rust/mk/platform.mk
Alex Crichton 7a3fdfbf67 Remove morestack support
This commit removes all morestack support from the compiler which entails:

* Segmented stacks are no longer emitted in codegen.
* We no longer build or distribute libmorestack.a
* The `stack_exhausted` lang item is no longer required

The only current use of the segmented stack support in LLVM is to detect stack
overflow. This is no longer really required, however, because we already have
guard pages for all threads and registered signal handlers watching for a
segfault on those pages (to print out a stack overflow message). Additionally,
major platforms (aka Windows) already don't use morestack.

This means that Rust is by default less likely to catch stack overflows because
if a function takes up more than one page of stack space it won't hit the guard
page. This is what the purpose of morestack was (to catch this case), but it's
better served with stack probes which have more cross platform support and no
runtime support necessary. Until LLVM supports this for all platform it looks
like morestack isn't really buying us much.

cc #16012 (still need stack probes)
Closes #26458 (a drive-by fix to help diagnostics on stack overflow)
2015-08-10 16:35:44 -07:00

293 lines
9.5 KiB
Makefile

# Copyright 2012-2015 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.
# Create variables HOST_<triple> containing the host part
# of each target triple. For example, the triple i686-darwin-macos
# would create a variable HOST_i686-darwin-macos with the value
# i386.
define DEF_HOST_VAR
HOST_$(1) = $(subst i686,i386,$(word 1,$(subst -, ,$(1))))
endef
$(foreach t,$(CFG_TARGET),$(eval $(call DEF_HOST_VAR,$(t))))
$(foreach t,$(CFG_TARGET),$(info cfg: host for $(t) is $(HOST_$(t))))
# Ditto for OSTYPE
define DEF_OSTYPE_VAR
OSTYPE_$(1) = $(subst $(firstword $(subst -, ,$(1)))-,,$(1))
endef
$(foreach t,$(CFG_TARGET),$(eval $(call DEF_OSTYPE_VAR,$(t))))
$(foreach t,$(CFG_TARGET),$(info cfg: os for $(t) is $(OSTYPE_$(t))))
# On Darwin, we need to run dsymutil so the debugging information ends
# up in the right place. On other platforms, it automatically gets
# embedded into the executable, so use a no-op command.
CFG_DSYMUTIL := true
# Hack: not sure how to test if a file exists in make other than this
OS_SUPP = $(patsubst %,--suppressions=%, \
$(wildcard $(CFG_SRC_DIR)src/etc/$(CFG_OSTYPE).supp*))
ifdef CFG_DISABLE_OPTIMIZE_CXX
$(info cfg: disabling C++ optimization (CFG_DISABLE_OPTIMIZE_CXX))
CFG_GCCISH_CFLAGS += -O0
else
CFG_GCCISH_CFLAGS += -O2
endif
# The soname thing is for supporting a statically linked jemalloc.
# see https://blog.mozilla.org/jseward/2012/06/05/valgrind-now-supports-jemalloc-builds-directly/
ifdef CFG_VALGRIND
CFG_VALGRIND += --error-exitcode=100 \
--fair-sched=try \
--quiet \
--soname-synonyms=somalloc=NONE \
--suppressions=$(CFG_SRC_DIR)src/etc/x86.supp \
$(OS_SUPP)
ifdef CFG_ENABLE_HELGRIND
CFG_VALGRIND += --tool=helgrind
else
CFG_VALGRIND += --tool=memcheck \
--leak-check=full
endif
endif
# If we actually want to run Valgrind on a given platform, set this variable
define DEF_GOOD_VALGRIND
ifeq ($(OSTYPE_$(1)),unknown-linux-gnu)
GOOD_VALGRIND_$(1) = 1
endif
ifneq (,$(filter $(OSTYPE_$(1)),darwin freebsd))
ifeq (HOST_$(1),x86_64)
GOOD_VALGRIND_$(1) = 1
endif
endif
endef
$(foreach t,$(CFG_TARGET),$(eval $(call DEF_GOOD_VALGRIND,$(t))))
$(foreach t,$(CFG_TARGET),$(info cfg: good valgrind for $(t) is $(GOOD_VALGRIND_$(t))))
ifneq ($(findstring linux,$(CFG_OSTYPE)),)
ifdef CFG_PERF
ifneq ($(CFG_PERF_WITH_LOGFD),)
CFG_PERF_TOOL := $(CFG_PERF) stat -r 3 --log-fd 2
else
CFG_PERF_TOOL := $(CFG_PERF) stat -r 3
endif
else
ifdef CFG_VALGRIND
CFG_PERF_TOOL := \
$(CFG_VALGRIND) --tool=cachegrind --cache-sim=yes --branch-sim=yes
else
CFG_PERF_TOOL := /usr/bin/time --verbose
endif
endif
endif
AR := ar
define SET_FROM_CFG
ifdef CFG_$(1)
ifeq ($(origin $(1)),undefined)
$$(info cfg: using $(1)=$(CFG_$(1)) (CFG_$(1)))
$(1)=$(CFG_$(1))
endif
ifeq ($(origin $(1)),default)
$$(info cfg: using $(1)=$(CFG_$(1)) (CFG_$(1)))
$(1)=$(CFG_$(1))
endif
endif
endef
$(foreach cvar,CC CXX CPP CFLAGS CXXFLAGS CPPFLAGS, \
$(eval $(call SET_FROM_CFG,$(cvar))))
CFG_RLIB_GLOB=lib$(1)-*.rlib
include $(wildcard $(CFG_SRC_DIR)mk/cfg/*.mk)
define ADD_INSTALLED_OBJECTS
INSTALLED_OBJECTS_$(1) += $$(call CFG_STATIC_LIB_NAME_$(1),compiler-rt)
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call ADD_INSTALLED_OBJECTS,$(target))))
define DEFINE_LINKER
ifndef LINK_$(1)
LINK_$(1) := $$(CC_$(1))
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call DEFINE_LINKER,$(target))))
# The -Qunused-arguments sidesteps spurious warnings from clang
define FILTER_FLAGS
ifeq ($$(CFG_USING_CLANG),1)
ifneq ($(findstring clang,$$(shell $(CC_$(1)) -v)),)
CFG_GCCISH_CFLAGS_$(1) += -Qunused-arguments
CFG_GCCISH_CXXFLAGS_$(1) += -Qunused-arguments
endif
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call FILTER_FLAGS,$(target))))
# Configure various macros to pass gcc or cl.exe style arguments
define CC_MACROS
CFG_CC_INCLUDE_$(1)=-I $$(1)
ifeq ($$(findstring msvc,$(1)),msvc)
CFG_CC_OUTPUT_$(1)=-Fo:$$(1)
CFG_CREATE_ARCHIVE_$(1)=$$(AR_$(1)) -OUT:$$(1)
else
CFG_CC_OUTPUT_$(1)=-o $$(1)
CFG_CREATE_ARCHIVE_$(1)=$$(AR_$(1)) crus $$(1)
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call CC_MACROS,$(target))))
ifeq ($(CFG_CCACHE_CPP2),1)
CCACHE_CPP2=1
export CCACHE_CPP
endif
ifdef CFG_CCACHE_BASEDIR
CCACHE_BASEDIR=$(CFG_CCACHE_BASEDIR)
export CCACHE_BASEDIR
endif
FIND_COMPILER = $(word 1,$(1:ccache=))
define CFG_MAKE_TOOLCHAIN
# Prepend the tools with their prefix if cross compiling
ifneq ($(CFG_BUILD),$(1))
ifneq ($$(findstring msvc,$(1)),msvc)
CC_$(1)=$(CROSS_PREFIX_$(1))$(CC_$(1))
CXX_$(1)=$(CROSS_PREFIX_$(1))$(CXX_$(1))
CPP_$(1)=$(CROSS_PREFIX_$(1))$(CPP_$(1))
AR_$(1)=$(CROSS_PREFIX_$(1))$(AR_$(1))
LINK_$(1)=$(CROSS_PREFIX_$(1))$(LINK_$(1))
RUSTC_CROSS_FLAGS_$(1)=-C linker=$$(call FIND_COMPILER,$$(LINK_$(1))) \
-C ar=$$(call FIND_COMPILER,$$(AR_$(1))) $(RUSTC_CROSS_FLAGS_$(1))
RUSTC_FLAGS_$(1)=$$(RUSTC_CROSS_FLAGS_$(1)) $(RUSTC_FLAGS_$(1))
endif
endif
CFG_COMPILE_C_$(1) = $$(CC_$(1)) \
$$(CFG_GCCISH_CFLAGS) \
$$(CFG_GCCISH_CFLAGS_$(1)) \
-c $$(call CFG_CC_OUTPUT_$(1),$$(1)) $$(2)
CFG_LINK_C_$(1) = $$(CC_$(1)) \
$$(CFG_GCCISH_LINK_FLAGS) -o $$(1) \
$$(CFG_GCCISH_LINK_FLAGS_$(1)) \
$$(CFG_GCCISH_DEF_FLAG_$(1))$$(3) $$(2) \
$$(call CFG_INSTALL_NAME_$(1),$$(4))
CFG_COMPILE_CXX_$(1) = $$(CXX_$(1)) \
$$(CFG_GCCISH_CFLAGS) \
$$(CFG_GCCISH_CXXFLAGS) \
$$(CFG_GCCISH_CFLAGS_$(1)) \
$$(CFG_GCCISH_CXXFLAGS_$(1)) \
-c $$(call CFG_CC_OUTPUT_$(1),$$(1)) $$(2)
CFG_LINK_CXX_$(1) = $$(CXX_$(1)) \
$$(CFG_GCCISH_LINK_FLAGS) -o $$(1) \
$$(CFG_GCCISH_LINK_FLAGS_$(1)) \
$$(CFG_GCCISH_DEF_FLAG_$(1))$$(3) $$(2) \
$$(call CFG_INSTALL_NAME_$(1),$$(4))
ifeq ($$(findstring $(HOST_$(1)),arm aarch64 mips mipsel powerpc),)
# On Bitrig, we need the relocation model to be PIC for everything
ifeq (,$(filter $(OSTYPE_$(1)),bitrig))
LLVM_MC_RELOCATION_MODEL="pic"
else
LLVM_MC_RELOCATION_MODEL="default"
endif
# We're using llvm-mc as our assembler because it supports
# .cfi pseudo-ops on mac
CFG_ASSEMBLE_$(1)=$$(CPP_$(1)) -E $$(2) | \
$$(LLVM_MC_$$(CFG_BUILD)) \
-assemble \
-relocation-model=$$(LLVM_MC_RELOCATION_MODEL) \
-filetype=obj \
-triple=$(1) \
-o=$$(1)
else
# For the ARM, AARCH64, MIPS and POWER crosses, use the toolchain assembler
# FIXME: We should be able to use the LLVM assembler
CFG_ASSEMBLE_$(1)=$$(CC_$(1)) $$(CFG_GCCISH_CFLAGS_$(1)) \
$$(2) -c -o $$(1)
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call CFG_MAKE_TOOLCHAIN,$(target))))
# There are more comments about this available in the target specification for
# Windows MSVC in the compiler, but the gist of it is that we use `llvm-ar.exe`
# instead of `lib.exe` for assembling archives, so we need to inject this custom
# dependency here.
define ADD_LLVM_AR_TO_MSVC_DEPS
ifeq ($$(findstring msvc,$(1)),msvc)
NATIVE_TOOL_DEPS_core_T_$(1) += llvm-ar.exe
INSTALLED_BINS_$(1) += llvm-ar.exe
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call ADD_LLVM_AR_TO_MSVC_DEPS,$(target))))
# When working with MSVC on windows, each DLL needs to explicitly declare its
# interface to the outside world through some means. The options for doing so
# include:
#
# 1. A custom attribute on each function itself
# 2. A linker argument saying what to export
# 3. A file which lists all symbols that need to be exported
#
# The Rust compiler takes care (1) for us for all Rust code by annotating all
# public-facing functions with dllexport, but we have a few native dependencies
# which need to cross the DLL boundary. The most important of these dependencies
# is LLVM which is linked into `rustc_llvm.dll` but primarily used from
# `rustc_trans.dll`. This means that many of LLVM's C API functions need to be
# exposed from `rustc_llvm.dll` to be forwarded over the boundary.
#
# Unfortunately, at this time, LLVM does not handle this sort of exportation on
# Windows for us, so we're forced to do it ourselves if we want it (which seems
# like the path of least resistance right now). To do this we generate a `.DEF`
# file [1] which we then custom-pass to the linker when building the rustc_llvm
# crate. This DEF file list all symbols that are exported from
# `src/librustc_llvm/lib.rs` and is generated by a small python script.
#
# Fun times!
#
# [1]: https://msdn.microsoft.com/en-us/library/28d6s79h.aspx
define ADD_RUSTC_LLVM_DEF_TO_MSVC
ifeq ($$(findstring msvc,$(1)),msvc)
RUSTFLAGS_rustc_llvm_T_$(1) += -C link-args="-DEF:$(1)/rt/rustc_llvm.def"
CUSTOM_DEPS_rustc_llvm_T_$(1) += $(1)/rt/rustc_llvm.def
$(1)/rt/rustc_llvm.def: $$(S)src/etc/mklldef.py $$(S)src/librustc_llvm/lib.rs
$$(CFG_PYTHON) $$^ $$@ rustc_llvm-$$(CFG_FILENAME_EXTRA)
endif
endef
$(foreach target,$(CFG_TARGET), \
$(eval $(call ADD_RUSTC_LLVM_DEF_TO_MSVC,$(target))))