kc3-lang/libffi/Makefile.am

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• Hash : 9ba55921
  Author :
  Date : 2021-03-05T10:07:30
  

  Static tramp v5 (#624)
  
  * Static Trampolines
  
  Closure Trampoline Security Issue
  =================================
  
  Currently, the trampoline code used in libffi is not statically defined in
  a source file (except for MACH). The trampoline is either pre-defined
  machine code in a data buffer. Or, it is generated at runtime. In order to
  execute a trampoline, it needs to be placed in a page with executable
  permissions.
  
  Executable data pages are attack surfaces for attackers who may try to
  inject their own code into the page and contrive to have it executed. The
  security settings in a system may prevent various tricks used in user land
  to write code into a page and to have it executed somehow. On such systems,
  libffi trampolines would not be able to run.
  
  Static Trampoline
  =================
  
  To solve this problem, the trampoline code needs to be defined statically
  in a source file, compiled and placed in the text segment so it can be
  mapped and executed naturally without any tricks. However, the trampoline
  needs to be able to access the closure pointer at runtime.
  
  PC-relative data referencing
  ============================
  
  The solution implemented in this patch set uses PC-relative data references.
  The trampoline is mapped in a code page. Adjacent to the code page, a data
  page is mapped that contains the parameters of the trampoline:
  
  	- the closure pointer
  	- pointer to the ABI handler to jump to
  
  The trampoline code uses an offset relative to its current PC to access its
  data.
  
  Some architectures support PC-relative data references in the ISA itself.
  E.g., X64 supports RIP-relative references. For others, the PC has to
  somehow be loaded into a general purpose register to do PC-relative data
  referencing. To do this, we need to define a get_pc() kind of function and
  call it to load the PC in a desired register.
  
  There are two cases:
  
  1. The call instruction pushes the return address on the stack.
  
     In this case, get_pc() will extract the return address from the stack
     and load it in the desired register and return.
  
  2. The call instruction stores the return address in a designated register.
  
     In this case, get_pc() will copy the return address to the desired
     register and return.
  
  Either way, the PC next to the call instruction is obtained.
  
  Scratch register
  ================
  
  In order to do its job, the trampoline code would need to use a scratch
  register. Depending on the ABI, there may not be a register available for
  scratch. This problem needs to be solved so that all ABIs will work.
  
  The trampoline will save two values on the stack:
  
  	- the closure pointer
  	- the original value of the scratch register
  
  This is what the stack will look like:
  
  	sp before trampoline ------>	--------------------
  					| closure pointer  |
  					--------------------
  					| scratch register |
  	sp after trampoline ------->	--------------------
  
  The ABI handler can do the following as needed by the ABI:
  
  	- the closure pointer can be loaded in a desired register
  
  	- the scratch register can be restored to its original value
  
  	- the stack pointer can be restored to its original value
  	  (the value when the trampoline was invoked)
  
  To do this, I have defined prolog code for each ABI handler. The legacy
  trampoline jumps to the ABI handler directly. But the static trampoline
  defined in this patch jumps tp the prolog code which performs the above
  actions before jumping to the ABI handler.
  
  Trampoline Table
  ================
  
  In order to reduce the trampoline memory footprint, the trampoline code
  would be defined as a code array in the text segment. This array would be
  mapped into the address space of the caller. The mapping would, therefore,
  contain a trampoline table.
  
  Adjacent to the trampoline table mapping, there will be a data mapping that
  contains a parameter table, one parameter block for each trampoline. The
  parameter block will contain:
  
  	- a pointer to the closure
  	- a pointer to the ABI handler
  
  The static trampoline code would finally look like this:
  
  	- Make space on the stack for the closure and the scratch register
  	  by moving the stack pointer down
  	- Store the original value of the scratch register on the stack
  	- Using PC-relative reference, get the closure pointer
  	- Store the closure pointer on the stack
  	- Using PC-relative reference, get the ABI handler pointer
  	- Jump to the ABI handler
  
  Mapping size
  ============
  
  The size of the code mapping that contains the trampoline table needs to be
  determined on a per architecture basis. If a particular architecture
  supports multiple base page sizes, then the largest supported base page size
  needs to be chosen. E.g., we choose 16K for ARM64.
  
  Trampoline allocation and free
  ==============================
  
  Static trampolines are allocated in ffi_closure_alloc() and freed in
  ffi_closure_free().
  
  Normally, applications use these functions. But there are some cases out
  there where the user of libffi allocates and manages its own closure
  memory. In such cases, static trampolines cannot be used. These will
  fall back to using legacy trampolines. The user has to make sure that
  the memory is executable.
  
  ffi_closure structure
  =====================
  
  I did not want to make any changes to the size of the closure structure for
  this feature to guarantee compatibility. But the opaque static trampoline
  handle needs to be stored in the closure. I have defined it as follows:
  
  -  char tramp[FFI_TRAMPOLINE_SIZE];
  +  union {
  +    char tramp[FFI_TRAMPOLINE_SIZE];
  +    void *ftramp;
  +  };
  
  If static trampolines are used, then tramp[] is not needed to store a
  dynamic trampoline. That space can be reused to store the handle. Hence,
  the union.
  
  Architecture Support
  ====================
  
  Support has been added for x64, i386, aarch64 and arm. Support for other
  architectures can be added very easily in the future.
  
  OS Support
  ==========
  
  Support has been added for Linux. Support for other OSes can be added very
  easily.
  
  Signed-off-by: Madhavan T. Venkataraman <madvenka@linux.microsoft.com>
  
  * x86: Support for Static Trampolines
  
  	- Define the arch-specific initialization function ffi_tramp_arch ()
  	  that returns trampoline size information to common code.
  
  	- Define the trampoline code mapping and data mapping sizes.
  
  	- Define the trampoline code table statically. Define two tables,
  	  actually, one with CET and one without.
  
  	- Introduce a tiny prolog for each ABI handling function. The ABI
  	  handlers addressed are:
  
  	  	- ffi_closure_unix64
  		- ffi_closure_unix64_sse
  		- ffi_closure_win64
  
  	  The prolog functions are called:
  
  		- ffi_closure_unix64_alt
  		- ffi_closure_unix64_sse_alt
  		- ffi_closure_win64_alt
  
  	  The legacy trampoline jumps to the ABI handler. The static
  	  trampoline jumps to the prolog function. The prolog function uses
  	  the information provided by the static trampoline, sets things up
  	  for the ABI handler and then jumps to the ABI handler.
  
  	- Call ffi_tramp_set_parms () in ffi_prep_closure_loc () to
  	  initialize static trampoline parameters.
  
  Signed-off-by: Madhavan T. Venkataraman <madvenka@linux.microsoft.com>
  
  * i386: Support for Static Trampolines
  
  	- Define the arch-specific initialization function ffi_tramp_arch ()
  	  that returns trampoline size information to common code.
  
  	- Define the trampoline code table statically. Define two tables,
  	  actually, one with CET and one without.
  
  	- Define the trampoline code table statically.
  
  	- Introduce a tiny prolog for each ABI handling function. The ABI
  	  handlers addressed are:
  
  	  	- ffi_closure_i386
  		- ffi_closure_STDCALL
  		- ffi_closure_REGISTER
  
  	  The prolog functions are called:
  
  	  	- ffi_closure_i386_alt
  		- ffi_closure_STDCALL_alt
  		- ffi_closure_REGISTER_alt
  
  	  The legacy trampoline jumps to the ABI handler. The static
  	  trampoline jumps to the prolog function. The prolog function uses
  	  the information provided by the static trampoline, sets things up
  	  for the ABI handler and then jumps to the ABI handler.
  
  	- Call ffi_tramp_set_parms () in ffi_prep_closure_loc () to
  	  initialize static trampoline parameters.
  
  Signed-off-by: Madhavan T. Venkataraman <madvenka@linux.microsoft.com>
  
  * arm64: Support for Static Trampolines
  
  	- Define the arch-specific initialization function ffi_tramp_arch ()
  	  that returns trampoline size information to common code.
  
  	- Define the trampoline code mapping and data mapping sizes.
  
  	- Define the trampoline code table statically.
  
  	- Introduce a tiny prolog for each ABI handling function. The ABI
  	  handlers addressed are:
  
  	  	- ffi_closure_SYSV
  		- ffi_closure_SYSV_V
  
  	  The prolog functions are called:
  
  	  	- ffi_closure_SYSV_alt
  		- ffi_closure_SYSV_V_alt
  
  	  The legacy trampoline jumps to the ABI handler. The static
  	  trampoline jumps to the prolog function. The prolog function uses
  	  the information provided by the static trampoline, sets things up
  	  for the ABI handler and then jumps to the ABI handler.
  
  	- Call ffi_tramp_set_parms () in ffi_prep_closure_loc () to
  	  initialize static trampoline parameters.
  
  Signed-off-by: Madhavan T. Venkataraman <madvenka@linux.microsoft.com>
  
  * arm: Support for Static Trampolines
  
  	- Define the arch-specific initialization function ffi_tramp_arch ()
  	  that returns trampoline size information to common code.
  
  	- Define the trampoline code mapping and data mapping sizes.
  
  	- Define the trampoline code table statically.
  
  	- Introduce a tiny prolog for each ABI handling function. The ABI
  	  handlers addressed are:
  
  	  	- ffi_closure_SYSV
  		- ffi_closure_VFP
  
  	  The prolog functions are called:
  
  	  	- ffi_closure_SYSV_alt
  		- ffi_closure_VFP_alt
  
  	  The legacy trampoline jumps to the ABI handler. The static
  	  trampoline jumps to the prolog function. The prolog function uses
  	  the information provided by the static trampoline, sets things up
  	  for the ABI handler and then jumps to the ABI handler.
  
  	- Call ffi_tramp_set_parms () in ffi_prep_closure_loc () to
  	  initialize static trampoline parameters.
  
  Signed-off-by: Madhavan T. Venkataraman <madvenka@linux.microsoft.com>

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• Makefile.am

• ## Process this with automake to create Makefile.in
  
  AUTOMAKE_OPTIONS = foreign subdir-objects
  
  ACLOCAL_AMFLAGS = -I m4
  
  SUBDIRS = include testsuite man
  if BUILD_DOCS
  ## This hack is needed because it doesn't seem possible to make a
  ## conditional info_TEXINFOS in Automake.  At least Automake 1.14
  ## either gives errors -- if this attempted in the most
  ## straightforward way -- or simply unconditionally tries to build the
  ## info file.
  SUBDIRS += doc
  endif
  
  EXTRA_DIST = LICENSE ChangeLog.old					\
  	m4/libtool.m4 m4/lt~obsolete.m4					\
  	 m4/ltoptions.m4 m4/ltsugar.m4 m4/ltversion.m4			\
  	 m4/ltversion.m4 src/debug.c msvcc.sh				\
  	generate-darwin-source-and-headers.py				\
  	libffi.xcodeproj/project.pbxproj				\
  	libtool-ldflags libtool-version configure.host README.md        \
  	libffi.map.in LICENSE-BUILDTOOLS msvc_build make_sunver.pl	
  
  # local.exp is generated by configure
  DISTCLEANFILES = local.exp
  
  # Subdir rules rely on $(FLAGS_TO_PASS)
  FLAGS_TO_PASS = $(AM_MAKEFLAGS)
  
  MAKEOVERRIDES=
  
  pkgconfigdir = $(libdir)/pkgconfig
  pkgconfig_DATA = libffi.pc
  
  toolexeclib_LTLIBRARIES = libffi.la
  noinst_LTLIBRARIES = libffi_convenience.la
  
  libffi_la_SOURCES = src/prep_cif.c src/types.c \
  		src/raw_api.c src/java_raw_api.c src/closures.c \
  		src/tramp.c
  
  if FFI_DEBUG
  libffi_la_SOURCES += src/debug.c
  endif
  
  noinst_HEADERS = src/aarch64/ffitarget.h src/aarch64/internal.h		\
  	src/alpha/ffitarget.h src/alpha/internal.h			\
  	src/arc/ffitarget.h src/arm/ffitarget.h src/arm/internal.h	\
  	src/avr32/ffitarget.h src/bfin/ffitarget.h			\
  	src/cris/ffitarget.h src/csky/ffitarget.h src/frv/ffitarget.h	\
  	src/ia64/ffitarget.h src/ia64/ia64_flags.h			\
  	src/m32r/ffitarget.h src/m68k/ffitarget.h			\
  	src/m88k/ffitarget.h src/metag/ffitarget.h			\
  	src/microblaze/ffitarget.h src/mips/ffitarget.h			\
  	src/moxie/ffitarget.h src/nios2/ffitarget.h			\
  	src/or1k/ffitarget.h src/pa/ffitarget.h				\
  	src/powerpc/ffitarget.h src/powerpc/asm.h			\
  	src/powerpc/ffi_powerpc.h src/riscv/ffitarget.h			\
  	src/s390/ffitarget.h src/s390/internal.h src/sh/ffitarget.h	\
  	src/sh64/ffitarget.h src/sparc/ffitarget.h			\
  	src/sparc/internal.h src/tile/ffitarget.h src/vax/ffitarget.h	\
  	src/x86/ffitarget.h src/x86/internal.h src/x86/internal64.h	\
  	src/x86/asmnames.h src/xtensa/ffitarget.h src/dlmalloc.c	\
  	src/kvx/ffitarget.h
  
  EXTRA_libffi_la_SOURCES = src/aarch64/ffi.c src/aarch64/sysv.S		\
  	src/aarch64/win64_armasm.S src/alpha/ffi.c src/alpha/osf.S	\
  	src/arc/ffi.c src/arc/arcompact.S src/arm/ffi.c			\
  	src/arm/sysv.S src/arm/ffi.c src/arm/sysv_msvc_arm32.S		\
  	src/avr32/ffi.c src/avr32/sysv.S src/bfin/ffi.c			\
  	src/bfin/sysv.S src/cris/ffi.c src/cris/sysv.S src/frv/ffi.c	\
  	src/csky/ffi.c src/csky/sysv.S src/frv/eabi.S src/ia64/ffi.c	\
  	src/ia64/unix.S src/m32r/ffi.c src/m32r/sysv.S src/m68k/ffi.c	\
  	src/m68k/sysv.S src/m88k/ffi.c src/m88k/obsd.S			\
  	src/metag/ffi.c src/metag/sysv.S src/microblaze/ffi.c		\
  	src/microblaze/sysv.S src/mips/ffi.c src/mips/o32.S		\
  	src/mips/n32.S src/moxie/ffi.c src/moxie/eabi.S			\
  	src/nios2/ffi.c src/nios2/sysv.S src/or1k/ffi.c			\
  	src/or1k/sysv.S src/pa/ffi.c src/pa/linux.S src/pa/hpux32.S	\
  	src/powerpc/ffi.c src/powerpc/ffi_sysv.c			\
  	src/powerpc/ffi_linux64.c src/powerpc/sysv.S			\
  	src/powerpc/linux64.S src/powerpc/linux64_closure.S		\
  	src/powerpc/ppc_closure.S src/powerpc/aix.S			\
  	src/powerpc/darwin.S src/powerpc/aix_closure.S			\
  	src/powerpc/darwin_closure.S src/powerpc/ffi_darwin.c		\
  	src/riscv/ffi.c src/riscv/sysv.S src/s390/ffi.c			\
  	src/s390/sysv.S src/sh/ffi.c src/sh/sysv.S src/sh64/ffi.c	\
  	src/sh64/sysv.S src/sparc/ffi.c src/sparc/ffi64.c		\
  	src/sparc/v8.S src/sparc/v9.S src/tile/ffi.c src/tile/tile.S	\
  	src/vax/ffi.c src/vax/elfbsd.S src/x86/ffi.c src/x86/sysv.S	\
  	src/x86/ffiw64.c src/x86/win64.S src/x86/ffi64.c		\
  	src/x86/unix64.S src/x86/sysv_intel.S src/x86/win64_intel.S	\
  	src/xtensa/ffi.c src/xtensa/sysv.S src/kvx/ffi.c		\
  	src/kvx/sysv.S
  
  TARGET_OBJ = @TARGET_OBJ@
  libffi_la_LIBADD = $(TARGET_OBJ)
  
  libffi_convenience_la_SOURCES = $(libffi_la_SOURCES)
  EXTRA_libffi_convenience_la_SOURCES = $(EXTRA_libffi_la_SOURCES)
  libffi_convenience_la_LIBADD = $(libffi_la_LIBADD)
  libffi_convenience_la_DEPENDENCIES = $(libffi_la_DEPENDENCIES)
  nodist_libffi_convenience_la_SOURCES = $(nodist_libffi_la_SOURCES)
  
  LTLDFLAGS = $(shell $(SHELL) $(top_srcdir)/libtool-ldflags $(LDFLAGS))
  
  AM_CFLAGS =
  if FFI_DEBUG
  # Build debug. Define FFI_DEBUG on the commandline so that, when building with
  # MSVC, it can link against the debug CRT.
  AM_CFLAGS += -DFFI_DEBUG
  endif
  
  if LIBFFI_BUILD_VERSIONED_SHLIB
  if LIBFFI_BUILD_VERSIONED_SHLIB_GNU
  libffi_version_script = -Wl,--version-script,libffi.map
  libffi_version_dep = libffi.map
  endif
  if LIBFFI_BUILD_VERSIONED_SHLIB_SUN
  libffi_version_script = -Wl,-M,libffi.map-sun
  libffi_version_dep = libffi.map-sun
  libffi.map-sun : libffi.map $(top_srcdir)/make_sunver.pl \
  		 $(libffi_la_OBJECTS) $(libffi_la_LIBADD)
  	perl $(top_srcdir)/make_sunver.pl libffi.map \
  	 `echo $(libffi_la_OBJECTS) $(libffi_la_LIBADD) | \
  	    sed 's,\([^/        ]*\)\.l\([ao]\),.libs/\1.\2,g'` \
  	 > $@ || (rm -f $@ ; exit 1)
  endif
  else
  libffi_version_script =
  libffi_version_dep =
  endif
  libffi_version_info = -version-info `grep -v '^\#' $(srcdir)/libtool-version`
  
  libffi.map: $(top_srcdir)/libffi.map.in
  	$(COMPILE) -D$(TARGET) -DGENERATE_LIBFFI_MAP \
  	 -E -x assembler-with-cpp -o $@ $(top_srcdir)/libffi.map.in
  
  libffi_la_LDFLAGS = -no-undefined $(libffi_version_info) $(libffi_version_script) $(LTLDFLAGS) $(AM_LTLDFLAGS)
  libffi_la_DEPENDENCIES = $(libffi_la_LIBADD) $(libffi_version_dep)
  
  AM_CPPFLAGS = -I. -I$(top_srcdir)/include -Iinclude -I$(top_srcdir)/src
  AM_CCASFLAGS = $(AM_CPPFLAGS)
  
  dist-hook:
  	d=`(cd $(distdir); pwd)`; (cd doc; make pdf; cp *.pdf $$d/doc)
  	if [ -d $(top_srcdir)/.git ] ; then (cd $(top_srcdir); git log --no-decorate) ; else echo 'See git log for history.' ; fi > $(distdir)/ChangeLog
  	s=`awk '/was released on/{ print NR; exit}' $(top_srcdir)/README.md`; tail -n +$$(($$s-1)) $(top_srcdir)/README.md > $(distdir)/README.md
  
  

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