rust/mk/target.mk
Alex Crichton 91c22b6302 msvc: Lookup linker in windows registry
This commit alters the compiler to no longer "just run link.exe" but instead
probe the system's registry to find where the linker is located. The default
library search path (normally found through LIB) is also found through the
registry. This also brings us in line with the default behavior of Clang, and
much of the logic of where to look for information is copied over from Clang as
well. Finally, this commit removes the makefile logic for updating the
environment variables for the compiler, except for stage0 where it's still
necessary.

The motivation for this change is rooted in two positions:

* Not having to set up these environment variables is much less hassle both for
  the bootstrap and for running the compiler itself. This means that the
  compiler can be run outside of VS shells and be run inside of cmd.exe or a
  MSYS shell.

* When dealing with cross compilation, there's not actually a set of environment
  variables that can be set for the compiler. This means, for example, if a
  Cargo compilation is targeting 32-bit from 64-bit you can't actually set up
  one set of environment variables. Having the compiler deal with the logic
  instead is generally much more convenient!
2015-07-01 09:35:55 -07:00

258 lines
9.7 KiB
Makefile

# Copyright 2012 The Rust Project Developers. See the COPYRIGHT
# file at the top-level directory of this distribution and at
# http://rust-lang.org/COPYRIGHT.
#
# Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
# http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
# <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
# option. This file may not be copied, modified, or distributed
# except according to those terms.
# This is the compile-time target-triple for the compiler. For the compiler at
# runtime, this should be considered the host-triple. More explanation for why
# this exists can be found on issue #2400
export CFG_COMPILER_HOST_TRIPLE
# The standard libraries should be held up to a higher standard than any old
# code, make sure that these common warnings are denied by default. These can
# be overridden during development temporarily. For stage0, we allow warnings
# which may be bugs in stage0 (should be fixed in stage1+)
RUST_LIB_FLAGS_ST0 += -W warnings
RUST_LIB_FLAGS_ST1 += -D warnings
RUST_LIB_FLAGS_ST2 += -D warnings
# Macro that generates the full list of dependencies for a crate at a particular
# stage/target/host tuple.
#
# $(1) - stage
# $(2) - target
# $(3) - host
# $(4) crate
define RUST_CRATE_FULLDEPS
CRATE_FULLDEPS_$(1)_T_$(2)_H_$(3)_$(4) := \
$$(CRATEFILE_$(4)) \
$$(RSINPUTS_$(4)) \
$$(foreach dep,$$(RUST_DEPS_$(4)), \
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$$(dep)) \
$$(foreach dep,$$(NATIVE_DEPS_$(4)), \
$$(RT_OUTPUT_DIR_$(2))/$$(call CFG_STATIC_LIB_NAME_$(2),$$(dep))) \
$$(foreach dep,$$(NATIVE_DEPS_$(4)_T_$(2)), \
$$(RT_OUTPUT_DIR_$(2))/$$(dep)) \
$$(foreach dep,$$(NATIVE_TOOL_DEPS_$(4)_T_$(2)), \
$$(TBIN$(1)_T_$(3)_H_$(3))/$$(dep)) \
$$(CUSTOM_DEPS_$(4)_T_$(2))
endef
$(foreach host,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(foreach stage,$(STAGES), \
$(foreach crate,$(CRATES), \
$(eval $(call RUST_CRATE_FULLDEPS,$(stage),$(target),$(host),$(crate)))))))
# RUST_TARGET_STAGE_N template: This defines how target artifacts are built
# for all stage/target architecture combinations. This is one giant rule which
# works as follows:
#
# 1. The immediate dependencies are the rust source files
# 2. Each rust crate dependency is listed (based on their stamp files),
# as well as all native dependencies (listed in RT_OUTPUT_DIR)
# 3. The stage (n-1) compiler is required through the TSREQ dependency, along
# with the morestack library
# 4. When actually executing the rule, the first thing we do is to clean out
# old libs and rlibs via the REMOVE_ALL_OLD_GLOB_MATCHES macro
# 5. Finally, we get around to building the actual crate. It's just one
# "small" invocation of the previous stage rustc. We use -L to
# RT_OUTPUT_DIR so all the native dependencies are picked up.
# Additionally, we pass in the llvm dir so rustc can link against it.
# 6. Some cleanup is done (listing what was just built) if verbose is turned
# on.
#
# $(1) is the stage
# $(2) is the target triple
# $(3) is the host triple
# $(4) is the crate name
define RUST_TARGET_STAGE_N
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$(4): CFG_COMPILER_HOST_TRIPLE = $(2)
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$(4): \
$$(CRATEFILE_$(4)) \
$$(CRATE_FULLDEPS_$(1)_T_$(2)_H_$(3)_$(4)) \
$$(LLVM_CONFIG_$(2)) \
$$(TSREQ$(1)_T_$(2)_H_$(3)) \
| $$(TLIB$(1)_T_$(2)_H_$(3))/
@$$(call E, rustc: $$(@D)/lib$(4))
@touch $$@.start_time
$$(call REMOVE_ALL_OLD_GLOB_MATCHES, \
$$(dir $$@)$$(call CFG_LIB_GLOB_$(2),$(4)))
$$(call REMOVE_ALL_OLD_GLOB_MATCHES, \
$$(dir $$@)$$(call CFG_RLIB_GLOB,$(4)))
$(Q)CFG_LLVM_LINKAGE_FILE=$$(LLVM_LINKAGE_PATH_$(2)) \
$$(subst @,,$$(STAGE$(1)_T_$(2)_H_$(3))) \
$$(RUST_LIB_FLAGS_ST$(1)) \
-L "$$(RT_OUTPUT_DIR_$(2))" \
$$(LLVM_LIBDIR_RUSTFLAGS_$(2)) \
$$(LLVM_STDCPP_RUSTFLAGS_$(2)) \
$$(RUSTFLAGS_$(4)) \
$$(RUSTFLAGS_$(4)_T_$(2)) \
--out-dir $$(@D) \
-C extra-filename=-$$(CFG_FILENAME_EXTRA) \
$$<
@touch -r $$@.start_time $$@ && rm $$@.start_time
$$(call LIST_ALL_OLD_GLOB_MATCHES, \
$$(dir $$@)$$(call CFG_LIB_GLOB_$(2),$(4)))
$$(call LIST_ALL_OLD_GLOB_MATCHES, \
$$(dir $$@)$$(call CFG_RLIB_GLOB,$(4)))
endef
# Macro for building any tool as part of the rust compilation process. Each
# tool is defined in crates.mk with a list of library dependencies as well as
# the source file for the tool. Building each tool will also be passed '--cfg
# <tool>' for usage in driver.rs
#
# This build rule is similar to the one found above, just tweaked for
# locations and things.
#
# $(1) - stage
# $(2) - target triple
# $(3) - host triple
# $(4) - name of the tool being built
define TARGET_TOOL
$$(TBIN$(1)_T_$(2)_H_$(3))/$(4)$$(X_$(2)): \
$$(TOOL_SOURCE_$(4)) \
$$(TOOL_INPUTS_$(4)) \
$$(foreach dep,$$(TOOL_DEPS_$(4)), \
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$$(dep)) \
$$(TSREQ$(1)_T_$(2)_H_$(3)) \
| $$(TBIN$(1)_T_$(2)_H_$(3))/
@$$(call E, rustc: $$@)
$$(STAGE$(1)_T_$(2)_H_$(3)) -o $$@ $$< --cfg $(4)
endef
# Every recipe in RUST_TARGET_STAGE_N outputs to $$(TLIB$(1)_T_$(2)_H_$(3),
# a directory that can be cleaned out during the middle of a run of
# the get-snapshot.py script. Therefore, every recipe needs to have
# an order-only dependency either on $(SNAPSHOT_RUSTC_POST_CLEANUP) or
# on $$(TSREQ$(1)_T_$(2)_H_$(3)), to ensure that no products will be
# put into the target area until after the get-snapshot.py script has
# had its chance to clean it out; otherwise the other products will be
# inadvertently included in the clean out.
SNAPSHOT_RUSTC_POST_CLEANUP=$(HBIN0_H_$(CFG_BUILD))/rustc$(X_$(CFG_BUILD))
define TARGET_HOST_RULES
$$(TBIN$(1)_T_$(2)_H_$(3))/:
mkdir -p $$@
$$(TLIB$(1)_T_$(2)_H_$(3))/:
mkdir -p $$@
$$(TLIB$(1)_T_$(2)_H_$(3))/%: $$(RT_OUTPUT_DIR_$(2))/% \
| $$(TLIB$(1)_T_$(2)_H_$(3))/ $$(SNAPSHOT_RUSTC_POST_CLEANUP)
@$$(call E, cp: $$@)
$$(Q)cp $$< $$@
$$(TBIN$(1)_T_$(2)_H_$(3))/%: $$(CFG_LLVM_INST_DIR_$(2))/bin/% \
| $$(TBIN$(1)_T_$(2)_H_$(3))/ $$(SNAPSHOT_RUSTC_POST_CLEANUP)
@$$(call E, cp: $$@)
$$(Q)cp $$< $$@
endef
$(foreach source,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(eval $(call TARGET_HOST_RULES,0,$(target),$(source))) \
$(eval $(call TARGET_HOST_RULES,1,$(target),$(source))) \
$(eval $(call TARGET_HOST_RULES,2,$(target),$(source))) \
$(eval $(call TARGET_HOST_RULES,3,$(target),$(source)))))
# In principle, each host can build each target for both libs and tools
$(foreach crate,$(CRATES), \
$(foreach source,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(eval $(call RUST_TARGET_STAGE_N,0,$(target),$(source),$(crate))) \
$(eval $(call RUST_TARGET_STAGE_N,1,$(target),$(source),$(crate))) \
$(eval $(call RUST_TARGET_STAGE_N,2,$(target),$(source),$(crate))) \
$(eval $(call RUST_TARGET_STAGE_N,3,$(target),$(source),$(crate))))))
$(foreach host,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(foreach stage,$(STAGES), \
$(foreach tool,$(TOOLS), \
$(eval $(call TARGET_TOOL,$(stage),$(target),$(host),$(tool)))))))
# We have some triples which are bootstrapped from other triples, and this means
# that we need to fixup some of the native tools that a triple depends on.
#
# For example, MSVC requires the llvm-ar.exe executable to manage archives, but
# it bootstraps from the GNU Windows triple. This means that the compiler will
# add this directory to PATH when executing new processes:
#
# $SYSROOT/rustlib/x86_64-pc-windows-gnu/bin
#
# Unfortunately, however, the GNU triple is not known about in stage0, so the
# tools are actually located in:
#
# $SYSROOT/rustlib/x86_64-pc-windows-msvc/bin
#
# To remedy this problem, the rules below copy all native tool dependencies into
# the bootstrap triple's location in stage 0 so the bootstrap compiler can find
# the right sets of tools. Later stages (1+) will have the right host triple for
# the compiler, so there's no need to worry there.
#
# $(1) - stage
# $(2) - triple that's being used as host/target
# $(3) - triple snapshot is built for
# $(4) - crate
# $(5) - tool
define MOVE_TOOLS_TO_SNAPSHOT_HOST_DIR
ifneq (,$(3))
$$(TLIB$(1)_T_$(2)_H_$(2))/stamp.$(4): $$(HLIB$(1)_H_$(2))/rustlib/$(3)/bin/$(5)
$$(HLIB$(1)_H_$(2))/rustlib/$(3)/bin/$(5): $$(TBIN$(1)_T_$(2)_H_$(2))/$(5)
mkdir -p $$(@D)
cp $$< $$@
endif
endef
$(foreach target,$(CFG_TARGET), \
$(foreach crate,$(CRATES), \
$(foreach tool,$(NATIVE_TOOL_DEPS_$(crate)_T_$(target)), \
$(eval $(call MOVE_TOOLS_TO_SNAPSHOT_HOST_DIR,0,$(target),$(BOOTSTRAP_FROM_$(target)),$(crate),$(tool))))))
# For MSVC targets we need to set up some environment variables for the linker
# to work correctly when building Rust crates. These two variables are:
#
# - LIB tells the linker the default search path for finding system libraries,
# for example kernel32.dll
# - PATH needs to be modified to ensure that MSVC's link.exe is first in the
# path instead of MinGW's /usr/bin/link.exe (entirely unrelated)
#
# The values for these variables are detected by the configure script.
define SETUP_LIB_MSVC_ENV_VARS
ifeq ($$(findstring msvc,$(2)),msvc)
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$(4): \
export LIB := $$(CFG_MSVC_LIB_PATH_$$(HOST_$(2)))
$$(TLIB$(1)_T_$(2)_H_$(3))/stamp.$(4): \
export PATH := $$(CFG_MSVC_BINDIR_$$(HOST_$(2))):$$(PATH)
endif
endef
define SETUP_TOOL_MSVC_ENV_VARS
ifeq ($$(findstring msvc,$(2)),msvc)
$$(TBIN$(1)_T_$(2)_H_$(3))/$(4)$$(X_$(2)): \
export LIB := $$(CFG_MSVC_LIB_PATH_$$(HOST_$(2)))
$$(TBIN$(1)_T_$(2)_H_$(3))/$(4)$$(X_$(2)): \
export PATH := $$(CFG_MSVC_BINDIR_$$(HOST_$(2))):$$(PATH)
endif
endef
$(foreach host,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(foreach crate,$(CRATES), \
$(eval $(call SETUP_LIB_MSVC_ENV_VARS,0,$(target),$(host),$(crate))))))
$(foreach host,$(CFG_HOST), \
$(foreach target,$(CFG_TARGET), \
$(foreach tool,$(TOOLS), \
$(eval $(call SETUP_TOOL_MSVC_ENV_VARS,0,$(target),$(host),$(tool))))))