Makefile (revision 25b05a3e) - OpenGrok cross reference for /illumos-gate/usr/src/pkg/Makefile

#
# CDDL HEADER START
#
# The contents of this file are subject to the terms of the
# Common Development and Distribution License (the "License").
# You may not use this file except in compliance with the License.
#
# You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
# or http://www.opensolaris.org/os/licensing.
# See the License for the specific language governing permissions
# and limitations under the License.
#
# When distributing Covered Code, include this CDDL HEADER in each
# file and include the License file at usr/src/OPENSOLARIS.LICENSE.
# If applicable, add the following below this CDDL HEADER, with the
# fields enclosed by brackets "[]" replaced with your own identifying
# information: Portions Copyright [yyyy] [name of copyright owner]
#
# CDDL HEADER END
#

#
# Copyright (c) 2010, Oracle and/or its affiliates. All rights reserved.
# Copyright 2015, OmniTI Computer Consulting, Inc. All rights reserved.
# Copyright 2015 Igor Kozhukhov <ikozhukhov@gmail.com>
# Copyright 2016 RackTop Systems.
# Copyright 2020 OmniOS Community Edition (OmniOSce) Association.
# Copyright 2020 Peter Tribble
#

include $(SRC)/Makefile.master
include $(SRC)/Makefile.buildnum

#
# Make sure we're getting a consistent execution environment for the
# embedded scripts.
#
SHELL= /usr/bin/ksh93

#
# To suppress package dependency generation on any system, regardless
# of how it was installed, set SUPPRESSPKGDEP=true in the build
# environment.
#
SUPPRESSPKGDEP= false

#
# Comment this line out or set "PKGDEBUG=" in your build environment
# to get more verbose output from the make processes in usr/src/pkg
#
PKGDEBUG= @

#
# Cross platform packaging notes
#
# By default, we package the proto area from the same architecture as
# the packaging build.  In other words, if you're running nightly or
# bldenv on an x86 platform, it will take objects from the x86 proto
# area and use them to create x86 repositories.
#
# If you want to create repositories for an architecture that's
# different from $(uname -p), you do so by setting PKGMACH in your
# build environment.
#
# For this to work correctly, the following must all happen:
#
#   1. You need the desired proto area, which you can get either by
#      doing a gatekeeper-style build with the -U option to
#      nightly(1), or by using rsync.  If you don't do this, you will
#      get packaging failures building all packages, because pkgsend
#      is unable to find the required binaries.
#   2. You need the desired tools proto area, which you can get in the
#      same ways as the normal proto area.  If you don't do this, you
#      will get packaging failures building onbld, because pkgsend is
#      unable to find the tools binaries.
#   3. The remainder of this Makefile should never refer directly to
#      $(MACH).  Instead, $(PKGMACH) should be used whenever an
#      architecture-specific path or token is needed.  If this is done
#      incorrectly, then packaging will fail, and you will see the
#      value of $(uname -p) instead of the value of $(PKGMACH) in the
#      commands that fail.
#   4. Each time a rule in this Makefile invokes $(MAKE), it should
#      pass PKGMACH=$(PKGMACH) explicitly on the command line.  If
#      this is done incorrectly, then packaging will fail, and you
#      will see the value of $(uname -p) instead of the value of
#      $(PKGMACH) in the commands that fail.
#
# Refer also to the convenience targets defined later in this
# Makefile.
#
PKGMACH=	$(MACH)

#
# ROOT, TOOLS_PROTO, and PKGARCHIVE should be set by nightly or
# bldenv.  These macros translate them into terms of $PKGMACH, instead
# of $ARCH.
#
PKGROOT.cmd=	print $(ROOT) | sed -e s:/root_$(MACH):/root_$(PKGMACH):
PKGROOT=	$(PKGROOT.cmd:sh)
TOOLSROOT.cmd=	print $(TOOLS_PROTO) | sed -e s:/root_$(MACH):/root_$(PKGMACH):
TOOLSROOT=	$(TOOLSROOT.cmd:sh)
PKGDEST.cmd=	print $(PKGARCHIVE) | sed -e s:/$(MACH)/:/$(PKGMACH)/:
PKGDEST=	$(PKGDEST.cmd:sh)

EXCEPTIONS= packaging

PKGMOGRIFY= pkgmogrify

#
# Always build the redistributable repository, but only build the
# nonredistributable bits if we have access to closed source.
#
# Some objects that result from the closed build are still
# redistributable, and should be packaged as part of an open-only
# build.  Access to those objects is provided via the closed-bins
# tarball.  See usr/src/tools/scripts/bindrop.sh for details.
#
REPOS= redist

#
# The packages directory will contain the processed manifests as
# direct build targets and subdirectories for package metadata extracted
# incidentally during manifest processing.
#
# Nothing underneath $(PDIR) should ever be managed by SCM.
#
PDIR= packages.$(PKGMACH)

#
# The tools proto must be specified for dependency generation.
# Publication from the tools proto area is managed in the
# publication rule.
#
$(PDIR)/developer-build-onbld.dep:= PKGROOT= $(TOOLSROOT)

PKGPUBLISHER= $(PKGPUBLISHER_REDIST)

#
# To get these defaults, manifests should simply refer to $(PKGVERS).
#
PKGVERS_COMPONENT= 0.$(RELEASE)
PKGVERS_BUILTON= $(RELEASE)
PKGVERS_BRANCH= 0.$(ONNV_BUILDNUM)
PKGVERS= $(PKGVERS_COMPONENT),$(PKGVERS_BUILTON)-$(PKGVERS_BRANCH)

#
# The ARCH32 and ARCH64 macros are used in the manifests to express
# architecture-specific subdirectories in the installation paths
# for isaexec'd commands.
#
# We can't simply use $(MACH32) and $(MACH64) here, because they're
# only defined for the build architecture.  To do cross-platform
# packaging, we need both values.
#
i386_ARCH32= i86
sparc_ARCH32= sparcv7
i386_ARCH64= amd64
sparc_ARCH64= sparcv9

#
# macros and transforms needed by pkgmogrify
#
# If you append to this list using target-specific assignments (:=),
# be very careful that the targets are of the form $(PDIR)/pkgname.  If
# you use a higher level target, or a package list, you'll trigger a
# complete reprocessing of all manifests because they'll fail command
# dependency checking.
#
PM_TRANSFORMS= common_actions publish restart_fmri facets defaults \
	extract_metadata
PM_FINAL_TRANSFORMS= strip_dependinfo
PM_INC= transforms manifests

JAVA_8_ONLY=
JAVA_11_ONLY=
$(BLD_JAVA_11)JAVA_8_ONLY=$(POUND_SIGN)
$(JAVA_8_ONLY)JAVA_11_ONLY=$(POUND_SIGN)

PKGMOG_DEFINES= \
	i386_ONLY=$(POUND_SIGN) \
	sparc_ONLY=$(POUND_SIGN) \
	$(PKGMACH)_ONLY= \
	ARCH=$(PKGMACH) \
	ARCH32=$($(PKGMACH)_ARCH32) \
	ARCH64=$($(PKGMACH)_ARCH64) \
	PKGVERS_COMPONENT=$(PKGVERS_COMPONENT) \
	PKGVERS_BUILTON=$(PKGVERS_BUILTON) \
	PKGVERS_BRANCH=$(PKGVERS_BRANCH) \
	PKGVERS=$(PKGVERS) \
	PERL_ARCH=$(PERL_ARCH) \
	PERL_ARCH64=$(PERL_ARCH64) \
	PERL_VERSION=$(PERL_VERSION) \
	PERL_PKGVERS=$(PERL_PKGVERS) \
	BUILDPERL32=$(BUILDPERL32) \
	BUILDPERL64=$(BUILDPERL64) \
	PYTHON_VERSION=$(PYTHON_VERSION) \
	PYTHON3_VERSION=$(PYTHON3_VERSION) \
	PYTHON_PKGVERS=$(PYTHON_PKGVERS) \
	PYTHON3_PKGVERS=$(PYTHON3_PKGVERS) \
	python2_ONLY=$(BUILDPY2) \
	python3_ONLY=$(BUILDPY3) \
	python2tools_ONLY=$(BUILDPY2TOOLS) \
	python3tools_ONLY=$(BUILDPY3TOOLS) \
	JAVA_11_ONLY=$(JAVA_11_ONLY) \
	JAVA_8_ONLY=$(JAVA_8_ONLY)

PKGDEP_TOKENS_i386= \
	'PLATFORM=i86hvm' \
	'PLATFORM=i86pc' \
	'PLATFORM=i86xpv' \
	'ISALIST=amd64' \
	'ISALIST=i386'
PKGDEP_TOKENS_sparc= \
	'PLATFORM=sun4u' \
	'PLATFORM=sun4v' \
	'ISALIST=sparcv9' \
	'ISALIST=sparc'
PKGDEP_TOKENS= $(PKGDEP_TOKENS_$(PKGMACH))

#
# The package lists are generated with $(PKGDEP_TYPE) as their
# dependency types, so that they can be included by either an
# incorporation or a group package.
#
$(PDIR)/osnet-redist.mog := PKGDEP_TYPE= require
$(PDIR)/osnet-incorporation.mog:= PKGDEP_TYPE= incorporate

PKGDEP_INCORP= \
	depend fmri=consolidation/osnet/osnet-incorporation type=require

#
# All packaging build products should go into $(PDIR), so they don't
# need to be included separately in CLOBBERFILES.
#
CLOBBERFILES= $(PDIR) proto_list_$(PKGMACH) install-$(PKGMACH).out \
	license-list

#
# By default, PKGS will list all manifests.  To build and/or publish a
# subset of packages, override this on the command line or in the
# build environment and then reference (implicitly or explicitly) the all
# or install targets.
#
# We want some manifests to optionally build based on environment options, so
# those are excluded when generating the list of manifests and added back in if
# necessary. We also want a relatively easy way to add files to the list of
# manifests given special treatment. Add any other special ones to the
# SPECIAL_MANIFESTS variable. It can contain wildcards in regexp form, i.e.
# SUNW.* as one useful example.
#
SPECIAL_MANIFESTS = system-library-python-.*
LIST_MANIFESTS_CMD = (cd manifests ; /usr/bin/ls -1 *.p5m |\
	$(SED) $(SPECIAL_MANIFESTS:%=-e '/^%$$/d') )
MANIFESTS = $(LIST_MANIFESTS_CMD:sh)

# Conditionally add back python modules
$(BUILDPY2) MANIFESTS += \
	system-library-python-libbe-2.p5m \
	system-library-python-solaris-2.p5m \
	system-library-python-zfs-2.p5m
$(BUILDPY3) MANIFESTS += \
	system-library-python-libbe-3.p5m \
	system-library-python-solaris-3.p5m \
	system-library-python-zfs-3.p5m

PKGS= $(MANIFESTS:%.p5m=%)
DEP_PKGS= $(PKGS:%=$(PDIR)/%.dep)
PROC_PKGS= $(PKGS:%=$(PDIR)/%.mog)
FIN_PKGS= $(PKGS:%=$(PDIR)/%.fin)

#
# Track the synthetic manifests separately so we can properly express
# build rules and dependencies.  The synthetic and real packages use
# different sets of transforms and macros for pkgmogrify.
#
SYNTH_PKGS= osnet-incorporation osnet-redist
DEP_SYNTH_PKGS= $(SYNTH_PKGS:%=$(PDIR)/%.dep)
PROC_SYNTH_PKGS= $(SYNTH_PKGS:%=$(PDIR)/%.mog)

#
# Root of pkg image to use for dependency resolution
# Normally / on the machine used to build the binaries
#
PKGDEP_RESOLVE_IMAGE = /

#
# For each package, we determine the target repository based on
# manifest-embedded metadata.  Because we make that determination on
# the fly, the publication target cannot be expressed as a
# subdirectory inside the unknown-by-the-makefile target repository.
#
# In order to limit the target set to real files in known locations,
# we use a ".pub" file in $(PDIR) for each processed manifest, regardless
# of content or target repository.
#
PUB_PKGS= $(SYNTH_PKGS:%=$(PDIR)/%.pub) $(PKGS:%=$(PDIR)/%.pub)

#
# Any given repository- and status-specific package list may be empty,
# but we can only determine that dynamically, so we always generate all
# lists for each repository we're building.
#
# The meanings of each package status are as follows:
#
#	PKGSTAT		meaning
#	----------	----------------------------------------------------
#	noincorp	Do not include in incorporation or group package
#	obsolete	Include in incorporation, but not group package
#	renamed		Include in incorporation, but not group package
#	current		Include in incorporation and group package
#
# Since the semantics of the "noincorp" package status dictate that
# such packages are not included in the incorporation or group packages,
# there is no need to build noincorp package lists.
#
PKGLISTS= \
	$(REPOS:%=$(PDIR)/packages.%.current) \
	$(REPOS:%=$(PDIR)/packages.%.renamed) \
	$(REPOS:%=$(PDIR)/packages.%.obsolete)

.KEEP_STATE:

.PARALLEL: $(PKGS) $(PROC_PKGS) $(DEP_PKGS) \
	$(PROC_SYNTH_PKGS) $(DEP_SYNTH_PKGS) $(FIN_PKGS) $(PUB_PKGS)

#
# For a single manifest, the dependency chain looks like this:
#
#	raw manifest (mypkg.p5m)
#		|
#		| use pkgmogrify to process raw manifest
#		|
#	processed manifest (mypkg.mog)
#		|
#	   *    | use pkgdepend generate to generate dependencies
#		|
#	manifest with TBD dependencies (mypkg.dep)
#		|
#	   %    | use pkgdepend resolve to resolve dependencies
#		|
#	manifest with dependencies resolved (mypkg.res)
#		|
#		| use pkgmogrify to apply final cleanups
#		|
#	cleaned up manifest (mypkg.fin)
#		|
#		| use pkgsend to publish the package
#		|
#	placeholder to indicate successful publication (mypkg.pub)
#
# * This may be suppressed via SUPPRESSPKGDEP.  The resulting
#   packages will install correctly, but care must be taken to
#   install all dependencies, because pkg will not have the input
#   it needs to determine this automatically.
#
# % This is included in this diagram to make the picture complete, but
#   this is a point of synchronization in the build process.
#   Dependency resolution is actually done once on the entire set of
#   manifests, not on a per-package basis.
#
# The full dependency chain for generating everything that needs to be
# published, without actually publishing it, looks like this:
#
#	processed synthetic packages
#		|		|
#       package lists	    synthetic package manifests
#		|
#	processed real packages
#	    |		|
#	package dir	real package manifests
#
# Here, each item is a set of real or synthetic packages.  For this
# portion of the build, no reference is made to the proto area.  It is
# therefore suitable for the "all" target, as opposed to "install."
#
# Since each of these steps is expressed explicitly, "all" need only
# depend on the head of the chain.
#
# From the end of manifest processing, the publication dependency
# chain looks like this:
#
#		repository metadata (catalogs and search indices)
#			|
#			| pkgrepo refresh
#			|
#		published packages
#		 |		|
#		 |		| pkgsend publish
#		 |		|
#	  repositories	    final manifests
#		 |			|
# pkgsend	 |			| pkgmogrify final
# create-repository			|
#		 |		resolved dependencies
#	 repo directories		|
#					| pkgdepend resolve
#					|
#				    generated dependencies
#					|
#					| pkgdepend
#					|
#                                    processed manifests

ALL_TARGETS= $(PROC_SYNTH_PKGS) proto_list_$(PKGMACH)

all: $(ALL_TARGETS)

#
# This will build the directory to contain the processed manifests
# and the metadata symlinks.
#
$(PDIR):
	@print "Creating $(@)"
	$(PKGDEBUG)$(INS.dir)

#
# This rule resolves dependencies across all published manifests.
#
$(PDIR)/gendeps: $(DEP_SYNTH_PKGS) $(DEP_PKGS)
	$(PKGDEBUG)if [ "$(SUPPRESSPKGDEP)" = "true" ]; then \
		print "Suppressing dependency resolution"; \
		for p in $(DEP_PKGS:%.dep=%); do \
			$(CP) $$p.dep $$p.res; \
		done; \
	else \
		print "Resolving dependencies"; \
		pkgdepend -R $(PKGDEP_RESOLVE_IMAGE) resolve \
		    -m $(DEP_SYNTH_PKGS) $(DEP_PKGS); \
		for p in $(DEP_SYNTH_PKGS:%.dep=%) $(DEP_PKGS:%.dep=%); do \
			if [ "$$(print $$p.metadata.*)" = \
			     "$$(print $$p.metadata.noincorp.*)" ]; \
			then \
				print "Removing dependency versions from $$p"; \
				$(PKGMOGRIFY) $(PKGMOG_VERBOSE) \
				    -O $$p.res -I transforms \
				    strip_versions $$p.dep.res; \
				$(RM) $$p.dep.res; \
			else \
				$(MV) $$p.dep.res $$p.res; \
			fi; \
		done; \
	fi
	$(PKGDEBUG)$(TOUCH) $(@)

install: $(ALL_TARGETS) repository-metadata

repository-metadata: publish_pkgs
	$(PKGDEBUG)for r in $(REPOS); do \
		pkgrepo refresh -s $(PKGDEST)/repo.$$r; \
	done

#
# Since we create zero-length processed manifests for a graceful abort
# from pkgmogrify, we need to detect that here and make no effort to
# publish the package.
#
# For all other packages, we publish them regardless of status.  We
# derive the target repository as a component of the metadata-derived
# symlink for each package.
#
publish_pkgs: $(REPOS:%=$(PKGDEST)/repo.%) $(PDIR)/gendeps .WAIT $(PUB_PKGS)

#
# Before publishing, we want to pull the license files from $CODEMGR_WS
# into the proto area.  This allows us to NOT pass $SRC (or
# $CODEMGR_WS) as a basedir for publication.
#
$(PUB_PKGS): stage-licenses

#
# Initialize the empty on-disk repositories
#
$(REPOS:%=$(PKGDEST)/repo.%):
	@print "Initializing $(@F)"
	$(PKGDEBUG)$(INS.dir)
	$(PKGDEBUG)pkgsend -s file://$(@) create-repository \
		--set-property publisher.prefix=$(PKGPUBLISHER)

#
# rule to process real manifests
#
# To allow redistributability and package status to change, we must
# remove not only the actual build target (the processed manifest), but
# also the incidental ones (the metadata-derived symlinks).
#
# If pkgmogrify exits cleanly but fails to create the specified output
# file, it means that it encountered an abort directive.  That means
# that this package should not be published for this particular build
# environment.  Since we can't prune such packages from $(PKGS)
# retroactively, we need to create an empty target file to keep make
# from trying to rebuild it every time.  For these empty targets, we
# do not create metadata symlinks.
#
# Automatic dependency resolution to files is also done at this phase of
# processing.  The skipped packages are skipped due to existing bugs
# in pkgdepend.
#
# The incorporation dependency is tricky: it needs to go into all
# current and renamed manifests (ie all incorporated packages), but we
# don't know which those are until after we run pkgmogrify.  So
# instead of expressing it as a transform, we tack it on ex post facto.
#
# Implementation notes:
#
# - The first $(RM) must not match other manifests, or we'll run into
#   race conditions with parallel manifest processing.
#
# - The make macros [ie $(MACRO)] are evaluated when the makefile is
#   read in, and will result in a fixed, macro-expanded rule for each
#   target enumerated in $(PROC_PKGS).
#
# - The shell variables (ie $$VAR) are assigned on the fly, as the rule
#   is executed.  The results may only be referenced in the shell in
#   which they are assigned, so from the perspective of make, all code
#   that needs these variables needs to be part of the same line of
#   code.  Hence the use of command separators and line continuation
#   characters.
#
# - The extract_metadata transforms are designed to spit out shell
#   variable assignments to stdout.  Those are published to the
#   .vars temporary files, and then used as input to the eval
#   statement.  This is done in stages specifically so that pkgmogrify
#   can signal failure if the manifest has a syntactic or other error.
#   The eval statement should begin with the default values, and the
#   output from pkgmogrify (if any) should be in the form of a
#   variable assignment to override those defaults.
#
# - When this rule completes execution, it must leave an updated
#   target file ($@) in place, or make will reprocess the package
#   every time it encounters it as a dependency.  Hence the "touch"
#   statement to ensure that the target is created, even when
#   pkgmogrify encounters an abort in the publish transforms.
#

.SUFFIXES: .p5m .mog .dep .res .fin .pub

$(PDIR)/%.mog: manifests/%.p5m
	@print "Processing manifest $(<F)"
	@pkgfmt -fv2 -c $<
	$(PKGDEBUG)$(RM) $(@) $(@:%.mog=%) $(@:%.mog=%.nodepend) \
		$(@:%.mog=%.lics) $(PDIR)/$(@F:%.mog=%).metadata.* $(@).vars
	$(PKGDEBUG)$(PKGMOGRIFY) $(PKGMOG_VERBOSE) $(PM_INC:%= -I %) \
		$(PKGMOG_DEFINES:%=-D %) -P $(@).vars -O $(@) \
		$(<) $(PM_TRANSFORMS)
	$(PKGDEBUG)eval REPO=redist PKGSTAT=current NODEPEND=$(SUPPRESSPKGDEP) \
		`$(CAT) -s $(@).vars`; \
	if [ -f $(@) ]; then \
		if [ "$$NODEPEND" != "false" ]; then \
			 $(TOUCH) $(@:%.mog=%.nodepend); \
		fi; \
		$(LN) -s $(@F) \
			$(PDIR)/$(@F:%.mog=%).metadata.$$PKGSTAT.$$REPO; \
		if [ \( "$$PKGSTAT" = "current" \) -o \
		     \( "$$PKGSTAT" = "renamed" \) ]; \
			then print $(PKGDEP_INCORP) >> $(@); \
		fi; \
		print $$LICS > $(@:%.mog=%.lics); \
	else \
		$(TOUCH) $(@) $(@:%.mog=%.lics); \
	fi
	$(PKGDEBUG)$(RM) $(@).vars

$(PDIR)/%.dep: $(PDIR)/%.mog
	@print "Generating dependencies for $(<F)"
	$(PKGDEBUG)$(RM) $(@)
	$(PKGDEBUG)if [ ! -f $(@:%.dep=%.nodepend) ]; then \
		pkgdepend generate -m $(PKGDEP_TOKENS:%=-D %) $(<) \
			$(PKGROOT) > $(@); \
	else \
		$(CP) $(<) $(@); \
	fi

#
# The full chain implies that there should be a .dep.res suffix rule,
# but dependency generation is done on a set of manifests, rather than
# on a per-manifest basis.  Instead, see the gendeps rule above.
#

$(PDIR)/%.fin: $(PDIR)/%.res
	$(PKGDEBUG)$(RM) $(@)
	$(PKGDEBUG)if [ -s $(<) ]; then \
		print "Running final transforms for $(<F)"; \
		$(PKGMOGRIFY) $(PKGMOG_VERBOSE) $(PM_INC:%= -I %) -O $(@) \
		    $(<) $(PM_FINAL_TRANSFORMS); \
	else \
		$(TOUCH) $(@); \
	fi

$(PDIR)/%.pub: $(PDIR)/%.fin
	$(PKGDEBUG)m=$$(basename $(@:%.pub=%).metadata.*); \
	r=$${m#$(@F:%.pub=%.metadata.)+(?).}; \
	if [ -s $(<) ]; then \
		print "Publishing $(@F:%.pub=%) to $$r repository"; \
		pkgsend -s file://$(PKGDEST)/repo.$$r publish \
		    -d $(PKGROOT) -d $(TOOLSROOT) \
		    -d license_files -d $(PKGROOT)/licenses \
		    --fmri-in-manifest --no-index --no-catalog $(<) \
		    > /dev/null; \
	fi; \
	$(TOUCH) $(@);

#
# rule to build the synthetic manifests
#
# This rule necessarily has PKGDEP_TYPE that changes according to
# the specific synthetic manifest.  Rather than escape command
# dependency checking for the real manifest processing, or failing to
# express the (indirect) dependency of synthetic manifests on real
# manifests, we simply split this rule out from the one above.
#
# The implementation notes from the previous rule are applicable
# here, too.
#
$(PROC_SYNTH_PKGS): $(PKGLISTS) $$(@F:%.mog=%.p5m)
	@print "Processing synthetic manifest $(@F:%.mog=%.p5m)"
	$(PKGDEBUG)$(RM) $(@) $(PDIR)/$(@F:%.mog=%).metadata.* $(@).vars
	$(PKGDEBUG)$(PKGMOGRIFY) $(PKGMOG_VERBOSE) -I transforms -I $(PDIR) \
		$(PKGMOG_DEFINES:%=-D %) -D PKGDEP_TYPE=$(PKGDEP_TYPE) \
		-P $(@).vars -O $(@) $(@F:%.mog=%.p5m) \
		$(PM_TRANSFORMS) synthetic
	$(PKGDEBUG)eval REPO=redist PKGSTAT=current `$(CAT) -s $(@).vars`; \
	if [ -f $(@) ]; then \
		$(LN) -s $(@F) \
			$(PDIR)/$(@F:%.mog=%).metadata.$$PKGSTAT.$$REPO; \
	else \
		$(TOUCH) $(@); \
	fi
	$(PKGDEBUG)$(RM) $(@).vars

$(DEP_SYNTH_PKGS): $$(@:%.dep=%.mog)
	@print "Skipping dependency generation for $(@F:%.dep=%)"
	$(PKGDEBUG)$(CP) $(@:%.dep=%.mog) $(@)

clean:

clobber: clean
	$(RM) -r $(CLOBBERFILES)

#
# This rule assumes that all links in the $PKGSTAT directories
# point to valid manifests, and will fail the make run if one
# does not contain an fmri.
#
# The protolist is used for bfu archive creation, which may be invoked
# interactively by the user.  Both protolist and PKGLISTS targets
# depend on $(PROC_PKGS), but protolist builds them recursively.
# To avoid collisions, we insert protolist into the dependency chain
# here.  This has two somewhat subtle benefits: it allows bfu archive
# creation to work correctly, even when -a was not part of NIGHTLY_OPTIONS,
# and it ensures that a protolist file here will always correspond to the
# contents of the processed manifests, which can vary depending on build
# environment.
#
$(PKGLISTS): scripts/pkglist.awk $(PROC_PKGS)
	$(PKGDEBUG)sdotr=$(@F:packages.%=%); \
	r=$${sdotr%.+(?)}; s=$${sdotr#+(?).}; \
	print "Generating $$r $$s package list"; \
	$(RM) $(@); $(TOUCH) $(@); \
	$(AWK) -f scripts/pkglist.awk \
	    `find $(PDIR) -type l -a \( $(PKGS:%=-name %.metadata.$$s.$$r -o) \
	    -name NOSUCHFILE \)` >> $(@)

#
# rules to validate proto area against manifests, check for safe
# file permission modes, and generate a faux proto list
#
# For the check targets, the dependencies on $(PROC_PKGS) is specified
# as a subordinate make process in order to suppress output.
#
makesilent:
	@$(MAKE) -e $(PROC_PKGS) PKGMACH=$(PKGMACH) \
		SUPPRESSPKGDEP=$(SUPPRESSPKGDEP) > /dev/null

#
# The .lics files were created during pkgmogrification, and list the
# set of licenses to pull from $SRC for each package.  Because
# licenses may be duplicated between packages, we uniquify them as
# well as aggregating them here.
#
license-list: makesilent
	$(PKGDEBUG)( for l in `cat $(PROC_PKGS:%.mog=%.lics)`; \
		do print $$l; done ) | sort -u > $@

#
# Staging the license and description files in the proto area allows
# us to do proper unreferenced file checking of both license and
# description files without blanket exceptions, and to pull license
# content without reference to $CODEMGR_WS during publication.
#
stage-licenses: license-list FRC
	$(PKGDEBUG)$(MAKE) -e -f Makefile.lic \
		PKGDEBUG=$(PKGDEBUG) LICROOT=$(PKGROOT)/licenses \
		`$(AWK) '{ \
			print "$(PKGROOT)/licenses/" $$0; \
			print "$(PKGROOT)/licenses/" $$0 ".descrip"; \
		}' license-list` > /dev/null;

protocmp: makesilent
	@validate_pkg -a $(PKGMACH) -v \
		$(EXCEPTIONS:%=-e $(CODEMGR_WS)/exception_lists/%) \
		-m $(PDIR) -p $(PKGROOT) -p $(TOOLSROOT)

pmodes: makesilent
	@validate_pkg -a $(PKGMACH) -M -m $(PDIR) \
		-e $(CODEMGR_WS)/exception_lists/pmodes

pkglint: makesilent
	$(PKGDEBUG)$(CP) etc/pkglintrc $(PDIR)/pkglintrc
	$(PKGDEBUG)$(GREP) pkg:/ $(CODEMGR_WS)/exception_lists/packaging.deps \
	    | sed 's/.*/    & \\/' >> $(PDIR)/pkglintrc
	$(PKGDEBUG)echo "    pkg:/runtime/python$(PYTHON_PKGVERS) \\" \
	     >> $(PDIR)/pkglintrc
	$(PKGDEBUG)echo "    pkg:/runtime/python$(PYTHON3_PKGVERS) \\" \
	     >> $(PDIR)/pkglintrc
	$(PKGDEBUG) echo "    pkg:/runtime/perl$(PERL_PKGVERS) \\" \
	     >> $(PDIR)/pkglintrc
	$(PKGDEBUG)echo >> $(PDIR)/pkglintrc
	$(PKGDEBUG)$(RM) -rf $(PKGDEST)/lint.image
	$(PKGDEBUG)for r in $(REPOS); do \
		pkglint \
		    -f $(PDIR)/pkglintrc \
		    -c $(PKGDEST)/lint.image \
		    -r $(PKGDEST)/repo.$$r \
		    `$(FIND) $(PDIR) -name \*.fin \! -size 0c -print`; \
	done

check: protocmp pmodes pkglint

protolist: proto_list_$(PKGMACH)

proto_list_$(PKGMACH): $(PROC_PKGS)
	@validate_pkg -a $(PKGMACH) -L -m $(PDIR) > $(@)

$(PROC_PKGS): $(PDIR)

#
# This is a convenience target to allow package names to function as
# build targets.  Generally, using it is only useful when iterating on
# development of a manifest.
#
# When processing a manifest, use the basename (without extension) of
# the package.  When publishing, use the basename with a ".pub"
# extension.
#
# Other than during manifest development, the preferred usage is to
# avoid these targets and override PKGS on the make command line and
# use the provided all and install targets.
#
$(PKGS) $(SYNTH_PKGS): $(PDIR)/$$(@:%=%.mog)

$(PKGS:%=%.pub) $(SYNTH_PKGS:%=%.pub): $(PDIR)/$$(@)

#
# This is a convenience target to resolve dependencies without publishing
# packages.
#
gendeps: $(PDIR)/gendeps

#
# These are convenience targets for cross-platform packaging.  If you
# want to build any of "the normal" targets for a different
# architecture, simply use "arch/target" as your build target.
#
# Since the most common use case for this is "install," the architecture
# specific install targets have been further abbreviated to elide "/install."
#
i386/% sparc/%:
	$(MAKE) -e $(@F) PKGMACH=$(@D) SUPPRESSPKGDEP=$(SUPPRESSPKGDEP)

i386 sparc: $$(@)/install

FRC: