q)$(nl)export $(variable)$(nl)" ;
}
}
# Returns a command to sets a named shell path variable to the given NATIVE
# paths on the current platform.
#
rule path-variable-setting-command ( variable : paths * )
{
local sep = [ os.path-separator ] ;
return [ variable-setting-command $(variable) : $(paths:J=$(sep)) ] ;
}
# Returns a command that prepends the given paths to the named path variable on
# the current platform.
#
rule prepend-path-variable-command ( variable : paths * )
{
return [ path-variable-setting-command $(variable)
: $(paths) [ os.expand-variable $(variable) ] ] ;
}
# Return a command which can create a file. If 'r' is result of invocation, then
# 'r foobar' will create foobar with unspecified content. What happens if file
# already exists is unspecified.
#
rule file-creation-command ( )
{
if [ os.name ] = NT
{
# A few alternative implementations on Windows:
#
# 'type NUL >> '
# That would construct an empty file instead of a file containing
# a space and an end-of-line marker but it would also not change
# the target's timestamp in case the file already exists.
#
# 'type NUL > '
# That would construct an empty file instead of a file containing
# a space and an end-of-line marker but it would also destroy an
# already existing file by overwriting it with an empty one.
#
# I guess the best solution would be to allow Boost Jam to define
# built-in functions such as 'create a file', 'touch a file' or 'copy a
# file' which could be used from inside action code. That would allow
# completely portable operations without this kind of kludge.
# (22.02.2009.) (Jurko)
return "echo. > " ;
}
else if [ os.name ] = VMS
{
return "APPEND /NEW NL: " ;
}
else
{
return "touch " ;
}
}
# Returns a command that may be used for 'touching' files. It is not a real
# 'touch' command on NT because it adds an empty line at the end of file but it
# works with source files.
#
rule file-touch-command ( )
{
if [ os.name ] = NT
{
return "echo. >> " ;
}
else if [ os.name ] = VMS
{
return "APPEND /NEW NL: " ;
}
else
{
return "touch " ;
}
}
rule MkDir
{
# If dir exists, do not update it. Do this even for $(DOT).
NOUPDATE $(<) ;
if $(<) != $(DOT) && ! $($(<)-mkdir)
{
# Cheesy gate to prevent multiple invocations on same dir.
$(<)-mkdir = true ;
# Schedule the mkdir build action.
common.mkdir $(<) ;
# Prepare a Jam 'dirs' target that can be used to make the build only
# construct all the target directories.
DEPENDS dirs : $(<) ;
# Recursively create parent directories. $(<:P) = $(<)'s parent & we
# recurse until root.
local s = $(<:P) ;
if [ os.name ] = NT
{
switch $(s)
{
case "*:" : s = ;
case "*:\\" : s = ;
}
}
if $(s)
{
if $(s) != $(<)
{
DEPENDS $(<) : $(s) ;
MkDir $(s) ;
}
else
{
NOTFILE $(s) ;
}
}
}
}
#actions MkDir1
#{
# mkdir "$(<)"
#}
# The following quick-fix actions should be replaced using the original MkDir1
# action once Boost Jam gets updated to correctly detect different paths leading
# up to the same filesystem target and triggers their build action only once.
# (todo) (04.07.2008.) (Jurko)
if [ os.name ] = NT
{
actions quietly mkdir
{
if not exist "$(<)\\" mkdir "$(<)"
}
}
else
{
actions quietly mkdir
{
mkdir -p "$(<)"
}
}
actions piecemeal together existing Clean
{
$(RM) "$(>)"
}
rule copy
{
}
actions copy
{
$(CP) "$(>)" $(WINDOWS-CP-HACK) "$(<)"
}
rule RmTemps
{
}
actions quietly updated piecemeal together RmTemps
{
$(RM) "$(>)" $(IGNORE)
}
actions hard-link
{
$(RM) "$(<)" 2$(NULL_OUT) $(NULL_OUT)
$(LN) "$(>)" "$(<)" $(NULL_OUT)
}
if [ os.name ] = VMS
{
actions mkdir
{
IF F$PARSE("$(<:W)") .EQS. "" THEN CREATE /DIR $(<:W)
}
actions piecemeal together existing Clean
{
$(RM) $(>:WJ=;*,);*
}
actions copy
{
$(CP) $(>:WJ=,) $(<:W)
}
actions quietly updated piecemeal together RmTemps
{
$(PIPE) $(RM) $(>:WJ=;*,);* $(IGNORE)
}
actions hard-link
{
$(PIPE) $(RM) $(>[1]:W);* $(IGNORE)
$(PIPE) $(LN) $(>[1]:W) $(<:W) $(NULL_OUT)
}
}
# Given a target, as given to a custom tag rule, returns a string formatted
# according to the passed format. Format is a list of properties that is
# represented in the result. For each element of format the corresponding target
# information is obtained and added to the result string. For all, but the
# literal, the format value is taken as the as string to prepend to the output
# to join the item to the rest of the result. If not given "-" is used as a
# joiner.
#
# The format options can be:
#
# <base>[joiner]
# :: The basename of the target name.
# <toolset>[joiner]
# :: The abbreviated toolset tag being used to build the target.
# <threading>[joiner]
# :: Indication of a multi-threaded build.
# <runtime>[joiner]
# :: Collective tag of the build runtime.
# <version:/version-feature | X.Y[.Z]/>[joiner]
# :: Short version tag taken from the given "version-feature" in the
# build properties. Or if not present, the literal value as the
# version number.
# <property:/property-name/>[joiner]
# :: Direct lookup of the given property-name value in the build
# properties. /property-name/ is a regular expression. E.g.
# <property:toolset-.*:flavor> will match every toolset.
# /otherwise/
# :: The literal value of the format argument.
#
# For example this format:
#
# boost_ <base> <toolset> <threading> <runtime> <version:boost-version>
#
# Might return:
#
# boost_thread-vc80-mt-gd-1_33.dll, or
# boost_regex-vc80-gd-1_33.dll
#
# The returned name also has the target type specific prefix and suffix which
# puts it in a ready form to use as the value from a custom tag rule.
#
rule format-name ( format * : name : type ? : property-set )
{
local result = "" ;
for local f in $(format)
{
switch $(f:G)
{
case <base> :
result += $(name:B) ;
case <toolset> :
result += [ join-tag $(f:G=) : [ toolset-tag $(name) : $(type) :
$(property-set) ] ] ;
case <threading> :
result += [ join-tag $(f:G=) : [ threading-tag $(name) : $(type)
: $(property-set) ] ] ;
case <runtime> :
result += [ join-tag $(f:G=) : [ runtime-tag $(name) : $(type) :
$(property-set) ] ] ;
case <qt> :
result += [ join-tag $(f:G=) : [ qt-tag $(name) : $(type) :
$(property-set) ] ] ;
case <address-model> :
result += [ join-tag $(f:G=) : [ address-model-tag $(name) :
$(type) : $(property-set) ] ] ;
case <arch-and-model> :
result += [ join-tag $(f:G=) : [ arch-and-model-tag $(name) :
$(type) : $(property-set) ] ] ;
case <version:*> :
local key = [ MATCH <version:(.*)> : $(f:G) ] ;
local version = [ $(property-set).get <$(key)> ] ;
version ?= $(key) ;
version = [ MATCH "^([^.]+)[.]([^.]+)[.]?([^.]*)" : $(version) ] ;
result += [ join-tag $(f:G=) : $(version[1])_$(version[2]) ] ;
case <property:*> :
local key = [ MATCH <property:(.*)> : $(f:G) ] ;
local p0 = [ MATCH <($(key))> : [ $(property-set).raw ] ] ;
if $(p0)
{
local p = [ $(property-set).get <$(p0)> ] ;
if $(p)
{
result += [ join-tag $(f:G=) : $(p) ] ;
}
}
case * :
result += $(f:G=) ;
}
}
return [ virtual-target.add-prefix-and-suffix $(result:J=) : $(type) :
$(property-set) ] ;
}
local rule join-tag ( joiner ? : tag ? )
{
if ! $(joiner) { joiner = - ; }
return $(joiner)$(tag) ;
}
local rule toolset-tag ( name : type ? : property-set )
{
local tag = ;
local properties = [ $(property-set).raw ] ;
switch [ $(property-set).get <toolset> ]
{
case borland* : tag += bcb ;
case clang* :
{
switch [ $(property-set).get <toolset-clang:platform> ]
{
case darwin : tag += clang-darwin ;
case linux : tag += clang ;
case win : tag += clangw ;
}
}
case como* : tag += como ;
case cw : tag += cw ;
case darwin* : tag += xgcc ;
case edg* : tag += edg ;
case gcc* :
{
switch [ $(property-set).get <target-os> ]
{
case *windows* : tag += mgw ;
case * : tag += gcc ;
}
}
case intel :
if [ $(property-set).get <toolset-intel:platform> ] = win
{
tag += iw ;
}
else
{
tag += il ;
}
case kcc* : tag += kcc ;
case kylix* : tag += bck ;
#case metrowerks* : tag += cw ;
#case mingw* : tag += mgw ;
case mipspro* : tag += mp ;
case msvc* : tag += vc ;
case qcc* : tag += qcc ;
case sun* : tag += sw ;
case tru64cxx* : tag += tru ;
case vacpp* : tag += xlc ;
}
local version = [ MATCH "<toolset.*version>([0123456789]+)[.]?([0123456789]*)"
: $(properties) ] ;
# For historical reasons, vc6.0 and vc7.0 use different naming.
if $(tag) = vc
{
if $(version[1]) = 6
{
# Cancel minor version.
version = 6 ;
}
else if $(version[1]) = 7 && $(version[2]) = 0
{
version = 7 ;
}
}
# From GCC 5, versioning changes and minor becomes patch
if ( $(tag) = gcc || $(tag) = mgw ) && [ numbers.less 4 $(version[1]) ]
{
version = $(version[1]) ;
}
# Ditto, from Clang 4
if ( $(tag) = clang || $(tag) = clangw ) && [ numbers.less 3 $(version[1]) ]
{
version = $(version[1]) ;
}
# On intel, version is not added, because it does not matter and it is the
# version of vc used as backend that matters. Ideally, we should encode the
# backend version but that would break compatibility with V1.
if $(tag) = iw
{
version = ;
}
# On borland, version is not added for compatibility with V1.
if $(tag) = bcb
{
version = ;
}
tag += $(version) ;
return $(tag:J=) ;
}
local rule threading-tag ( name : type ? : property-set )
{
if <threading>multi in [ $(property-set).raw ]
{
return mt ;
}
}
local rule runtime-tag ( name : type ? : property-set )
{
local tag = ;
local properties = [ $(property-set).raw ] ;
if <runtime-link>static in $(properties) { tag += s ; }
# This is an ugly thing. In V1, there is code to automatically detect which
# properties affect a target. So, if <runtime-debugging> does not affect gcc
# toolset, the tag rules will not even see <runtime-debugging>. Similar
# functionality in V2 is not implemented yet, so we just check for toolsets
# known to care about runtime debugging.
if ( <toolset>msvc in $(properties) ) ||
( <stdlib>stlport in $(properties) ) ||
( <toolset-intel:platform>win in $(properties) )
{
if <runtime-debugging>on in $(properties) { tag += g ; }
}
if <python-debugging>on in $(properties) { tag += y ; }
if <variant>debug in $(properties) { tag += d ; }
if <stdlib>stlport in $(properties) { tag += p ; }
if <stdlib-stlport:iostream>hostios in $(properties) { tag += n ; }
return $(tag:J=) ;
}
# Create a tag for the Qt library version
# "<qt>4.6.0" will result in tag "qt460"
local rule qt-tag ( name : type ? : property-set )
{
local v = [ MATCH "([0123456789]+)[.]?([0123456789]*)[.]?([0123456789]*)" :
[ $(property-set).get <qt> ] ] ;
return qt$(v:J=) ;
}
# Create a tag for the address-model
# <address-model>64 will simply generate "64"
local rule address-model-tag ( name : type ? : property-set )
{
return [ $(property-set).get <address-model> ] ;
}
# Create a tag for the architecture and model
# <architecture>x86 <address-model>32 would generate "x32"
# This relies on the fact that all architectures start with
# unique letters.
local rule arch-and-model-tag ( name : type ? : property-set )
{
local architecture = [ $(property-set).get <architecture> ] ;
local address-model = [ $(property-set).get <address-model> ] ;
local arch = [ MATCH ^(.) : $(architecture) ] ;
return $(arch)$(address-model) ;
}
rule __test__ ( )
{
import assert ;
local save-os = [ modules.peek os : .name ] ;
modules.poke os : .name : LINUX ;
assert.result "PATH=\"foo:bar:baz\"\nexport PATH\n"
: path-variable-setting-command PATH : foo bar baz ;
assert.result "PATH=\"foo:bar:$PATH\"\nexport PATH\n"
: prepend-path-variable-command PATH : foo bar ;
modules.poke os : .name : NT ;
assert.result "set PATH=foo;bar;baz\n"
: path-variable-setting-command PATH : foo bar baz ;
assert.result "set PATH=foo;bar;%PATH%\n"
: prepend-path-variable-command PATH : foo bar ;
modules.poke os : .name : $(save-os) ;
}