6869d26ad9
For silvermont, the __popcountsi2 symbol does not get exported by libc.
But for atom, this symbol is exported. Since we already exported this symbol
for previous releases, it's better to just follow through and force
the export, but only for 32 bit. x86 64 bit will not export this symbol.
Bug: 17681440
(cherry picked from commit d11eac3455
)
Change-Id: I93704c721d98d569922f606f214069bda24872ba
137 lines
5.6 KiB
Python
Executable File
137 lines
5.6 KiB
Python
Executable File
#!/usr/bin/python
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'''
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/* This file generates libgcc_compat.c file that contains dummy
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* references to libgcc.a functions to force the dynamic linker
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* to copy their definition into the final libc.so binary.
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*
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* They are required to ensure backwards binary compatibility with
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* libc.so provided by the platform and binaries built with the NDK or
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* different versions/configurations of toolchains.
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*
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* Now, for a more elaborate description of the issue:
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*
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* libgcc.a is a compiler-specific library containing various helper
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* functions used to implement certain operations that are not necessarily
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* supported by the target CPU. For example, integer division doesn't have a
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* corresponding CPU instruction on ARMv5, and is instead implemented in the
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* compiler-generated machine code as a call to an __idiv helper function.
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*
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* Normally, one has to place libgcc.a in the link command used to generate
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* target binaries (shared libraries and executables) after all objects and
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* static libraries, but before dependent shared libraries, i.e. something
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* like:
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* gcc <options> -o libfoo.so foo.a libgcc.a -lc -lm
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*
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* This ensures that any helper function needed by the code in foo.a is copied
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* into the final libfoo.so. However, doing so will link a bunch of other __cxa
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* functions from libgcc.a into each .so and executable, causing 4k+ increase
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* in every binary. Therefore the Android platform build system has been
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* using this instead:
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*
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* gcc <options> -o libfoo.so foo.a -lc -lm libgcc.a
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*
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* The problem with this is that if one helper function needed by foo.a has
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* already been copied into libc.so or libm.so, then nothing will be copied
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* into libfoo.so. Instead, a symbol import definition will be added to it
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* so libfoo.so can directly call the one in libc.so at runtime.
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*
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* When refreshing toolchains for new versions or using different architecture
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* flags, the set of helper functions copied to libc.so may change, which
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* resulted in some native shared libraries generated with the NDK or prebuilts
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* from vendors to fail to load properly.
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*
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* The NDK has been fixed after 1.6_r1 to use the correct link command, so
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* any native shared library generated with it should now be safe from that
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* problem. On the other hand, existing shared libraries distributed with
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* applications that were generated with a previous version of the NDK
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* still need all 1.5/1.6 helper functions in libc.so and libm.so
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*
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* After 3.2, the toolchain was updated again, adding __aeabi_f2uiz to the
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* list of requirements. Technically, this is due to mis-linked NDK libraries
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* but it is easier to add a single function here than asking several app
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* developers to fix their build.
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*
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* The __aeabi_idiv function is added to the list since cortex-a15 supports
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* HW idiv instructions so the system libc.so doesn't pull in the reference to
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* __aeabi_idiv but legacy libraries built against cortex-a9 targets still need
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* it.
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*
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* Final note: some of the functions below should really be in libm.so to
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* completely reflect the state of 1.5/1.6 system images. However,
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* since libm.so depends on libc.so, it's easier to put all of
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* these in libc.so instead, since the dynamic linker will always
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* search in libc.so before libm.so for dependencies.
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*/
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'''
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import os
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import sys
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import subprocess
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import tempfile
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import re
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libgcc_compat_header = "/* Generated by genlibgcc_compat.py */\n\n"
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class Generator:
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def process(self):
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android_build_top_path = os.environ["ANDROID_BUILD_TOP"]
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print "* ANDROID_BUILD_TOP=" + android_build_top_path
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# Check TARGET_ARCH
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arch = subprocess.check_output(["CALLED_FROM_SETUP=true BUILD_SYSTEM=build/core make --no-print-directory -f build/core/config.mk dumpvar-TARGET_ARCH"],
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cwd=android_build_top_path, shell=True).strip()
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if arch != 'arm' and arch != 'x86':
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sys.exit("Error: Invalid TARGET_ARCH='" + arch + "' expecting 'arm' or 'x86'")
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build_path = android_build_top_path + "/bionic/libc"
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file_name = "libgcc_compat.c"
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file_path = build_path + "/arch-" + arch + "/bionic/" + file_name
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build_output_file_path = tempfile.mkstemp()[1]
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p = subprocess.Popen(["ONE_SHOT_MAKEFILE=bionic/libc/Android.mk make -C " + android_build_top_path
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+ " -f build/core/main.mk all_modules TARGET_LIBGCC= -j20 -B 2>&1 | tee " + build_output_file_path],
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cwd=build_path, shell=True)
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p.wait()
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print "* Build complete, logfile: " + build_output_file_path
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symbol_set = set()
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prog=re.compile("(?<=undefined reference to ')\w+")
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fd = open(build_output_file_path, 'r')
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for line in fd:
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m = prog.search(line)
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if m:
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symbol_set.add(m.group(0))
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fd.close()
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symbol_list = sorted(symbol_set)
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print "* Found " + repr(len(symbol_list)) + " referenced symbols: " + repr(symbol_list)
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if 0 == len(symbol_list):
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sys.exit("Error: symbol list is empty, please check the build log: " + build_output_file_path)
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print "* Generating " + file_path
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fres = open(file_path, 'w')
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fres.write(libgcc_compat_header)
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for sym_name in symbol_list:
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fres.write("extern char "+sym_name+";\n")
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fres.write("\n");
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fres.write("void* __bionic_libgcc_compat_symbols[] = {\n");
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for sym_name in symbol_list:
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fres.write(" &"+sym_name+",\n")
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fres.write("};\n");
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fres.close()
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generator = Generator()
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generator.process()
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