freebsd-dev/Makefile.inc1

3397 lines
114 KiB
Makefile
Raw Normal View History

#
1999-08-28 01:35:59 +00:00
# $FreeBSD$
#
# Make command line options:
# -DNO_CLEANDIR run ${MAKE} clean, instead of ${MAKE} cleandir
# -DNO_CLEAN do not clean at all
# -DDB_FROM_SRC use the user/group databases in src/etc instead of
# the system database when installing.
2004-12-21 12:13:23 +00:00
# -DNO_SHARE do not go into share subdir
# -DKERNFAST define NO_KERNEL{CONFIG,CLEAN,OBJ}
# -DNO_KERNELCONFIG do not run config in ${MAKE} buildkernel
# -DNO_KERNELCLEAN do not run ${MAKE} clean in ${MAKE} buildkernel
# -DNO_KERNELOBJ do not run ${MAKE} obj in ${MAKE} buildkernel
# -DNO_PORTSUPDATE do not update ports in ${MAKE} update
# -DNO_ROOT install without using root privilege
# -DNO_DOCUPDATE do not update doc in ${MAKE} update
# -DWITHOUT_CTF do not run the DTrace CTF conversion tools on built objects
# LOCAL_DIRS="list of dirs" to add additional dirs to the SUBDIR list
# LOCAL_ITOOLS="list of tools" to add additional tools to the ITOOLS list
# LOCAL_LIB_DIRS="list of dirs" to add additional dirs to libraries target
# LOCAL_MTREE="list of mtree files" to process to allow local directories
# to be created before files are installed
# LOCAL_TOOL_DIRS="list of dirs" to add additional dirs to the build-tools
# list
# LOCAL_XTOOL_DIRS="list of dirs" to add additional dirs to the
# cross-tools target
# METALOG="path to metadata log" to write permission and ownership
# when NO_ROOT is set. (default: ${DESTDIR}/METALOG)
# TARGET="machine" to crossbuild world for a different machine type
2010-04-14 18:56:07 +00:00
# TARGET_ARCH= may be required when a TARGET supports multiple endians
# BUILDENV_SHELL= shell to launch for the buildenv target (def:${SHELL})
# WORLD_FLAGS= additional flags to pass to make(1) during buildworld
# KERNEL_FLAGS= additional flags to pass to make(1) during buildkernel
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
# SUBDIR_OVERRIDE="list of dirs" to build rather than everything.
# All libraries and includes, and some build tools will still build.
#
# The intended user-driven targets are:
# buildworld - rebuild *everything*, including glue to help do upgrades
# installworld- install everything built by "buildworld"
# checkworld - run test suite on installed world
# doxygen - build API documentation of the kernel
# update - convenient way to update your source tree (eg: svn/svnup)
#
# Standard targets (not defined here) are documented in the makefiles in
# /usr/share/mk. These include:
# obj depend all install clean cleandepend cleanobj
.if !defined(TARGET) || !defined(TARGET_ARCH)
.error "Both TARGET and TARGET_ARCH must be defined."
.endif
.if make(showconfig) || make(test-system-*)
_MKSHOWCONFIG= t
.endif
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
SRCDIR?= ${.CURDIR}
LOCALBASE?= /usr/local
2008-09-19 16:14:42 +00:00
# Cross toolchain changes must be in effect before bsd.compiler.mk
# so that gets the right CC, and pass CROSS_TOOLCHAIN to submakes.
.if defined(CROSS_TOOLCHAIN)
.if exists(${LOCALBASE}/share/toolchains/${CROSS_TOOLCHAIN}.mk)
.include "${LOCALBASE}/share/toolchains/${CROSS_TOOLCHAIN}.mk"
.elif exists(${CROSS_TOOLCHAIN})
.include "${CROSS_TOOLCHAIN}"
.else
.error CROSS_TOOLCHAIN ${CROSS_TOOLCHAIN} not found
.endif
CROSSENV+=CROSS_TOOLCHAIN="${CROSS_TOOLCHAIN}"
.endif
.if defined(CROSS_TOOLCHAIN_PREFIX)
CROSS_COMPILER_PREFIX?=${CROSS_TOOLCHAIN_PREFIX}
.endif
XCOMPILERS= CC CXX CPP
.for COMPILER in ${XCOMPILERS}
.if defined(CROSS_COMPILER_PREFIX)
X${COMPILER}?= ${CROSS_COMPILER_PREFIX}${${COMPILER}}
.else
X${COMPILER}?= ${${COMPILER}}
.endif
.endfor
# If a full path to an external cross compiler is given, don't build
# a cross compiler.
.if ${XCC:N${CCACHE_BIN}:M/*}
MK_CLANG_BOOTSTRAP= no
MK_GCC_BOOTSTRAP= no
.endif
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
# Pull in compiler metadata from buildworld/toolchain if possible to avoid
# running CC from bsd.compiler.mk.
.if make(installworld) || make(install) || make(distributeworld) || \
make(stageworld)
.-include "${OBJTOP}/toolchain-metadata.mk"
.if !defined(_LOADED_TOOLCHAIN_METADATA)
.error A build is required first. You may have the wrong MAKEOBJDIRPREFIX set.
.endif
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
.endif
# Pull in COMPILER_TYPE and COMPILER_FREEBSD_VERSION early. Pull it from the
# tree to be friendlier to foreign OS builds. It's safe to do so unconditionally
# here since we will always have the right make, unlike in src/Makefile
# Don't include bsd.linker.mk yet until XBINUTILS is handled (after src.opts.mk)
_NO_INCLUDE_LINKERMK= t
# We also want the X_COMPILER* variables if we are using an external toolchain.
_WANT_TOOLCHAIN_CROSS_VARS= t
.include "share/mk/bsd.compiler.mk"
.undef _NO_INCLUDE_LINKERMK
.undef _WANT_TOOLCHAIN_CROSS_VARS
# src.opts.mk depends on COMPILER_FEATURES
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.include "share/mk/src.opts.mk"
.if ${TARGET} == ${MACHINE}
TARGET_CPUTYPE?=${CPUTYPE}
.else
TARGET_CPUTYPE?=
.endif
.if !empty(TARGET_CPUTYPE)
_TARGET_CPUTYPE=${TARGET_CPUTYPE}
.else
_TARGET_CPUTYPE=dummy
.endif
.if ${TARGET} == "arm"
.if ${TARGET_ARCH:Marmv[67]*} != "" && ${TARGET_CPUTYPE:M*soft*} == ""
TARGET_ABI= gnueabihf
.else
TARGET_ABI= gnueabi
.endif
.endif
MACHINE_ABI?= unknown
MACHINE_TRIPLE?=${MACHINE_ARCH:S/amd64/x86_64/:C/hf$//:S/mipsn32/mips64/}-${MACHINE_ABI}-freebsd13.0
TARGET_ABI?= unknown
TARGET_TRIPLE?= ${TARGET_ARCH:S/amd64/x86_64/:C/hf$//:S/mipsn32/mips64/}-${TARGET_ABI}-freebsd13.0
KNOWN_ARCHES?= aarch64/arm64 \
amd64 \
arm \
armv6/arm \
armv7/arm \
i386 \
mips \
mipsel/mips \
mips64el/mips \
mipsn32el/mips \
mips64/mips \
mipsn32/mips \
mipshf/mips \
mipselhf/mips \
mips64elhf/mips \
mips64hf/mips \
powerpc \
powerpc64/powerpc \
powerpcspe/powerpc \
riscv64/riscv \
riscv64sf/riscv \
sparc64
.if ${TARGET} == ${TARGET_ARCH}
_t= ${TARGET}
.else
_t= ${TARGET_ARCH}/${TARGET}
.endif
.for _t in ${_t}
.if empty(KNOWN_ARCHES:M${_t})
.error Unknown target ${TARGET_ARCH}:${TARGET}.
.endif
.endfor
# If all targets are disabled for system llvm then don't expect it to work
# for cross-builds.
.if !defined(TOOLS_PREFIX) && ${MK_LLVM_TARGET_ALL} == "no" && \
${MACHINE} != ${TARGET} && ${MACHINE_ARCH} != ${TARGET_ARCH} && \
!make(showconfig)
MK_SYSTEM_COMPILER= no
MK_SYSTEM_LINKER= no
.endif
# Handle external binutils.
.if defined(CROSS_TOOLCHAIN_PREFIX)
CROSS_BINUTILS_PREFIX?=${CROSS_TOOLCHAIN_PREFIX}
.endif
# If we do not have a bootstrap binutils (because the in-tree one does not
# support the target architecture), provide a default cross-binutils prefix.
# This allows riscv64 builds, for example, to automatically use the
# riscv64-binutils port or package.
.if !make(showconfig) && !defined(_NO_INCLUDE_COMPILERMK)
.if !empty(BROKEN_OPTIONS:MBINUTILS_BOOTSTRAP) && \
${MK_LLD_BOOTSTRAP} == "no" && \
!defined(CROSS_BINUTILS_PREFIX)
CROSS_BINUTILS_PREFIX=/usr/local/${TARGET_TRIPLE}/bin/
.if !exists(${CROSS_BINUTILS_PREFIX})
.error In-tree binutils does not support the ${TARGET_ARCH} architecture. Install the ${TARGET_ARCH}-binutils port or package or set CROSS_BINUTILS_PREFIX.
.endif
.endif
.endif
XBINUTILS= AS AR LD NM OBJCOPY RANLIB SIZE STRINGS
.for BINUTIL in ${XBINUTILS}
.if defined(CROSS_BINUTILS_PREFIX) && \
exists(${CROSS_BINUTILS_PREFIX}/${${BINUTIL}})
X${BINUTIL}?= ${CROSS_BINUTILS_PREFIX:C,/*$,,}/${${BINUTIL}}
.else
X${BINUTIL}?= ${${BINUTIL}}
.endif
.endfor
# If a full path to an external linker is given, don't build lld.
.if ${XLD:M/*}
MK_LLD_BOOTSTRAP= no
.endif
# We also want the X_LINKER* variables if we are using an external toolchain.
_WANT_TOOLCHAIN_CROSS_VARS= t
.include "share/mk/bsd.linker.mk"
.undef _WANT_TOOLCHAIN_CROSS_VARS
# Begin WITH_SYSTEM_COMPILER / WITH_SYSTEM_LD
# WITH_SYSTEM_COMPILER - Pull in needed values and make a decision.
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
# Check if there is a local compiler that can satisfy as an external compiler.
# Which compiler is expected to be used?
.if ${MK_CLANG_BOOTSTRAP} == "yes"
WANT_COMPILER_TYPE= clang
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.elif ${MK_GCC_BOOTSTRAP} == "yes"
WANT_COMPILER_TYPE= gcc
.else
WANT_COMPILER_TYPE=
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.endif
.if !defined(WANT_COMPILER_FREEBSD_VERSION) && !make(showconfig) && \
!make(test-system-linker)
.if ${WANT_COMPILER_TYPE} == "clang"
WANT_COMPILER_FREEBSD_VERSION_FILE= lib/clang/freebsd_cc_version.h
WANT_COMPILER_FREEBSD_VERSION!= \
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
awk '$$2 == "FREEBSD_CC_VERSION" {printf("%d\n", $$3)}' \
${SRCDIR}/${WANT_COMPILER_FREEBSD_VERSION_FILE} || echo unknown
WANT_COMPILER_VERSION_FILE= lib/clang/include/clang/Basic/Version.inc
WANT_COMPILER_VERSION!= \
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
awk '$$2 == "CLANG_VERSION" {split($$3, a, "."); print a[1] * 10000 + a[2] * 100 + a[3]}' \
${SRCDIR}/${WANT_COMPILER_VERSION_FILE} || echo unknown
.elif ${WANT_COMPILER_TYPE} == "gcc"
WANT_COMPILER_FREEBSD_VERSION_FILE= gnu/usr.bin/cc/cc_tools/freebsd-native.h
WANT_COMPILER_FREEBSD_VERSION!= \
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
awk '$$2 == "FBSD_CC_VER" {printf("%d\n", $$3)}' \
${SRCDIR}/${WANT_COMPILER_FREEBSD_VERSION_FILE} || echo unknown
WANT_COMPILER_VERSION_FILE= contrib/gcc/BASE-VER
WANT_COMPILER_VERSION!= \
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
awk -F. '{print $$1 * 10000 + $$2 * 100 + $$3}' \
${SRCDIR}/${WANT_COMPILER_VERSION_FILE} || echo unknown
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.endif
.export WANT_COMPILER_FREEBSD_VERSION WANT_COMPILER_VERSION
.endif # !defined(WANT_COMPILER_FREEBSD_VERSION)
# It needs to be the same revision as we would build for the bootstrap.
# If the expected vs CC is different then we can't skip.
# GCC cannot be used for cross-arch yet. For clang we pass -target later if
# TARGET_ARCH!=MACHINE_ARCH.
.if ${MK_SYSTEM_COMPILER} == "yes" && \
defined(WANT_COMPILER_FREEBSD_VERSION) && \
(${MK_CLANG_BOOTSTRAP} == "yes" || ${MK_GCC_BOOTSTRAP} == "yes") && \
!make(xdev*) && \
${X_COMPILER_TYPE} == ${WANT_COMPILER_TYPE} && \
(${X_COMPILER_TYPE} == "clang" || ${TARGET_ARCH} == ${MACHINE_ARCH}) && \
${X_COMPILER_VERSION} == ${WANT_COMPILER_VERSION} && \
${X_COMPILER_FREEBSD_VERSION} == ${WANT_COMPILER_FREEBSD_VERSION}
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
# Everything matches, disable the bootstrap compiler.
MK_CLANG_BOOTSTRAP= no
MK_GCC_BOOTSTRAP= no
USING_SYSTEM_COMPILER= yes
.endif # ${WANT_COMPILER_TYPE} == ${COMPILER_TYPE}
# WITH_SYSTEM_LD - Pull in needed values and make a decision.
# Check if there is a local linker that can satisfy as an external linker.
# Which linker is expected to be used?
.if ${MK_LLD_BOOTSTRAP} == "yes"
WANT_LINKER_TYPE= lld
.elif ${MK_BINUTILS_BOOTSTRAP} == "yes"
# Note that there's no support for bfd in WITH_SYSTEM_LINKER.
WANT_LINKER_TYPE= bfd
.else
WANT_LINKER_TYPE=
.endif
.if !defined(WANT_LINKER_FREEBSD_VERSION) && !make(showconfig) && \
!make(test-system-compiler)
.if ${WANT_LINKER_TYPE} == "lld"
WANT_LINKER_FREEBSD_VERSION_FILE= lib/clang/include/lld/Common/Version.inc
WANT_LINKER_FREEBSD_VERSION!= \
awk '$$2 == "LLD_REVISION_STRING" {gsub(/"/, "", $$3); print $$3}' \
${SRCDIR}/${WANT_LINKER_FREEBSD_VERSION_FILE} || echo unknown
WANT_LINKER_VERSION_FILE= lib/clang/include/lld/Common/Version.inc
WANT_LINKER_VERSION!= \
awk '$$2 == "LLD_VERSION" {split($$3, a, "."); print a[1] * 10000 + a[2] * 100 + a[3]}' \
${SRCDIR}/${WANT_LINKER_VERSION_FILE} || echo unknown
.else
WANT_LINKER_FREEBSD_VERSION_FILE=
WANT_LINKER_FREEBSD_VERSION=
.endif
.export WANT_LINKER_FREEBSD_VERSION WANT_LINKER_VERSION
.endif # !defined(WANT_LINKER_FREEBSD_VERSION)
.if ${MK_SYSTEM_LINKER} == "yes" && \
defined(WANT_LINKER_FREEBSD_VERSION) && \
(${MK_LLD_BOOTSTRAP} == "yes") && \
!make(xdev*) && \
${X_LINKER_TYPE} == ${WANT_LINKER_TYPE} && \
${X_LINKER_VERSION} == ${WANT_LINKER_VERSION} && \
${X_LINKER_FREEBSD_VERSION} == ${WANT_LINKER_FREEBSD_VERSION}
# Everything matches, disable the bootstrap linker.
MK_LLD_BOOTSTRAP= no
USING_SYSTEM_LINKER= yes
.endif # ${WANT_LINKER_TYPE} == ${LINKER_TYPE}
# WITH_SYSTEM_COMPILER / WITH_SYSTEM_LINKER - Handle defaults and debug.
USING_SYSTEM_COMPILER?= no
USING_SYSTEM_LINKER?= no
TEST_SYSTEM_COMPILER_VARS= \
USING_SYSTEM_COMPILER MK_SYSTEM_COMPILER \
MK_CROSS_COMPILER MK_CLANG_BOOTSTRAP MK_GCC_BOOTSTRAP \
WANT_COMPILER_TYPE WANT_COMPILER_VERSION WANT_COMPILER_VERSION_FILE \
WANT_COMPILER_FREEBSD_VERSION WANT_COMPILER_FREEBSD_VERSION_FILE \
CC COMPILER_TYPE COMPILER_FEATURES COMPILER_VERSION \
COMPILER_FREEBSD_VERSION \
XCC X_COMPILER_TYPE X_COMPILER_FEATURES X_COMPILER_VERSION \
X_COMPILER_FREEBSD_VERSION
TEST_SYSTEM_LINKER_VARS= \
USING_SYSTEM_LINKER MK_SYSTEM_LINKER \
MK_LLD_BOOTSTRAP MK_BINUTILS_BOOTSTRAP \
WANT_LINKER_TYPE WANT_LINKER_VERSION WANT_LINKER_VERSION_FILE \
WANT_LINKER_FREEBSD_VERSION WANT_LINKER_FREEBSD_VERSION_FILE \
LD LINKER_TYPE LINKER_FEATURES LINKER_VERSION \
LINKER_FREEBSD_VERSION \
XLD X_LINKER_TYPE X_LINKER_FEATURES X_LINKER_VERSION \
X_LINKER_FREEBSD_VERSION
.for _t in compiler linker
test-system-${_t}: .PHONY
.for v in ${TEST_SYSTEM_${_t:tu}_VARS}
${_+_}@printf "%-35s= %s\n" "${v}" "${${v}}"
.endfor
.endfor
.if (make(buildworld) || make(buildkernel) || make(kernel-toolchain) || \
make(toolchain) || make(_cross-tools))
.if ${USING_SYSTEM_COMPILER} == "yes"
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.info SYSTEM_COMPILER: Determined that CC=${CC} matches the source tree. Not bootstrapping a cross-compiler.
.elif ${MK_CLANG_BOOTSTRAP} == "yes"
.info SYSTEM_COMPILER: libclang will be built for bootstrapping a cross-compiler.
.endif
.if ${USING_SYSTEM_LINKER} == "yes"
.info SYSTEM_LINKER: Determined that LD=${LD} matches the source tree. Not bootstrapping a cross-linker.
.elif ${MK_LLD_BOOTSTRAP} == "yes"
.info SYSTEM_LINKER: libclang will be built for bootstrapping a cross-linker.
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
.endif
.endif
# End WITH_SYSTEM_COMPILER / WITH_SYSTEM_LD
Opportunistically skip building a cross-compiler with SYSTEM_COMPILER set. This will still build the compiler for the target but will not build the bootstrap cross-compiler in the cross-tools phase. Other toolchain bootstrapping, such as elftoolchan and binutils, currently still occurs. This will utilize the default CC (cc, /usr/bin/cc) as an external compiler. This is planned to be on-by-default eventually. This will utilize the __FreeBSD_cc_version compiler macro defined in the source tree and compare it to CC's version. If they match then the cross-compiler is skipped. If [X]CC is an external compiler (absolute path) or WITHOUT_CROSS_COMPILER is already set, then this logic is skipped. If the expected bootstrap compiler type no longer matches the found CC compiler type (clang vs gcc), then the logic is skipped. As an extra safety check the version number is also compared from the compiler to the tree version. Clang: The macro FREEBSD_CC_VERSION is defined in: lib/clang/include/clang/Basic/Version.inc For clang -target will be used if TARGET_ARCH != MACHINE_ARCH. This is from the current external toolchain logic. There is currently an assumption that the host compiler can build the TARGET_ARCH. This will usually be the case since we don't conditionalize target arch support in clang, but it will break when introducing new architectures. This problem is mitigated by incrementing the version when adding new architectures. GCC: The macro FBSD_CC_VER is defined in: gnu/usr.bin/cc/cc_tools/freebsd-native.h For GCC there is no simple -target support when TARGET_ARCH != MACHINE_ARCH. In this case the opportunistic skip is not done. If we add proper support for this case in external toolchain logic then it will be fine to enable. This relies on the macros being incremented whenever any change occurs to these compilers that warrant rebuilding files. It also should never repeat earlier values. Reviewed by: brooks, bapt, imp Sponsored by: EMC / Isilon Storage Division Differential Revision: https://reviews.freebsd.org/D6357
2016-05-21 01:32:23 +00:00
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
# Store some compiler metadata for use in installworld where we don't
# want to invoke CC at all.
_TOOLCHAIN_METADATA_VARS= COMPILER_VERSION \
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
COMPILER_TYPE \
COMPILER_FEATURES \
COMPILER_FREEBSD_VERSION \
LINKER_VERSION \
LINKER_FEATURES \
LINKER_TYPE \
LINKER_FREEBSD_VERSION
toolchain-metadata.mk: .PHONY .META
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
@: > ${.TARGET}
@echo ".info Using cached toolchain metadata from build at $$(hostname) on $$(date)" \
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
> ${.TARGET}
@echo "_LOADED_TOOLCHAIN_METADATA=t" >> ${.TARGET}
.for v in ${_TOOLCHAIN_METADATA_VARS}
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
@echo "${v}=${${v}}" >> ${.TARGET}
@echo "X_${v}=${X_${v}}" >> ${.TARGET}
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
.endfor
@echo ".export ${_TOOLCHAIN_METADATA_VARS}" >> ${.TARGET}
@echo ".export ${_TOOLCHAIN_METADATA_VARS:C,^,X_,}" >> ${.TARGET}
2008-09-19 16:14:42 +00:00
# We must do lib/ and libexec/ before bin/ in case of a mid-install error to
# keep the users system reasonably usable. For static->dynamic root upgrades,
# we don't want to install a dynamic binary without rtld and the needed
# libraries. More commonly, for dynamic root, we don't want to install a
# binary that requires a newer library version that hasn't been installed yet.
# This ordering is not a guarantee though. The only guarantee of a working
# system here would require fine-grained ordering of all components based
# on their dependencies.
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
.if !empty(SUBDIR_OVERRIDE)
SUBDIR= ${SUBDIR_OVERRIDE}
.else
2015-02-09 13:41:29 +00:00
SUBDIR= lib libexec
# Add LOCAL_LIB_DIRS, but only if they will not be picked up as a SUBDIR
# of a LOCAL_DIRS directory. This allows LOCAL_DIRS=foo and
# LOCAL_LIB_DIRS=foo/lib to behave as expected.
.for _DIR in ${LOCAL_DIRS:M*/} ${LOCAL_DIRS:N*/:S|$|/|}
_REDUNDANT_LIB_DIRS+= ${LOCAL_LIB_DIRS:M${_DIR}*}
.endfor
.for _DIR in ${LOCAL_LIB_DIRS}
.if ${_DIR} == ".WAIT" || (empty(_REDUNDANT_LIB_DIRS:M${_DIR}) && exists(${.CURDIR}/${_DIR}/Makefile))
SUBDIR+= ${_DIR}
.endif
.endfor
.if !defined(NO_ROOT) && (make(installworld) || make(install))
Rework the world subdir build targets to use the standard SUBDIR_PARALLEL mechanism. Back in r30113, the 'par-*' targets were added to parallelize portions of the build in a very similar fashion as the SUBDIR_PARALLEL feature used in r263778. Calling a target without 'par-' (for 'parallel') resulted in the standard bsd.subdir.mk handling without parallelization. Given we have SUBDIR_PARALLEL now there is no reason to duplicate the handling here. In build logs this will result in the ${dir}.${target}__D targets now showing as the normal ${target}_subdir_${dir} targets. I audited all of the uses of Makefile.inc1 and Makefile's targets that use bsd.subdir.mk and found that all but 'all' and 'install' were fine to use as always parallel. - For 'install' (from installworld -j) the ordering of lib/ and libexec/ before the rest of the system (described in r289433), and etc/ being last (described in r289435), is all that matters. So now a .WAIT is added in the proper places when invoking any 'install*' target. A parallel installworld does work and took 46% of the time a non-parallel install would take on my system with -j15 to ZFS. - For 'all' I left the default handling for this to not run in parallel. A 'par-all' target is still used by the 'everything' stage of buildworld to continue building in parallel as it already has been. This works because most of the dependencies are handled by the early bootstrap phases as well as 'libraries' and 'includes' phases. This lets all of the SUBDIR build in parallel fine, such as bin/ and lib/. This will not work if the user invokes 'all' though as we have dependencies spread all over the system with no way to depend between them (except for the dirdeps feature in the META_MODE build). Calling 'make all' from the top-level is still useful at least when using SUBDIR_OVERRIDE. MFC after: 2 weeks Sponsored by: EMC / Isilon Storage Division
2015-10-17 03:51:50 +00:00
# Ensure libraries are installed before progressing.
SUBDIR+=.WAIT
.endif
SUBDIR+=bin
2007-04-06 02:13:30 +00:00
.if ${MK_CDDL} != "no"
SUBDIR+=cddl
.endif
SUBDIR+=gnu include
.if ${MK_KERBEROS} != "no"
SUBDIR+=kerberos5
.endif
.if ${MK_RESCUE} != "no"
SUBDIR+=rescue
.endif
SUBDIR+=sbin
.if ${MK_CRYPT} != "no"
SUBDIR+=secure
.endif
2004-12-21 12:13:23 +00:00
.if !defined(NO_SHARE)
SUBDIR+=share
.endif
.if ${MK_BOOT} != "no"
SUBDIR+=stand
.endif
SUBDIR+=sys usr.bin usr.sbin
.if ${MK_TESTS} != "no"
SUBDIR+= tests
.endif
# Local directories are built in parallel with the base system directories.
# Users may insert a .WAIT directive at the beginning or elsewhere within
# the LOCAL_DIRS and LOCAL_LIB_DIRS lists as needed.
.for _DIR in ${LOCAL_DIRS}
.if ${_DIR} == ".WAIT" || exists(${.CURDIR}/${_DIR}/Makefile)
SUBDIR+= ${_DIR}
.endif
.endfor
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
# We must do etc/ last as it hooks into building the man whatis file
# by calling 'makedb' in share/man. This is only relevant for
# install/distribute so they build the whatis file after every manpage is
# installed.
.if make(installworld) || make(install)
Rework the world subdir build targets to use the standard SUBDIR_PARALLEL mechanism. Back in r30113, the 'par-*' targets were added to parallelize portions of the build in a very similar fashion as the SUBDIR_PARALLEL feature used in r263778. Calling a target without 'par-' (for 'parallel') resulted in the standard bsd.subdir.mk handling without parallelization. Given we have SUBDIR_PARALLEL now there is no reason to duplicate the handling here. In build logs this will result in the ${dir}.${target}__D targets now showing as the normal ${target}_subdir_${dir} targets. I audited all of the uses of Makefile.inc1 and Makefile's targets that use bsd.subdir.mk and found that all but 'all' and 'install' were fine to use as always parallel. - For 'install' (from installworld -j) the ordering of lib/ and libexec/ before the rest of the system (described in r289433), and etc/ being last (described in r289435), is all that matters. So now a .WAIT is added in the proper places when invoking any 'install*' target. A parallel installworld does work and took 46% of the time a non-parallel install would take on my system with -j15 to ZFS. - For 'all' I left the default handling for this to not run in parallel. A 'par-all' target is still used by the 'everything' stage of buildworld to continue building in parallel as it already has been. This works because most of the dependencies are handled by the early bootstrap phases as well as 'libraries' and 'includes' phases. This lets all of the SUBDIR build in parallel fine, such as bin/ and lib/. This will not work if the user invokes 'all' though as we have dependencies spread all over the system with no way to depend between them (except for the dirdeps feature in the META_MODE build). Calling 'make all' from the top-level is still useful at least when using SUBDIR_OVERRIDE. MFC after: 2 weeks Sponsored by: EMC / Isilon Storage Division
2015-10-17 03:51:50 +00:00
SUBDIR+=.WAIT
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
.endif
SUBDIR+=etc
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
.endif # !empty(SUBDIR_OVERRIDE)
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
.if defined(NOCLEAN)
.warning NOCLEAN option is deprecated. Use NO_CLEAN instead.
NO_CLEAN= ${NOCLEAN}
.endif
.if defined(NO_CLEANDIR)
CLEANDIR= clean cleandepend
.else
CLEANDIR= cleandir
.endif
.if defined(WORLDFAST)
NO_CLEAN= t
NO_OBJWALK= t
.endif
.if ${MK_META_MODE} == "yes"
# If filemon is used then we can rely on the build being incremental-safe.
# The .meta files will also track the build command and rebuild should
# it change.
.if empty(.MAKE.MODE:Mnofilemon)
NO_CLEAN= t
.endif
.endif
.if defined(NO_OBJWALK) || ${MK_AUTO_OBJ} == "yes"
NO_OBJWALK= t
NO_KERNELOBJ= t
.endif
.if !defined(NO_OBJWALK)
_obj= obj
.endif
LOCAL_TOOL_DIRS?=
PACKAGEDIR?= ${DESTDIR}/${DISTDIR}
.if empty(SHELL:M*csh*)
BUILDENV_SHELL?=${SHELL}
.else
BUILDENV_SHELL?=/bin/sh
.endif
.if !defined(_MKSHOWCONFIG)
.if !defined(SVN_CMD) || empty(SVN_CMD)
. for _P in /usr/bin /usr/local/bin
. for _S in svn svnlite
. if exists(${_P}/${_S})
SVN_CMD= ${_P}/${_S}
. endif
. endfor
. endfor
.export SVN_CMD
.endif
SVNFLAGS?= -r HEAD
.if !defined(VCS_REVISION) || empty(VCS_REVISION)
.if !defined(SVNVERSION_CMD) || empty(SVNVERSION_CMD)
. for _D in ${PATH:S,:, ,g}
. if exists(${_D}/svnversion)
SVNVERSION_CMD?=${_D}/svnversion
. endif
. if exists(${_D}/svnliteversion)
SVNVERSION_CMD?=${_D}/svnliteversion
. endif
. endfor
.endif
_VCS_REVISION?= $$(eval ${SVNVERSION_CMD} ${SRCDIR})
. if !empty(_VCS_REVISION)
VCS_REVISION= $$(echo r${_VCS_REVISION})
. endif
.export VCS_REVISION
.endif
.if !defined(OSRELDATE)
.if exists(/usr/include/osreldate.h)
OSRELDATE!= awk '/^\#define[[:space:]]*__FreeBSD_version/ { print $$3 }' \
/usr/include/osreldate.h
.else
OSRELDATE= 0
.endif
.export OSRELDATE
.endif
# Set VERSION for CTFMERGE to use via the default CTFFLAGS=-L VERSION.
.if !defined(_REVISION)
_REVISION!= ${MAKE} -C ${SRCDIR}/release MK_AUTO_OBJ=no -V REVISION
.export _REVISION
.endif
.if !defined(_BRANCH)
_BRANCH!= ${MAKE} -C ${SRCDIR}/release MK_AUTO_OBJ=no -V BRANCH
.export _BRANCH
.endif
.if !defined(SRCRELDATE)
SRCRELDATE!= awk '/^\#define[[:space:]]*__FreeBSD_version/ { print $$3 }' \
${SRCDIR}/sys/sys/param.h
.export SRCRELDATE
.endif
.if !defined(VERSION)
VERSION= FreeBSD ${_REVISION}-${_BRANCH:C/-p[0-9]+$//} ${TARGET_ARCH} ${SRCRELDATE}
.export VERSION
.endif
.if !defined(PKG_VERSION)
.if ${_BRANCH:MSTABLE*} || ${_BRANCH:MCURRENT*}
2015-03-15 14:41:26 +00:00
TIMENOW= %Y%m%d%H%M%S
EXTRA_REVISION= .s${TIMENOW:gmtime}
.elif ${_BRANCH:MALPHA*}
EXTRA_REVISION= _${_BRANCH:C/-ALPHA/.a/}
.elif ${_BRANCH:MBETA*}
EXTRA_REVISION= _${_BRANCH:C/-BETA/.b/}
.elif ${_BRANCH:MRC*}
EXTRA_REVISION= _${_BRANCH:C/-RC/.r/}
.elif ${_BRANCH:MPRERELEASE*}
EXTRA_REVISION= _${_BRANCH:C/-PRERELEASE/.p/}
.elif ${_BRANCH:M*-p*}
EXTRA_REVISION= _${_BRANCH:C/.*-p([0-9]+$)/\1/}
.endif
PKG_VERSION= ${_REVISION}${EXTRA_REVISION}
.endif
.endif # !defined(PKG_VERSION)
.if !defined(_MKSHOWCONFIG)
_CPUTYPE!= MAKEFLAGS= CPUTYPE=${_TARGET_CPUTYPE} ${MAKE} -f /dev/null \
-m ${.CURDIR}/share/mk MK_AUTO_OBJ=no -V CPUTYPE
.if ${_CPUTYPE} != ${_TARGET_CPUTYPE}
.error CPUTYPE global should be set with ?=.
.endif
.endif
Fix cross-building, etc: 1. To cross-build, one now needs to set TARGET_ARCH, and not the MACHINE_ARCH. MACHINE_ARCH should never be changed manually! 2. Initialize DESTDIR= explicitly for bootstrap-tools, build-tools, and cross-tools stages. This fixes broken header and library dependencies problem. We build them in the host environment, and obviously want them to depend on host headers and libraries. The problem with broken header dependencies for bootstrap-tools and cross-tools was already partially solved (see BOOTSTRAPPING tests in bsd.prog.mk and bsd.lib.mk), but it was still there for build-tools if the user ran "make world DESTDIR=/foo". Also, for all of these stages, the library dependencies were broken because of how bsd.libnames.mk define DPADD members. We still provide a glue to install bootstrap- and cross-tools under the ${WORLDTMP}. Removed PATH overrides for bootstrap-, build-, and cross-tools stages. There is just no reason why we would need to override it, and the hacks to clean up the ${WORLDTMP} in the -DNOCLEAN case are no longer needed with fixes from this step. That is, we now never use ${WORLDTMP} headers and libraries, and we don't use any ${WORLDTMP} installed binaries during these stages. Again, these stages depend solely on the host environment, including compiler, headers, and libraries. 3. Moved "miniperl" back from cross-tools (it has nothing to do with a cross-compiler) to build-tools where it belongs. The change from step 1 let to do this. Also, to make this work, build-tools targets of "cc_tools" and "miniperl" were modified to call "depend". Here follow the detailed explanations. There are two categories of build tools, for now. In the first category there are "cc_tools" and "miniperl". They occupy the whole (sub)directory, and nothing needs to be done in this subdirectory later during the "all" stage. They are also constructed using system makefiles. We must build the .depend early in the build-tools stage because: 1) They use (and depend on) the host environment. 2) If we don't do this in build-tools, the "depend" stage of buildworld will do this for us; wrong library and header dependencies will be recorded (DESTDIR=${WORLDTMP}) and, what's worse, the "all" stage may then clobber the build-architecture format tools (that we built in the build-tools stage) with the target-architecture format ones, breaking cross build. In the second category there are all other build-tools. They share their directory with the "main" module that needs them in the "all" stage, and they don't show up themselves in the .depend file. The portion of this fix was already committed in gnu/usr.bin/cc/cc_tools/Makefile,v 1.52. 4. "libperl" is no longer a build tool, and "miniperl" is the stand-alone application. I had to make this change because build-tools and "all" stages share the same object directory. Without this change, if we cross compile, libperl.a is first built for the build architecture during the build-tools stage (for the purposes of immediate linkage with "miniperl"). Later on, the "all" stage sees this library as up-to-date, and doesn't rebuild it. The effect is that the wrong format static libperl library is installed with installworld. 5. Fixed "includes" to install secure/lib/libtelnet headers if required. Reviewed by: bde
2001-09-29 13:17:54 +00:00
.if make(buildworld)
BUILD_ARCH!= uname -p
Fix cross-building, etc: 1. To cross-build, one now needs to set TARGET_ARCH, and not the MACHINE_ARCH. MACHINE_ARCH should never be changed manually! 2. Initialize DESTDIR= explicitly for bootstrap-tools, build-tools, and cross-tools stages. This fixes broken header and library dependencies problem. We build them in the host environment, and obviously want them to depend on host headers and libraries. The problem with broken header dependencies for bootstrap-tools and cross-tools was already partially solved (see BOOTSTRAPPING tests in bsd.prog.mk and bsd.lib.mk), but it was still there for build-tools if the user ran "make world DESTDIR=/foo". Also, for all of these stages, the library dependencies were broken because of how bsd.libnames.mk define DPADD members. We still provide a glue to install bootstrap- and cross-tools under the ${WORLDTMP}. Removed PATH overrides for bootstrap-, build-, and cross-tools stages. There is just no reason why we would need to override it, and the hacks to clean up the ${WORLDTMP} in the -DNOCLEAN case are no longer needed with fixes from this step. That is, we now never use ${WORLDTMP} headers and libraries, and we don't use any ${WORLDTMP} installed binaries during these stages. Again, these stages depend solely on the host environment, including compiler, headers, and libraries. 3. Moved "miniperl" back from cross-tools (it has nothing to do with a cross-compiler) to build-tools where it belongs. The change from step 1 let to do this. Also, to make this work, build-tools targets of "cc_tools" and "miniperl" were modified to call "depend". Here follow the detailed explanations. There are two categories of build tools, for now. In the first category there are "cc_tools" and "miniperl". They occupy the whole (sub)directory, and nothing needs to be done in this subdirectory later during the "all" stage. They are also constructed using system makefiles. We must build the .depend early in the build-tools stage because: 1) They use (and depend on) the host environment. 2) If we don't do this in build-tools, the "depend" stage of buildworld will do this for us; wrong library and header dependencies will be recorded (DESTDIR=${WORLDTMP}) and, what's worse, the "all" stage may then clobber the build-architecture format tools (that we built in the build-tools stage) with the target-architecture format ones, breaking cross build. In the second category there are all other build-tools. They share their directory with the "main" module that needs them in the "all" stage, and they don't show up themselves in the .depend file. The portion of this fix was already committed in gnu/usr.bin/cc/cc_tools/Makefile,v 1.52. 4. "libperl" is no longer a build tool, and "miniperl" is the stand-alone application. I had to make this change because build-tools and "all" stages share the same object directory. Without this change, if we cross compile, libperl.a is first built for the build architecture during the build-tools stage (for the purposes of immediate linkage with "miniperl"). Later on, the "all" stage sees this library as up-to-date, and doesn't rebuild it. The effect is that the wrong format static libperl library is installed with installworld. 5. Fixed "includes" to install secure/lib/libtelnet headers if required. Reviewed by: bde
2001-09-29 13:17:54 +00:00
.if ${MACHINE_ARCH} != ${BUILD_ARCH}
.error To cross-build, set TARGET_ARCH.
.endif
.endif
WORLDTMP?= ${OBJTOP}/tmp
BPATH= ${CCACHE_WRAPPER_PATH_PFX}${WORLDTMP}/legacy/usr/sbin:${WORLDTMP}/legacy/usr/bin:${WORLDTMP}/legacy/bin
XPATH= ${WORLDTMP}/usr/sbin:${WORLDTMP}/usr/bin
# When building we want to find the cross tools before the host tools in ${BPATH}.
# We also need to add UNIVERSE_TOOLCHAIN_PATH so that we can find the shared
# toolchain files (clang, lld, etc.) during make universe/tinderbox
STRICTTMPPATH= ${XPATH}:${BPATH}:${UNIVERSE_TOOLCHAIN_PATH}
# We should not be using tools from /usr/bin accidentally since this could cause
# the build to break on other systems that don't have that tool. For now we
# still allow using the old behaviour (inheriting $PATH) if
# BUILD_WITH_STRICT_TMPPATH is set to 0 but this will eventually be removed.
# Currently strict $PATH can cause build failures and does not work yet with
# USING_SYSTEM_LINKER/USING_SYSTEM_COMPILER. Once these issues have been
# resolved it will be turned on by default.
BUILD_WITH_STRICT_TMPPATH?=0
.if ${BUILD_WITH_STRICT_TMPPATH} != 0
TMPPATH= ${STRICTTMPPATH}
.else
TMPPATH= ${STRICTTMPPATH}:${PATH}
.endif
#
# Avoid running mktemp(1) unless actually needed.
# It may not be functional, e.g., due to new ABI
# when in the middle of installing over this system.
#
.if make(distributeworld) || make(installworld) || make(stageworld)
.if ${BUILD_WITH_STRICT_TMPPATH} != 0
MKTEMP=${WORLDTMP}/legacy/usr/bin/mktemp
.if !exists(${MKTEMP})
.error "mktemp binary doesn't exist in expected location: ${MKTEMP}"
.endif
.else
MKTEMP=mktemp
.endif
INSTALLTMP!= ${MKTEMP} -d -u -t install
.endif
.if make(stagekernel) || make(distributekernel)
TAGS+= kernel
PACKAGE= kernel
.endif
#
# Building a world goes through the following stages
#
# 1. legacy stage [BMAKE]
# This stage is responsible for creating compatibility
# shims that are needed by the bootstrap-tools,
# build-tools and cross-tools stages. These are generally
# APIs that tools from one of those three stages need to
# build that aren't present on the host.
# 1. bootstrap-tools stage [BMAKE]
# This stage is responsible for creating programs that
# are needed for backward compatibility reasons. They
# are not built as cross-tools.
# 2. build-tools stage [TMAKE]
# This stage is responsible for creating the object
# tree and building any tools that are needed during
# the build process. Some programs are listed during
# this phase because they build binaries to generate
# files needed to build these programs. This stage also
# builds the 'build-tools' target rather than 'all'.
# 3. cross-tools stage [XMAKE]
# This stage is responsible for creating any tools that
# are needed for building the system. A cross-compiler is one
# of them. This differs from build tools in two ways:
# 1. the 'all' target is built rather than 'build-tools'
# 2. these tools are installed into TMPPATH for stage 4.
# 4. world stage [WMAKE]
# This stage actually builds the world.
# 5. install stage (optional) [IMAKE]
# This stage installs a previously built world.
#
BOOTSTRAPPING?= 0
# Keep these in sync
MINIMUM_SUPPORTED_OSREL?= 1002501
MINIMUM_SUPPORTED_REL?= 10.3
# Common environment for world related stages
CROSSENV+= \
Fix cross-building, etc: 1. To cross-build, one now needs to set TARGET_ARCH, and not the MACHINE_ARCH. MACHINE_ARCH should never be changed manually! 2. Initialize DESTDIR= explicitly for bootstrap-tools, build-tools, and cross-tools stages. This fixes broken header and library dependencies problem. We build them in the host environment, and obviously want them to depend on host headers and libraries. The problem with broken header dependencies for bootstrap-tools and cross-tools was already partially solved (see BOOTSTRAPPING tests in bsd.prog.mk and bsd.lib.mk), but it was still there for build-tools if the user ran "make world DESTDIR=/foo". Also, for all of these stages, the library dependencies were broken because of how bsd.libnames.mk define DPADD members. We still provide a glue to install bootstrap- and cross-tools under the ${WORLDTMP}. Removed PATH overrides for bootstrap-, build-, and cross-tools stages. There is just no reason why we would need to override it, and the hacks to clean up the ${WORLDTMP} in the -DNOCLEAN case are no longer needed with fixes from this step. That is, we now never use ${WORLDTMP} headers and libraries, and we don't use any ${WORLDTMP} installed binaries during these stages. Again, these stages depend solely on the host environment, including compiler, headers, and libraries. 3. Moved "miniperl" back from cross-tools (it has nothing to do with a cross-compiler) to build-tools where it belongs. The change from step 1 let to do this. Also, to make this work, build-tools targets of "cc_tools" and "miniperl" were modified to call "depend". Here follow the detailed explanations. There are two categories of build tools, for now. In the first category there are "cc_tools" and "miniperl". They occupy the whole (sub)directory, and nothing needs to be done in this subdirectory later during the "all" stage. They are also constructed using system makefiles. We must build the .depend early in the build-tools stage because: 1) They use (and depend on) the host environment. 2) If we don't do this in build-tools, the "depend" stage of buildworld will do this for us; wrong library and header dependencies will be recorded (DESTDIR=${WORLDTMP}) and, what's worse, the "all" stage may then clobber the build-architecture format tools (that we built in the build-tools stage) with the target-architecture format ones, breaking cross build. In the second category there are all other build-tools. They share their directory with the "main" module that needs them in the "all" stage, and they don't show up themselves in the .depend file. The portion of this fix was already committed in gnu/usr.bin/cc/cc_tools/Makefile,v 1.52. 4. "libperl" is no longer a build tool, and "miniperl" is the stand-alone application. I had to make this change because build-tools and "all" stages share the same object directory. Without this change, if we cross compile, libperl.a is first built for the build architecture during the build-tools stage (for the purposes of immediate linkage with "miniperl"). Later on, the "all" stage sees this library as up-to-date, and doesn't rebuild it. The effect is that the wrong format static libperl library is installed with installworld. 5. Fixed "includes" to install secure/lib/libtelnet headers if required. Reviewed by: bde
2001-09-29 13:17:54 +00:00
MACHINE_ARCH=${TARGET_ARCH} \
MACHINE=${TARGET} \
CPUTYPE=${TARGET_CPUTYPE}
.if ${MK_META_MODE} != "no"
# Don't rebuild build-tools targets during normal build.
CROSSENV+= BUILD_TOOLS_META=.NOMETA
.endif
.if defined(TARGET_CFLAGS)
CROSSENV+= ${TARGET_CFLAGS}
.endif
BOOTSTRAPPING_OSRELDATE?=${OSRELDATE}
# bootstrap-tools stage
BMAKEENV= INSTALL="sh ${.CURDIR}/tools/install.sh" \
TOOLS_PREFIX=${TOOLS_PREFIX_UNDEF:U${WORLDTMP}} \
PATH=${BPATH}:${PATH} \
WORLDTMP=${WORLDTMP} \
MAKEFLAGS="-m ${.CURDIR}/tools/build/mk ${.MAKEFLAGS}"
# need to keep this in sync with targets/pseudo/bootstrap-tools/Makefile
BSARGS= DESTDIR= \
OBJTOP='${WORLDTMP}/obj-tools' \
OBJROOT='$${OBJTOP}/' \
MAKEOBJDIRPREFIX= \
BOOTSTRAPPING=${BOOTSTRAPPING_OSRELDATE} \
BWPHASE=${.TARGET:C,^_,,} \
SSP_CFLAGS= \
MK_HTML=no NO_LINT=yes MK_MAN=no \
2014-04-25 19:25:26 +00:00
-DNO_PIC MK_PROFILE=no -DNO_SHARED \
-DNO_CPU_CFLAGS MK_WARNS=no MK_CTF=no \
MK_CLANG_EXTRAS=no MK_CLANG_FULL=no \
MK_LLDB=no MK_RETPOLINE=no MK_TESTS=no \
MK_INCLUDES=yes
BMAKE= \
${BMAKEENV} ${MAKE} ${WORLD_FLAGS} -f Makefile.inc1 \
${BSARGS}
.if empty(.MAKEOVERRIDES:MMK_LLVM_TARGET_ALL)
BMAKE+= MK_LLVM_TARGET_ALL=no
.endif
# build-tools stage
TMAKE= \
${BMAKEENV} ${MAKE} ${WORLD_FLAGS} -f Makefile.inc1 \
TARGET=${TARGET} TARGET_ARCH=${TARGET_ARCH} \
DESTDIR= \
BOOTSTRAPPING=${BOOTSTRAPPING_OSRELDATE} \
BWPHASE=${.TARGET:C,^_,,} \
SSP_CFLAGS= \
-DNO_LINT \
-DNO_CPU_CFLAGS MK_WARNS=no MK_CTF=no \
MK_CLANG_EXTRAS=no MK_CLANG_FULL=no \
MK_LLDB=no MK_RETPOLINE=no MK_TESTS=no
# cross-tools stage
# TOOLS_PREFIX set in BMAKE
XMAKE= ${BMAKE} \
TARGET=${TARGET} TARGET_ARCH=${TARGET_ARCH} \
MK_GDB=no MK_TESTS=no
This change builds kernel tools based on the same assumption as building the kernel itself: If building for the same architecture as the build host, the kernel build assumes that the host toolchain is capable of building the kernel. If it's not, "make kernel-toolchain" will bootstrap a new set of tools that will work. With this change the same assumptions are made for building kernel tools, and the existing host toolchain is used to do the build (notably, the build doesn't link the tools with the legacy libraries, which may not even exist). If ever for some reason the host toolchain isn't capable of building the kernel tools, then doing a "make kernel-toolchain" will bootstrap newer tools to get the job done. So when built as part of buildworld or kernel-toolchain, the kernel tools are built using the XMAKE (via BMAKE) commands and environment. When built as part of building just the kernel on a same-target host, the tools are built using the new KTMAKE commands and environment. What doesn't jump out at you in the diffs is that the difference between BMAKE and KTMAKE is that BMAKE contains this magic line which changes how the build is done because it changes what files get included for .include <bsd.prog.mk> and other standard includes: MAKEFLAGS="-m ${.CURDIR}/tools/build/mk ${.MAKEFLAGS}" and KTMAKE doesn't, and contains this instead: TOOLS_PREFIX=${WORLDTMP} Hopefully this brings the "how to build aicasm with the right toolchain" saga to a conclusion that works in all usage scenarios that have historically been supported.
2013-11-09 00:15:36 +00:00
# kernel-tools stage
KTMAKEENV= INSTALL="sh ${.CURDIR}/tools/install.sh" \
PATH=${BPATH}:${PATH} \
WORLDTMP=${WORLDTMP}
KTMAKE= \
TOOLS_PREFIX=${TOOLS_PREFIX_UNDEF:U${WORLDTMP}} \
This change builds kernel tools based on the same assumption as building the kernel itself: If building for the same architecture as the build host, the kernel build assumes that the host toolchain is capable of building the kernel. If it's not, "make kernel-toolchain" will bootstrap a new set of tools that will work. With this change the same assumptions are made for building kernel tools, and the existing host toolchain is used to do the build (notably, the build doesn't link the tools with the legacy libraries, which may not even exist). If ever for some reason the host toolchain isn't capable of building the kernel tools, then doing a "make kernel-toolchain" will bootstrap newer tools to get the job done. So when built as part of buildworld or kernel-toolchain, the kernel tools are built using the XMAKE (via BMAKE) commands and environment. When built as part of building just the kernel on a same-target host, the tools are built using the new KTMAKE commands and environment. What doesn't jump out at you in the diffs is that the difference between BMAKE and KTMAKE is that BMAKE contains this magic line which changes how the build is done because it changes what files get included for .include <bsd.prog.mk> and other standard includes: MAKEFLAGS="-m ${.CURDIR}/tools/build/mk ${.MAKEFLAGS}" and KTMAKE doesn't, and contains this instead: TOOLS_PREFIX=${WORLDTMP} Hopefully this brings the "how to build aicasm with the right toolchain" saga to a conclusion that works in all usage scenarios that have historically been supported.
2013-11-09 00:15:36 +00:00
${KTMAKEENV} ${MAKE} ${WORLD_FLAGS} -f Makefile.inc1 \
DESTDIR= \
OBJTOP='${WORLDTMP}/obj-kernel-tools' \
OBJROOT='$${OBJTOP}/' \
MAKEOBJDIRPREFIX= \
BOOTSTRAPPING=${BOOTSTRAPPING_OSRELDATE} \
SSP_CFLAGS= \
MK_HTML=no -DNO_LINT MK_MAN=no \
2014-04-25 19:25:26 +00:00
-DNO_PIC MK_PROFILE=no -DNO_SHARED \
-DNO_CPU_CFLAGS MK_RETPOLINE=no MK_WARNS=no MK_CTF=no
This change builds kernel tools based on the same assumption as building the kernel itself: If building for the same architecture as the build host, the kernel build assumes that the host toolchain is capable of building the kernel. If it's not, "make kernel-toolchain" will bootstrap a new set of tools that will work. With this change the same assumptions are made for building kernel tools, and the existing host toolchain is used to do the build (notably, the build doesn't link the tools with the legacy libraries, which may not even exist). If ever for some reason the host toolchain isn't capable of building the kernel tools, then doing a "make kernel-toolchain" will bootstrap newer tools to get the job done. So when built as part of buildworld or kernel-toolchain, the kernel tools are built using the XMAKE (via BMAKE) commands and environment. When built as part of building just the kernel on a same-target host, the tools are built using the new KTMAKE commands and environment. What doesn't jump out at you in the diffs is that the difference between BMAKE and KTMAKE is that BMAKE contains this magic line which changes how the build is done because it changes what files get included for .include <bsd.prog.mk> and other standard includes: MAKEFLAGS="-m ${.CURDIR}/tools/build/mk ${.MAKEFLAGS}" and KTMAKE doesn't, and contains this instead: TOOLS_PREFIX=${WORLDTMP} Hopefully this brings the "how to build aicasm with the right toolchain" saga to a conclusion that works in all usage scenarios that have historically been supported.
2013-11-09 00:15:36 +00:00
# world stage
WMAKEENV= ${CROSSENV} \
INSTALL="sh ${.CURDIR}/tools/install.sh" \
PATH=${TMPPATH} \
SYSROOT=${WORLDTMP}
# make hierarchy
HMAKE= PATH=${TMPPATH} ${MAKE} LOCAL_MTREE=${LOCAL_MTREE:Q}
.if defined(NO_ROOT)
HMAKE+= PATH=${TMPPATH} METALOG=${METALOG} -DNO_ROOT
.endif
Update libc++ to 3.8.0. Excerpted list of fixes (with upstream revision numbers): r242679 Implement the plugin-based version of std::search. There are no searchers yet; those are coming soon. r242682 Implement the default searcher for std::experimental::search. r243728 Add <experimental/any> v2. r245330 implement more of N4258 - Cleaning up noexcept in the standard library. Specifically add new noexcept stuff to vector and string's move-assignment operations r245334 Fix PR22606 - Leak pthread_key with static storage duration to ensure all of thread-local destructors are called. r245335 Fix PR23589: std::function doesn't recognize null pointer to varargs function. r247036 Implementation of Boyer-Moore and Boyer-Moore-Horspool searchers for the LFTS. r249325 Implement LWG#2063, and update the issues links to point to the github generated pages r249738 Split <ctype.h> out of <cctype>. r249739 Split <errno.h> out of <cerrno>. r249740 Split <float.h> out of <cfloat>. r249741 Split <inttypes.h> out of <cinttypes>. r249742 Split <math.h> out of <cmath>. r249743 Split <setjmp.h> out of <csetjmp>. r249761 Split <stddef.h> out of <cstddef>. r249798 Split <stdio.h> out of <cstdio>. r249800 Split <stdlib.h> out of <cstdlib>. r249889 Split <wchar.h> out of <cwchar>. r249890 Split <wctype.h> out of <cwctype>. r249929 Split <string.h> out of <cstring>. r250254 ABI versioning macros for libc++. r251246 Fix LWG#2244: basic_istream::seekg r251247 Fix LWG#2127: Move-construction with raw_storage_iterator. r251253 Fix LWG#2476: scoped_allocator_adaptor is not assignable r251257 Fix LWG#2489: mem_fn() should be noexcept r251618 Implement P0004R1 'Remove Deprecated iostreams aliases' r251766 Implement the first part of P0006R0: Adopt Type Traits Variable Templates for C++17. r252195 Implement P0092R1 for C++1z r252350 Allow deque to handle incomplete types. r252406 More of P0006R0: type traits variable aliases for C++17. r252407 Implement LWG#2353: std::next is over-constrained r252905 Implement P0074: Making owner_less more flexible r253215 Implement P0013R1: Logical Operator Type Traits. r253274 Implement P0007: Constant View: A proposal for a std::as_const helper function template. r254119 Add static_assert to set/multiset/map/multimap/forward_list/deque that the allocator's value_type match the container's value_type. r254283 Implement more of P0006; Type Traits Variable Templates. r255941 LWG2485: get() should be overloaded for const tuple&&. r256325 Fix LWG Issue #2367 - Fixing std::tuple and std::pair's default constructors. r256652 Fix for ALL undefined behavior in <list>. r256859 First half of LWG#2354: 'Unnecessary copying when inserting into maps with braced-init syntax' Exp-run: antoine Relnotes: yes
2016-05-26 18:52:49 +00:00
CROSSENV+= CC="${XCC} ${XCFLAGS}" CXX="${XCXX} ${XCXXFLAGS} ${XCFLAGS}" \
CPP="${XCPP} ${XCFLAGS}" \
AS="${XAS}" AR="${XAR}" LD="${XLD}" LLVM_LINK="${XLLVM_LINK}" \
NM=${XNM} OBJCOPY="${XOBJCOPY}" \
RANLIB=${XRANLIB} STRINGS=${XSTRINGS} \
SIZE="${XSIZE}"
.if defined(CROSS_BINUTILS_PREFIX) && exists(${CROSS_BINUTILS_PREFIX})
# In the case of xdev-build tools, CROSS_BINUTILS_PREFIX won't be a
# directory, but the compiler will look in the right place for its
# tools so we don't need to tell it where to look.
BFLAGS+= -B${CROSS_BINUTILS_PREFIX}
.endif
# The internal bootstrap compiler has a default sysroot set by TOOLS_PREFIX
# and target set by TARGET/TARGET_ARCH. However, there are several needs to
# always pass an explicit --sysroot and -target.
# - External compiler needs sysroot and target flags.
# - External ld needs sysroot.
# - To be clear about the use of a sysroot when using the internal compiler.
# - Easier debugging.
# - Allowing WITH_SYSTEM_COMPILER+WITH_META_MODE to work together due to
# the flip-flopping build command when sometimes using external and
# sometimes using internal.
# - Allow using lld which has no support for default paths.
.if !defined(CROSS_BINUTILS_PREFIX) || !exists(${CROSS_BINUTILS_PREFIX})
BFLAGS+= -B${WORLDTMP}/usr/bin
.endif
.if ${WANT_COMPILER_TYPE} == gcc || \
(defined(X_COMPILER_TYPE) && ${X_COMPILER_TYPE} == gcc)
.elif ${WANT_COMPILER_TYPE} == clang || \
(defined(X_COMPILER_TYPE) && ${X_COMPILER_TYPE} == clang)
XCFLAGS+= -target ${TARGET_TRIPLE}
.endif
XCFLAGS+= --sysroot=${WORLDTMP}
.if !empty(BFLAGS)
XCFLAGS+= ${BFLAGS}
.endif
.if ${MK_LIB32} != "no" && (${TARGET_ARCH} == "amd64" || \
${TARGET_ARCH} == "powerpc64" || ${TARGET_ARCH:Mmips64*} != "")
LIBCOMPAT= 32
.include "Makefile.libcompat"
.elif ${MK_LIBSOFT} != "no" && ${TARGET_ARCH:Marmv[67]*} != ""
LIBCOMPAT= SOFT
.include "Makefile.libcompat"
.endif
# META_MODE normally ignores host file changes since every build updates
# timestamps (see NO_META_IGNORE_HOST in sys.mk). There are known times
# when the ABI breaks though that we want to force rebuilding WORLDTMP
# to get updated host tools.
.if ${MK_META_MODE} == "yes" && defined(NO_CLEAN) && \
!defined(NO_META_IGNORE_HOST) && !defined(NO_META_IGNORE_HOST_HEADERS) && \
!defined(_MKSHOWCONFIG)
# r318736 - ino64 major ABI breakage
META_MODE_BAD_ABI_VERS+= 1200031
.if !defined(OBJDIR_HOST_OSRELDATE)
.if exists(${OBJTOP}/host-osreldate.h)
OBJDIR_HOST_OSRELDATE!= \
awk '/^\#define[[:space:]]*__FreeBSD_version/ { print $$3 }' \
${OBJTOP}/host-osreldate.h
.elif exists(${WORLDTMP}/usr/include/osreldate.h)
OBJDIR_HOST_OSRELDATE= 0
.endif
.export OBJDIR_HOST_OSRELDATE
.endif
# Note that this logic is the opposite of normal BOOTSTRAP handling. We want
# to compare the WORLDTMP's OSRELDATE to the host's OSRELDATE. If the WORLDTMP
# is older than the ABI-breakage OSRELDATE of the HOST then we rebuild.
.if defined(OBJDIR_HOST_OSRELDATE)
.for _ver in ${META_MODE_BAD_ABI_VERS}
.if ${OSRELDATE} >= ${_ver} && ${OBJDIR_HOST_OSRELDATE} < ${_ver}
_meta_mode_need_rebuild= ${_ver}
.endif
.endfor
.if defined(_meta_mode_need_rebuild)
.info META_MODE: Rebuilding host tools due to ABI breakage in __FreeBSD_version ${_meta_mode_need_rebuild}.
NO_META_IGNORE_HOST_HEADERS= 1
.export NO_META_IGNORE_HOST_HEADERS
.endif # defined(_meta_mode_need_rebuild)
.endif # defined(OBJDIR_HOST_OSRELDATE)
.endif # ${MK_META_MODE} == "yes" && defined(NO_CLEAN) ...
# This is only used for META_MODE+filemon to track what the oldest
# __FreeBSD_version is in WORLDTMP. This purposely does NOT have
# a make dependency on /usr/include/osreldate.h as the file should
# only be copied when it is missing or meta mode determines it has changed.
# Since host files are normally ignored without NO_META_IGNORE_HOST
# the file will never be updated unless that flag is specified. This
# allows tracking the oldest osreldate to force rebuilds via
# META_MODE_BADABI_REVS above.
host-osreldate.h: # DO NOT ADD /usr/include/osreldate.h here
@cp -f /usr/include/osreldate.h ${.TARGET}
WMAKE= ${WMAKEENV} ${MAKE} ${WORLD_FLAGS} -f Makefile.inc1 \
BWPHASE=${.TARGET:C,^_,,} \
DESTDIR=${WORLDTMP}
IMAKEENV= ${CROSSENV}
IMAKE= ${IMAKEENV} ${MAKE} -f Makefile.inc1 \
${IMAKE_INSTALL} ${IMAKE_MTREE}
.if empty(.MAKEFLAGS:M-n)
IMAKEENV+= PATH=${STRICTTMPPATH}:${INSTALLTMP} \
LD_LIBRARY_PATH=${INSTALLTMP} \
PATH_LOCALE=${INSTALLTMP}/locale
IMAKE+= __MAKE_SHELL=${INSTALLTMP}/sh
.else
IMAKEENV+= PATH=${TMPPATH}:${INSTALLTMP}
.endif
# When generating install media, do not allow user and group information from
# the build host to affect the contents of the distribution.
.if make(distributeworld) || make(distrib-dirs) || make(distribution)
DB_FROM_SRC= yes
.endif
.if defined(DB_FROM_SRC)
INSTALLFLAGS+= -N ${.CURDIR}/etc
MTREEFLAGS+= -N ${.CURDIR}/etc
.endif
_INSTALL_DDIR= ${DESTDIR}/${DISTDIR}
INSTALL_DDIR= ${_INSTALL_DDIR:S://:/:g:C:/$::}
.if defined(NO_ROOT)
METALOG?= ${DESTDIR}/${DISTDIR}/METALOG
METALOG:= ${METALOG:C,//+,/,g}
IMAKE+= -DNO_ROOT METALOG=${METALOG}
INSTALLFLAGS+= -U -M ${METALOG} -D ${INSTALL_DDIR}
MTREEFLAGS+= -W
.endif
.if defined(BUILD_PKGS)
INSTALLFLAGS+= -h sha256
.endif
.if defined(DB_FROM_SRC) || defined(NO_ROOT)
IMAKE_INSTALL= INSTALL="install ${INSTALLFLAGS}"
IMAKE_MTREE= MTREE_CMD="mtree ${MTREEFLAGS}"
.endif
DESTDIR_MTREEFLAGS= -deU
# When creating worldtmp we don't need to set the directories as owned by root
# so we also pass -W
WORLDTMP_MTREEFLAGS= -deUW
.if defined(NO_ROOT)
# When building with -DNO_ROOT we shouldn't be changing the directories
# that are created by mtree to be owned by root/wheel.
DESTDIR_MTREEFLAGS+= -W
.endif
MTREE?= mtree
.if ${BUILD_WITH_STRICT_TMPPATH} != 0
MTREE= ${WORLDTMP}/legacy/usr/sbin/mtree
.endif
WORLDTMP_MTREE= ${MTREE} ${WORLDTMP_MTREEFLAGS}
DESTDIR_MTREE= ${MTREE} ${DESTDIR_MTREEFLAGS}
# kernel stage
KMAKEENV= ${WMAKEENV:NSYSROOT=*}
KMAKE= ${KMAKEENV} ${MAKE} ${.MAKEFLAGS} ${KERNEL_FLAGS} KERNEL=${INSTKERNNAME}
#
# buildworld
#
# Attempt to rebuild the entire system, with reasonable chance of
# success, regardless of how old your existing system is.
#
_sanity_check: .PHONY .MAKE
.if ${.CURDIR:C/[^,]//g} != ""
# The m4 build of sendmail files doesn't like it if ',' is used
# anywhere in the path of it's files.
@echo
@echo "*** Error: path to source tree contains a comma ','"
@echo
@false
.elif ${.CURDIR:M*\:*} != ""
# Using ':' leaks into PATH and breaks finding cross-tools.
@echo
@echo "*** Error: path to source tree contains a colon ':'"
@echo
@false
.endif
# Our current approach to dependency tracking cannot cope with certain source
# tree changes, particularly with respect to removing source files and
# replacing generated files. Handle these cases here in an ad-hoc fashion.
_cleanobj_fast_depend_hack: .PHONY
2018-04-04 22:46:30 +00:00
# Syscall stubs rewritten in C and obsolete MD assembly implementations
# Date SVN Rev Syscalls
# 20180604 r334626 brk sbrk
.for f in brk sbrk
@if [ -e "${OBJTOP}/lib/libc/.depend.${f}.o" ] && \
egrep -qw '${f}\.[sS]' ${OBJTOP}/lib/libc/.depend.${f}.o; then \
echo "Removing stale dependencies for ${f} syscall wrappers"; \
rm -f ${OBJTOP}/lib/libc/.depend.${f}.* \
${LIBCOMPAT:D${LIBCOMPAT_OBJTOP}/lib/libc/.depend.${f}.*}; \
fi
.endfor
# 20181013 r339348 bcopy reimplemented as .c
.for f in bcopy memcpy memmove
@if [ -e "${OBJTOP}/lib/libc/.depend.${f}.o" ] && \
egrep -qw 'bcopy\.[sS]' ${OBJTOP}/lib/libc/.depend.${f}.o; then \
echo "Removing stale dependencies for bcopy"; \
rm -f ${OBJTOP}/lib/libc/.depend.${f}.* \
${LIBCOMPAT:D${LIBCOMPAT_OBJTOP}/lib/libc/.depend.${f}.*}; \
fi
.endfor
# 20181115 r340463 bzero reimplemented as .c
@if [ -e "${OBJTOP}/lib/libc/.depend.bzero.o" ] && \
egrep -qw 'bzero\.[sS]' ${OBJTOP}/lib/libc/.depend.bzero.o; then \
echo "Removing stale dependencies for bzero"; \
rm -f ${OBJTOP}/lib/libc/.depend.bzero.* \
${LIBCOMPAT:D${LIBCOMPAT_OBJTOP}/lib/libc/.depend.bzero.*}; \
fi
# 20181009 track migration from ntp's embedded libevent to updated one
@if [ -e "${OBJTOP}/usr.sbin/ntp/libntpevent/.depend.bufferevent_openssl.o" ] && \
egrep -q 'contrib/ntp/sntp/libevent/bufferevent_openssl.c' \
${OBJTOP}/usr.sbin/ntp/libntpevent/.depend.bufferevent_openssl.o ; then \
echo "Removing stale libevent dependencies"; \
rm -f ${OBJTOP}/usr.sbin/ntp/libntpevent/.depend.*; \
fi
# 20181209 r341759 track migration across wpa update
@if [ -e "${OBJTOP}/usr.sbin/wpa/wpa_supplicant/.depend.rrm.o" ] && \
egrep -q 'src/ap/rrm.c' \
${OBJTOP}/usr.sbin/wpa/wpa_supplicant/.depend.rrm.o; then \
echo "Removing stale wpa dependencies"; \
rm -f ${OBJTOP}/usr.sbin/wpa/*/.depend*; \
fi
_worldtmp: .PHONY
@echo
@echo "--------------------------------------------------------------"
@echo ">>> Rebuilding the temporary build tree"
@echo "--------------------------------------------------------------"
.if !defined(NO_CLEAN)
rm -rf ${WORLDTMP}
.else
# Note: for delete-old we need to set $PATH to also include the host $PATH
# since otherwise a partial build with missing symlinks in ${WORLDTMP}/legacy/
# will fail to run due to missing binaries. $WMAKE sets PATH to only ${TMPPATH}
# so we remove that assingnment from $WMAKE and prepend the new $PATH
${_+_}@if [ -e "${WORLDTMP}" ]; then \
echo ">>> Deleting stale files in build tree..."; \
cd ${.CURDIR}; env PATH=${TMPPATH}:${PATH} ${WMAKE:NPATH=*} \
_NO_INCLUDE_COMPILERMK=t -DBATCH_DELETE_OLD_FILES delete-old \
delete-old-libs >/dev/null; \
fi
rm -rf ${WORLDTMP}/legacy/usr/include
.if ${USING_SYSTEM_COMPILER} == "yes"
.for cc in cc c++
if [ -x ${WORLDTMP}/usr/bin/${cc} ]; then \
inum=$$(stat -f %i ${WORLDTMP}/usr/bin/${cc}); \
find ${WORLDTMP}/usr/bin -inum $${inum} -delete; \
fi
.endfor
.endif # ${USING_SYSTEM_COMPILER} == "yes"
.if ${USING_SYSTEM_LINKER} == "yes"
@rm -f ${WORLDTMP}/usr/bin/ld ${WORLDTMP}/usr/bin/ld.lld
.endif # ${USING_SYSTEM_LINKER} == "yes"
.endif # !defined(NO_CLEAN)
@mkdir -p ${WORLDTMP}
@touch ${WORLDTMP}/${.TARGET}
# We can't use mtree to create the worldtmp directories since it may not be
# available on the target system (this happens e.g. when building on non-FreeBSD)
cd ${.CURDIR}/tools/build; \
${MAKE} DIRPRFX=tools/build/ DESTDIR=${WORLDTMP}/legacy installdirs
# In order to build without inheriting $PATH we need to add symlinks to the host
# tools in $WORLDTMP for the tools that we don't build during bootstrap-tools
cd ${.CURDIR}/tools/build; \
${MAKE} DIRPRFX=tools/build/ DESTDIR=${WORLDTMP}/legacy host-symlinks
_legacy:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 1.1: legacy release compatibility shims"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${BMAKE} legacy
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_bootstrap-tools:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 1.2: bootstrap tools"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${BMAKE} bootstrap-tools
mkdir -p ${WORLDTMP}/usr ${WORLDTMP}/lib/casper ${WORLDTMP}/lib/geom
${WORLDTMP_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
-p ${WORLDTMP}/usr >/dev/null
${WORLDTMP_MTREE} -f ${.CURDIR}/etc/mtree/BSD.include.dist \
-p ${WORLDTMP}/usr/include >/dev/null
ln -sf ${.CURDIR}/sys ${WORLDTMP}
.if ${MK_DEBUG_FILES} != "no"
${WORLDTMP_MTREE} -f ${.CURDIR}/etc/mtree/BSD.debug.dist \
-p ${WORLDTMP}/usr/lib >/dev/null
.endif
.for _mtree in ${LOCAL_MTREE}
${WORLDTMP_MTREE} -f ${.CURDIR}/${_mtree} -p ${WORLDTMP} > /dev/null
.endfor
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_cleanobj:
.if !defined(NO_CLEAN)
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.1: cleaning up the object tree"
@echo "--------------------------------------------------------------"
# Avoid including bsd.compiler.mk in clean and obj with _NO_INCLUDE_COMPILERMK
# since the restricted $PATH might not contain a valid cc binary
${_+_}cd ${.CURDIR}; ${WMAKE} _NO_INCLUDE_COMPILERMK=t ${CLEANDIR}
.if defined(LIBCOMPAT)
${_+_}cd ${.CURDIR}; ${LIBCOMPATWMAKE} _NO_INCLUDE_COMPILERMK=t -f Makefile.inc1 ${CLEANDIR}
.endif
.else
${_+_}cd ${.CURDIR}; ${WMAKE} _NO_INCLUDE_COMPILERMK=t _cleanobj_fast_depend_hack
.endif # !defined(NO_CLEAN)
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_obj:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.2: rebuilding the object tree"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${WMAKE} _NO_INCLUDE_COMPILERMK=t obj
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_build-tools:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.3: build tools"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${TMAKE} build-tools
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_cross-tools:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 3: cross tools"
@echo "--------------------------------------------------------------"
@rm -f ${OBJTOP}/toolchain-metadata.mk
${_+_}cd ${.CURDIR}; ${XMAKE} cross-tools
${_+_}cd ${.CURDIR}; ${XMAKE} kernel-tools
_build-metadata:
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 3.1: recording build metadata"
Cache compiler metadata and reuse it at installworld time. Right after cross-tools, a compiler-metadata.mk file is created that stores all of the bsd.compiler.mk metadata. It is then read in with a fail-safe during installworld time. The file is explicitly removed when invoking cross-tools to ensure that a stale file is not left around from odd manual 'make _cross-tools' -> 'make installworld' invocations. This fixes several issues: - With WITH_SYSTEM_COMPILER (default yes on head and no on releng/11.0): If you build on a system where the bootstrap compiler does not build due to the host compiler matching the in-tree one, but then installworld on another system where that logic fails (a bootstrap compiler is needed), the installworld immediately fails with: sh: cc: not found Note that fixing this logic may then hit a case where a rebuild is attempted in installworld. Normally cc would be ran with 'CFLAGS+=ERROR-tried-to-rebuild-during-make-install' to cause an error such as: cc: error: no such file or directory: 'ERROR-tried-to-rebuild-during-make-install' However, now it will just fail with the 'cc: not found' error. Inspection of the compile line will show 'ERROR-tried-to-rebuild-during-make-install'; It's not useful to set CC to anything other than 'cc' during install as it is more helpful to see the attempted compile rather than some other bogus error. - This now avoids running bsd.compiler.mk (cc executions) even more during installworld. There are compiler-dependent SUBDIR in the tree which required having a compiler during install. There is at least 1 case where CC is still executed in the install, such as from a LOOKUP!= in secure/lib/libcrypto/Makefile.inc checking for 'vzeroall' support. This is not significant for installworld as the lookup has a fallback (and hides its error) and only modifies CFLAGS, thus it's not worth fixing. PR: 212877 MFC after: 2 weeks Sponsored by: Dell EMC Isilon
2017-04-13 22:07:34 +00:00
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${WMAKE} toolchain-metadata.mk
${_+_}cd ${.CURDIR}; ${WMAKE} host-osreldate.h
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_includes:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 4.1: building includes"
@echo "--------------------------------------------------------------"
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
# Special handling for SUBDIR_OVERRIDE in buildworld as they most likely need
# headers from default SUBDIR. Do SUBDIR_OVERRIDE includes last.
${_+_}cd ${.CURDIR}; ${WMAKE} SUBDIR_OVERRIDE= SHARED=symlinks \
MK_INCLUDES=yes includes
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
.if !empty(SUBDIR_OVERRIDE) && make(buildworld)
${_+_}cd ${.CURDIR}; ${WMAKE} MK_INCLUDES=yes SHARED=symlinks includes
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
.endif
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
_libraries:
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 4.2: building libraries"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; \
${WMAKE} -DNO_FSCHG MK_HTML=no -DNO_LINT MK_MAN=no \
MK_PROFILE=no MK_TESTS=no MK_TESTS_SUPPORT=${MK_TESTS} libraries
everything: .PHONY
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 4.3: building everything"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; _PARALLEL_SUBDIR_OK=1 ${WMAKE} all
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
WMAKE_TGTS=
.if !defined(WORLDFAST)
WMAKE_TGTS+= _sanity_check _worldtmp _legacy
Let SUBDIR_OVERRIDE with 'make buildworld' be more useful. Now it can be used to effectively "build in a subdir". It will use the 'cross-tools', 'libraries', and 'includes' phases of 'buildworld' to properly setup a WORLDTMP to use. Then it will build 'everything' only in the listed SUBDIR_OVERRIDE directories. It is still required to list custom library directories in LOCAL_LIB_DIRS if SUBDIR_OVERRIDE is something that contains libraries outside of the normal area (such as SUBDIR_OVERRIDE=contrib/ofed needing LOCAL_LIB_DIRS=contrib/ofed/usr.lib) Without these changes, SUBDIR_OVERRIDE with buildworld was broken or hit obscure failures due to missing libraries, includes, or cross compiler. SUBDIR_OVERRIDE with 'make <target that is not buildworld>' will continue to work as it did before although its usefulness is questionable. With a fully populated WORLDTMP, building with a SUBDIR_OVERRIDE with -DNO_CLEAN only takes a few minutes to start building the target directories. This is still much better than building unneeded things via 'everything' when testing small subset changes. A BUILDFAST or SKIPWORLDTMP might make sense for this as well. - Add in '_worldtmp' as we still need to create WORLDTMP as later targets, such as '_libraries' and '_includes' use it. This probably was avoiding calling '_worldtmp' to not remove WORLDTMP for debugging purposes, but -DNO_CLEAN can be used for that. - '_legacy' must be included since '_build-tools' uses -legacy. The SUBDIR_OVERRIDE change came in r95509, while -legacy being part of build-tools came in r113136. - 'bootstrap-tools' is still skipped as this feature is not for upgrades. - Fix buildworld combined with SUBDIR_OVERRIDE not installing all includes. The original change for SUBDIR_OVERRIDE in r95509 kept '_includes' and '_libraries' as building everything possible as the SUBDIR_OVERRIDE could need anything from them. However in r96462 the real 'includes' target was changed from manual sub-makes to just recursing 'includes' on SUBDIR, thus not all includes have been installed into WORLDTMP since then when combined with 'buildworld'. This is not done unless calling 'make buildworld' as it would be unexpected to have it go into all directories when doing 'make SUBDIR_OVERRIDE=mydir includes'. - Also need to build the cross-compiler so it is used with --sysroot. If this is burdensome then telling the build to use the local compiler as an external compiler (thus using a proper --sysroot to WORLDTMP) is possible by setting CC=/usr/bin/cc, CXX=/usr/bin/c++, etc. - Don't build the lib32 distribution with SUBDIR_OVERRIDE in buildworld since it won't contain anything related to SUBDIR_OVERRIDE. Testing of the lib32 build can be done with 'make build32'. - Document these changes in build.7 Sponsored by: EMC / Isilon Storage Division MFC after: 2 weeks
2015-10-22 00:07:48 +00:00
.if empty(SUBDIR_OVERRIDE)
WMAKE_TGTS+= _bootstrap-tools
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
.endif
WMAKE_TGTS+= _cleanobj
.if !defined(NO_OBJWALK)
WMAKE_TGTS+= _obj
.endif
WMAKE_TGTS+= _build-tools _cross-tools
WMAKE_TGTS+= _build-metadata
WMAKE_TGTS+= _includes
.endif
.if !defined(NO_LIBS)
WMAKE_TGTS+= _libraries
.endif
WMAKE_TGTS+= everything
.if defined(LIBCOMPAT) && empty(SUBDIR_OVERRIDE)
WMAKE_TGTS+= build${libcompat}
.endif
Milestone #1 in cross-arch make releases. Do not install games and profiled libraries to the ${CHROOTDIR} with the initial installworld. Eliminate the need in the second installworld. For that, make sure _everything_ is built in the "world" environment, using the right tool chain. Added SUBDIR_OVERRIDE helper stuff to Makefile.inc1. Split the buildworld process into stages, and skip some stages when SUBDIR_OVERRIDE is set (used to build crypto, krb4, and krb5 dists). Added NO_MAKEDB_RUN knob to Makefile.inc1 to avoid running makewhatis(1) at the end of installworld (used when making crypto, krb4, and krb5 dists). In release/scripts/doFS.sh, ensure that the correct boot blocks are used. Moved the creation of the "crypto" dist from release.5 to release.2. In release.3 and doMFSKERN, build kernels in the "world" environment. KERNELS now means "additional" kernels, GENERIC is always built. Ensure we build crunched binaries in the "world" environment. Obfuscate release/Makefile some more (WMAKEENV) to achieve this. Inline createBOOTMFS target. Use already built GENERIC kernel modules to augment mfsfd's /stand/modules. GC doMODULES as such. Assorted fixes: Get rid of the "afterdistribute" target by moving the single use of it from sys/Makefile to etc/Makefile's "distribute". Makefile.inc1: apparently "etc" no longer needs to be last for "distribute" to succeed. gnu/usr.bin/perl/library/Makefile.inc: do not override the "install" and "distribute" targets, do it the "canonical" way. release/scripts/{man,cat}pages-make.sh: make sure Perl manpages and catpages appear in the right dists. Note that because Perl does not respect the MANBUILDCAT (and NOMAN), this results in a loss of /usr/share/perl/man/cat* empty directories. This will be fixed soon. Turn MAKE_KERBEROS4 into a plain boolean variable (if it is set it means "make KerberosIV"), as documented in the make.conf(5) manpage. Most of the userland makefiles did not test it for "YES" anyway. XXX Should specialized kerberized libpam versions be included into the krb4 and krb5 dists? (libpam.a would be incorrect anyway if both krb4 and krb5 dists were choosen.) Make sure "games" dist is made before "catpages", otherwise games catpages settle in the wrong dist. Fast build machine provided by: Igor Kucherenko <kivvy@sunbay.com>
2002-04-26 17:55:27 +00:00
# record buildworld time in seconds
.if make(buildworld)
_BUILDWORLD_START!= date '+%s'
.export _BUILDWORLD_START
.endif
buildworld: buildworld_prologue ${WMAKE_TGTS} buildworld_epilogue .PHONY
.ORDER: buildworld_prologue ${WMAKE_TGTS} buildworld_epilogue
buildworld_prologue: .PHONY
@echo "--------------------------------------------------------------"
@echo ">>> World build started on `LC_ALL=C date`"
@echo "--------------------------------------------------------------"
buildworld_epilogue: .PHONY
@echo
@echo "--------------------------------------------------------------"
@echo ">>> World build completed on `LC_ALL=C date`"
@seconds=$$(($$(date '+%s') - ${_BUILDWORLD_START})); \
echo -n ">>> World built in $$seconds seconds, "; \
echo "ncpu: $$(sysctl -n hw.ncpu)${.MAKE.JOBS:S/^/, make -j/}"
@echo "--------------------------------------------------------------"
#
# We need to have this as a target because the indirection between Makefile
# and Makefile.inc1 causes the correct PATH to be used, rather than a
# modification of the current environment's PATH. In addition, we need
# to quote multiword values.
#
buildenvvars: .PHONY
@echo ${WMAKEENV:Q} ${.MAKE.EXPORTED:@v@$v=\"${$v}\"@}
.if ${.TARGETS:Mbuildenv}
.if ${.MAKEFLAGS:M-j}
.error The buildenv target is incompatible with -j
.endif
.endif
BUILDENV_DIR?= ${.CURDIR}
#
# Note: make will report any errors the shell reports. This can
# be odd if the last command in an interactive shell generates an
# error or is terminated by SIGINT. These reported errors look bad,
# but are harmless. Allowing them also allows BUIDLENV_SHELL to
# be a complex command whose status will be returned to the caller.
# Some scripts in tools rely on this behavior to report build errors.
#
buildenv: .PHONY
@echo Entering world for ${TARGET_ARCH}:${TARGET}
.if ${BUILDENV_SHELL:M*zsh*}
@echo For ZSH you must run: export CPUTYPE=${TARGET_CPUTYPE}
.endif
@cd ${BUILDENV_DIR} && env ${WMAKEENV} BUILDENV=1 ${BUILDENV_SHELL}
TOOLCHAIN_TGTS= ${WMAKE_TGTS:Neverything:Nbuild${libcompat}}
toolchain: ${TOOLCHAIN_TGTS} .PHONY
KERNEL_TOOLCHAIN_TGTS= ${TOOLCHAIN_TGTS:N_obj:N_cleanobj:N_includes:N_libraries}
.if make(kernel-toolchain)
.ORDER: ${KERNEL_TOOLCHAIN_TGTS}
.endif
kernel-toolchain: ${KERNEL_TOOLCHAIN_TGTS} .PHONY
#
# installcheck
#
# Checks to be sure system is ready for installworld/installkernel.
#
installcheck: _installcheck_world _installcheck_kernel .PHONY
_installcheck_world: .PHONY
@echo "--------------------------------------------------------------"
@echo ">>> Install check world"
@echo "--------------------------------------------------------------"
_installcheck_kernel: .PHONY
@echo "--------------------------------------------------------------"
@echo ">>> Install check kernel"
@echo "--------------------------------------------------------------"
#
# Require DESTDIR to be set if installing for a different architecture or
# using the user/group database in the source tree.
#
.if ${TARGET_ARCH} != ${MACHINE_ARCH} || ${TARGET} != ${MACHINE} || \
defined(DB_FROM_SRC)
.if !make(distributeworld)
_installcheck_world: __installcheck_DESTDIR
_installcheck_kernel: __installcheck_DESTDIR
__installcheck_DESTDIR: .PHONY
.if !defined(DESTDIR) || empty(DESTDIR)
@echo "ERROR: Please set DESTDIR!"; \
false
.endif
.endif
.endif
.if !defined(DB_FROM_SRC)
#
# Check for missing UIDs/GIDs.
#
CHECK_UIDS= auditdistd
CHECK_GIDS= audit
CHECK_UIDS+= ntpd
CHECK_GIDS+= ntpd
CHECK_UIDS+= proxy
CHECK_GIDS+= proxy authpf
CHECK_UIDS+= smmsp
CHECK_GIDS+= smmsp
CHECK_UIDS+= unbound
CHECK_GIDS+= unbound
_installcheck_world: __installcheck_UGID
__installcheck_UGID: .PHONY
.for uid in ${CHECK_UIDS}
@if ! `id -u ${uid} >/dev/null 2>&1`; then \
echo "ERROR: Required ${uid} user is missing, see /usr/src/UPDATING."; \
false; \
fi
.endfor
.for gid in ${CHECK_GIDS}
@if ! `find / -prune -group ${gid} >/dev/null 2>&1`; then \
echo "ERROR: Required ${gid} group is missing, see /usr/src/UPDATING."; \
false; \
fi
.endfor
.endif
#
# If installing over the running system (DESTDIR is / or unset) and the install
# includes rescue, try running rescue from the objdir as a sanity check. If
# rescue is not functional (e.g., because it depends on a system call not
# supported by the currently running kernel), abort the installation.
#
.if !make(distributeworld) && ${MK_RESCUE} != "no" && \
(empty(DESTDIR) || ${DESTDIR} == "/") && empty(BYPASS_INSTALLCHECK_SH)
_installcheck_world: __installcheck_sh_check
__installcheck_sh_check: .PHONY
@if [ "`${OBJTOP}/rescue/rescue/rescue sh -c 'echo OK'`" != \
OK ]; then \
echo "rescue/sh check failed, installation aborted" >&2; \
false; \
fi
.endif
#
# Required install tools to be saved in a scratch dir for safety.
#
.if ${MK_ZONEINFO} != "no"
_zoneinfo= zic tzsetup
.endif
ITOOLS= [ awk cap_mkdb cat chflags chmod chown cmp cp \
date echo egrep find grep id install ${_install-info} \
ln make mkdir mtree mv pwd_mkdb \
rm sed services_mkdb sh sort strip sysctl test true uname wc ${_zoneinfo} \
${LOCAL_ITOOLS}
# Needed for share/man
.if ${MK_MAN_UTILS} != "no"
ITOOLS+=makewhatis
.endif
#
# distributeworld
#
# Distributes everything compiled by a `buildworld'.
#
# installworld
#
# Installs everything compiled by a 'buildworld'.
#
# Non-base distributions produced by the base system
EXTRA_DISTRIBUTIONS=
.if defined(LIBCOMPAT)
EXTRA_DISTRIBUTIONS+= lib${libcompat}
.endif
.if ${MK_TESTS} != "no"
EXTRA_DISTRIBUTIONS+= tests
.endif
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
DEBUG_DISTRIBUTIONS=
.if ${MK_DEBUG_FILES} != "no"
DEBUG_DISTRIBUTIONS+= base ${EXTRA_DISTRIBUTIONS:S,tests,,}
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
.endif
MTREE_MAGIC?= mtree 2.0
distributeworld installworld stageworld: _installcheck_world .PHONY
mkdir -p ${INSTALLTMP}
progs=$$(for prog in ${ITOOLS}; do \
if progpath=`which $$prog`; then \
echo $$progpath; \
else \
echo "Required tool $$prog not found in PATH." >&2; \
exit 1; \
fi; \
done); \
libs=$$(ldd -f "%o %p\n" -f "%o %p\n" $$progs 2>/dev/null | sort -u | \
while read line; do \
set -- $$line; \
if [ "$$2 $$3" != "not found" ]; then \
echo $$2; \
else \
echo "Required library $$1 not found." >&2; \
exit 1; \
fi; \
done); \
cp $$libs $$progs ${INSTALLTMP}
cp -R $${PATH_LOCALE:-"/usr/share/locale"} ${INSTALLTMP}/locale
.if defined(NO_ROOT)
-mkdir -p ${METALOG:H}
echo "#${MTREE_MAGIC}" > ${METALOG}
.endif
.if make(distributeworld)
.for dist in ${EXTRA_DISTRIBUTIONS}
-mkdir ${DESTDIR}/${DISTDIR}/${dist}
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.root.dist \
-p ${DESTDIR}/${DISTDIR}/${dist} >/dev/null
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr >/dev/null
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.include.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr/include >/dev/null
.if ${MK_DEBUG_FILES} != "no"
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.debug.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr/lib >/dev/null
.endif
.if defined(LIBCOMPAT)
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.lib${libcompat}.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr >/dev/null
.if ${MK_DEBUG_FILES} != "no"
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.lib${libcompat}.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr/lib/debug/usr >/dev/null
.endif
.endif
.if ${MK_TESTS} != "no" && ${dist} == "tests"
-mkdir -p ${DESTDIR}/${DISTDIR}/${dist}${TESTSBASE}
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.tests.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}${TESTSBASE} >/dev/null
.if ${MK_DEBUG_FILES} != "no"
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.tests.dist \
-p ${DESTDIR}/${DISTDIR}/${dist}/usr/lib/debug/${TESTSBASE} >/dev/null
.endif
.endif
.if defined(NO_ROOT)
${IMAKEENV} ${MTREE} -C -f ${.CURDIR}/etc/mtree/BSD.root.dist | \
sed -e 's#^\./#./${dist}/#' >> ${METALOG}
${IMAKEENV} ${MTREE} -C -f ${.CURDIR}/etc/mtree/BSD.usr.dist | \
sed -e 's#^\./#./${dist}/usr/#' >> ${METALOG}
${IMAKEENV} ${MTREE} -C -f ${.CURDIR}/etc/mtree/BSD.include.dist | \
sed -e 's#^\./#./${dist}/usr/include/#' >> ${METALOG}
.if defined(LIBCOMPAT)
${IMAKEENV} ${MTREE} -C -f ${.CURDIR}/etc/mtree/BSD.lib${libcompat}.dist | \
sed -e 's#^\./#./${dist}/usr/#' >> ${METALOG}
.endif
.endif
.endfor
-mkdir ${DESTDIR}/${DISTDIR}/base
${_+_}cd ${.CURDIR}/etc; ${CROSSENV} PATH=${TMPPATH} ${MAKE} \
METALOG=${METALOG} ${IMAKE_INSTALL} ${IMAKE_MTREE} \
DISTBASE=/base DESTDIR=${DESTDIR}/${DISTDIR}/base \
LOCAL_MTREE=${LOCAL_MTREE:Q} distrib-dirs
${INSTALL_SYMLINK} ${INSTALLFLAGS} usr/src/sys ${INSTALL_DDIR}/base/sys
.endif
${_+_}cd ${.CURDIR}; ${IMAKE} re${.TARGET:S/world$//}; \
${IMAKEENV} rm -rf ${INSTALLTMP}
.if make(distributeworld)
.for dist in ${EXTRA_DISTRIBUTIONS}
find ${DESTDIR}/${DISTDIR}/${dist} -mindepth 1 -type d -empty -delete
.endfor
.if defined(NO_ROOT)
.for dist in base ${EXTRA_DISTRIBUTIONS}
@# For each file that exists in this dist, print the corresponding
@# line from the METALOG. This relies on the fact that
@# a line containing only the filename will sort immediately before
@# the relevant mtree line.
cd ${DESTDIR}/${DISTDIR}; \
find ./${dist} | sort -u ${METALOG} - | \
awk 'BEGIN { print "#${MTREE_MAGIC}" } !/ type=/ { file = $$1 } / type=/ { if ($$1 == file) { sub(/^\.\/${dist}\//, "./"); print } }' > \
${DESTDIR}/${DISTDIR}/${dist}.meta
.endfor
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
.for dist in ${DEBUG_DISTRIBUTIONS}
@# For each file that exists in this dist, print the corresponding
@# line from the METALOG. This relies on the fact that
@# a line containing only the filename will sort immediately before
@# the relevant mtree line.
cd ${DESTDIR}/${DISTDIR}; \
find ./${dist}/usr/lib/debug | sort -u ${METALOG} - | \
awk 'BEGIN { print "#${MTREE_MAGIC}" } !/ type=/ { file = $$1 } / type=/ { if ($$1 == file) { sub(/^\.\/${dist}\//, "./"); print } }' > \
${DESTDIR}/${DISTDIR}/${dist}.debug.meta
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
.endfor
.endif
.endif
packageworld: .PHONY
.for dist in base ${EXTRA_DISTRIBUTIONS}
.if defined(NO_ROOT)
${_+_}cd ${DESTDIR}/${DISTDIR}/${dist}; \
tar cvf - --exclude usr/lib/debug \
@${DESTDIR}/${DISTDIR}/${dist}.meta | \
${XZ_CMD} > ${PACKAGEDIR}/${dist}.txz
.else
${_+_}cd ${DESTDIR}/${DISTDIR}/${dist}; \
tar cvf - --exclude usr/lib/debug . | \
${XZ_CMD} > ${PACKAGEDIR}/${dist}.txz
.endif
.endfor
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
.for dist in ${DEBUG_DISTRIBUTIONS}
. if defined(NO_ROOT)
${_+_}cd ${DESTDIR}/${DISTDIR}/${dist}; \
tar cvf - @${DESTDIR}/${DISTDIR}/${dist}.debug.meta | \
${XZ_CMD} > ${PACKAGEDIR}/${dist}-dbg.txz
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
. else
${_+_}cd ${DESTDIR}/${DISTDIR}/${dist}; \
tar cvLf - usr/lib/debug | \
${XZ_CMD} > ${PACKAGEDIR}/${dist}-dbg.txz
Merge ^/projects/release-debugdist into ^/head: r262491, r262493, r262516, r267345, r267397: r262491: Add DEBUG_DISTRIBUTIONS, and set it to include base and EXTRA_DISTRIBUTIONS, excluding 'doc', since the documentation distribution does not have corresponding debug information. Use DEBUG_DISTRIBUTIONS in the 'distributeworld installworld' and 'packageworld' targets, to reduce the number of occurances of excluding distributions that do not have .debug files. r262493: In release/Makefile, explicitly set WITHOUT_DEBUG_FILES=1 for dvdrom and cdrom targets. (Later reverted.) Exclude the *.debug.txz distributions from dvdrom and cdrom images, but include them for ftp distribution. r262516: Rename ${dist}.debug.txz to ${dist}-dbg.txz to prevent the following output: eval: ${base....}: Bad substitution eval: ${doc....}: Bad substitution eval: ${games....}: Bad substitution eval: ${lib32....}: Bad substitution This also follows other naming conventions seen in the wild. r267345: Explicitly set MK_DEBUG_FILES=no, which overrides the WITH_DEBUG_FILES=1 and WITHOUT_DEBUG_FILES=1 collisions previously experienced. This change allows us to create the {base,kernel}_debug.txz distributions without accidentally installing the *.debug files on the medium itself. r267397: Remove evaluations of MK_DEBUG_FILES where not needed. If DEBUG_DISTRIBUTIONS is empty, which is true if MK_DEBUG_FILES evaluates to 'no' above, the loop does nothing. MFC after: 1 month Tested on: head@r267801 Reviewed by: brooks [1], emaste, imp [1] [1] earlier version Sponsored by: The FreeBSD Foundation
2014-07-01 19:04:04 +00:00
. endif
.endfor
_sysent_dirs= sys/kern
_sysent_dirs+= sys/compat/freebsd32
_sysent_dirs+= sys/amd64/linux \
sys/amd64/linux32 \
sys/arm64/linux \
sys/i386/linux
sysent: .PHONY
.for _dir in ${_sysent_dirs}
${_+_}${MAKE} -C ${.CURDIR}/${_dir} sysent
.endfor
#
# reinstall
#
# If you have a build server, you can NFS mount the source and obj directories
# and do a 'make reinstall' on the *client* to install new binaries from the
# most recent server build.
#
restage reinstall: .MAKE .PHONY
@echo "--------------------------------------------------------------"
@echo ">>> Making hierarchy"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 \
LOCAL_MTREE=${LOCAL_MTREE:Q} hierarchy
.if make(restage)
@echo "--------------------------------------------------------------"
@echo ">>> Making distribution"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 \
LOCAL_MTREE=${LOCAL_MTREE:Q} distribution
.endif
@echo
@echo "--------------------------------------------------------------"
@echo ">>> Installing everything started on `LC_ALL=C date`"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 install
.if defined(LIBCOMPAT)
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 install${libcompat}
.endif
@echo "--------------------------------------------------------------"
@echo ">>> Installing everything completed on `LC_ALL=C date`"
@echo "--------------------------------------------------------------"
redistribute: .MAKE .PHONY
@echo "--------------------------------------------------------------"
2004-03-19 17:57:07 +00:00
@echo ">>> Distributing everything"
@echo "--------------------------------------------------------------"
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 distribute
.if defined(LIBCOMPAT)
${_+_}cd ${.CURDIR}; ${MAKE} -f Makefile.inc1 distribute${libcompat} \
DISTRIBUTION=lib${libcompat}
.endif
distrib-dirs distribution: .MAKE .PHONY
${_+_}cd ${.CURDIR}/etc; ${CROSSENV} PATH=${TMPPATH} ${MAKE} \
${IMAKE_INSTALL} ${IMAKE_MTREE} METALOG=${METALOG} ${.TARGET}
.if make(distribution)
${_+_}cd ${.CURDIR}; ${CROSSENV} PATH=${TMPPATH} \
${MAKE} -f Makefile.inc1 ${IMAKE_INSTALL} \
METALOG=${METALOG} MK_TESTS=no installconfig
.endif
#
# buildkernel and installkernel
#
# Which kernels to build and/or install is specified by setting
# KERNCONF. If not defined a GENERIC kernel is built/installed.
# Only the existing (depending TARGET) config files are used
# for building kernels and only the first of these is designated
# as the one being installed.
#
# Note that we have to use TARGET instead of TARGET_ARCH when
Fix cross-building, etc: 1. To cross-build, one now needs to set TARGET_ARCH, and not the MACHINE_ARCH. MACHINE_ARCH should never be changed manually! 2. Initialize DESTDIR= explicitly for bootstrap-tools, build-tools, and cross-tools stages. This fixes broken header and library dependencies problem. We build them in the host environment, and obviously want them to depend on host headers and libraries. The problem with broken header dependencies for bootstrap-tools and cross-tools was already partially solved (see BOOTSTRAPPING tests in bsd.prog.mk and bsd.lib.mk), but it was still there for build-tools if the user ran "make world DESTDIR=/foo". Also, for all of these stages, the library dependencies were broken because of how bsd.libnames.mk define DPADD members. We still provide a glue to install bootstrap- and cross-tools under the ${WORLDTMP}. Removed PATH overrides for bootstrap-, build-, and cross-tools stages. There is just no reason why we would need to override it, and the hacks to clean up the ${WORLDTMP} in the -DNOCLEAN case are no longer needed with fixes from this step. That is, we now never use ${WORLDTMP} headers and libraries, and we don't use any ${WORLDTMP} installed binaries during these stages. Again, these stages depend solely on the host environment, including compiler, headers, and libraries. 3. Moved "miniperl" back from cross-tools (it has nothing to do with a cross-compiler) to build-tools where it belongs. The change from step 1 let to do this. Also, to make this work, build-tools targets of "cc_tools" and "miniperl" were modified to call "depend". Here follow the detailed explanations. There are two categories of build tools, for now. In the first category there are "cc_tools" and "miniperl". They occupy the whole (sub)directory, and nothing needs to be done in this subdirectory later during the "all" stage. They are also constructed using system makefiles. We must build the .depend early in the build-tools stage because: 1) They use (and depend on) the host environment. 2) If we don't do this in build-tools, the "depend" stage of buildworld will do this for us; wrong library and header dependencies will be recorded (DESTDIR=${WORLDTMP}) and, what's worse, the "all" stage may then clobber the build-architecture format tools (that we built in the build-tools stage) with the target-architecture format ones, breaking cross build. In the second category there are all other build-tools. They share their directory with the "main" module that needs them in the "all" stage, and they don't show up themselves in the .depend file. The portion of this fix was already committed in gnu/usr.bin/cc/cc_tools/Makefile,v 1.52. 4. "libperl" is no longer a build tool, and "miniperl" is the stand-alone application. I had to make this change because build-tools and "all" stages share the same object directory. Without this change, if we cross compile, libperl.a is first built for the build architecture during the build-tools stage (for the purposes of immediate linkage with "miniperl"). Later on, the "all" stage sees this library as up-to-date, and doesn't rebuild it. The effect is that the wrong format static libperl library is installed with installworld. 5. Fixed "includes" to install secure/lib/libtelnet headers if required. Reviewed by: bde
2001-09-29 13:17:54 +00:00
# we're in kernel-land. Since only TARGET_ARCH is (expected) to
# be set to cross-build, we have to make sure TARGET is set
# properly.
.if defined(KERNFAST)
NO_KERNELCLEAN= t
NO_KERNELCONFIG= t
NO_KERNELOBJ= t
# Shortcut for KERNCONF=Blah -DKERNFAST is now KERNFAST=Blah
.if !defined(KERNCONF) && ${KERNFAST} != "1"
KERNCONF=${KERNFAST}
.endif
.endif
.if ${TARGET_ARCH} == "powerpc64"
KERNCONF?= GENERIC64
.else
KERNCONF?= GENERIC
.endif
INSTKERNNAME?= kernel
KERNSRCDIR?= ${.CURDIR}/sys
KRNLCONFDIR= ${KERNSRCDIR}/${TARGET}/conf
KRNLOBJDIR= ${OBJTOP}${KERNSRCDIR:C,^${.CURDIR},,}
KERNCONFDIR?= ${KRNLCONFDIR}
BUILDKERNELS=
INSTALLKERNEL=
.if defined(NO_INSTALLKERNEL)
# All of the BUILDKERNELS loops start at index 1.
BUILDKERNELS+= dummy
.endif
.for _kernel in ${KERNCONF}
.if !defined(_MKSHOWCONFIG) && exists(${KERNCONFDIR}/${_kernel})
BUILDKERNELS+= ${_kernel}
.if empty(INSTALLKERNEL) && !defined(NO_INSTALLKERNEL)
INSTALLKERNEL= ${_kernel}
.endif
.else
.if make(buildkernel)
.error Missing KERNCONF ${KERNCONFDIR}/${_kernel}
.endif
.endif
.endfor
_cleankernobj_fast_depend_hack: .PHONY
# 20180320 remove stale generated assym.s after renaming to .inc in r331254
@if [ -e "${OBJTOP}/sys/${KERNCONF}/assym.s" ]; then \
echo "Removing stale generated assym files"; \
rm -f ${OBJTOP}/sys/${KERNCONF}/assym.* \
${OBJTOP}/sys/${KERNCONF}/.depend.assym.*; \
fi
${WMAKE_TGTS:N_worldtmp:Nbuild${libcompat}} ${.ALLTARGETS:M_*:N_worldtmp}: .MAKE .PHONY
# record kernel(s) build time in seconds
.if make(buildkernel)
_BUILDKERNEL_START!= date '+%s'
.endif
#
# buildkernel
#
# Builds all kernels defined by BUILDKERNELS.
#
buildkernel: .MAKE .PHONY
.if empty(BUILDKERNELS:Ndummy)
2005-02-27 11:48:45 +00:00
@echo "ERROR: Missing kernel configuration file(s) (${KERNCONF})."; \
false
.endif
@echo
.for _kernel in ${BUILDKERNELS:Ndummy}
@echo "--------------------------------------------------------------"
@echo ">>> Kernel build for ${_kernel} started on `LC_ALL=C date`"
@echo "--------------------------------------------------------------"
@echo "===> ${_kernel}"
mkdir -p ${KRNLOBJDIR}
.if !defined(NO_KERNELCONFIG)
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 1: configuring the kernel"
@echo "--------------------------------------------------------------"
cd ${KRNLCONFDIR}; \
PATH=${TMPPATH} \
config ${CONFIGARGS} -d ${KRNLOBJDIR}/${_kernel} \
-I '${KERNCONFDIR}' '${KERNCONFDIR}/${_kernel}'
.endif
.if !defined(NO_CLEAN) && !defined(NO_KERNELCLEAN)
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.1: cleaning up the object tree"
@echo "--------------------------------------------------------------"
${_+_}cd ${KRNLOBJDIR}/${_kernel}; ${KMAKE} ${CLEANDIR}
.else
${_+_}cd ${.CURDIR}; ${WMAKE} _cleankernobj_fast_depend_hack
.endif
.if !defined(NO_KERNELOBJ)
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.2: rebuilding the object tree"
@echo "--------------------------------------------------------------"
${_+_}cd ${KRNLOBJDIR}/${_kernel}; ${KMAKE} obj
.endif
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 2.3: build tools"
@echo "--------------------------------------------------------------"
This change builds kernel tools based on the same assumption as building the kernel itself: If building for the same architecture as the build host, the kernel build assumes that the host toolchain is capable of building the kernel. If it's not, "make kernel-toolchain" will bootstrap a new set of tools that will work. With this change the same assumptions are made for building kernel tools, and the existing host toolchain is used to do the build (notably, the build doesn't link the tools with the legacy libraries, which may not even exist). If ever for some reason the host toolchain isn't capable of building the kernel tools, then doing a "make kernel-toolchain" will bootstrap newer tools to get the job done. So when built as part of buildworld or kernel-toolchain, the kernel tools are built using the XMAKE (via BMAKE) commands and environment. When built as part of building just the kernel on a same-target host, the tools are built using the new KTMAKE commands and environment. What doesn't jump out at you in the diffs is that the difference between BMAKE and KTMAKE is that BMAKE contains this magic line which changes how the build is done because it changes what files get included for .include <bsd.prog.mk> and other standard includes: MAKEFLAGS="-m ${.CURDIR}/tools/build/mk ${.MAKEFLAGS}" and KTMAKE doesn't, and contains this instead: TOOLS_PREFIX=${WORLDTMP} Hopefully this brings the "how to build aicasm with the right toolchain" saga to a conclusion that works in all usage scenarios that have historically been supported.
2013-11-09 00:15:36 +00:00
${_+_}cd ${.CURDIR}; ${KTMAKE} kernel-tools
@echo
@echo "--------------------------------------------------------------"
@echo ">>> stage 3.1: building everything"
@echo "--------------------------------------------------------------"
${_+_}cd ${KRNLOBJDIR}/${_kernel}; ${KMAKE} all -DNO_MODULES_OBJ
@echo "--------------------------------------------------------------"
@echo ">>> Kernel build for ${_kernel} completed on `LC_ALL=C date`"
@echo "--------------------------------------------------------------"
.endfor
@seconds=$$(($$(date '+%s') - ${_BUILDKERNEL_START})); \
echo -n ">>> Kernel(s) ${BUILDKERNELS} built in $$seconds seconds, "; \
echo "ncpu: $$(sysctl -n hw.ncpu)${.MAKE.JOBS:S/^/, make -j/}"
@echo "--------------------------------------------------------------"
NO_INSTALLEXTRAKERNELS?= yes
#
# installkernel, etc.
#
# Install the kernel defined by INSTALLKERNEL
#
installkernel installkernel.debug \
reinstallkernel reinstallkernel.debug: _installcheck_kernel .PHONY
.if !defined(NO_INSTALLKERNEL)
.if empty(INSTALLKERNEL)
2005-02-27 11:48:45 +00:00
@echo "ERROR: No kernel \"${KERNCONF}\" to install."; \
false
.endif
@echo "--------------------------------------------------------------"
@echo ">>> Installing kernel ${INSTALLKERNEL} on $$(LC_ALL=C date)"
@echo "--------------------------------------------------------------"
${_+_}cd ${KRNLOBJDIR}/${INSTALLKERNEL}; \
${CROSSENV} PATH=${TMPPATH} \
${MAKE} ${IMAKE_INSTALL} KERNEL=${INSTKERNNAME} ${.TARGET:S/kernel//}
@echo "--------------------------------------------------------------"
@echo ">>> Installing kernel ${INSTALLKERNEL} completed on $$(LC_ALL=C date)"
@echo "--------------------------------------------------------------"
.endif
.if ${BUILDKERNELS:[#]} > 1 && ${NO_INSTALLEXTRAKERNELS} != "yes"
.for _kernel in ${BUILDKERNELS:[2..-1]}
@echo "--------------------------------------------------------------"
@echo ">>> Installing kernel ${_kernel} $$(LC_ALL=C date)"
@echo "--------------------------------------------------------------"
${_+_}cd ${KRNLOBJDIR}/${_kernel}; \
${CROSSENV} PATH=${TMPPATH} \
${MAKE} ${IMAKE_INSTALL} KERNEL=${INSTKERNNAME}.${_kernel} ${.TARGET:S/kernel//}
@echo "--------------------------------------------------------------"
@echo ">>> Installing kernel ${_kernel} completed on $$(LC_ALL=C date)"
@echo "--------------------------------------------------------------"
.endfor
.endif
distributekernel distributekernel.debug: .PHONY
.if !defined(NO_INSTALLKERNEL)
.if empty(INSTALLKERNEL)
@echo "ERROR: No kernel \"${KERNCONF}\" to install."; \
false
.endif
mkdir -p ${DESTDIR}/${DISTDIR}
.if defined(NO_ROOT)
@echo "#${MTREE_MAGIC}" > ${DESTDIR}/${DISTDIR}/kernel.premeta
.endif
${_+_}cd ${KRNLOBJDIR}/${INSTALLKERNEL}; \
${IMAKEENV} ${IMAKE_INSTALL:S/METALOG/kernel.premeta/} \
${IMAKE_MTREE} PATH=${TMPPATH} ${MAKE} KERNEL=${INSTKERNNAME} \
DESTDIR=${INSTALL_DDIR}/kernel \
${.TARGET:S/distributekernel/install/}
.if defined(NO_ROOT)
@sed -e 's|^./kernel|.|' ${DESTDIR}/${DISTDIR}/kernel.premeta > \
${DESTDIR}/${DISTDIR}/kernel.meta
.endif
.endif
.if ${BUILDKERNELS:[#]} > 1 && ${NO_INSTALLEXTRAKERNELS} != "yes"
.for _kernel in ${BUILDKERNELS:[2..-1]}
.if defined(NO_ROOT)
@echo "#${MTREE_MAGIC}" > ${DESTDIR}/${DISTDIR}/kernel.${_kernel}.premeta
.endif
${_+_}cd ${KRNLOBJDIR}/${_kernel}; \
${IMAKEENV} ${IMAKE_INSTALL:S/METALOG/kernel.${_kernel}.premeta/} \
${IMAKE_MTREE} PATH=${TMPPATH} ${MAKE} \
KERNEL=${INSTKERNNAME}.${_kernel} \
DESTDIR=${INSTALL_DDIR}/kernel.${_kernel} \
${.TARGET:S/distributekernel/install/}
.if defined(NO_ROOT)
@sed -e "s|^./kernel.${_kernel}|.|" \
${DESTDIR}/${DISTDIR}/kernel.${_kernel}.premeta > \
${DESTDIR}/${DISTDIR}/kernel.${_kernel}.meta
.endif
.endfor
.endif
packagekernel: .PHONY
.if defined(NO_ROOT)
.if !defined(NO_INSTALLKERNEL)
cd ${DESTDIR}/${DISTDIR}/kernel; \
tar cvf - --exclude '*.debug' \
@${DESTDIR}/${DISTDIR}/kernel.meta | \
${XZ_CMD} > ${PACKAGEDIR}/kernel.txz
.endif
.if ${MK_DEBUG_FILES} != "no"
cd ${DESTDIR}/${DISTDIR}/kernel; \
tar cvf - --include '*/*/*.debug' \
@${DESTDIR}/${DISTDIR}/kernel.meta | \
${XZ_CMD} > ${DESTDIR}/${DISTDIR}/kernel-dbg.txz
.endif
.if ${BUILDKERNELS:[#]} > 1 && ${NO_INSTALLEXTRAKERNELS} != "yes"
.for _kernel in ${BUILDKERNELS:[2..-1]}
cd ${DESTDIR}/${DISTDIR}/kernel.${_kernel}; \
tar cvf - --exclude '*.debug' \
@${DESTDIR}/${DISTDIR}/kernel.${_kernel}.meta | \
${XZ_CMD} > ${PACKAGEDIR}/kernel.${_kernel}.txz
.if ${MK_DEBUG_FILES} != "no"
cd ${DESTDIR}/${DISTDIR}/kernel.${_kernel}; \
tar cvf - --include '*/*/*.debug' \
@${DESTDIR}/${DISTDIR}/kernel.${_kernel}.meta | \
${XZ_CMD} > ${DESTDIR}/${DISTDIR}/kernel.${_kernel}-dbg.txz
.endif
.endfor
.endif
.else
.if !defined(NO_INSTALLKERNEL)
cd ${DESTDIR}/${DISTDIR}/kernel; \
tar cvf - --exclude '*.debug' . | \
${XZ_CMD} > ${PACKAGEDIR}/kernel.txz
.endif
.if ${MK_DEBUG_FILES} != "no"
cd ${DESTDIR}/${DISTDIR}/kernel; \
tar cvf - --include '*/*/*.debug' $$(eval find .) | \
${XZ_CMD} > ${DESTDIR}/${DISTDIR}/kernel-dbg.txz
.endif
.if ${BUILDKERNELS:[#]} > 1 && ${NO_INSTALLEXTRAKERNELS} != "yes"
.for _kernel in ${BUILDKERNELS:[2..-1]}
cd ${DESTDIR}/${DISTDIR}/kernel.${_kernel}; \
tar cvf - --exclude '*.debug' . | \
${XZ_CMD} > ${PACKAGEDIR}/kernel.${_kernel}.txz
.if ${MK_DEBUG_FILES} != "no"
cd ${DESTDIR}/${DISTDIR}/kernel.${_kernel}; \
tar cvf - --include '*/*/*.debug' $$(eval find .) | \
${XZ_CMD} > ${DESTDIR}/${DISTDIR}/kernel.${_kernel}-dbg.txz
.endif
.endfor
.endif
.endif
stagekernel: .PHONY
${_+_}${MAKE} -C ${.CURDIR} ${.MAKEFLAGS} distributekernel
PORTSDIR?= /usr/ports
WSTAGEDIR?= ${OBJTOP}/worldstage
KSTAGEDIR?= ${OBJTOP}/kernelstage
REPODIR?= ${OBJROOT}repo
PKGSIGNKEY?= # empty
.ORDER: stage-packages create-packages
.ORDER: create-packages create-world-packages
.ORDER: create-packages create-kernel-packages
.ORDER: create-packages sign-packages
_pkgbootstrap: .PHONY
.if make(*package*) && !exists(${LOCALBASE}/sbin/pkg)
@env ASSUME_ALWAYS_YES=YES pkg bootstrap
.endif
packages: .PHONY
${_+_}${MAKE} -C ${.CURDIR} PKG_VERSION=${PKG_VERSION} real-packages
package-pkg: .PHONY
rm -rf /tmp/ports.${TARGET} || :
env ${WMAKEENV:Q} SRCDIR=${.CURDIR} PORTSDIR=${PORTSDIR} REVISION=${_REVISION} \
PKG_CMD=${PKG_CMD} PKG_VERSION=${PKG_VERSION} REPODIR=${REPODIR} \
WSTAGEDIR=${WSTAGEDIR} \
sh ${.CURDIR}/release/scripts/make-pkg-package.sh
real-packages: stage-packages create-packages sign-packages .PHONY
stage-packages-world: .PHONY
@mkdir -p ${WSTAGEDIR}
${_+_}@cd ${.CURDIR}; \
${MAKE} DESTDIR=${WSTAGEDIR} -DNO_ROOT stageworld
stage-packages-kernel: .PHONY
@mkdir -p ${KSTAGEDIR}
${_+_}@cd ${.CURDIR}; \
${MAKE} DESTDIR=${KSTAGEDIR} -DNO_ROOT stagekernel
stage-packages: .PHONY stage-packages-world stage-packages-kernel
_repodir: .PHONY
@mkdir -p ${REPODIR}
create-packages-world: _pkgbootstrap _repodir .PHONY
${_+_}@cd ${.CURDIR}; \
${MAKE} -f Makefile.inc1 \
DESTDIR=${WSTAGEDIR} \
PKG_VERSION=${PKG_VERSION} create-world-packages
create-packages-kernel: _pkgbootstrap _repodir .PHONY
${_+_}@cd ${.CURDIR}; \
${MAKE} -f Makefile.inc1 \
DESTDIR=${KSTAGEDIR} \
PKG_VERSION=${PKG_VERSION} DISTDIR=kernel \
create-kernel-packages
create-packages: .PHONY create-packages-world create-packages-kernel
create-world-packages: _pkgbootstrap .PHONY
@rm -f ${WSTAGEDIR}/*.plist 2>/dev/null || :
@cd ${WSTAGEDIR} ; \
env -i LC_COLLATE=C sort ${WSTAGEDIR}/${DISTDIR}/METALOG | \
awk -f ${SRCDIR}/release/scripts/mtree-to-plist.awk
@for plist in ${WSTAGEDIR}/*.plist; do \
plist=$${plist##*/} ; \
pkgname=$${plist%.plist} ; \
echo "_PKGS+= $${pkgname}" ; \
done > ${WSTAGEDIR}/packages.mk
${_+_}@cd ${.CURDIR}; \
${MAKE} -f Makefile.inc1 create-world-packages-jobs \
.MAKE.JOB.PREFIX=
.if make(create-world-packages-jobs)
.include "${WSTAGEDIR}/packages.mk"
.endif
create-world-packages-jobs: .PHONY
.for pkgname in ${_PKGS}
create-world-packages-jobs: create-world-package-${pkgname}
create-world-package-${pkgname}: .PHONY
@sh ${SRCDIR}/release/packages/generate-ucl.sh -o ${pkgname} \
-s ${SRCDIR} -u ${WSTAGEDIR}/${pkgname}.ucl
@awk -F\" ' \
/^name/ { printf("===> Creating %s-", $$2); next } \
/^version/ { print $$2; next } \
' ${WSTAGEDIR}/${pkgname}.ucl
@if [ "${pkgname}" == "runtime" ]; then \
sed -i '' -e "s/%VCS_REVISION%/${VCS_REVISION}/" ${WSTAGEDIR}/${pkgname}.ucl ; \
fi
${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname -o ALLOW_BASE_SHLIBS=yes \
create -M ${WSTAGEDIR}/${pkgname}.ucl \
-p ${WSTAGEDIR}/${pkgname}.plist \
-r ${WSTAGEDIR} \
-o ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/${PKG_VERSION}
.endfor
_default_flavor= -default
.if make(*package*) && exists(${KSTAGEDIR}/kernel.meta)
. if ${MK_DEBUG_FILES} != "no"
_debug=-debug
. endif
create-kernel-packages: .PHONY
. for flavor in "" ${_debug}
create-kernel-packages: create-kernel-packages-flavor${flavor:C,^""$,${_default_flavor},}
create-kernel-packages-flavor${flavor:C,^""$,${_default_flavor},}: _pkgbootstrap .PHONY
@cd ${KSTAGEDIR}/${DISTDIR} ; \
env -i LC_COLLATE=C sort ${KSTAGEDIR}/kernel.meta | \
awk -f ${SRCDIR}/release/scripts/mtree-to-plist.awk \
-v kernel=yes -v _kernconf=${INSTALLKERNEL} ; \
sed -e "s/%VERSION%/${PKG_VERSION}/" \
-e "s/%PKGNAME%/kernel-${INSTALLKERNEL:tl}${flavor}/" \
-e "s/%KERNELDIR%/kernel/" \
-e "s/%COMMENT%/FreeBSD ${INSTALLKERNEL} kernel ${flavor}/" \
-e "s/%DESC%/FreeBSD ${INSTALLKERNEL} kernel ${flavor}/" \
-e "s/ %VCS_REVISION%/${VCS_REVISION}/" \
${SRCDIR}/release/packages/kernel.ucl \
> ${KSTAGEDIR}/${DISTDIR}/kernel.${INSTALLKERNEL}${flavor}.ucl ; \
awk -F\" ' \
/name/ { printf("===> Creating %s-", $$2); next } \
/version/ {print $$2; next } ' \
${KSTAGEDIR}/${DISTDIR}/kernel.${INSTALLKERNEL}${flavor}.ucl ; \
${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname -o ALLOW_BASE_SHLIBS=yes \
create -M ${KSTAGEDIR}/${DISTDIR}/kernel.${INSTALLKERNEL}${flavor}.ucl \
-p ${KSTAGEDIR}/${DISTDIR}/kernel.${INSTALLKERNEL}${flavor}.plist \
-r ${KSTAGEDIR}/${DISTDIR} \
-o ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/${PKG_VERSION}
. endfor
.endif
.if ${BUILDKERNELS:[#]} > 1 && ${NO_INSTALLEXTRAKERNELS} != "yes"
. for _kernel in ${BUILDKERNELS:[2..-1]}
. if exists(${KSTAGEDIR}/kernel.${_kernel}.meta)
. if ${MK_DEBUG_FILES} != "no"
_debug=-debug
. endif
. for flavor in "" ${_debug}
create-kernel-packages: create-kernel-packages-extra-flavor${flavor:C,^""$,${_default_flavor},}-${_kernel}
create-kernel-packages-extra-flavor${flavor:C,^""$,${_default_flavor},}-${_kernel}: _pkgbootstrap .PHONY
@cd ${KSTAGEDIR}/kernel.${_kernel} ; \
env -i LC_COLLATE=C sort ${KSTAGEDIR}/kernel.${_kernel}.meta | \
awk -f ${SRCDIR}/release/scripts/mtree-to-plist.awk \
-v kernel=yes -v _kernconf=${_kernel} ; \
sed -e "s/%VERSION%/${PKG_VERSION}/" \
-e "s/%PKGNAME%/kernel-${_kernel:tl}${flavor}/" \
-e "s/%KERNELDIR%/kernel.${_kernel}/" \
-e "s/%COMMENT%/FreeBSD ${_kernel} kernel ${flavor}/" \
-e "s/%DESC%/FreeBSD ${_kernel} kernel ${flavor}/" \
-e "s/ %VCS_REVISION%/${VCS_REVISION}/" \
${SRCDIR}/release/packages/kernel.ucl \
> ${KSTAGEDIR}/kernel.${_kernel}/kernel.${_kernel}${flavor}.ucl ; \
awk -F\" ' \
/name/ { printf("===> Creating %s-", $$2); next } \
/version/ {print $$2; next } ' \
${KSTAGEDIR}/kernel.${_kernel}/kernel.${_kernel}${flavor}.ucl ; \
${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname -o ALLOW_BASE_SHLIBS=yes \
create -M ${KSTAGEDIR}/kernel.${_kernel}/kernel.${_kernel}${flavor}.ucl \
-p ${KSTAGEDIR}/kernel.${_kernel}/kernel.${_kernel}${flavor}.plist \
-r ${KSTAGEDIR}/kernel.${_kernel} \
-o ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/${PKG_VERSION}
. endfor
. endif
. endfor
.endif
sign-packages: _pkgbootstrap .PHONY
@[ -L "${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/latest" ] && \
unlink ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/latest ; \
${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname repo \
-o ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/${PKG_VERSION} \
${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI)/${PKG_VERSION} \
${PKGSIGNKEY} ; \
cd ${REPODIR}/$$(${PKG_CMD} -o ABI_FILE=${WSTAGEDIR}/usr/bin/uname config ABI); \
ln -s ${PKG_VERSION} latest
#
#
# checkworld
#
# Run test suite on installed world.
#
checkworld: .PHONY
@if [ ! -x "${LOCALBASE}/bin/kyua" ]; then \
echo "You need kyua (devel/kyua) to run the test suite." | /usr/bin/fmt; \
exit 1; \
fi
${_+_}PATH="$$PATH:${LOCALBASE}/bin" kyua test -k ${TESTSBASE}/Kyuafile
#
#
# doxygen
#
# Build the API documentation with doxygen
#
doxygen: .PHONY
@if [ ! -x "${LOCALBASE}/bin/doxygen" ]; then \
echo "You need doxygen (devel/doxygen) to generate the API documentation of the kernel." | /usr/bin/fmt; \
exit 1; \
fi
${_+_}cd ${.CURDIR}/tools/kerneldoc/subsys; ${MAKE} obj all
#
# update
#
# Update the source tree(s), by running svn/svnup to update to the
# latest copy.
#
update: .PHONY
.if defined(SVN_UPDATE)
@echo "--------------------------------------------------------------"
@echo ">>> Updating ${.CURDIR} using Subversion"
@echo "--------------------------------------------------------------"
@(cd ${.CURDIR}; ${SVN_CMD} update ${SVNFLAGS})
.endif
#
# ------------------------------------------------------------------------
#
# From here onwards are utility targets used by the 'make world' and
# related targets. If your 'world' breaks, you may like to try to fix
# the problem and manually run the following targets to attempt to
# complete the build. Beware, this is *not* guaranteed to work, you
# need to have a pretty good grip on the current state of the system
# to attempt to manually finish it. If in doubt, 'make world' again.
#
#
# legacy: Build compatibility shims for the next three targets. This is a
# minimal set of tools and shims necessary to compensate for older systems
# which don't have the APIs required by the targets built in bootstrap-tools,
# build-tools or cross-tools.
#
# libnv and libl are both requirements for config(8), which is an unconditional
# bootstrap-tool.
_config_deps= lib/libnv usr.bin/lex/lib
legacy: .PHONY
.if ${BOOTSTRAPPING} < ${MINIMUM_SUPPORTED_OSREL} && ${BOOTSTRAPPING} != 0
@echo "ERROR: Source upgrades from versions prior to ${MINIMUM_SUPPORTED_REL} are not supported."; \
false
.endif
.for _tool in tools/build ${_config_deps}
${_+_}@${ECHODIR} "===> ${_tool} (obj,includes,all,install)"; \
cd ${.CURDIR}/${_tool}; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} DIRPRFX=${_tool}/ obj; fi; \
${MAKE} DIRPRFX=${_tool}/ DESTDIR=${WORLDTMP}/legacy includes; \
${MAKE} DIRPRFX=${_tool}/ MK_INCLUDES=no all; \
${MAKE} DIRPRFX=${_tool}/ MK_INCLUDES=no \
DESTDIR=${WORLDTMP}/legacy install
.endfor
#
# bootstrap-tools: Build tools needed for compatibility. These are binaries that
# are built to build other binaries in the system. However, the focus of these
# binaries is usually quite narrow. Bootstrap tools use the host's compiler and
# libraries, augmented by -legacy, in addition to the libraries built during
# bootstrap-tools.
#
_bt= _bootstrap-tools
# We want to run the build with only ${WORLDTMP} in $PATH to ensure we don't
# accidentally run tools that are incompatible but happen to be in $PATH.
# This is especially important when building on Linux/MacOS where many of the
# programs used during the build accept different flags or generate different
# output. On those platforms we only symlink the tools known to be compatible
# (e.g. basic utilities such as mkdir) into ${WORLDTMP} and build all others
# from the FreeBSD sources during the bootstrap-tools stage.
# We want to build without the user's $PATH starting in the bootstrap-tools
# phase so the tools used in that phase (ln, cp, etc) must have already been
# linked to $WORLDTMP. The tools are listed in the _host_tools_to_symlink
# variable in tools/build/Makefile and are linked during the legacy phase.
# Since they could be Linux or MacOS binaries, too we must only use flags that
# are portable across operating systems.
# If BOOTSTRAP_ALL_TOOLS is set we will build all the required tools from the
# current source tree. Otherwise we create a symlink to the version found in
# $PATH during the bootstrap-tools stage.
.if defined(BOOTSTRAP_ALL_TOOLS)
# BOOTSTRAPPING will be set on the command line so we can't override it here.
# Instead set BOOTSTRAPPING_OSRELDATE so that the value 0 is set ${BSARGS}
BOOTSTRAPPING_OSRELDATE:= 0
.endif
.if ${MK_GAMES} != "no"
_strfile= usr.bin/fortune/strfile
.endif
.if ${MK_GCC} != "no" && ${MK_CXX} != "no"
_gperf= gnu/usr.bin/gperf
.endif
.if ${MK_VT} != "no"
_vtfontcvt= usr.bin/vtfontcvt
.endif
# If we are not building the bootstrap because BOOTSTRAPPING is sufficient
# we symlink the host version to $WORLDTMP instead. By doing this we can also
# detect when a bootstrap tool is being used without the required MK_FOO.
# If you add a new bootstrap tool where we could also use the host version,
# please ensure that you also add a .else case where you add the tool to the
# _bootstrap_tools_links variable.
.if ${BOOTSTRAPPING} < 1000033
_m4= usr.bin/m4
_lex= usr.bin/lex
# Note: lex needs m4 to build but m4 also depends on lex. However, lex can be
# bootstrapped so we build lex first.
${_bt}-usr.bin/m4: ${_bt}-lib/libopenbsd ${_bt}-usr.bin/yacc ${_bt}-${_lex}
_bt_m4_depend=${_bt}-${_m4}
_bt_lex_depend=${_bt}-${_lex} ${_bt_m4_depend}
.else
_bootstrap_tools_links+=m4 lex
.endif
# ELF Tool Chain libraries are needed for ELF tools and dtrace tools.
# r296685 fix cross-endian objcopy
# r310724 fixed PR 215350, a crash in libdwarf with objects built by GCC 6.2.
# r334881 added libdwarf constants used by ctfconvert.
# r338478 fixed a crash in objcopy for mips64el objects
# r339083 libelf: correct mips64el test to use ELF header
# r348347 Add missing powerpc64 relocation support to libdwarf
.if ${BOOTSTRAPPING} < 1300030
_elftoolchain_libs= lib/libelf lib/libdwarf
${_bt}-lib/libelf: ${_bt_m4_depend}
${_bt}-lib/libdwarf: ${_bt_m4_depend}
.endif
# r245440 mtree -N support added
# r313404 requires sha384.h for libnetbsd, added to libmd in r292782
.if ${BOOTSTRAPPING} < 1100093
_nmtree= lib/libmd \
lib/libnetbsd \
usr.sbin/nmtree
${_bt}-lib/libnetbsd: ${_bt}-lib/libmd
${_bt}-usr.sbin/nmtree: ${_bt}-lib/libnetbsd
.else
_bootstrap_tools_links+=mtree
.endif
2017-02-21 18:49:30 +00:00
# r246097: log addition login.conf.db, passwd, pwd.db, and spwd.db with cat -l
.if ${BOOTSTRAPPING} < 1000027
_cat= bin/cat
.else
_bootstrap_tools_links+=cat
.endif
# r277259 crunchide: Correct 64-bit section header offset
# r281674 crunchide: always include both 32- and 64-bit ELF support
.if ${BOOTSTRAPPING} < 1100078
_crunchide= usr.sbin/crunch/crunchide
.else
_bootstrap_tools_links+=crunchide
.endif
# r285986 crunchen: use STRIPBIN rather than STRIP
# 1100113: Support MK_AUTO_OBJ
# 1200006: META_MODE fixes
.if ${BOOTSTRAPPING} < 1100078 || \
(${MK_AUTO_OBJ} == "yes" && ${BOOTSTRAPPING} < 1100114) || \
(${MK_META_MODE} == "yes" && ${BOOTSTRAPPING} < 1200006)
_crunchgen= usr.sbin/crunch/crunchgen
.else
_bootstrap_tools_links+=crunchgen
.endif
# r296926 -P keymap search path, MFC to stable/10 in r298297
.if ${BOOTSTRAPPING} < 1003501 || \
(${BOOTSTRAPPING} >= 1100000 && ${BOOTSTRAPPING} < 1100103)
_kbdcontrol= usr.sbin/kbdcontrol
.else
_bootstrap_tools_links+=kbdcontrol
.endif
_yacc= lib/liby \
usr.bin/yacc
${_bt}-usr.bin/yacc: ${_bt}-lib/liby
.if ${MK_BSNMP} != "no"
2006-03-31 14:10:35 +00:00
_gensnmptree= usr.sbin/bsnmpd/gensnmptree
.endif
.if ${MK_LOCALES} != "no"
_localedef= usr.bin/localedef
.endif
# We need to build tblgen when we're building clang or lld, either as
# bootstrap tools, or as the part of the normal build.
.if ${MK_CLANG_BOOTSTRAP} != "no" || ${MK_CLANG} != "no" || \
${MK_LLD_BOOTSTRAP} != "no" || ${MK_LLD} != "no"
_clang_tblgen= \
lib/clang/libllvmminimal \
usr.bin/clang/llvm-tblgen \
usr.bin/clang/clang-tblgen
${_bt}-usr.bin/clang/clang-tblgen: ${_bt}-lib/clang/libllvmminimal
${_bt}-usr.bin/clang/llvm-tblgen: ${_bt}-lib/clang/libllvmminimal
.endif
# Default to building the GPL DTC, but build the BSDL one if users explicitly
# request it.
_dtc= usr.bin/dtc
.if ${MK_GPL_DTC} != "no"
_dtc= gnu/usr.bin/dtc
.endif
.if ${MK_LOCALES} != "no"
_localedef= usr.bin/localedef
.endif
.if ${MK_KERBEROS} != "no"
_kerberos5_bootstrap_tools= \
kerberos5/tools/make-roken \
kerberos5/lib/libroken \
kerberos5/lib/libvers \
kerberos5/tools/asn1_compile \
kerberos5/tools/slc \
usr.bin/compile_et
.ORDER: ${_kerberos5_bootstrap_tools:C/^/${_bt}-/g}
.for _tool in ${_kerberos5_bootstrap_tools}
${_bt}-${_tool}: ${_bt}-usr.bin/yacc ${_bt_lex_depend}
.endfor
.endif
${_bt}-usr.bin/mandoc: ${_bt}-lib/libopenbsd
# The tools listed in _basic_bootstrap_tools will generally not be
# bootstrapped unless BOOTSTRAP_ALL_TOOL is set. However, when building on a
# Linux or MacOS host the host versions are incompatible so we need to build
# them from the source tree. Usually the link name will be the same as the subdir,
# but some directories such as grep or test install multiple binaries. In that
# case we use the _basic_bootstrap_tools_multilink variable which is a list of
# subdirectory and comma-separated list of files.
_basic_bootstrap_tools_multilink=usr.bin/grep grep,egrep,fgrep
_basic_bootstrap_tools_multilink+=bin/test test,[
# bootstrap tools needed by buildworld:
_basic_bootstrap_tools=usr.bin/awk usr.bin/cut bin/expr usr.bin/gencat \
usr.bin/join usr.bin/mktemp bin/rmdir usr.bin/sed usr.bin/sort \
usr.bin/truncate usr.bin/tsort
# elf2aout is required for sparc64 build
_basic_bootstrap_tools+=usr.bin/elf2aout
# file2c is required for building usr.sbin/config:
_basic_bootstrap_tools+=usr.bin/file2c
# uuencode/uudecode required for share/tabset
_basic_bootstrap_tools+=usr.bin/uuencode usr.bin/uudecode
# xargs is required by mkioctls
_basic_bootstrap_tools+=usr.bin/xargs
# cap_mkdb is required for share/termcap:
_basic_bootstrap_tools+=usr.bin/cap_mkdb
# ldd is required for installcheck (TODO: just always use /usr/bin/ldd instead?)
_basic_bootstrap_tools+=usr.bin/ldd
# services_mkdb/pwd_mkdb are required for installworld:
_basic_bootstrap_tools+=usr.sbin/services_mkdb usr.sbin/pwd_mkdb
# sysctl/chflags are required for installkernel:
_basic_bootstrap_tools+=sbin/sysctl bin/chflags
# mkfifo is used by sys/conf/newvers.sh
_basic_bootstrap_tools+=usr.bin/mkfifo
.if ${MK_AMD} != "no"
# unifdef is only used by usr.sbin/amd/libamu/Makefile
_basic_bootstrap_tools+=usr.bin/unifdef
.endif
.if ${MK_BOOT} != "no"
_basic_bootstrap_tools+=bin/dd
# xz/unxz is used by EFI
_basic_bootstrap_tools_multilink+=usr.bin/xz xz,unxz
# md5 is used by boot/beri (and possibly others)
_basic_bootstrap_tools+=sbin/md5
.if defined(BOOTSTRAP_ALL_TOOLS)
${_bt}-sbin/md5: ${_bt}-lib/libmd
.endif
.endif
.if ${MK_ZONEINFO} != "no"
_basic_bootstrap_tools+=usr.sbin/zic usr.sbin/tzsetup
.endif
.if defined(BOOTSTRAP_ALL_TOOLS)
_other_bootstrap_tools+=${_basic_bootstrap_tools}
.for _subdir _links in ${_basic_bootstrap_tools_multilink}
_other_bootstrap_tools+=${_subdir}
.endfor
${_bt}-usr.bin/awk: ${_bt_lex_depend} ${_bt}-usr.bin/yacc
${_bt}-bin/expr: ${_bt_lex_depend} ${_bt}-usr.bin/yacc
# If we are bootstrapping file2c, we have to build it before config:
${_bt}-usr.sbin/config: ${_bt}-usr.bin/file2c ${_bt_lex_depend}
# Note: no symlink to make/bmake in the !BOOTSTRAP_ALL_TOOLS case here since
# the links to make/bmake make links will have already have been created in the
# `make legacy` step. Not adding a link to make is important on non-FreeBSD
# since "make" will usually point to GNU make there.
_other_bootstrap_tools+=usr.bin/bmake
.else
# All tools in _basic_bootstrap_tools have the same name as the subdirectory
# so we can use :T to get the name of the symlinks that we need to create.
_bootstrap_tools_links+=${_basic_bootstrap_tools:T}
.for _subdir _links in ${_basic_bootstrap_tools_multilink}
_bootstrap_tools_links+=${_links:S/,/ /g}
.endfor
.endif # defined(BOOTSTRAP_ALL_TOOLS)
# Link the tools that we need for building but don't need to bootstrap because
# the host version is known to be compatible into ${WORLDTMP}/legacy
# We do this before building any of the bootstrap tools in case they depend on
# the presence of any of the links (e.g. as m4/lex/awk)
${_bt}-links: .PHONY
.for _tool in ${_bootstrap_tools_links}
${_bt}-link-${_tool}: .PHONY .MAKE
@if [ ! -e "${WORLDTMP}/legacy/bin/${_tool}" ]; then \
source_path=`which ${_tool}`; \
if [ ! -e "$${source_path}" ] ; then \
echo "Cannot find host tool '${_tool}'"; false; \
fi; \
ln -sfnv "$${source_path}" "${WORLDTMP}/legacy/bin/${_tool}"; \
fi
${_bt}-links: ${_bt}-link-${_tool}
.endfor
bootstrap-tools: ${_bt}-links .PHONY
# Please document (add comment) why something is in 'bootstrap-tools'.
# Try to bound the building of the bootstrap-tool to just the
# FreeBSD versions that need the tool built at this stage of the build.
.for _tool in \
${_clang_tblgen} \
${_kerberos5_bootstrap_tools} \
${_strfile} \
${_gperf} \
${_dtc} \
${_cat} \
${_kbdcontrol} \
${_elftoolchain_libs} \
usr.bin/lorder \
lib/libopenbsd \
usr.bin/mandoc \
usr.bin/rpcgen \
${_yacc} \
${_m4} \
${_lex} \
${_other_bootstrap_tools} \
usr.bin/xinstall \
${_gensnmptree} \
usr.sbin/config \
${_crunchide} \
${_crunchgen} \
${_nmtree} \
2015-08-08 00:18:32 +00:00
${_vtfontcvt} \
${_localedef}
${_bt}-${_tool}: ${_bt}-links .PHONY .MAKE
${_+_}@${ECHODIR} "===> ${_tool} (obj,all,install)"; \
cd ${.CURDIR}/${_tool}; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} DIRPRFX=${_tool}/ obj; fi; \
if [ "${_tool}" = "usr.bin/lex" ]; then \
${MAKE} DIRPRFX=${_tool}/ bootstrap; \
fi; \
${MAKE} DIRPRFX=${_tool}/ all; \
${MAKE} DIRPRFX=${_tool}/ DESTDIR=${WORLDTMP}/legacy install
bootstrap-tools: ${_bt}-${_tool}
.endfor
#
# build-tools: Build special purpose build tools
#
.if !defined(NO_SHARE) && ${MK_SYSCONS} != "no"
_share= share/syscons/scrnmaps
.endif
.if ${MK_GCC} != "no"
_gcc_tools= gnu/usr.bin/cc/cc_tools
.endif
.if ${MK_RESCUE} != "no"
# rescue includes programs that have build-tools targets
_rescue=rescue/rescue
.endif
.if ${MK_TCSH} != "no"
_tcsh=bin/csh
.endif
.if ${MK_FILE} != "no"
_libmagic=lib/libmagic
.endif
.if ${MK_PMC} != "no" && \
(${TARGET_ARCH} == "amd64" || ${TARGET_ARCH} == "i386")
_jevents=lib/libpmc/pmu-events
.endif
# kernel-toolchain skips _cleanobj, so handle cleaning up previous
# build-tools directories if needed.
.if !defined(NO_CLEAN) && make(kernel-toolchain)
_bt_clean= ${CLEANDIR}
.endif
.for _tool in \
${_tcsh} \
bin/sh \
${LOCAL_TOOL_DIRS} \
${_jevents} \
lib/ncurses/ncurses \
lib/ncurses/ncursesw \
2015-08-12 19:21:58 +00:00
${_rescue} \
${_share} \
usr.bin/awk \
${_libmagic} \
Add the BSD-licensed Citrus iconv to the base system with default off setting. It can be built by setting the WITH_ICONV knob. While this knob is unset, the library part, the binaries, the header file and the metadata files will not be built or installed so it makes no impact on the system if left turned off. This work is based on the iconv implementation in NetBSD but a great number of improvements and feature additions have been included: - Some utilities have been added. There is a conversion table generator, which can compare conversion tables to reference data generated by GNU libiconv. This helps ensuring conversion compatibility. - UTF-16 surrogate support and some endianness issues have been fixed. - The rather chaotic Makefiles to build metadata have been refactored and cleaned up, now it is easy to read and it is also easier to add support for new encodings. - A bunch of new encodings and encoding aliases have been added. - Support for 1->2, 1->3 and 1->4 mappings, which is needed for transliterating with flying accents as GNU does, like "u. - Lots of warnings have been fixed, the major part of the code is now WARNS=6 clean. - New section 1 and section 5 manual pages have been added. - Some GNU-specific calls have been implemented: iconvlist(), iconvctl(), iconv_canonicalize(), iconv_open_into() - Support for GNU's //IGNORE suffix has been added. - The "-" argument for stdin is now recognized in iconv(1) as per POSIX. - The Big5 conversion module has been fixed. - The iconv.h header files is supposed to be compatible with the GNU version, i.e. sources should build with base iconv.h and GNU libiconv. It also includes a macro magic to deal with the char ** and const char ** incompatibility. - GNU compatibility: "" or "char" means the current local encoding in use - Various cleanups and style(9) fixes. Approved by: delphij (mentor) Obtained from: The NetBSD Project Sponsored by: Google Summer of Code 2009
2011-02-25 00:04:39 +00:00
usr.bin/mkesdb_static \
usr.bin/mkcsmapper_static \
usr.bin/vi/catalog \
${_gcc_tools}
build-tools_${_tool}: .PHONY
${_+_}@${ECHODIR} "===> ${_tool} (${_bt_clean:D${_bt_clean},}obj,build-tools)"; \
cd ${.CURDIR}/${_tool}; \
if [ -n "${_bt_clean}" ]; then ${MAKE} DIRPRFX=${_tool}/ ${_bt_clean}; fi; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} DIRPRFX=${_tool}/ obj; fi; \
${MAKE} DIRPRFX=${_tool}/ build-tools
build-tools: build-tools_${_tool}
.endfor
#
# kernel-tools: Build kernel-building tools
#
kernel-tools: .PHONY
mkdir -p ${WORLDTMP}/usr
${WORLDTMP_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
-p ${WORLDTMP}/usr >/dev/null
#
# cross-tools: All the tools needed to build the rest of the system after
# we get done with the earlier stages. It is the last set of tools needed
# to begin building the target binaries.
#
.if ${TARGET_ARCH} != ${MACHINE_ARCH} || ${BUILD_WITH_STRICT_TMPPATH} != 0
2005-12-07 20:01:12 +00:00
.if ${TARGET_ARCH} == "amd64" || ${TARGET_ARCH} == "i386"
_btxld= usr.sbin/btxld
.endif
2008-04-15 05:14:42 +00:00
.endif
# Rebuild ctfconvert and ctfmerge to avoid difficult-to-diagnose failures
# resulting from missing bug fixes or ELF Toolchain updates.
.if ${MK_CDDL} != "no"
_dtrace_tools= cddl/lib/libctf cddl/usr.bin/ctfconvert \
cddl/usr.bin/ctfmerge
.endif
# If we're given an XAS, don't build binutils.
.if ${XAS:M/*} == ""
.if ${MK_BINUTILS_BOOTSTRAP} != "no"
_binutils= gnu/usr.bin/binutils
.endif
.if ${MK_ELFTOOLCHAIN_BOOTSTRAP} != "no"
_elftctools= lib/libelftc \
lib/libpe \
usr.bin/objcopy \
usr.bin/nm \
usr.bin/size \
usr.bin/strings
# These are not required by the build, but can be useful for developers who
# cross-build on a FreeBSD 10 host:
_elftctools+= usr.bin/addr2line
.endif
.elif ${TARGET_ARCH} != ${MACHINE_ARCH} && ${MK_ELFTOOLCHAIN_BOOTSTRAP} != "no"
# If cross-building with an external binutils we still need to build strip for
# the target (for at least crunchide).
_elftctools= lib/libelftc \
lib/libpe \
usr.bin/objcopy
.endif
.if ${MK_CLANG_BOOTSTRAP} != "no"
_clang= usr.bin/clang
.endif
.if ${MK_LLD_BOOTSTRAP} != "no"
_lld= usr.bin/clang/lld
.endif
.if ${MK_CLANG_BOOTSTRAP} != "no" || ${MK_LLD_BOOTSTRAP} != "no"
_clang_libs= lib/clang
.endif
.if ${MK_GCC_BOOTSTRAP} != "no"
_gcc= gnu/usr.bin/cc
.endif
.if ${MK_USB} != "no"
_usb_tools= stand/usb/tools
.endif
.if ${BUILD_WITH_STRICT_TMPPATH} != 0 || defined(BOOTSTRAP_ALL_TOOLS)
_ar=usr.bin/ar
.endif
cross-tools: .MAKE .PHONY
.for _tool in \
${LOCAL_XTOOL_DIRS} \
${_ar} \
${_clang_libs} \
${_clang} \
${_lld} \
${_binutils} \
${_elftctools} \
${_dtrace_tools} \
${_gcc} \
${_btxld} \
${_usb_tools}
${_+_}@${ECHODIR} "===> ${_tool} (obj,all,install)"; \
cd ${.CURDIR}/${_tool}; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} DIRPRFX=${_tool}/ obj; fi; \
${MAKE} DIRPRFX=${_tool}/ all; \
${MAKE} DIRPRFX=${_tool}/ DESTDIR=${WORLDTMP} install
.endfor
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
#
# native-xtools is the current target for qemu-user cross builds of ports
# via poudriere and the imgact_binmisc kernel module.
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
# This target merely builds a toolchan/sysroot, then builds the tools it wants
# with the options it wants in a special MAKEOBJDIRPREFIX, using the toolchain
# already built. It then installs the static tools to NXBDESTDIR for Poudriere
# to pickup.
#
NXBOBJROOT= ${OBJROOT}${MACHINE}.${MACHINE_ARCH}/nxb/
NXBOBJTOP= ${NXBOBJROOT}${NXB_TARGET}.${NXB_TARGET_ARCH}
NXTP?= /nxb-bin
.if ${NXTP:N/*}
.error NXTP variable should be an absolute path
.endif
NXBDESTDIR?= ${DESTDIR}${NXTP}
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
# This is the list of tools to be built/installed as static and where
# appropriate to build for the given TARGET.TARGET_ARCH.
NXBDIRS+= \
bin/cat \
bin/chmod \
bin/cp \
${_tcsh} \
bin/echo \
bin/expr \
bin/hostname \
bin/ln \
bin/ls \
bin/mkdir \
bin/mv \
bin/ps \
bin/realpath \
bin/rm \
bin/rmdir \
bin/sh \
bin/sleep \
sbin/md5 \
sbin/sysctl \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/addr2line \
usr.bin/ar \
usr.bin/awk \
usr.bin/basename \
usr.bin/bmake \
usr.bin/bzip2 \
usr.bin/cmp \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/diff \
usr.bin/dirname \
usr.bin/objcopy \
usr.bin/env \
usr.bin/fetch \
usr.bin/find \
usr.bin/grep \
usr.bin/gzip \
usr.bin/head \
usr.bin/id \
usr.bin/lex \
usr.bin/limits \
usr.bin/lorder \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/mandoc \
usr.bin/mktemp \
usr.bin/mt \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/nm \
usr.bin/patch \
usr.bin/readelf \
usr.bin/sed \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/size \
usr.bin/sort \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
usr.bin/strings \
usr.bin/tar \
usr.bin/touch \
usr.bin/tr \
usr.bin/true \
usr.bin/uniq \
usr.bin/unzip \
usr.bin/wc \
usr.bin/xargs \
usr.bin/xinstall \
usr.bin/xz \
usr.bin/yacc \
usr.sbin/chown
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
SUBDIR_DEPEND_usr.bin/clang= lib/clang
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
.if ${MK_CLANG} != "no"
NXBDIRS+= lib/clang
NXBDIRS+= usr.bin/clang
.endif
.if ${MK_GCC} != "no"
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
NXBDIRS+= gnu/usr.bin/cc
.endif
.if ${MK_BINUTILS} != "no"
NXBDIRS+= gnu/usr.bin/binutils
.endif
# XXX: native-xtools passes along ${NXBDIRS} in SUBDIR_OVERRIDE that needs
# to be evaluated after NXBDIRS is set.
.if make(install) && !empty(SUBDIR_OVERRIDE)
SUBDIR= ${SUBDIR_OVERRIDE}
.endif
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
NXBMAKEARGS+= \
OBJTOP=${NXBOBJTOP:Q} \
OBJROOT=${NXBOBJROOT:Q} \
MAKEOBJDIRPREFIX= \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
-DNO_SHARED \
-DNO_CPU_CFLAGS \
-DNO_PIC \
SSP_CFLAGS= \
MK_CASPER=no \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
MK_CLANG_EXTRAS=no \
MK_CLANG_FULL=no \
MK_CTF=no \
MK_DEBUG_FILES=no \
MK_GDB=no \
MK_HTML=no \
MK_LLDB=no \
MK_MAN=no \
MK_MAN_UTILS=yes \
MK_OFED=no \
MK_OPENSSH=no \
MK_PROFILE=no \
MK_RETPOLINE=no \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
MK_SENDMAIL=no \
MK_SVNLITE=no \
MK_TESTS=no \
MK_WARNS=no \
MK_ZFS=no
.if make(native-xtools*) && \
(!defined(NXB_TARGET) || !defined(NXB_TARGET_ARCH))
.error Missing NXB_TARGET / NXB_TARGET_ARCH
.endif
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
# For 'toolchain' we want to produce native binaries that themselves generate
# native binaries.
NXBTMAKE= ${NXBMAKEENV} ${MAKE} ${NXBMAKEARGS:N-DNO_PIC:N-DNO_SHARED} \
TARGET=${MACHINE} TARGET_ARCH=${MACHINE_ARCH}
# For 'everything' we want to produce native binaries (hence -target to
# be MACHINE) that themselves generate TARGET.TARGET_ARCH binaries.
# TARGET/TARGET_ARCH are still passed along from user.
#
# Use the toolchain we create as an external toolchain.
.if ${USING_SYSTEM_COMPILER} == "yes" || ${XCC:N${CCACHE_BIN}:M/*}
NXBMAKE+= XCC="${XCC}" \
XCXX="${XCXX}" \
XCPP="${XCPP}"
.else
NXBMAKE+= XCC="${NXBOBJTOP}/tmp/usr/bin/cc" \
XCXX="${NXBOBJTOP}/tmp/usr/bin/c++" \
XCPP="${NXBOBJTOP}/tmp/usr/bin/cpp"
.endif
NXBMAKE+= ${NXBMAKEENV} ${MAKE} -f Makefile.inc1 ${NXBMAKEARGS} \
TARGET=${NXB_TARGET} TARGET_ARCH=${NXB_TARGET_ARCH} \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
TARGET_TRIPLE=${MACHINE_TRIPLE:Q}
# NXBDIRS is improperly based on MACHINE rather than NXB_TARGET. Need to
# invoke a sub-make to reevaluate MK_GCC, etc, for NXBDIRS.
NXBMAKE+= SUBDIR_OVERRIDE='$${NXBDIRS:M*}'
# Need to avoid the -isystem logic when using clang as an external toolchain
# even if the TARGET being built for wants GCC.
NXBMAKE+= WANT_COMPILER_TYPE='$${X_COMPILER_TYPE}'
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
native-xtools: .PHONY
${_+_}cd ${.CURDIR}; ${NXBTMAKE} _cleanobj MK_GCC=yes
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
# Build the bootstrap/host/cross tools that produce native binaries
# Pass along MK_GCC=yes to ensure GCC-needed build tools are built.
# We don't quite know what the NXB_TARGET wants so just build it.
${_+_}cd ${.CURDIR}; ${NXBTMAKE} kernel-toolchain MK_GCC=yes
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
# Populate includes/libraries sysroot that produce native binaries.
# This is split out from 'toolchain' above mostly so that target LLVM
# libraries have a proper LLVM_DEFAULT_TARGET_TRIPLE without
# polluting the cross-compiler build. The LLVM/GCC libs are skipped
# here to avoid the problem but are kept in 'toolchain' so that
# needed build tools are built.
${_+_}cd ${.CURDIR}; ${NXBTMAKE} _includes MK_CLANG=no MK_GCC=no
${_+_}cd ${.CURDIR}; ${NXBTMAKE} _libraries MK_CLANG=no MK_GCC=no
# Clean out improper TARGET=MACHINE files
${_+_}cd ${.CURDIR}/gnu/usr.bin/cc/cc_tools; ${NXBTMAKE} cleandir
.if !defined(NO_OBJWALK)
${_+_}cd ${.CURDIR}; ${NXBMAKE} _obj
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
.endif
${_+_}cd ${.CURDIR}; ${NXBMAKE} everything
@echo ">> native-xtools done. Use 'make native-xtools-install' to install to a given DESTDIR"
native-xtools-install: .PHONY
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
mkdir -p ${NXBDESTDIR}/bin ${NXBDESTDIR}/sbin ${NXBDESTDIR}/usr
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
-p ${NXBDESTDIR}/usr >/dev/null
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.include.dist \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
-p ${NXBDESTDIR}/usr/include >/dev/null
${_+_}cd ${.CURDIR}; ${NXBMAKE} \
Fix native-xtools build to use a proper sysroot. This takes longer but should reliably produce working binaries. The old version linked against system libraries and headers which would be a problem if building a native-xtools against a newer source than the host system. With a proper sysroot made first this is not a problem. This also allows: - NXBDIRS to be built in parallel - NXBDIRS to be installed to NXBDESTDIR in parallel - SYSTEM_COMPILER logic to work again. Note that because this change is adding a sysroot phase the compiler may be built up to twice now. The first is the "cross-compiler" even though it is for the native architecture, but it is still built to ensure the latest compiler is used to generate the binaries, unless SYSTEM_COMPILER allows /usr/bin/cc to be used. Then the target compiler is built which is actually a cross-compiler since it runs on native host but generates TARGET.TARGET_ARCH binaries. Note this also changes the path used for the OBJDIR. It used to use /usr/obj/target.target_arch/nxb/<srcdir> for objects and /usr/obj/target.target_arch/nxb-bin for installed files, but now uses /usr/obj/nxb/target.target_arch/<srcdir> for objects and /usr/obj/nxb/target.target_arch/<srcdir>/nxb-bin for installed files. - NXBDESTDIR can be specified for where to install or queried with `make -f Makefile.inc1 TARGET=... TARGET_ARCH=... -V NXBDESTDIR` This could potentially be improved to reuse an existing sysroot. The problem is with building the SUBDIR_OVERRIDE list it needs to use a different OBJDIR since it is building all statically. We don't want to pollute the existing 'buildworld' OBJDIR and cause confusion on the next build. Using a separate OBJDIR for the 'everything' phase mostly works except for some things like linking in INTERNALLIBS that exist in the other OBJDIR. MFC after: 1 month Sponsored by: Dell EMC Isilon
2017-10-25 21:46:36 +00:00
DESTDIR=${NXBDESTDIR} \
-DNO_ROOT \
install
#
# hierarchy - ensure that all the needed directories are present
#
hierarchy hier: .MAKE .PHONY
${_+_}cd ${.CURDIR}/etc; ${HMAKE} distrib-dirs
#
# libraries - build all libraries, and install them under ${DESTDIR}.
#
# The list of libraries with dependents (${_prebuild_libs}) and their
# interdependencies (__L) are built automatically by the
# ${.CURDIR}/tools/make_libdeps.sh script.
#
libraries: .MAKE .PHONY
${_+_}cd ${.CURDIR}; \
${MAKE} -f Makefile.inc1 _prereq_libs; \
${MAKE} -f Makefile.inc1 _startup_libs; \
${MAKE} -f Makefile.inc1 _prebuild_libs; \
2013-07-06 00:13:08 +00:00
${MAKE} -f Makefile.inc1 _generic_libs
#
# static libgcc.a prerequisite for shared libc
#
_prereq_libs= lib/libcompiler_rt
.if ${MK_SSP} != "no"
_prereq_libs+= gnu/lib/libssp/libssp_nonshared
.endif
# These dependencies are not automatically generated:
#
# gnu/lib/csu, gnu/lib/libgcc, lib/csu and lib/libc must be built before
# all shared libraries for ELF.
#
_startup_libs= lib/csu
.if ${MK_BSD_CRTBEGIN} == "no"
_startup_libs+= gnu/lib/csu
.endif
_startup_libs+= lib/libcompiler_rt
_startup_libs+= lib/libc
_startup_libs+= lib/libc_nonshared
.if ${MK_LIBCPLUSPLUS} != "no"
_startup_libs+= lib/libcxxrt
.endif
.if ${MK_LLVM_LIBUNWIND} != "no"
_prereq_libs+= lib/libgcc_eh lib/libgcc_s
_startup_libs+= lib/libgcc_eh lib/libgcc_s
lib/libgcc_s__L: lib/libc__L
lib/libgcc_s__L: lib/libc_nonshared__L
.if ${MK_LIBCPLUSPLUS} != "no"
lib/libcxxrt__L: lib/libgcc_s__L
.endif
.else # MK_LLVM_LIBUNWIND == no
_prereq_libs+= gnu/lib/libgcc
_startup_libs+= gnu/lib/libgcc
gnu/lib/libgcc__L: lib/libc__L
gnu/lib/libgcc__L: lib/libc_nonshared__L
.if ${MK_LIBCPLUSPLUS} != "no"
lib/libcxxrt__L: gnu/lib/libgcc__L
.endif
.endif
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
_prebuild_libs= ${_kerberos5_lib_libasn1} \
${_kerberos5_lib_libhdb} \
${_kerberos5_lib_libheimbase} \
${_kerberos5_lib_libheimntlm} \
${_libsqlite3} \
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
${_kerberos5_lib_libheimipcc} \
${_kerberos5_lib_libhx509} ${_kerberos5_lib_libkrb5} \
${_kerberos5_lib_libroken} \
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
${_kerberos5_lib_libwind} \
lib/libbz2 ${_libcom_err} lib/libcrypt \
lib/libelf lib/libexpat \
lib/libfigpar \
${_lib_libgssapi} \
lib/libkiconv lib/libkvm lib/liblzma lib/libmd lib/libnv \
${_lib_casper} \
lib/ncurses/ncurses lib/ncurses/ncursesw \
lib/libopie lib/libpam/libpam ${_lib_libthr} \
${_lib_libradius} lib/libsbuf lib/libtacplus \
lib/libgeom \
${_cddl_lib_libumem} ${_cddl_lib_libnvpair} \
${_cddl_lib_libuutil} \
${_cddl_lib_libavl} \
${_cddl_lib_libzfs_core} ${_cddl_lib_libzfs} \
${_cddl_lib_libctf} \
lib/libufs \
lib/libutil lib/libpjdlog ${_lib_libypclnt} lib/libz lib/msun \
${_secure_lib_libcrypto} ${_secure_lib_libssl} \
${_lib_libldns} ${_secure_lib_libssh}
.if ${MK_GNUCXX} != "no"
_prebuild_libs+= gnu/lib/libstdc++ gnu/lib/libsupc++
gnu/lib/libstdc++__L: lib/msun__L
gnu/lib/libsupc++__L: gnu/lib/libstdc++__L
.endif
.if ${MK_DIALOG} != "no"
_prebuild_libs+= gnu/lib/libdialog
gnu/lib/libdialog__L: lib/msun__L lib/ncurses/ncursesw__L
.endif
.if ${MK_LIBCPLUSPLUS} != "no"
_prebuild_libs+= lib/libc++
.endif
lib/libgeom__L: lib/libexpat__L
Add support to libkvm for reading vmcores from other architectures. - Add a kvaddr_type to represent kernel virtual addresses instead of unsigned long. - Add a struct kvm_nlist which is a stripped down version of struct nlist that uses kvaddr_t for n_value. - Add a kvm_native() routine that returns true if an open kvm descriptor is for a native kernel and memory image. - Add a kvm_open2() function similar to kvm_openfiles(). It drops the unused 'swapfile' argument and adds a new function pointer argument for a symbol resolving function. Native kernels still use _fdnlist() from libc to resolve symbols if a resolver function is not supplied, but cross kernels require a resolver. - Add a kvm_nlist2() function similar to kvm_nlist() except that it uses struct kvm_nlist instead of struct nlist. - Add a kvm_read2() function similar to kvm_read() except that it uses kvaddr_t instead of unsigned long for the kernel virtual address. - Add a new kvm_arch switch of routines needed by a vmcore backend. Each backend is responsible for implementing kvm_read2() for a given vmcore format. - Use libelf to read headers from ELF kernels and cores (except for powerpc cores). - Add internal helper routines for the common page offset hash table used by the minidump backends. - Port all of the existing kvm backends to implement a kvm_arch switch and to be cross-friendly by using private constants instead of ones that vary by platform (e.g. PAGE_SIZE). Static assertions are present when a given backend is compiled natively to ensure the private constants match the real ones. - Enable all of the existing vmcore backends on all platforms. This means that libkvm on any platform should be able to perform KVA translation and read data from a vmcore of any platform. Tested on: amd64, i386, sparc64 (marius) Differential Revision: https://reviews.freebsd.org/D3341
2015-11-27 18:58:26 +00:00
lib/libkvm__L: lib/libelf__L
.if ${MK_LIBTHR} != "no"
_lib_libthr= lib/libthr
.endif
.if ${MK_RADIUS_SUPPORT} != "no"
_lib_libradius= lib/libradius
.endif
.if ${MK_OFED} != "no"
_prebuild_libs+= \
lib/ofed/libibverbs \
lib/ofed/libibmad \
lib/ofed/libibumad \
lib/ofed/complib \
lib/ofed/libmlx5
lib/ofed/libibmad__L: lib/ofed/libibumad__L
lib/ofed/complib__L: lib/libthr__L
lib/ofed/libmlx5__L: lib/ofed/libibverbs__L lib/libthr__L
.endif
.if ${MK_CASPER} != "no"
_lib_casper= lib/libcasper
.endif
lib/libpjdlog__L: lib/libutil__L
lib/libcasper__L: lib/libnv__L
lib/liblzma__L: lib/libthr__L
_generic_libs= ${_cddl_lib} gnu/lib ${_kerberos5_lib} lib ${_secure_lib} usr.bin/lex/lib
.if ${MK_IPFILTER} != "no"
_generic_libs+= sbin/ipf/libipf
.endif
.for _DIR in ${LOCAL_LIB_DIRS}
.if ${_DIR} == ".WAIT" || (empty(_generic_libs:M${_DIR}) && exists(${.CURDIR}/${_DIR}/Makefile))
_generic_libs+= ${_DIR}
.endif
.endfor
lib/libopie__L lib/libtacplus__L: lib/libmd__L
2007-04-06 02:13:30 +00:00
.if ${MK_CDDL} != "no"
_cddl_lib_libumem= cddl/lib/libumem
_cddl_lib_libnvpair= cddl/lib/libnvpair
_cddl_lib_libavl= cddl/lib/libavl
_cddl_lib_libuutil= cddl/lib/libuutil
.if ${MK_ZFS} != "no"
_cddl_lib_libzfs_core= cddl/lib/libzfs_core
_cddl_lib_libzfs= cddl/lib/libzfs
cddl/lib/libzfs_core__L: cddl/lib/libnvpair__L
cddl/lib/libzfs__L: cddl/lib/libzfs_core__L lib/msun__L lib/libutil__L
cddl/lib/libzfs__L: lib/libthr__L lib/libmd__L lib/libz__L cddl/lib/libumem__L
cddl/lib/libzfs__L: cddl/lib/libuutil__L cddl/lib/libavl__L lib/libgeom__L
lib/libbe__L: cddl/lib/libzfs__L
.endif
_cddl_lib_libctf= cddl/lib/libctf
2007-04-06 02:13:30 +00:00
_cddl_lib= cddl/lib
cddl/lib/libctf__L: lib/libz__L
2007-04-06 02:13:30 +00:00
.endif
# cddl/lib/libdtrace requires lib/libproc and lib/librtld_db; it's only built
# on select architectures though (see cddl/lib/Makefile)
.if ${MACHINE_CPUARCH} != "sparc64"
_prebuild_libs+= lib/libprocstat lib/libproc lib/librtld_db
lib/libprocstat__L: lib/libelf__L lib/libkvm__L lib/libutil__L
lib/libproc__L: lib/libprocstat__L
lib/librtld_db__L: lib/libprocstat__L
.endif
2007-04-06 02:13:30 +00:00
.if ${MK_CRYPT} != "no"
.if ${MK_OPENSSL} != "no"
_secure_lib_libcrypto= secure/lib/libcrypto
_secure_lib_libssl= secure/lib/libssl
lib/libradius__L secure/lib/libssl__L: secure/lib/libcrypto__L
secure/lib/libcrypto__L: lib/libthr__L
.if ${MK_LDNS} != "no"
_lib_libldns= lib/libldns
lib/libldns__L: secure/lib/libssl__L
.endif
.if ${MK_OPENSSH} != "no"
_secure_lib_libssh= secure/lib/libssh
secure/lib/libssh__L: lib/libz__L secure/lib/libcrypto__L lib/libcrypt__L
.if ${MK_LDNS} != "no"
secure/lib/libssh__L: lib/libldns__L
.endif
.if ${MK_GSSAPI} != "no" && ${MK_KERBEROS_SUPPORT} != "no"
secure/lib/libssh__L: lib/libgssapi__L kerberos5/lib/libkrb5__L \
kerberos5/lib/libhx509__L kerberos5/lib/libasn1__L lib/libcom_err__L \
lib/libmd__L kerberos5/lib/libroken__L
.endif
.endif
.endif
_secure_lib= secure/lib
.endif
.if ${MK_KERBEROS} != "no"
kerberos5/lib/libasn1__L: lib/libcom_err__L kerberos5/lib/libroken__L
kerberos5/lib/libhdb__L: kerberos5/lib/libasn1__L lib/libcom_err__L \
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
kerberos5/lib/libkrb5__L kerberos5/lib/libroken__L \
kerberos5/lib/libwind__L lib/libsqlite3__L
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
kerberos5/lib/libheimntlm__L: secure/lib/libcrypto__L kerberos5/lib/libkrb5__L \
kerberos5/lib/libroken__L lib/libcom_err__L
kerberos5/lib/libhx509__L: kerberos5/lib/libasn1__L lib/libcom_err__L \
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
secure/lib/libcrypto__L kerberos5/lib/libroken__L kerberos5/lib/libwind__L
kerberos5/lib/libkrb5__L: kerberos5/lib/libasn1__L lib/libcom_err__L \
lib/libcrypt__L secure/lib/libcrypto__L kerberos5/lib/libhx509__L \
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
kerberos5/lib/libroken__L kerberos5/lib/libwind__L \
kerberos5/lib/libheimbase__L kerberos5/lib/libheimipcc__L
kerberos5/lib/libroken__L: lib/libcrypt__L
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
kerberos5/lib/libwind__L: kerberos5/lib/libroken__L lib/libcom_err__L
kerberos5/lib/libheimbase__L: lib/libthr__L
kerberos5/lib/libheimipcc__L: kerberos5/lib/libroken__L kerberos5/lib/libheimbase__L lib/libthr__L
.endif
lib/libsqlite3__L: lib/libthr__L
.if ${MK_GSSAPI} != "no"
_lib_libgssapi= lib/libgssapi
.endif
.if ${MK_KERBEROS} != "no"
_kerberos5_lib= kerberos5/lib
_kerberos5_lib_libasn1= kerberos5/lib/libasn1
_kerberos5_lib_libhdb= kerberos5/lib/libhdb
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
_kerberos5_lib_libheimbase= kerberos5/lib/libheimbase
_kerberos5_lib_libkrb5= kerberos5/lib/libkrb5
_kerberos5_lib_libhx509= kerberos5/lib/libhx509
_kerberos5_lib_libroken= kerberos5/lib/libroken
_kerberos5_lib_libheimntlm= kerberos5/lib/libheimntlm
_libsqlite3= lib/libsqlite3
- Update FreeBSD Heimdal distribution to version 1.5.1. This also brings several new kerberos related libraries and applications to FreeBSD: o kgetcred(1) allows one to manually get a ticket for a particular service. o kf(1) securily forwards ticket to another host through an authenticated and encrypted stream. o kcc(1) is an umbrella program around klist(1), kswitch(1), kgetcred(1) and other user kerberos operations. klist and kswitch are just symlinks to kcc(1) now. o kswitch(1) allows you to easily switch between kerberos credentials if you're running KCM. o hxtool(1) is a certificate management tool to use with PKINIT. o string2key(1) maps a password into key. o kdigest(8) is a userland tool to access the KDC's digest interface. o kimpersonate(8) creates a "fake" ticket for a service. We also now install manpages for some lirbaries that were not installed before, libheimntlm and libhx509. - The new HEIMDAL version no longer supports Kerberos 4. All users are recommended to switch to Kerberos 5. - Weak ciphers are now disabled by default. To enable DES support (used by telnet(8)), use "allow_weak_crypto" option in krb5.conf. - libtelnet, pam_ksu and pam_krb5 are now compiled with error on warnings disabled due to the function they use (krb5_get_err_text(3)) being deprecated. I plan to work on this next. - Heimdal's KDC now require sqlite to operate. We use the bundled version and install it as libheimsqlite. If some other FreeBSD components will require it in the future we can rename it to libbsdsqlite and use for these components as well. - This is not a latest Heimdal version, the new one was released while I was working on the update. I will update it to 1.5.2 soon, as it fixes some important bugs and security issues.
2012-03-22 08:48:42 +00:00
_kerberos5_lib_libheimipcc= kerberos5/lib/libheimipcc
_kerberos5_lib_libwind= kerberos5/lib/libwind
_libcom_err= lib/libcom_err
.endif
.if ${MK_NIS} != "no"
_lib_libypclnt= lib/libypclnt
.endif
.if ${MK_OPENSSL} == "no"
lib/libradius__L: lib/libmd__L
.endif
lib/libproc__L: \
${_cddl_lib_libctf:D${_cddl_lib_libctf}__L} lib/libelf__L lib/librtld_db__L lib/libutil__L
.if ${MK_CXX} != "no"
.if ${MK_LIBCPLUSPLUS} != "no"
lib/libproc__L: lib/libcxxrt__L
.else # This implies MK_GNUCXX != "no"; see lib/libproc
lib/libproc__L: gnu/lib/libsupc++__L
.endif
.endif
.for _lib in ${_prereq_libs}
2013-07-06 00:13:08 +00:00
${_lib}__PL: .PHONY .MAKE
.if !defined(_MKSHOWCONFIG) && exists(${.CURDIR}/${_lib})
${_+_}@${ECHODIR} "===> ${_lib} (obj,all,install)"; \
cd ${.CURDIR}/${_lib}; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} MK_TESTS=no DIRPRFX=${_lib}/ obj; fi; \
2014-04-25 19:25:26 +00:00
${MAKE} MK_TESTS=no MK_PROFILE=no -DNO_PIC \
DIRPRFX=${_lib}/ all; \
2014-04-25 19:25:26 +00:00
${MAKE} MK_TESTS=no MK_PROFILE=no -DNO_PIC \
DIRPRFX=${_lib}/ install
.endif
.endfor
.for _lib in ${_startup_libs} ${_prebuild_libs} ${_generic_libs}
2013-07-06 00:13:08 +00:00
${_lib}__L: .PHONY .MAKE
.if !defined(_MKSHOWCONFIG) && exists(${.CURDIR}/${_lib})
${_+_}@${ECHODIR} "===> ${_lib} (obj,all,install)"; \
cd ${.CURDIR}/${_lib}; \
if [ -z "${NO_OBJWALK}" ]; then ${MAKE} MK_TESTS=no DIRPRFX=${_lib}/ obj; fi; \
${MAKE} MK_TESTS=no DIRPRFX=${_lib}/ all; \
${MAKE} MK_TESTS=no DIRPRFX=${_lib}/ install
.endif
.endfor
_prereq_libs: ${_prereq_libs:S/$/__PL/}
_startup_libs: ${_startup_libs:S/$/__L/}
_prebuild_libs: ${_prebuild_libs:S/$/__L/}
_generic_libs: ${_generic_libs:S/$/__L/}
bsd.subdir.mk: Only recurse on called targets, rather than dependencies. This is to fix 'make all' causing it to recurse on both 'all' and 'buildconfig' due to 'buildconfig' being in ALL_SUBDIR_TARGETS and being a dependency of 'all'. This now adds all of the '*includes', '*files' targets as subdir targets, allowing them to recurse. This also removes the need for some 'realinstall' hacks in bsd.subdir.mk since it no longer recurses; only 'install' will recurse and call the proper 'beforeinstall', 'realinstall', and 'afterinstall' in each sub-directory. This fixes 'make includes' and 'make files' to not be a rerolled ${MAKE} sub-shell but to rather just recurse on 'inclues' and 'files'. This avoids various issues such as the one fixed in r289462. As such revert Makefile.inc1 back to using 'includes' which avoids an extra tree walk and parallelizes the includes phases better. Makefile.inc1 includes a guard so that 'make all' will not use SUBDIR_PARALLEL, added in r289438. This is so users do not get a probably broken build if they run 'make all' from the top-level. Before the change in this commit, the workaround for 'make everything' was 'par-all' which would depend on 'all' and cause a proper parallel recursion. Now that will not work so a new _PARALLEL_SUBUDIR_OK is used to allow it. This is still part of an effort to combine bsd.(files|incs|confs).mk and move some of its logic out of bsd.subdir.mk, as attempted in r289282 and reverted in r289331. This commit fixes the problems found there which was mostly double recursing during 'includes' which would recurse on itself and 'buildincludes' and 'installincludes', all in parallel. The logic is still in bsd.subdir.mk for now. I've been cautious about this commit but have experienced no breakage on the tree except for the 'par-all' case which was already a hack. If something foo is depending on something bar that should recurse, it is very likely that the foo target is being recursed on already meaning that bar will still effectively recurse once sub-directories call foo. Discussed on: arch@ MFC after: never Sponsored by: EMC / Isilon Storage Division
2015-12-02 01:50:22 +00:00
# Enable SUBDIR_PARALLEL when not calling 'make all', unless called from
# 'everything' with _PARALLEL_SUBDIR_OK set. This is because it is unlikely
bsd.subdir.mk: Only recurse on called targets, rather than dependencies. This is to fix 'make all' causing it to recurse on both 'all' and 'buildconfig' due to 'buildconfig' being in ALL_SUBDIR_TARGETS and being a dependency of 'all'. This now adds all of the '*includes', '*files' targets as subdir targets, allowing them to recurse. This also removes the need for some 'realinstall' hacks in bsd.subdir.mk since it no longer recurses; only 'install' will recurse and call the proper 'beforeinstall', 'realinstall', and 'afterinstall' in each sub-directory. This fixes 'make includes' and 'make files' to not be a rerolled ${MAKE} sub-shell but to rather just recurse on 'inclues' and 'files'. This avoids various issues such as the one fixed in r289462. As such revert Makefile.inc1 back to using 'includes' which avoids an extra tree walk and parallelizes the includes phases better. Makefile.inc1 includes a guard so that 'make all' will not use SUBDIR_PARALLEL, added in r289438. This is so users do not get a probably broken build if they run 'make all' from the top-level. Before the change in this commit, the workaround for 'make everything' was 'par-all' which would depend on 'all' and cause a proper parallel recursion. Now that will not work so a new _PARALLEL_SUBUDIR_OK is used to allow it. This is still part of an effort to combine bsd.(files|incs|confs).mk and move some of its logic out of bsd.subdir.mk, as attempted in r289282 and reverted in r289331. This commit fixes the problems found there which was mostly double recursing during 'includes' which would recurse on itself and 'buildincludes' and 'installincludes', all in parallel. The logic is still in bsd.subdir.mk for now. I've been cautious about this commit but have experienced no breakage on the tree except for the 'par-all' case which was already a hack. If something foo is depending on something bar that should recurse, it is very likely that the foo target is being recursed on already meaning that bar will still effectively recurse once sub-directories call foo. Discussed on: arch@ MFC after: never Sponsored by: EMC / Isilon Storage Division
2015-12-02 01:50:22 +00:00
# that running 'make all' from the top-level, especially with a SUBDIR_OVERRIDE
# or LOCAL_DIRS set, will have a reliable build if SUBDIRs are built in
# parallel. This is safe for the world stage of buildworld though since it has
# already built libraries in a proper order and installed includes into
# WORLDTMP. Special handling is done for SUBDIR ordering for 'install*' to
# avoid trashing a system if it crashes mid-install.
.if !make(all) || defined(_PARALLEL_SUBDIR_OK)
Rework the world subdir build targets to use the standard SUBDIR_PARALLEL mechanism. Back in r30113, the 'par-*' targets were added to parallelize portions of the build in a very similar fashion as the SUBDIR_PARALLEL feature used in r263778. Calling a target without 'par-' (for 'parallel') resulted in the standard bsd.subdir.mk handling without parallelization. Given we have SUBDIR_PARALLEL now there is no reason to duplicate the handling here. In build logs this will result in the ${dir}.${target}__D targets now showing as the normal ${target}_subdir_${dir} targets. I audited all of the uses of Makefile.inc1 and Makefile's targets that use bsd.subdir.mk and found that all but 'all' and 'install' were fine to use as always parallel. - For 'install' (from installworld -j) the ordering of lib/ and libexec/ before the rest of the system (described in r289433), and etc/ being last (described in r289435), is all that matters. So now a .WAIT is added in the proper places when invoking any 'install*' target. A parallel installworld does work and took 46% of the time a non-parallel install would take on my system with -j15 to ZFS. - For 'all' I left the default handling for this to not run in parallel. A 'par-all' target is still used by the 'everything' stage of buildworld to continue building in parallel as it already has been. This works because most of the dependencies are handled by the early bootstrap phases as well as 'libraries' and 'includes' phases. This lets all of the SUBDIR build in parallel fine, such as bin/ and lib/. This will not work if the user invokes 'all' though as we have dependencies spread all over the system with no way to depend between them (except for the dirdeps feature in the META_MODE build). Calling 'make all' from the top-level is still useful at least when using SUBDIR_OVERRIDE. MFC after: 2 weeks Sponsored by: EMC / Isilon Storage Division
2015-10-17 03:51:50 +00:00
SUBDIR_PARALLEL=
.endif
.include <bsd.subdir.mk>
.if make(check-old) || make(check-old-dirs) || \
make(check-old-files) || make(check-old-libs) || \
make(delete-old) || make(delete-old-dirs) || \
make(delete-old-files) || make(delete-old-libs)
#
# check for / delete old files section
#
.include "ObsoleteFiles.inc"
OLD_LIBS_MESSAGE="Please be sure no application still uses those libraries, \
else you can not start such an application. Consult UPDATING for more \
information regarding how to cope with the removal/revision bump of a \
specific library."
.if !defined(BATCH_DELETE_OLD_FILES)
RM_I=-i
.else
RM_I=-v
.endif
delete-old-files: .PHONY
@echo ">>> Removing old files (only deletes safe to delete libs)"
# Ask for every old file if the user really wants to remove it.
2005-08-23 07:58:55 +00:00
# It's annoying, but better safe than sorry.
# NB: We cannot pass the list of OLD_FILES as a parameter because the
# argument list will get too long. Using .for/.endfor make "loops" will make
# the Makefile parser segfault.
@exec 3<&0; \
cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_FILES -V "OLD_FILES:Musr/share/*.gz:R" | xargs -n1 | sort | \
while read file; do \
if [ -f "${DESTDIR}/$${file}" -o -L "${DESTDIR}/$${file}" ]; then \
chflags noschg "${DESTDIR}/$${file}" 2>/dev/null || true; \
rm ${RM_I} "${DESTDIR}/$${file}" <&3; \
fi; \
for ext in debug symbols; do \
if ! [ -e "${DESTDIR}/$${file}" ] && [ -f \
"${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" ]; then \
rm ${RM_I} "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" \
<&3; \
fi; \
done; \
done
# Remove catpages without corresponding manpages.
@exec 3<&0; \
find ${DESTDIR}/usr/share/man/cat* ! -type d 2>/dev/null | sort | \
sed -ep -e's:${DESTDIR}/usr/share/man/cat:${DESTDIR}/usr/share/man/man:' | \
while read catpage; do \
read manpage; \
if [ ! -e "$${manpage}" ]; then \
rm ${RM_I} $${catpage} <&3; \
fi; \
done
@echo ">>> Old files removed"
check-old-files: .PHONY
@echo ">>> Checking for old files"
@cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_FILES -V "OLD_FILES:Musr/share/*.gz:R" | xargs -n1 | \
while read file; do \
if [ -f "${DESTDIR}/$${file}" -o -L "${DESTDIR}/$${file}" ]; then \
echo "${DESTDIR}/$${file}"; \
fi; \
for ext in debug symbols; do \
if [ -f "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" ]; then \
echo "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}"; \
fi; \
done; \
done | sort
# Check for catpages without corresponding manpages.
@find ${DESTDIR}/usr/share/man/cat* ! -type d 2>/dev/null | \
sed -ep -e's:${DESTDIR}/usr/share/man/cat:${DESTDIR}/usr/share/man/man:' | \
while read catpage; do \
read manpage; \
if [ ! -e "$${manpage}" ]; then \
echo $${catpage}; \
fi; \
done | sort
delete-old-libs: .PHONY
@echo ">>> Removing old libraries"
@echo "${OLD_LIBS_MESSAGE}" | fmt
@exec 3<&0; \
cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_LIBS | xargs -n1 | sort | \
while read file; do \
if [ -f "${DESTDIR}/$${file}" -o -L "${DESTDIR}/$${file}" ]; then \
chflags noschg "${DESTDIR}/$${file}" 2>/dev/null || true; \
rm ${RM_I} "${DESTDIR}/$${file}" <&3; \
fi; \
for ext in debug symbols; do \
if ! [ -e "${DESTDIR}/$${file}" ] && [ -f \
"${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" ]; then \
rm ${RM_I} "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" \
<&3; \
fi; \
done; \
done
@echo ">>> Old libraries removed"
check-old-libs: .PHONY
@echo ">>> Checking for old libraries"
@cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_LIBS | xargs -n1 | \
while read file; do \
if [ -f "${DESTDIR}/$${file}" -o -L "${DESTDIR}/$${file}" ]; then \
echo "${DESTDIR}/$${file}"; \
fi; \
for ext in debug symbols; do \
if [ -f "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}" ]; then \
echo "${DESTDIR}${DEBUGDIR}/$${file}.$${ext}"; \
fi; \
done; \
done | sort
delete-old-dirs: .PHONY
@echo ">>> Removing old directories"
@cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_DIRS | xargs -n1 | sort -r | \
while read dir; do \
if [ -d "${DESTDIR}/$${dir}" ]; then \
rmdir -v "${DESTDIR}/$${dir}" || true; \
elif [ -L "${DESTDIR}/$${dir}" ]; then \
echo "${DESTDIR}/$${dir} is a link, please remove everything manually."; \
fi; \
if [ -d "${DESTDIR}${DEBUGDIR}/$${dir}" ]; then \
rmdir -v "${DESTDIR}${DEBUGDIR}/$${dir}" || true; \
elif [ -L "${DESTDIR}${DEBUGDIR}/$${dir}" ]; then \
echo "${DESTDIR}${DEBUGDIR}/$${dir} is a link, please remove everything manually."; \
fi; \
done
@echo ">>> Old directories removed"
check-old-dirs: .PHONY
@echo ">>> Checking for old directories"
@cd ${.CURDIR}; \
${MAKE} -f ${.CURDIR}/Makefile.inc1 ${.MAKEFLAGS} ${.TARGET} \
-V OLD_DIRS | xargs -n1 | sort -r | \
while read dir; do \
if [ -d "${DESTDIR}/$${dir}" ]; then \
echo "${DESTDIR}/$${dir}"; \
elif [ -L "${DESTDIR}/$${dir}" ]; then \
echo "${DESTDIR}/$${dir} is a link, please remove everything manually."; \
fi; \
if [ -d "${DESTDIR}${DEBUGDIR}/$${dir}" ]; then \
echo "${DESTDIR}${DEBUGDIR}/$${dir}"; \
elif [ -L "${DESTDIR}${DEBUGDIR}/$${dir}" ]; then \
echo "${DESTDIR}${DEBUGDIR}/$${dir} is a link, please remove everything manually."; \
fi; \
done
delete-old: delete-old-files delete-old-dirs .PHONY
@echo "To remove old libraries run '${MAKE_CMD} delete-old-libs'."
check-old: check-old-files check-old-libs check-old-dirs .PHONY
@echo "To remove old files and directories run '${MAKE_CMD} delete-old'."
@echo "To remove old libraries run '${MAKE_CMD} delete-old-libs'."
.endif
#
# showconfig - show build configuration.
#
showconfig: .PHONY
@(${MAKE} -n -f ${.CURDIR}/sys/conf/kern.opts.mk -V dummy -dg1 UPDATE_DEPENDFILE=no NO_OBJ=yes; \
${MAKE} -n -f ${.CURDIR}/share/mk/src.opts.mk -V dummy -dg1 UPDATE_DEPENDFILE=no NO_OBJ=yes) 2>&1 | grep ^MK_ | sort -u
.if !empty(KRNLOBJDIR) && !empty(KERNCONF)
DTBOUTPUTPATH= ${KRNLOBJDIR}/${KERNCONF}/
.if !defined(FDT_DTS_FILE) || empty(FDT_DTS_FILE)
.if !defined(_MKSHOWCONFIG) && exists(${KERNCONFDIR}/${KERNCONF})
FDT_DTS_FILE!= awk 'BEGIN {FS="="} /^makeoptions[[:space:]]+FDT_DTS_FILE/ {print $$2}' \
'${KERNCONFDIR}/${KERNCONF}' ; echo
.endif
.endif
.endif
.if !defined(DTBOUTPUTPATH) || !exists(${DTBOUTPUTPATH})
DTBOUTPUTPATH= ${.CURDIR}
.endif
#
# Build 'standalone' Device Tree Blob
#
builddtb: .PHONY
@PATH=${TMPPATH} MACHINE=${TARGET} \
${.CURDIR}/sys/tools/fdt/make_dtb.sh ${.CURDIR}/sys \
"${FDT_DTS_FILE}" ${DTBOUTPUTPATH}
###############
# cleanworld
# In the following, the first 'rm' in a series will usually remove all
# files and directories. If it does not, then there are probably some
# files with file flags set, so this unsets them and tries the 'rm' a
# second time. There are situations where this target will be cleaning
# some directories via more than one method, but that duplication is
# needed to correctly handle all the possible situations. Removing all
# files without file flags set in the first 'rm' instance saves time,
# because 'chflags' will need to operate on fewer files afterwards.
#
# It is expected that BW_CANONICALOBJDIR == the CANONICALOBJDIR as would be
# created by bsd.obj.mk, except that we don't want to .include that file
# in this makefile. We don't do a cleandir walk if MK_AUTO_OBJ is yes
# since it is not possible for files to land in the wrong place.
#
.if make(cleanworld)
BW_CANONICALOBJDIR:=${OBJTOP}/
.elif make(cleanuniverse)
BW_CANONICALOBJDIR:=${OBJROOT}
.if ${MK_UNIFIED_OBJDIR} == "no"
.error ${.TARGETS} only supported with WITH_UNIFIED_OBJDIR enabled.
.endif
.endif
cleanworld cleanuniverse: .PHONY
.if !empty(BW_CANONICALOBJDIR) && exists(${BW_CANONICALOBJDIR}) && \
${.CURDIR:tA} != ${BW_CANONICALOBJDIR:tA}
-rm -rf ${BW_CANONICALOBJDIR}*
-chflags -R 0 ${BW_CANONICALOBJDIR}
rm -rf ${BW_CANONICALOBJDIR}*
.endif
.if make(cleanworld) && ${MK_AUTO_OBJ} == "no" && \
(empty(BW_CANONICALOBJDIR) || ${.CURDIR:tA} == ${BW_CANONICALOBJDIR:tA})
.if ${.CURDIR} == ${.OBJDIR} || ${.CURDIR}/obj == ${.OBJDIR}
# To be safe in this case, fall back to a 'make cleandir'
${_+_}@cd ${.CURDIR}; ${MAKE} cleandir
.endif
.endif
.if ${TARGET} == ${MACHINE} && ${TARGET_ARCH} == ${MACHINE_ARCH}
XDEV_CPUTYPE?=${CPUTYPE}
.else
XDEV_CPUTYPE?=${TARGET_CPUTYPE}
.endif
NOFUN=-DNO_FSCHG MK_HTML=no -DNO_LINT \
2014-04-25 19:25:26 +00:00
MK_MAN=no MK_NLS=no MK_PROFILE=no \
MK_KERBEROS=no MK_RESCUE=no MK_TESTS=no MK_WARNS=no \
TARGET=${TARGET} TARGET_ARCH=${TARGET_ARCH} \
CPUTYPE=${XDEV_CPUTYPE}
XDDIR=${TARGET_ARCH}-freebsd
XDTP?=/usr/${XDDIR}
.if ${XDTP:N/*}
.error XDTP variable should be an absolute path
.endif
CDBOBJROOT= ${OBJROOT}${MACHINE}.${MACHINE_ARCH}/xdev/
CDBOBJTOP= ${CDBOBJROOT}${XDDIR}
CDBENV= \
INSTALL="sh ${.CURDIR}/tools/install.sh"
CDENV= ${CDBENV} \
TOOLS_PREFIX=${XDTP}
CDMAKEARGS= \
OBJTOP=${CDBOBJTOP:Q} \
OBJROOT=${CDBOBJROOT:Q}
CD2MAKEARGS= ${CDMAKEARGS}
.if ${WANT_COMPILER_TYPE} == gcc || \
(defined(X_COMPILER_TYPE) && ${X_COMPILER_TYPE} == gcc)
# GCC requires -isystem and -L when using a cross-compiler. --sysroot
# won't set header path and -L is used to ensure the base library path
# is added before the port PREFIX library path.
CD2CFLAGS+= -isystem ${XDDESTDIR}/usr/include -L${XDDESTDIR}/usr/lib
# GCC requires -B to find /usr/lib/crti.o when using a cross-compiler
# combined with --sysroot.
CD2CFLAGS+= -B${XDDESTDIR}/usr/lib
# Force using libc++ for external GCC.
.if defined(X_COMPILER_TYPE) && \
${X_COMPILER_TYPE} == gcc && ${X_COMPILER_VERSION} >= 40800
CD2CXXFLAGS+= -isystem ${XDDESTDIR}/usr/include/c++/v1 -std=c++11 \
-nostdinc++
.endif
.endif
CD2CFLAGS+= --sysroot=${XDDESTDIR}/
CD2ENV=${CDENV} CC="${CC} ${CD2CFLAGS}" CXX="${CXX} ${CD2CXXFLAGS} ${CD2CFLAGS}" \
CPP="${CPP} ${CD2CFLAGS}" \
MACHINE=${TARGET} MACHINE_ARCH=${TARGET_ARCH}
CDTMP= ${OBJTOP}/${XDDIR}/tmp
CDMAKE=${CDENV} PATH=${CDTMP}/usr/bin:${PATH} ${MAKE} ${CDMAKEARGS} ${NOFUN}
CD2MAKE=${CD2ENV} PATH=${CDTMP}/usr/bin:${XDDESTDIR}/usr/bin:${PATH} \
${MAKE} ${CD2MAKEARGS} ${NOFUN}
.if ${MK_META_MODE} != "no"
# Don't rebuild build-tools targets during normal build.
CD2MAKE+= BUILD_TOOLS_META=.NOMETA
.endif
XDDESTDIR=${DESTDIR}${XDTP}
.ORDER: xdev-build xdev-install xdev-links
xdev: xdev-build xdev-install .PHONY
.ORDER: _xb-worldtmp _xb-bootstrap-tools _xb-build-tools _xb-cross-tools
xdev-build: _xb-worldtmp _xb-bootstrap-tools _xb-build-tools _xb-cross-tools .PHONY
_xb-worldtmp: .PHONY
mkdir -p ${CDTMP}/usr
${WORLDTMP_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
-p ${CDTMP}/usr >/dev/null
_xb-bootstrap-tools: .PHONY
.for _tool in \
${_clang_tblgen} \
${_gperf} \
${_yacc}
${_+_}@${ECHODIR} "===> ${_tool} (obj,all,install)"; \
cd ${.CURDIR}/${_tool}; \
if [ -z "${NO_OBJWALK}" ]; then ${CDMAKE} DIRPRFX=${_tool}/ obj; fi; \
${CDMAKE} DIRPRFX=${_tool}/ all; \
${CDMAKE} DIRPRFX=${_tool}/ DESTDIR=${CDTMP} install
.endfor
_xb-build-tools: .PHONY
${_+_}@cd ${.CURDIR}; \
${CDBENV} ${MAKE} ${CDMAKEARGS} -f Makefile.inc1 ${NOFUN} build-tools
XDEVDIRS= \
${_clang_libs} \
${_lld} \
${_binutils} \
${_elftctools} \
usr.bin/ar \
${_clang} \
${_gcc}
_xb-cross-tools: .PHONY
.for _tool in ${XDEVDIRS}
${_+_}@${ECHODIR} "===> xdev ${_tool} (obj,all)"; \
cd ${.CURDIR}/${_tool}; \
if [ -z "${NO_OBJWALK}" ]; then ${CDMAKE} DIRPRFX=${_tool}/ obj; fi; \
${CDMAKE} DIRPRFX=${_tool}/ all
.endfor
_xi-mtree: .PHONY
${_+_}@${ECHODIR} "mtree populating ${XDDESTDIR}"
mkdir -p ${XDDESTDIR}
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.root.dist \
-p ${XDDESTDIR} >/dev/null
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.usr.dist \
-p ${XDDESTDIR}/usr >/dev/null
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.include.dist \
-p ${XDDESTDIR}/usr/include >/dev/null
.if defined(LIBCOMPAT)
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.lib${libcompat}.dist \
-p ${XDDESTDIR}/usr >/dev/null
.endif
.if ${MK_TESTS} != "no"
mkdir -p ${XDDESTDIR}${TESTSBASE}
${DESTDIR_MTREE} -f ${.CURDIR}/etc/mtree/BSD.tests.dist \
-p ${XDDESTDIR}${TESTSBASE} >/dev/null
.endif
.ORDER: xdev-build _xi-mtree _xi-cross-tools _xi-includes _xi-libraries
xdev-install: xdev-build _xi-mtree _xi-cross-tools _xi-includes _xi-libraries .PHONY
_xi-cross-tools: .PHONY
@echo "_xi-cross-tools"
.for _tool in ${XDEVDIRS}
${_+_}@${ECHODIR} "===> xdev ${_tool} (install)"; \
cd ${.CURDIR}/${_tool}; \
${CDMAKE} DIRPRFX=${_tool}/ install DESTDIR=${XDDESTDIR}
.endfor
_xi-includes: .PHONY
.if !defined(NO_OBJWALK)
${_+_}cd ${.CURDIR}; ${CD2MAKE} -f Makefile.inc1 _obj \
DESTDIR=${XDDESTDIR}
.endif
bsd.subdir.mk: Only recurse on called targets, rather than dependencies. This is to fix 'make all' causing it to recurse on both 'all' and 'buildconfig' due to 'buildconfig' being in ALL_SUBDIR_TARGETS and being a dependency of 'all'. This now adds all of the '*includes', '*files' targets as subdir targets, allowing them to recurse. This also removes the need for some 'realinstall' hacks in bsd.subdir.mk since it no longer recurses; only 'install' will recurse and call the proper 'beforeinstall', 'realinstall', and 'afterinstall' in each sub-directory. This fixes 'make includes' and 'make files' to not be a rerolled ${MAKE} sub-shell but to rather just recurse on 'inclues' and 'files'. This avoids various issues such as the one fixed in r289462. As such revert Makefile.inc1 back to using 'includes' which avoids an extra tree walk and parallelizes the includes phases better. Makefile.inc1 includes a guard so that 'make all' will not use SUBDIR_PARALLEL, added in r289438. This is so users do not get a probably broken build if they run 'make all' from the top-level. Before the change in this commit, the workaround for 'make everything' was 'par-all' which would depend on 'all' and cause a proper parallel recursion. Now that will not work so a new _PARALLEL_SUBUDIR_OK is used to allow it. This is still part of an effort to combine bsd.(files|incs|confs).mk and move some of its logic out of bsd.subdir.mk, as attempted in r289282 and reverted in r289331. This commit fixes the problems found there which was mostly double recursing during 'includes' which would recurse on itself and 'buildincludes' and 'installincludes', all in parallel. The logic is still in bsd.subdir.mk for now. I've been cautious about this commit but have experienced no breakage on the tree except for the 'par-all' case which was already a hack. If something foo is depending on something bar that should recurse, it is very likely that the foo target is being recursed on already meaning that bar will still effectively recurse once sub-directories call foo. Discussed on: arch@ MFC after: never Sponsored by: EMC / Isilon Storage Division
2015-12-02 01:50:22 +00:00
${_+_}cd ${.CURDIR}; ${CD2MAKE} -f Makefile.inc1 includes \
DESTDIR=${XDDESTDIR}
_xi-libraries: .PHONY
${_+_}cd ${.CURDIR}; ${CD2MAKE} -f Makefile.inc1 libraries \
DESTDIR=${XDDESTDIR}
xdev-links: .PHONY
${_+_}cd ${XDDESTDIR}/usr/bin; \
mkdir -p ../../../../usr/bin; \
for i in *; do \
ln -sf ../../${XDTP}/usr/bin/$$i \
../../../../usr/bin/${XDDIR}-$$i; \
ln -sf ../../${XDTP}/usr/bin/$$i \
../../../../usr/bin/${XDDIR}${_REVISION}-$$i; \
done