boringssl/crypto/CMakeLists.txt

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CMake
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include_directories(../include)
if(NOT OPENSSL_NO_ASM)
if(UNIX)
if(${ARCH} STREQUAL "aarch64")
# The "armx" Perl scripts look for "64" in the style argument
# in order to decide whether to generate 32- or 64-bit asm.
if(APPLE)
set(PERLASM_STYLE ios64)
else()
set(PERLASM_STYLE linux64)
endif()
elseif(${ARCH} STREQUAL "arm")
if(APPLE)
set(PERLASM_STYLE ios32)
else()
set(PERLASM_STYLE linux32)
endif()
elseif(${ARCH} STREQUAL "ppc64le")
set(PERLASM_STYLE linux64le)
else()
if(${ARCH} STREQUAL "x86")
set(PERLASM_FLAGS "-fPIC -DOPENSSL_IA32_SSE2")
endif()
if(APPLE)
set(PERLASM_STYLE macosx)
else()
set(PERLASM_STYLE elf)
endif()
endif()
set(ASM_EXT S)
enable_language(ASM)
set(CMAKE_ASM_FLAGS "${CMAKE_ASM_FLAGS} -Wa,--noexecstack")
# Clang's integerated assembler does not support debug symbols.
if(NOT CMAKE_ASM_COMPILER_ID MATCHES "Clang")
set(CMAKE_ASM_FLAGS "${CMAKE_ASM_FLAGS} -Wa,-g")
endif()
# CMake does not add -isysroot and -arch flags to assembly.
if(APPLE)
if(CMAKE_OSX_SYSROOT)
set(CMAKE_ASM_FLAGS "${CMAKE_ASM_FLAGS} -isysroot \"${CMAKE_OSX_SYSROOT}\"")
endif()
foreach(arch ${CMAKE_OSX_ARCHITECTURES})
set(CMAKE_ASM_FLAGS "${CMAKE_ASM_FLAGS} -arch ${arch}")
endforeach()
endif()
else()
if(${ARCH} STREQUAL "x86_64")
set(PERLASM_STYLE nasm)
else()
set(PERLASM_STYLE win32n)
set(PERLASM_FLAGS "-DOPENSSL_IA32_SSE2")
endif()
set(CMAKE_ASM_NASM_FLAGS "-gcv8")
# On Windows, we use the NASM output, specifically built with Yasm.
set(ASM_EXT asm)
enable_language(ASM_NASM)
endif()
endif()
function(perlasm dest src)
get_filename_component(dir ${dest} DIRECTORY)
if ("${dir}" STREQUAL "")
set(dir ".")
endif()
add_custom_command(
OUTPUT ${dest}
COMMAND ${CMAKE_COMMAND} -E make_directory ${dir}
COMMAND ${PERL_EXECUTABLE} ${CMAKE_CURRENT_SOURCE_DIR}/${src} ${PERLASM_STYLE} ${PERLASM_FLAGS} ${ARGN} ${dest}
DEPENDS
${src}
${PROJECT_SOURCE_DIR}/crypto/perlasm/arm-xlate.pl
Add PPC64LE assembly for AES-GCM. This change adds AES and GHASH assembly from upstream, with the aim of speeding up AES-GCM. The PPC64LE assembly matches the interface of the ARMv8 assembly so I've changed the prefix of both sets of asm functions to be the same ("aes_hw_"). Otherwise, the new assmebly files and Perlasm match exactly those from upstream's c536b6be1a (from their master branch). Before: Did 1879000 AES-128-GCM (16 bytes) seal operations in 1000428us (1878196.1 ops/sec): 30.1 MB/s Did 61000 AES-128-GCM (1350 bytes) seal operations in 1006660us (60596.4 ops/sec): 81.8 MB/s Did 11000 AES-128-GCM (8192 bytes) seal operations in 1072649us (10255.0 ops/sec): 84.0 MB/s Did 1665000 AES-256-GCM (16 bytes) seal operations in 1000591us (1664016.6 ops/sec): 26.6 MB/s Did 52000 AES-256-GCM (1350 bytes) seal operations in 1006971us (51640.0 ops/sec): 69.7 MB/s Did 8840 AES-256-GCM (8192 bytes) seal operations in 1013294us (8724.0 ops/sec): 71.5 MB/s After: Did 4994000 AES-128-GCM (16 bytes) seal operations in 1000017us (4993915.1 ops/sec): 79.9 MB/s Did 1389000 AES-128-GCM (1350 bytes) seal operations in 1000073us (1388898.6 ops/sec): 1875.0 MB/s Did 319000 AES-128-GCM (8192 bytes) seal operations in 1000101us (318967.8 ops/sec): 2613.0 MB/s Did 4668000 AES-256-GCM (16 bytes) seal operations in 1000149us (4667304.6 ops/sec): 74.7 MB/s Did 1202000 AES-256-GCM (1350 bytes) seal operations in 1000646us (1201224.0 ops/sec): 1621.7 MB/s Did 269000 AES-256-GCM (8192 bytes) seal operations in 1002804us (268247.8 ops/sec): 2197.5 MB/s Change-Id: Id848562bd4e1aa79a4683012501dfa5e6c08cfcc Reviewed-on: https://boringssl-review.googlesource.com/11262 Reviewed-by: Adam Langley <agl@google.com> Commit-Queue: Adam Langley <agl@google.com> CQ-Verified: CQ bot account: commit-bot@chromium.org <commit-bot@chromium.org>
2016-09-23 20:47:24 +01:00
${PROJECT_SOURCE_DIR}/crypto/perlasm/ppc-xlate.pl
${PROJECT_SOURCE_DIR}/crypto/perlasm/x86_64-xlate.pl
${PROJECT_SOURCE_DIR}/crypto/perlasm/x86asm.pl
${PROJECT_SOURCE_DIR}/crypto/perlasm/x86gas.pl
${PROJECT_SOURCE_DIR}/crypto/perlasm/x86masm.pl
${PROJECT_SOURCE_DIR}/crypto/perlasm/x86nasm.pl
WORKING_DIRECTORY .
)
endfunction()
add_subdirectory(fipsmodule)
add_subdirectory(test)
if(FIPS_DELOCATE)
SET_SOURCE_FILES_PROPERTIES(fipsmodule/bcm.o PROPERTIES EXTERNAL_OBJECT true)
SET_SOURCE_FILES_PROPERTIES(fipsmodule/bcm.o PROPERTIES GENERATED true)
set(
CRYPTO_FIPS_OBJECTS
fipsmodule/bcm.o
)
endif()
if(${ARCH} STREQUAL "arm")
set(
CRYPTO_ARCH_SOURCES
chacha/chacha-armv4.${ASM_EXT}
curve25519/asm/x25519-asm-arm.S
poly1305/poly1305_arm_asm.S
)
endif()
if(${ARCH} STREQUAL "aarch64")
set(
CRYPTO_ARCH_SOURCES
chacha/chacha-armv8.${ASM_EXT}
)
endif()
if(${ARCH} STREQUAL "x86")
set(
CRYPTO_ARCH_SOURCES
chacha/chacha-x86.${ASM_EXT}
)
endif()
if(${ARCH} STREQUAL "x86_64")
set(
CRYPTO_ARCH_SOURCES
chacha/chacha-x86_64.${ASM_EXT}
cipher_extra/aes128gcmsiv-x86_64.${ASM_EXT}
cipher_extra/chacha20_poly1305_x86_64.${ASM_EXT}
)
endif()
perlasm(chacha/chacha-armv4.${ASM_EXT} chacha/asm/chacha-armv4.pl)
perlasm(chacha/chacha-armv8.${ASM_EXT} chacha/asm/chacha-armv8.pl)
perlasm(chacha/chacha-x86.${ASM_EXT} chacha/asm/chacha-x86.pl)
perlasm(chacha/chacha-x86_64.${ASM_EXT} chacha/asm/chacha-x86_64.pl)
perlasm(cipher_extra/aes128gcmsiv-x86_64.${ASM_EXT} cipher_extra/asm/aes128gcmsiv-x86_64.pl)
perlasm(cipher_extra/chacha20_poly1305_x86_64.${ASM_EXT} cipher_extra/asm/chacha20_poly1305_x86_64.pl)
add_custom_command(
OUTPUT err_data.c
COMMAND ${GO_EXECUTABLE} run err_data_generate.go > ${CMAKE_CURRENT_BINARY_DIR}/err_data.c
DEPENDS
err/err_data_generate.go
err/asn1.errordata
err/bio.errordata
err/bn.errordata
err/cipher.errordata
err/conf.errordata
err/dh.errordata
err/digest.errordata
err/dsa.errordata
err/ecdh.errordata
err/ecdsa.errordata
err/ec.errordata
err/engine.errordata
err/evp.errordata
err/hkdf.errordata
err/obj.errordata
err/pem.errordata
err/pkcs7.errordata
err/pkcs8.errordata
err/rsa.errordata
err/ssl.errordata
err/x509.errordata
err/x509v3.errordata
WORKING_DIRECTORY ${CMAKE_CURRENT_SOURCE_DIR}/err
)
add_library(
crypto
asn1/a_bitstr.c
asn1/a_bool.c
asn1/a_d2i_fp.c
asn1/a_dup.c
asn1/a_enum.c
asn1/a_gentm.c
asn1/a_i2d_fp.c
asn1/a_int.c
asn1/a_mbstr.c
asn1/a_object.c
asn1/a_octet.c
asn1/a_print.c
asn1/a_strnid.c
asn1/a_time.c
asn1/a_type.c
asn1/a_utctm.c
asn1/a_utf8.c
asn1/asn1_lib.c
asn1/asn1_par.c
asn1/asn_pack.c
asn1/f_enum.c
asn1/f_int.c
asn1/f_string.c
asn1/tasn_dec.c
asn1/tasn_enc.c
asn1/tasn_fre.c
asn1/tasn_new.c
asn1/tasn_typ.c
asn1/tasn_utl.c
asn1/time_support.c
base64/base64.c
bio/bio.c
bio/bio_mem.c
bio/connect.c
bio/fd.c
bio/file.c
bio/hexdump.c
bio/pair.c
bio/printf.c
bio/socket.c
bio/socket_helper.c
bn_extra/bn_asn1.c
bn_extra/convert.c
buf/buf.c
bytestring/asn1_compat.c
bytestring/ber.c
bytestring/cbb.c
bytestring/cbs.c
bytestring/unicode.c
chacha/chacha.c
cipher_extra/cipher_extra.c
cipher_extra/derive_key.c
cipher_extra/e_aesccm.c
cipher_extra/e_aesctrhmac.c
cipher_extra/e_aesgcmsiv.c
cipher_extra/e_chacha20poly1305.c
cipher_extra/e_null.c
cipher_extra/e_rc2.c
cipher_extra/e_rc4.c
cipher_extra/e_tls.c
cipher_extra/tls_cbc.c
cmac/cmac.c
conf/conf.c
cpu-aarch64-fuchsia.c
cpu-aarch64-linux.c
cpu-arm-linux.c
cpu-arm.c
cpu-intel.c
cpu-ppc64le.c
crypto.c
curve25519/spake25519.c
dh/dh.c
dh/params.c
dh/check.c
dh/dh_asn1.c
digest_extra/digest_extra.c
dsa/dsa.c
dsa/dsa_asn1.c
ecdh_extra/ecdh_extra.c
ecdsa_extra/ecdsa_asn1.c
ec_extra/ec_asn1.c
err/err.c
err_data.c
engine/engine.c
evp/digestsign.c
evp/evp.c
evp/evp_asn1.c
evp/evp_ctx.c
evp/p_dsa_asn1.c
evp/p_ec.c
evp/p_ec_asn1.c
evp/p_ed25519.c
evp/p_ed25519_asn1.c
evp/p_rsa.c
evp/p_rsa_asn1.c
evp/pbkdf.c
evp/print.c
evp/scrypt.c
evp/sign.c
ex_data.c
hkdf/hkdf.c
lhash/lhash.c
mem.c
obj/obj.c
obj/obj_xref.c
pem/pem_all.c
pem/pem_info.c
pem/pem_lib.c
pem/pem_oth.c
pem/pem_pk8.c
pem/pem_pkey.c
pem/pem_x509.c
pem/pem_xaux.c
pkcs7/pkcs7.c
pkcs7/pkcs7_x509.c
pkcs8/pkcs8.c
pkcs8/pkcs8_x509.c
pkcs8/p5_pbev2.c
poly1305/poly1305.c
poly1305/poly1305_arm.c
poly1305/poly1305_vec.c
pool/pool.c
rand_extra/deterministic.c
rand_extra/forkunsafe.c
rand_extra/fuchsia.c
rand_extra/rand_extra.c
rand_extra/windows.c
rc4/rc4.c
refcount_c11.c
refcount_lock.c
rsa_extra/rsa_asn1.c
rsa_extra/rsa_print.c
stack/stack.c
thread.c
thread_none.c
thread_pthread.c
thread_win.c
x509/a_digest.c
x509/a_sign.c
x509/a_strex.c
x509/a_verify.c
x509/algorithm.c
x509/asn1_gen.c
x509/by_dir.c
x509/by_file.c
x509/i2d_pr.c
x509/rsa_pss.c
x509/t_crl.c
x509/t_req.c
x509/t_x509.c
x509/t_x509a.c
x509/x509.c
x509/x509_att.c
x509/x509_cmp.c
x509/x509_d2.c
x509/x509_def.c
x509/x509_ext.c
x509/x509_lu.c
x509/x509_obj.c
x509/x509_r2x.c
x509/x509_req.c
x509/x509_set.c
x509/x509_trs.c
x509/x509_txt.c
x509/x509_v3.c
x509/x509_vfy.c
x509/x509_vpm.c
x509/x509cset.c
x509/x509name.c
x509/x509rset.c
x509/x509spki.c
x509/x_algor.c
x509/x_all.c
x509/x_attrib.c
x509/x_crl.c
x509/x_exten.c
x509/x_info.c
x509/x_name.c
x509/x_pkey.c
x509/x_pubkey.c
x509/x_req.c
x509/x_sig.c
x509/x_spki.c
x509/x_val.c
x509/x_x509.c
x509/x_x509a.c
x509v3/pcy_cache.c
x509v3/pcy_data.c
x509v3/pcy_lib.c
x509v3/pcy_map.c
x509v3/pcy_node.c
x509v3/pcy_tree.c
x509v3/v3_akey.c
x509v3/v3_akeya.c
x509v3/v3_alt.c
x509v3/v3_bcons.c
x509v3/v3_bitst.c
x509v3/v3_conf.c
x509v3/v3_cpols.c
x509v3/v3_crld.c
x509v3/v3_enum.c
x509v3/v3_extku.c
x509v3/v3_genn.c
x509v3/v3_ia5.c
x509v3/v3_info.c
x509v3/v3_int.c
x509v3/v3_lib.c
x509v3/v3_ncons.c
x509v3/v3_ocsp.c
x509v3/v3_pci.c
x509v3/v3_pcia.c
x509v3/v3_pcons.c
x509v3/v3_pku.c
x509v3/v3_pmaps.c
x509v3/v3_prn.c
x509v3/v3_purp.c
x509v3/v3_skey.c
x509v3/v3_sxnet.c
x509v3/v3_utl.c
../third_party/fiat/curve25519.c
$<TARGET_OBJECTS:fipsmodule>
${CRYPTO_ARCH_SOURCES}
${CRYPTO_FIPS_OBJECTS}
)
add_dependencies(crypto global_target)
if(FIPS_DELOCATE)
add_dependencies(crypto bcm_o_target)
endif()
SET_TARGET_PROPERTIES(crypto PROPERTIES LINKER_LANGUAGE C)
if(NOT MSVC AND NOT ANDROID)
target_link_libraries(crypto pthread)
endif()
# Every target depends on crypto, so we add libcxx as a dependency here to
# simplify injecting it everywhere.
if(USE_CUSTOM_LIBCXX)
target_link_libraries(crypto libcxx)
endif()
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
add_executable(
crypto_test
asn1/asn1_test.cc
base64/base64_test.cc
buf/buf_test.cc
bio/bio_test.cc
bytestring/bytestring_test.cc
chacha/chacha_test.cc
cipher_extra/aead_test.cc
cipher_extra/cipher_test.cc
cmac/cmac_test.cc
compiler_test.cc
constant_time_test.cc
cpu-arm-linux_test.cc
curve25519/ed25519_test.cc
curve25519/spake25519_test.cc
curve25519/x25519_test.cc
ecdh_extra/ecdh_test.cc
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
dh/dh_test.cc
digest_extra/digest_test.cc
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
dsa/dsa_test.cc
err/err_test.cc
evp/evp_extra_test.cc
evp/evp_test.cc
evp/pbkdf_test.cc
evp/scrypt_test.cc
fipsmodule/aes/aes_test.cc
fipsmodule/bn/bn_test.cc
fipsmodule/ec/ec_test.cc
fipsmodule/ec/p256-x86_64_test.cc
fipsmodule/ecdsa/ecdsa_test.cc
fipsmodule/modes/gcm_test.cc
fipsmodule/rand/ctrdrbg_test.cc
hkdf/hkdf_test.cc
hmac_extra/hmac_test.cc
lhash/lhash_test.cc
obj/obj_test.cc
pem/pem_test.cc
pkcs7/pkcs7_test.cc
pkcs8/pkcs8_test.cc
pkcs8/pkcs12_test.cc
poly1305/poly1305_test.cc
pool/pool_test.cc
rand_extra/rand_test.cc
refcount_test.cc
rsa_extra/rsa_test.cc
self_test.cc
test/file_test_gtest.cc
thread_test.cc
x509/x509_test.cc
x509/x509_time_test.cc
x509v3/tab_test.cc
x509v3/v3name_test.cc
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
$<TARGET_OBJECTS:crypto_test_data>
$<TARGET_OBJECTS:boringssl_gtest_main>
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
$<TARGET_OBJECTS:test_support>
)
add_dependencies(crypto_test global_target)
target_link_libraries(crypto_test crypto boringssl_gtest)
if(WIN32)
target_link_libraries(crypto_test ws2_32)
endif()
Do a cursory conversion of a few tests to GTest. For now, this is the laziest conversion possible. The intent is to just get the build setup ready so that we can get everything working in our consumers. The intended end state is: - The standalone build produces three test targets, one per library: {crypto,ssl,decrepit}_tests. - Each FOO_test is made up of: FOO/**/*_test.cc crypto/test/gtest_main.cc test_support - generate_build_files.py emits variables crypto_test_sources and ssl_test_sources. These variables are populated with FindCFiles, looking for *_test.cc. - The consuming file assembles those variables into the two test targets (plus decrepit) from there. This avoids having generate_build_files.py emit actual build rules. - Our standalone builders, Chromium, and Android just run the top-level test targets using whatever GTest-based reporting story they have. In transition, we start by converting one of two tests in each library to populate the three test targets. Those are added to all_tests.json and all_tests.go hacked to handle them transparently. This keeps our standalone builder working. generate_build_files.py, to start with, populates the new source lists manually and subtracts them out of the old machinery. We emit both for the time being. When this change rolls in, we'll write all the build glue needed to build the GTest-based tests and add it to consumers' continuous builders. Next, we'll subsume a file-based test and get the consumers working with that. (I.e. make sure the GTest targets can depend on a data file.) Once that's all done, we'll be sure all this will work. At that point, we start subsuming the remaining tests into the GTest targets and, asynchronously, rewriting tests to use GTest properly rather than cursory conversion here. When all non-GTest tests are gone, the old generate_build_files.py hooks will be removed, consumers updated to not depend on them, and standalone builders converted to not rely on all_tests.go, which can then be removed. (Unless bits end up being needed as a malloc test driver. I'm thinking we'll want to do something with --gtest_filter.) As part of this CL, I've bumped the CMake requirements (for target_include_directories) and added a few suppressions for warnings that GTest doesn't pass. BUG=129 Change-Id: I881b26b07a8739cc0b52dbb51a30956908e1b71a Reviewed-on: https://boringssl-review.googlesource.com/13232 Reviewed-by: Adam Langley <agl@google.com>
2017-01-20 00:05:47 +00:00
add_dependencies(all_tests crypto_test)