//===- subzero/crosstest/test_sync_atomic_main.cpp - Driver for tests -----===// // // The Subzero Code Generator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Driver for cross testing atomic intrinsics, via the sync builtins. // //===----------------------------------------------------------------------===// /* crosstest.py --test=test_sync_atomic.cpp --crosstest-bitcode=0 \ --driver=test_sync_atomic_main.cpp --prefix=Subzero_ \ --output=test_sync_atomic */ #include <pthread.h> #include <stdint.h> #include <cerrno> #include <climits> #include <cstdlib> #include <cstring> #include <iostream> // Include test_sync_atomic.h twice - once normally, and once within the // Subzero_ namespace, corresponding to the llc and Subzero translated // object files, respectively. #include "test_sync_atomic.h" #include "xdefs.h" namespace Subzero_ { #include "test_sync_atomic.h" } volatile uint64 Values[] = { 0, 1, 0x7e, 0x7f, 0x80, 0x81, 0xfe, 0xff, 0x7ffe, 0x7fff, 0x8000, 0x8001, 0xfffe, 0xffff, 0x007fffff /*Max subnormal + */, 0x00800000 /*Min+ */, 0x7f7fffff /*Max+ */, 0x7f800000 /*+Inf*/, 0xff800000 /*-Inf*/, 0x7fa00000 /*SNaN*/, 0x7fc00000 /*QNaN*/, 0x7ffffffe, 0x7fffffff, 0x80000000, 0x80000001, 0xfffffffe, 0xffffffff, 0x100000000ll, 0x100000001ll, 0x000fffffffffffffll /*Max subnormal + */, 0x0010000000000000ll /*Min+ */, 0x7fefffffffffffffll /*Max+ */, 0x7ff0000000000000ll /*+Inf*/, 0xfff0000000000000ll /*-Inf*/, 0x7ff0000000000001ll /*SNaN*/, 0x7ff8000000000000ll /*QNaN*/, 0x7ffffffffffffffell, 0x7fffffffffffffffll, 0x8000000000000000ll, 0x8000000000000001ll, 0xfffffffffffffffell, 0xffffffffffffffffll}; const static size_t NumValues = sizeof(Values) / sizeof(*Values); struct { volatile uint8_t l8; volatile uint16_t l16; volatile uint32_t l32; volatile uint64 l64; } AtomicLocs; template <typename Type> void testAtomicRMW(volatile Type *AtomicLoc, size_t &TotalTests, size_t &Passes, size_t &Failures) { typedef Type (*FuncType)(bool, volatile Type *, Type); static struct { const char *Name; FuncType FuncLlc; FuncType FuncSz; } Funcs[] = { #define X(inst) \ { STR(inst), test_##inst, Subzero_::test_##inst } \ , {STR(inst) "_alloca", test_alloca_##inst, Subzero_::test_alloca_##inst}, \ {STR(inst) "_const", test_const_##inst, Subzero_::test_const_##inst}, RMWOP_TABLE #undef X }; const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs); for (size_t f = 0; f < NumFuncs; ++f) { for (size_t i = 0; i < NumValues; ++i) { Type Value1 = static_cast<Type>(Values[i]); for (size_t j = 0; j < NumValues; ++j) { Type Value2 = static_cast<Type>(Values[j]); for (size_t k = 0; k < 2; ++k) { bool fetch_first = k; ++TotalTests; *AtomicLoc = Value1; Type ResultSz1 = Funcs[f].FuncSz(fetch_first, AtomicLoc, Value2); Type ResultSz2 = *AtomicLoc; *AtomicLoc = Value1; Type ResultLlc1 = Funcs[f].FuncLlc(fetch_first, AtomicLoc, Value2); Type ResultLlc2 = *AtomicLoc; if (ResultSz1 == ResultLlc1 && ResultSz2 == ResultLlc2) { ++Passes; } else { ++Failures; std::cout << "test_" << Funcs[f].Name << (CHAR_BIT * sizeof(Type)) << "(" << fetch_first << ", " << static_cast<uint64>(Value1) << ", " << static_cast<uint64>(Value2) << "): sz1=" << static_cast<uint64>(ResultSz1) << " llc1=" << static_cast<uint64>(ResultLlc1) << " sz2=" << static_cast<uint64>(ResultSz2) << " llc2=" << static_cast<uint64>(ResultLlc2) << "\n"; } } } } } } template <typename Type> void testValCompareAndSwap(volatile Type *AtomicLoc, size_t &TotalTests, size_t &Passes, size_t &Failures) { typedef Type (*FuncType)(volatile Type *, Type, Type); static struct { const char *Name; FuncType FuncLlc; FuncType FuncSz; } Funcs[] = {{"val_cmp_swap", test_val_cmp_swap, Subzero_::test_val_cmp_swap}, {"val_cmp_swap_loop", test_val_cmp_swap_loop, Subzero_::test_val_cmp_swap_loop}}; const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs); for (size_t f = 0; f < NumFuncs; ++f) { for (size_t i = 0; i < NumValues; ++i) { Type Value1 = static_cast<Type>(Values[i]); for (size_t j = 0; j < NumValues; ++j) { Type Value2 = static_cast<Type>(Values[j]); for (size_t f = 0; f < 2; ++f) { bool flip = f; ++TotalTests; *AtomicLoc = Value1; Type ResultSz1 = Funcs[f].FuncSz(AtomicLoc, flip ? Value2 : Value1, Value2); Type ResultSz2 = *AtomicLoc; *AtomicLoc = Value1; Type ResultLlc1 = Funcs[f].FuncLlc(AtomicLoc, flip ? Value2 : Value1, Value2); Type ResultLlc2 = *AtomicLoc; if (ResultSz1 == ResultLlc1 && ResultSz2 == ResultLlc2) { ++Passes; } else { ++Failures; std::cout << "test_" << Funcs[f].Name << (CHAR_BIT * sizeof(Type)) << "(" << static_cast<uint64>(Value1) << ", " << static_cast<uint64>(Value2) << ", flip=" << flip << "): sz1=" << static_cast<uint64>(ResultSz1) << " llc1=" << static_cast<uint64>(ResultLlc1) << " sz2=" << static_cast<uint64>(ResultSz2) << " llc2=" << static_cast<uint64>(ResultLlc2) << "\n"; } } } } } } template <typename Type> struct ThreadData { Type (*FuncPtr)(bool, volatile Type *, Type); bool Fetch; volatile Type *Ptr; Type Adjustment; }; template <typename Type> void *threadWrapper(void *Data) { #if defined(ARM32) || defined(MIPS32) // Given that most of times these crosstests for ARM are run under qemu, we // set a lower NumReps to allow crosstests to complete within a reasonable // amount of time. static const size_t NumReps = 1000; #else // ARM32 || MIPS32 static const size_t NumReps = 8000; #endif // ARM32 || MIPS32 ThreadData<Type> *TData = reinterpret_cast<ThreadData<Type> *>(Data); for (size_t i = 0; i < NumReps; ++i) { (void)TData->FuncPtr(TData->Fetch, TData->Ptr, TData->Adjustment); } return NULL; } template <typename Type> void testAtomicRMWThreads(volatile Type *AtomicLoc, size_t &TotalTests, size_t &Passes, size_t &Failures) { typedef Type (*FuncType)(bool, volatile Type *, Type); static struct { const char *Name; FuncType FuncLlc; FuncType FuncSz; } Funcs[] = { #define X(inst) \ { STR(inst), test_##inst, Subzero_::test_##inst } \ , {STR(inst) "_alloca", test_alloca_##inst, Subzero_::test_alloca_##inst}, RMWOP_TABLE #undef X }; const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs); // Just test a few values, otherwise it takes a *really* long time. volatile uint64 ValuesSubset[] = {1, 0x7e, 0x000fffffffffffffffll}; const size_t NumValuesSubset = sizeof(ValuesSubset) / sizeof(*ValuesSubset); for (size_t f = 0; f < NumFuncs; ++f) { for (size_t i = 0; i < NumValuesSubset; ++i) { Type Value1 = static_cast<Type>(ValuesSubset[i]); for (size_t j = 0; j < NumValuesSubset; ++j) { Type Value2 = static_cast<Type>(ValuesSubset[j]); bool fetch_first = true; ThreadData<Type> TDataSz = {Funcs[f].FuncSz, fetch_first, AtomicLoc, Value2}; ThreadData<Type> TDataLlc = {Funcs[f].FuncLlc, fetch_first, AtomicLoc, Value2}; ++TotalTests; const size_t NumThreads = 4; pthread_t t[NumThreads]; pthread_attr_t attr[NumThreads]; // Try N threads w/ just Llc. *AtomicLoc = Value1; for (size_t m = 0; m < NumThreads; ++m) { pthread_attr_init(&attr[m]); if (pthread_create(&t[m], &attr[m], &threadWrapper<Type>, reinterpret_cast<void *>(&TDataLlc)) != 0) { std::cout << "pthread_create failed w/ " << strerror(errno) << "\n"; abort(); } } for (size_t m = 0; m < NumThreads; ++m) { pthread_join(t[m], NULL); } Type ResultLlc = *AtomicLoc; // Try N threads w/ both Sz and Llc. *AtomicLoc = Value1; for (size_t m = 0; m < NumThreads; ++m) { pthread_attr_init(&attr[m]); if (pthread_create(&t[m], &attr[m], &threadWrapper<Type>, m % 2 == 0 ? reinterpret_cast<void *>(&TDataLlc) : reinterpret_cast<void *>(&TDataSz)) != 0) { ++Failures; std::cout << "pthread_create failed w/ " << strerror(errno) << "\n"; abort(); } } for (size_t m = 0; m < NumThreads; ++m) { if (pthread_join(t[m], NULL) != 0) { ++Failures; std::cout << "pthread_join failed w/ " << strerror(errno) << "\n"; abort(); } } Type ResultMixed = *AtomicLoc; if (ResultLlc == ResultMixed) { ++Passes; } else { ++Failures; std::cout << "test_with_threads_" << Funcs[f].Name << (8 * sizeof(Type)) << "(" << static_cast<uint64>(Value1) << ", " << static_cast<uint64>(Value2) << "): llc=" << static_cast<uint64>(ResultLlc) << " mixed=" << static_cast<uint64>(ResultMixed) << "\n"; } } } } } int main(int argc, char *argv[]) { size_t TotalTests = 0; size_t Passes = 0; size_t Failures = 0; testAtomicRMW<uint8_t>(&AtomicLocs.l8, TotalTests, Passes, Failures); testAtomicRMW<uint16_t>(&AtomicLocs.l16, TotalTests, Passes, Failures); testAtomicRMW<uint32_t>(&AtomicLocs.l32, TotalTests, Passes, Failures); testAtomicRMW<uint64>(&AtomicLocs.l64, TotalTests, Passes, Failures); testValCompareAndSwap<uint8_t>(&AtomicLocs.l8, TotalTests, Passes, Failures); testValCompareAndSwap<uint16_t>(&AtomicLocs.l16, TotalTests, Passes, Failures); testValCompareAndSwap<uint32_t>(&AtomicLocs.l32, TotalTests, Passes, Failures); testValCompareAndSwap<uint64>(&AtomicLocs.l64, TotalTests, Passes, Failures); testAtomicRMWThreads<uint8_t>(&AtomicLocs.l8, TotalTests, Passes, Failures); testAtomicRMWThreads<uint16_t>(&AtomicLocs.l16, TotalTests, Passes, Failures); testAtomicRMWThreads<uint32_t>(&AtomicLocs.l32, TotalTests, Passes, Failures); testAtomicRMWThreads<uint64>(&AtomicLocs.l64, TotalTests, Passes, Failures); std::cout << "TotalTests=" << TotalTests << " Passes=" << Passes << " Failures=" << Failures << "\n"; return Failures; }