# https://software.intel.com/sites/landingpage/IntrinsicsGuide/ # The variables HAVE_* determine if compiler has support for the flag to use the corresponding instruction set. # The options ENABLE_* determine if we will tell compiler to actually use the corresponding instruction set if compiler can do it. # All of them are unrelated to the instruction set at the host machine # (you can compile for newer instruction set on old machines and vice versa). option (ARCH_NATIVE "Add -march=native compiler flag. This makes your binaries non-portable but more performant code may be generated. This option overrides ENABLE_* options for specific instruction set. Highly not recommended to use." 0) if (ARCH_NATIVE) set (COMPILER_FLAGS "${COMPILER_FLAGS} -march=native") # Populate the ENABLE_ option flags. This is required for the build of some third-party dependencies, specifically snappy, which # (somewhat weirdly) expects the relative SNAPPY_HAVE_ preprocessor variables to be populated, in addition to the microarchitecture # feature flags being enabled in the compiler. This fixes the ARCH_NATIVE flag by automatically populating the ENABLE_ option flags # according to the current CPU's capabilities, detected using clang. if (ARCH_AMD64) execute_process( COMMAND sh -c "clang -E - -march=native -###" INPUT_FILE /dev/null OUTPUT_QUIET ERROR_VARIABLE TEST_FEATURE_RESULT) macro(TEST_AMD64_FEATURE TEST_FEATURE_RESULT feat flag) if (${TEST_FEATURE_RESULT} MATCHES "\"\\+${feat}\"") set(${flag} ON) else () set(${flag} OFF) endif () endmacro() TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} ssse3 ENABLE_SSSE3) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} sse4.1 ENABLE_SSE41) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} sse4.2 ENABLE_SSE42) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} vpclmulqdq ENABLE_PCLMULQDQ) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} popcnt ENABLE_POPCNT) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} avx ENABLE_AVX) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} avx2 ENABLE_AVX2) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} avx512f ENABLE_AVX512) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} avx512vbmi ENABLE_AVX512_VBMI) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} bmi ENABLE_BMI) TEST_AMD64_FEATURE (${TEST_FEATURE_RESULT} bmi2 ENABLE_BMI2) endif () elseif (ARCH_AARCH64) # ARM publishes almost every year a new revision of it's ISA [1]. Each version comes with new mandatory and optional features from # which CPU vendors can pick and choose. This creates a lot of variability ... We provide two build "profiles", one for maximum # compatibility intended to run on all 64-bit ARM hardware released after 2013 (e.g. Raspberry Pi 4), and one for modern ARM server # CPUs, (e.g. Graviton). # # [1] https://en.wikipedia.org/wiki/AArch64 option (NO_ARMV81_OR_HIGHER "Disable ARMv8.1 or higher on Aarch64 for maximum compatibility with older/embedded hardware." 0) if (NO_ARMV81_OR_HIGHER) # crc32 is optional in v8.0 and mandatory in v8.1. Enable it as __crc32()* is used in lot's of places and even very old ARM CPUs # support it. set (COMPILER_FLAGS "${COMPILER_FLAGS} -march=armv8+crc") else () # ARMv8.2 is quite ancient but the lowest common denominator supported by both Graviton 2 and 3 processors [1, 10]. In particular, it # includes LSE (made mandatory with ARMv8.1) which provides nice speedups without having to fall back to compat flag # "-moutline-atomics" for v8.0 [2, 3, 4] that requires a recent glibc with runtime dispatch helper, limiting our ability to run on # old OSs. # # simd: NEON, introduced as optional in v8.0, A few extensions were added with v8.1 but it's still not mandatory. Enables the # compiler to auto-vectorize. # sve: Scalable Vector Extensions, introduced as optional in v8.2. Available in Graviton 3 but not in Graviton 2, and most likely # also not in CI machines. Compiler support for autovectorization is rudimentary at the time of writing, see [5]. Can be # enabled one-fine-day (TM) but not now. # ssbs: "Speculative Store Bypass Safe". Optional in v8.0, mandatory in v8.5. Meltdown/spectre countermeasure. # crypto: SHA1, SHA256, AES. Optional in v8.0. In v8.4, further algorithms were added but it's still optional, see [6]. # dotprod: Scalar vector product (SDOT and UDOT instructions). Probably the most obscure extra flag with doubtful performance benefits # but it has been activated since always, so why not enable it. It's not 100% clear in which revision this flag was # introduced as optional, either in v8.2 [7] or in v8.4 [8]. # rcpc: Load-Acquire RCpc Register. Better support of release/acquire of atomics. Good for allocators and high contention code. # Optional in v8.2, mandatory in v8.3 [9]. Supported in Graviton >=2, Azure and GCP instances. # bf16: Bfloat16, a half-precision floating point format developed by Google Brain. Optional in v8.2, mandatory in v8.6. # # [1] https://github.com/aws/aws-graviton-getting-started/blob/main/c-c%2B%2B.md # [2] https://community.arm.com/arm-community-blogs/b/tools-software-ides-blog/posts/making-the-most-of-the-arm-architecture-in-gcc-10 # [3] https://mysqlonarm.github.io/ARM-LSE-and-MySQL/ # [4] https://dev.to/aws-builders/large-system-extensions-for-aws-graviton-processors-3eci # [5] https://developer.arm.com/tools-and-software/open-source-software/developer-tools/llvm-toolchain/sve-support # [6] https://developer.arm.com/documentation/100067/0612/armclang-Command-line-Options/-mcpu?lang=en # [7] https://gcc.gnu.org/onlinedocs/gcc/ARM-Options.html # [8] https://developer.arm.com/documentation/102651/a/What-are-dot-product-intructions- # [9] https://developer.arm.com/documentation/dui0801/g/A64-Data-Transfer-Instructions/LDAPR?lang=en # [10] https://github.com/aws/aws-graviton-getting-started/blob/main/README.md set (COMPILER_FLAGS "${COMPILER_FLAGS} -march=armv8.2-a+simd+crypto+dotprod+ssbs+rcpc+bf16") endif () # Best-effort check: The build generates and executes intermediate binaries, e.g. protoc and llvm-tablegen. If we build on ARM for ARM # and the build machine is too old, i.e. doesn't satisfy above modern profile, then these intermediate binaries will not run (dump # SIGILL). Even if they could run, the build machine wouldn't be able to run the ClickHouse binary. In that case, suggest to run the # build with the compat profile. if (OS_LINUX AND CMAKE_HOST_SYSTEM_PROCESSOR MATCHES "^(aarch64.*|AARCH64.*|arm64.*|ARM64.*)" AND NOT NO_ARMV81_OR_HIGHER) # CPU features in /proc/cpuinfo and compiler flags don't align :( ... pick some obvious flags contained in the modern but not in the # legacy profile (full Graviton 3 /proc/cpuinfo is "fp asimd evtstrm aes pmull sha1 sha2 crc32 atomics fphp asimdhp cpuid asimdrdm # jscvt fcma lrcpc dcpop sha3 sm3 sm4 asimddp sha512 sve asimdfhm dit uscat ilrcpc flagm ssbs paca pacg dcpodp svei8mm svebf16 i8mm # bf16 dgh rng") execute_process( COMMAND grep -P "^(?=.*atomic)(?=.*ssbs)" /proc/cpuinfo OUTPUT_VARIABLE FLAGS) if (NOT FLAGS) MESSAGE(FATAL_ERROR "The build machine does not satisfy the minimum CPU requirements, try to run cmake with -DNO_ARMV81_OR_HIGHER=1") endif() endif() elseif (ARCH_PPC64LE) # By Default, build for power8 and up, allow building for power9 and up # Note that gcc and clang have support for x86 SSE2 intrinsics when building for PowerPC option (POWER9 "Build for Power 9 CPU and above" 0) if(POWER9) set (COMPILER_FLAGS "${COMPILER_FLAGS} -maltivec -mcpu=power9 -D__SSE2__=1 -DNO_WARN_X86_INTRINSICS") else () set (COMPILER_FLAGS "${COMPILER_FLAGS} -maltivec -mcpu=power8 -D__SSE2__=1 -DNO_WARN_X86_INTRINSICS") endif () elseif (ARCH_AMD64) option (ENABLE_SSSE3 "Use SSSE3 instructions on x86_64" 1) option (ENABLE_SSE41 "Use SSE4.1 instructions on x86_64" 1) option (ENABLE_SSE42 "Use SSE4.2 instructions on x86_64" 1) option (ENABLE_PCLMULQDQ "Use pclmulqdq instructions on x86_64" 1) option (ENABLE_POPCNT "Use popcnt instructions on x86_64" 1) option (ENABLE_AVX "Use AVX instructions on x86_64" 0) option (ENABLE_AVX2 "Use AVX2 instructions on x86_64" 0) option (ENABLE_AVX512 "Use AVX512 instructions on x86_64" 0) option (ENABLE_AVX512_VBMI "Use AVX512_VBMI instruction on x86_64 (depends on ENABLE_AVX512)" 0) option (ENABLE_BMI "Use BMI instructions on x86_64" 0) option (ENABLE_BMI2 "Use BMI2 instructions on x86_64 (depends on ENABLE_AVX2)" 0) option (ENABLE_AVX2_FOR_SPEC_OP "Use avx2 instructions for specific operations on x86_64" 0) option (ENABLE_AVX512_FOR_SPEC_OP "Use avx512 instructions for specific operations on x86_64" 0) option (NO_SSE3_OR_HIGHER "Disable SSE3 or higher on x86_64 for maximum compatibility with older/embedded hardware." 0) if (NO_SSE3_OR_HIGHER) SET(ENABLE_SSSE3 0) SET(ENABLE_SSE41 0) SET(ENABLE_SSE42 0) SET(ENABLE_PCLMULQDQ 0) SET(ENABLE_POPCNT 0) SET(ENABLE_AVX 0) SET(ENABLE_AVX2 0) SET(ENABLE_AVX512 0) SET(ENABLE_AVX512_VBMI 0) SET(ENABLE_BMI 0) SET(ENABLE_BMI2 0) SET(ENABLE_AVX2_FOR_SPEC_OP 0) SET(ENABLE_AVX512_FOR_SPEC_OP 0) endif() # Same best-effort check for x86 as above for ARM. if (OS_LINUX AND CMAKE_HOST_SYSTEM_PROCESSOR MATCHES "amd64|x86_64" AND NOT NO_SSE3_OR_HIGHER) # Test for flags in standard profile but not in NO_SSE3_OR_HIGHER profile. # /proc/cpuid for Intel Xeon 8124: "fpu vme de pse tsc msr pae mce cx8 apic sep mtrr pge mca cmov pat pse36 clflush mmx fxsr sse # sse2 ss ht syscall nx pdpe1gb rdtscp lm constant_tsc arch_perfmon rep_good nopl xtopology nonstop_tsc cpuid aperfmperf # tsc_known_freq pni pclmulqdq monitor ssse3 fma cx16 pcid sse4_1 sse4_2 x2apic movbe popcnt tsc_deadline_timer aes xsave avx f16c # rdrand hypervisor lahf_lm abm 3dnowprefetch invpcid_single pti fsgsbase tsc_adjust bmi1 hle avx2 smep bmi2 erms invpcid rtm mpx # avx512f avx512dq rdseed adx smap clflushopt clwb avx512cd avx512bw avx512vl xsaveopt xsavec xgetbv1 xsaves ida arat pku ospke"" execute_process( COMMAND grep -P "^(?=.*ssse3)(?=.*sse4_1)(?=.*sse4_2)" /proc/cpuinfo OUTPUT_VARIABLE FLAGS) if (NOT FLAGS) MESSAGE(FATAL_ERROR "The build machine does not satisfy the minimum CPU requirements, try to run cmake with -DNO_SSE3_OR_HIGHER=1") endif() endif() # ClickHouse can be cross-compiled (e.g. on an ARM host for x86) but it is also possible to build ClickHouse on x86 w/o AVX for x86 w/ # AVX. We only assume that the compiler can emit certain SIMD instructions, we don't care if the host system is able to run the binary. if (ENABLE_SSSE3) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mssse3") endif () if (ENABLE_SSE41) set (COMPILER_FLAGS "${COMPILER_FLAGS} -msse4.1") endif () if (ENABLE_SSE42) set (COMPILER_FLAGS "${COMPILER_FLAGS} -msse4.2") endif () if (ENABLE_PCLMULQDQ) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mpclmul") endif () if (ENABLE_BMI) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mbmi") endif () if (ENABLE_POPCNT) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mpopcnt") endif () if (ENABLE_AVX) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mavx") endif () if (ENABLE_AVX2) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mavx2") if (ENABLE_BMI2) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mbmi2") endif () endif () if (ENABLE_AVX512) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mavx512f -mavx512bw -mavx512vl") if (ENABLE_AVX512_VBMI) set (COMPILER_FLAGS "${COMPILER_FLAGS} -mavx512vbmi") endif () endif () if (ENABLE_AVX512_FOR_SPEC_OP) set (X86_INTRINSICS_FLAGS "-mbmi -mavx512f -mavx512bw -mavx512vl -mprefer-vector-width=256") endif () else () # RISC-V + exotic platforms endif ()