// REQUIRES: nvptx-registered-target // REQUIRES: amdgpu-registered-target // Make sure we don't allow dynamic initialization for device // variables, but accept empty constructors allowed by CUDA. // RUN: %clang_cc1 -triple nvptx64-nvidia-cuda -fcuda-is-device -std=c++11 \ // RUN: -fno-threadsafe-statics -emit-llvm -o - %s | FileCheck -check-prefixes=DEVICE,NVPTX %s // RUN: %clang_cc1 -triple nvptx64-nvidia-cuda -std=c++11 \ // RUN: -fno-threadsafe-statics -emit-llvm -o - %s | FileCheck -check-prefixes=HOST %s // RUN: %clang_cc1 -triple amdgcn -fcuda-is-device -std=c++11 \ // RUN: -fno-threadsafe-statics -emit-llvm -o - %s | FileCheck -check-prefixes=DEVICE,AMDGCN %s #ifdef __clang__ #include "Inputs/cuda.h" #endif // Use the types we share with Sema tests. #include "Inputs/cuda-initializers.h" __device__ int d_v; // DEVICE: @d_v = addrspace(1) externally_initialized global i32 0, // HOST: @d_v = internal global i32 undef, __shared__ int s_v; // DEVICE: @s_v = addrspace(3) global i32 undef, // HOST: @s_v = internal global i32 undef, __constant__ int c_v; // DEVICE: addrspace(4) externally_initialized global i32 0, // HOST: @c_v = internal global i32 undef, __device__ int d_v_i = 1; // DEVICE: @d_v_i = addrspace(1) externally_initialized global i32 1, // HOST: @d_v_i = internal global i32 undef, // For `static` device variables, assume they won't be addressed from the host // side. static __device__ int d_s_v_i = 1; // DEVICE: @_ZL7d_s_v_i = internal addrspace(1) global i32 1, // Dummy function to keep static variables referenced. __device__ int foo() { return d_s_v_i; } // trivial constructor -- allowed __device__ T d_t; // DEVICE: @d_t = addrspace(1) externally_initialized global %struct.T zeroinitializer // HOST: @d_t = internal global %struct.T undef, __shared__ T s_t; // DEVICE: @s_t = addrspace(3) global %struct.T undef, // HOST: @s_t = internal global %struct.T undef, __constant__ T c_t; // DEVICE: @c_t = addrspace(4) externally_initialized global %struct.T zeroinitializer, // HOST: @c_t = internal global %struct.T undef, __device__ T d_t_i = {2}; // DEVICE: @d_t_i = addrspace(1) externally_initialized global %struct.T { i32 2 }, // HOST: @d_t_i = internal global %struct.T undef, __constant__ T c_t_i = {2}; // DEVICE: @c_t_i = addrspace(4) externally_initialized global %struct.T { i32 2 }, // HOST: @c_t_i = internal global %struct.T undef, // empty constructor __device__ EC d_ec; // DEVICE: @d_ec = addrspace(1) externally_initialized global %struct.EC zeroinitializer, // HOST: @d_ec = internal global %struct.EC undef, __shared__ EC s_ec; // DEVICE: @s_ec = addrspace(3) global %struct.EC undef, // HOST: @s_ec = internal global %struct.EC undef, __constant__ EC c_ec; // DEVICE: @c_ec = addrspace(4) externally_initialized global %struct.EC zeroinitializer, // HOST: @c_ec = internal global %struct.EC undef // empty destructor __device__ ED d_ed; // DEVICE: @d_ed = addrspace(1) externally_initialized global %struct.ED zeroinitializer, // HOST: @d_ed = internal global %struct.ED undef, __shared__ ED s_ed; // DEVICE: @s_ed = addrspace(3) global %struct.ED undef, // HOST: @s_ed = internal global %struct.ED undef, __constant__ ED c_ed; // DEVICE: @c_ed = addrspace(4) externally_initialized global %struct.ED zeroinitializer, // HOST: @c_ed = internal global %struct.ED undef, __device__ ECD d_ecd; // DEVICE: @d_ecd = addrspace(1) externally_initialized global %struct.ECD zeroinitializer, // HOST: @d_ecd = internal global %struct.ECD undef, __shared__ ECD s_ecd; // DEVICE: @s_ecd = addrspace(3) global %struct.ECD undef, // HOST: @s_ecd = internal global %struct.ECD undef, __constant__ ECD c_ecd; // DEVICE: @c_ecd = addrspace(4) externally_initialized global %struct.ECD zeroinitializer, // HOST: @c_ecd = internal global %struct.ECD undef, // empty templated constructor -- allowed with no arguments __device__ ETC d_etc; // DEVICE: @d_etc = addrspace(1) externally_initialized global %struct.ETC zeroinitializer, // HOST: @d_etc = internal global %struct.ETC undef, __shared__ ETC s_etc; // DEVICE: @s_etc = addrspace(3) global %struct.ETC undef, // HOST: @s_etc = internal global %struct.ETC undef, __constant__ ETC c_etc; // DEVICE: @c_etc = addrspace(4) externally_initialized global %struct.ETC zeroinitializer, // HOST: @c_etc = internal global %struct.ETC undef, __device__ NCFS d_ncfs; // DEVICE: @d_ncfs = addrspace(1) externally_initialized global %struct.NCFS { i32 3 } // HOST: @d_ncfs = internal global %struct.NCFS undef, __constant__ NCFS c_ncfs; // DEVICE: @c_ncfs = addrspace(4) externally_initialized global %struct.NCFS { i32 3 } // HOST: @c_ncfs = internal global %struct.NCFS undef, // Regular base class -- allowed __device__ T_B_T d_t_b_t; // DEVICE: @d_t_b_t = addrspace(1) externally_initialized global %struct.T_B_T zeroinitializer, // HOST: @d_t_b_t = internal global %struct.T_B_T undef, __shared__ T_B_T s_t_b_t; // DEVICE: @s_t_b_t = addrspace(3) global %struct.T_B_T undef, // HOST: @s_t_b_t = internal global %struct.T_B_T undef, __constant__ T_B_T c_t_b_t; // DEVICE: @c_t_b_t = addrspace(4) externally_initialized global %struct.T_B_T zeroinitializer, // HOST: @c_t_b_t = internal global %struct.T_B_T undef, // Incapsulated object of allowed class -- allowed __device__ T_F_T d_t_f_t; // DEVICE: @d_t_f_t = addrspace(1) externally_initialized global %struct.T_F_T zeroinitializer, // HOST: @d_t_f_t = internal global %struct.T_F_T undef, __shared__ T_F_T s_t_f_t; // DEVICE: @s_t_f_t = addrspace(3) global %struct.T_F_T undef, // HOST: @s_t_f_t = internal global %struct.T_F_T undef, __constant__ T_F_T c_t_f_t; // DEVICE: @c_t_f_t = addrspace(4) externally_initialized global %struct.T_F_T zeroinitializer, // HOST: @c_t_f_t = internal global %struct.T_F_T undef, // array of allowed objects -- allowed __device__ T_FA_T d_t_fa_t; // DEVICE: @d_t_fa_t = addrspace(1) externally_initialized global %struct.T_FA_T zeroinitializer, // HOST: @d_t_fa_t = internal global %struct.T_FA_T undef, __shared__ T_FA_T s_t_fa_t; // DEVICE: @s_t_fa_t = addrspace(3) global %struct.T_FA_T undef, // HOST: @s_t_fa_t = internal global %struct.T_FA_T undef, __constant__ T_FA_T c_t_fa_t; // DEVICE: @c_t_fa_t = addrspace(4) externally_initialized global %struct.T_FA_T zeroinitializer, // HOST: @c_t_fa_t = internal global %struct.T_FA_T undef, // Calling empty base class initializer is OK __device__ EC_I_EC d_ec_i_ec; // DEVICE: @d_ec_i_ec = addrspace(1) externally_initialized global %struct.EC_I_EC zeroinitializer, // HOST: @d_ec_i_ec = internal global %struct.EC_I_EC undef, __shared__ EC_I_EC s_ec_i_ec; // DEVICE: @s_ec_i_ec = addrspace(3) global %struct.EC_I_EC undef, // HOST: @s_ec_i_ec = internal global %struct.EC_I_EC undef, __constant__ EC_I_EC c_ec_i_ec; // DEVICE: @c_ec_i_ec = addrspace(4) externally_initialized global %struct.EC_I_EC zeroinitializer, // HOST: @c_ec_i_ec = internal global %struct.EC_I_EC undef, // DEVICE: @_ZZ2dfvE4s_ec = internal addrspace(3) global %struct.EC undef // DEVICE: @_ZZ2dfvE5s_etc = internal addrspace(3) global %struct.ETC undef // DEVICE: @_ZZ2dfvE11const_array = internal addrspace(4) constant [5 x i32] [i32 1, i32 2, i32 3, i32 4, i32 5] // DEVICE: @_ZZ2dfvE9const_int = internal addrspace(4) constant i32 123 // We should not emit global initializers for device-side variables. // DEVICE-NOT: @__cxx_global_var_init // Make sure that initialization restrictions do not apply to local // variables. __device__ void df() { // NVPTX: %[[ec:.*]] = alloca %struct.EC // NVPTX: %[[ed:.*]] = alloca %struct.ED // NVPTX: %[[ecd:.*]] = alloca %struct.ECD // NVPTX: %[[etc:.*]] = alloca %struct.ETC // NVPTX: %[[uc:.*]] = alloca %struct.UC // NVPTX: %[[ud:.*]] = alloca %struct.UD // NVPTX: %[[eci:.*]] = alloca %struct.ECI // NVPTX: %[[nec:.*]] = alloca %struct.NEC // NVPTX: %[[ned:.*]] = alloca %struct.NED // NVPTX: %[[ncv:.*]] = alloca %struct.NCV // NVPTX: %[[vd:.*]] = alloca %struct.VD // NVPTX: %[[ncf:.*]] = alloca %struct.NCF // NVPTX: %[[ncfs:.*]] = alloca %struct.NCFS // NVPTX: %[[utc:.*]] = alloca %struct.UTC // NVPTX: %[[netc:.*]] = alloca %struct.NETC // NVPTX: %[[ec_i_ec:.*]] = alloca %struct.EC_I_EC // NVPTX: %[[ec_i_ec1:.*]] = alloca %struct.EC_I_EC1 // NVPTX: %[[t_v_t:.*]] = alloca %struct.T_V_T // NVPTX: %[[t_b_nec:.*]] = alloca %struct.T_B_NEC // NVPTX: %[[t_f_nec:.*]] = alloca %struct.T_F_NEC // NVPTX: %[[t_fa_nec:.*]] = alloca %struct.T_FA_NEC // NVPTX: %[[t_b_ned:.*]] = alloca %struct.T_B_NED // NVPTX: %[[t_f_ned:.*]] = alloca %struct.T_F_NED // NVPTX: %[[t_fa_ned:.*]] = alloca %struct.T_FA_NED // AMDGCN: %[[ec:.*]] = addrspacecast %struct.EC addrspace(5)* %ec to %struct.EC* // AMDGCN: %[[ed:.*]] = addrspacecast %struct.ED addrspace(5)* %ed to %struct.ED* // AMDGCN: %[[ecd:.*]] = addrspacecast %struct.ECD addrspace(5)* %ecd to %struct.ECD* // AMDGCN: %[[etc:.*]] = addrspacecast %struct.ETC addrspace(5)* %etc to %struct.ETC* // AMDGCN: %[[uc:.*]] = addrspacecast %struct.UC addrspace(5)* %uc to %struct.UC* // AMDGCN: %[[ud:.*]] = addrspacecast %struct.UD addrspace(5)* %ud to %struct.UD* // AMDGCN: %[[eci:.*]] = addrspacecast %struct.ECI addrspace(5)* %eci to %struct.ECI* // AMDGCN: %[[nec:.*]] = addrspacecast %struct.NEC addrspace(5)* %nec to %struct.NEC* // AMDGCN: %[[ned:.*]] = addrspacecast %struct.NED addrspace(5)* %ned to %struct.NED* // AMDGCN: %[[ncv:.*]] = addrspacecast %struct.NCV addrspace(5)* %ncv to %struct.NCV* // AMDGCN: %[[vd:.*]] = addrspacecast %struct.VD addrspace(5)* %vd to %struct.VD* // AMDGCN: %[[ncf:.*]] = addrspacecast %struct.NCF addrspace(5)* %ncf to %struct.NCF* // AMDGCN: %[[ncfs:.*]] = addrspacecast %struct.NCFS addrspace(5)* %ncfs to %struct.NCFS* // AMDGCN: %[[utc:.*]] = addrspacecast %struct.UTC addrspace(5)* %utc to %struct.UTC* // AMDGCN: %[[netc:.*]] = addrspacecast %struct.NETC addrspace(5)* %netc to %struct.NETC* // AMDGCN: %[[ec_i_ec:.*]] = addrspacecast %struct.EC_I_EC addrspace(5)* %ec_i_ec to %struct.EC_I_EC* // AMDGCN: %[[ec_i_ec1:.*]] = addrspacecast %struct.EC_I_EC1 addrspace(5)* %ec_i_ec1 to %struct.EC_I_EC1* // AMDGCN: %[[t_v_t:.*]] = addrspacecast %struct.T_V_T addrspace(5)* %t_v_t to %struct.T_V_T* // AMDGCN: %[[t_b_nec:.*]] = addrspacecast %struct.T_B_NEC addrspace(5)* %t_b_nec to %struct.T_B_NEC* // AMDGCN: %[[t_f_nec:.*]] = addrspacecast %struct.T_F_NEC addrspace(5)* %t_f_nec to %struct.T_F_NEC* // AMDGCN: %[[t_fa_nec:.*]] = addrspacecast %struct.T_FA_NEC addrspace(5)* %t_fa_nec to %struct.T_FA_NEC* // AMDGCN: %[[t_b_ned:.*]] = addrspacecast %struct.T_B_NED addrspace(5)* %t_b_ned to %struct.T_B_NED* // AMDGCN: %[[t_f_ned:.*]] = addrspacecast %struct.T_F_NED addrspace(5)* %t_f_ned to %struct.T_F_NED* // AMDGCN: %[[t_fa_ned:.*]] = addrspacecast %struct.T_FA_NED addrspace(5)* %t_fa_ned to %struct.T_FA_NED* T t; // DEVICE-NOT: call EC ec; // DEVICE: call void @_ZN2ECC1Ev(%struct.EC* {{[^,]*}} %[[ec]]) ED ed; // DEVICE-NOT: call ECD ecd; // DEVICE: call void @_ZN3ECDC1Ev(%struct.ECD* {{[^,]*}} %[[ecd]]) ETC etc; // DEVICE: call void @_ZN3ETCC1IJEEEDpT_(%struct.ETC* {{[^,]*}} %[[etc]]) UC uc; // undefined constructor -- not allowed // DEVICE: call void @_ZN2UCC1Ev(%struct.UC* {{[^,]*}} %[[uc]]) UD ud; // undefined destructor -- not allowed // DEVICE-NOT: call ECI eci; // empty constructor w/ initializer list -- not allowed // DEVICE: call void @_ZN3ECIC1Ev(%struct.ECI* {{[^,]*}} %[[eci]]) NEC nec; // non-empty constructor -- not allowed // DEVICE: call void @_ZN3NECC1Ev(%struct.NEC* {{[^,]*}} %[[nec]]) // non-empty destructor -- not allowed NED ned; // no-constructor, virtual method -- not allowed // DEVICE: call void @_ZN3NCVC1Ev(%struct.NCV* {{[^,]*}} %[[ncv]]) NCV ncv; // DEVICE-NOT: call VD vd; // DEVICE: call void @_ZN2VDC1Ev(%struct.VD* {{[^,]*}} %[[vd]]) NCF ncf; // DEVICE: call void @_ZN3NCFC1Ev(%struct.NCF* {{[^,]*}} %[[ncf]]) NCFS ncfs; // DEVICE: call void @_ZN4NCFSC1Ev(%struct.NCFS* {{[^,]*}} %[[ncfs]]) UTC utc; // DEVICE: call void @_ZN3UTCC1IJEEEDpT_(%struct.UTC* {{[^,]*}} %[[utc]]) NETC netc; // DEVICE: call void @_ZN4NETCC1IJEEEDpT_(%struct.NETC* {{[^,]*}} %[[netc]]) T_B_T t_b_t; // DEVICE-NOT: call T_F_T t_f_t; // DEVICE-NOT: call T_FA_T t_fa_t; // DEVICE-NOT: call EC_I_EC ec_i_ec; // DEVICE: call void @_ZN7EC_I_ECC1Ev(%struct.EC_I_EC* {{[^,]*}} %[[ec_i_ec]]) EC_I_EC1 ec_i_ec1; // DEVICE: call void @_ZN8EC_I_EC1C1Ev(%struct.EC_I_EC1* {{[^,]*}} %[[ec_i_ec1]]) T_V_T t_v_t; // DEVICE: call void @_ZN5T_V_TC1Ev(%struct.T_V_T* {{[^,]*}} %[[t_v_t]]) T_B_NEC t_b_nec; // DEVICE: call void @_ZN7T_B_NECC1Ev(%struct.T_B_NEC* {{[^,]*}} %[[t_b_nec]]) T_F_NEC t_f_nec; // DEVICE: call void @_ZN7T_F_NECC1Ev(%struct.T_F_NEC* {{[^,]*}} %[[t_f_nec]]) T_FA_NEC t_fa_nec; // DEVICE: call void @_ZN8T_FA_NECC1Ev(%struct.T_FA_NEC* {{[^,]*}} %[[t_fa_nec]]) T_B_NED t_b_ned; // DEVICE-NOT: call T_F_NED t_f_ned; // DEVICE-NOT: call T_FA_NED t_fa_ned; // DEVICE-NOT: call static __shared__ EC s_ec; // DEVICE-NOT: call void @_ZN2ECC1Ev(%struct.EC* addrspacecast (%struct.EC addrspace(3)* @_ZZ2dfvE4s_ec to %struct.EC*)) static __shared__ ETC s_etc; // DEVICE-NOT: call void @_ZN3ETCC1IJEEEDpT_(%struct.ETC* addrspacecast (%struct.ETC addrspace(3)* @_ZZ2dfvE5s_etc to %struct.ETC*)) static const int const_array[] = {1, 2, 3, 4, 5}; static const int const_int = 123; // anchor point separating constructors and destructors df(); // DEVICE: call void @_Z2dfv() // Verify that we only call non-empty destructors // DEVICE-NEXT: call void @_ZN8T_FA_NEDD1Ev(%struct.T_FA_NED* {{[^,]*}} %[[t_fa_ned]]) // DEVICE-NEXT: call void @_ZN7T_F_NEDD1Ev(%struct.T_F_NED* {{[^,]*}} %[[t_f_ned]]) // DEVICE-NEXT: call void @_ZN7T_B_NEDD1Ev(%struct.T_B_NED* {{[^,]*}} %[[t_b_ned]]) // DEVICE-NEXT: call void @_ZN2VDD1Ev(%struct.VD* {{[^,]*}} %[[vd]]) // DEVICE-NEXT: call void @_ZN3NEDD1Ev(%struct.NED* {{[^,]*}} %[[ned]]) // DEVICE-NEXT: call void @_ZN2UDD1Ev(%struct.UD* {{[^,]*}} %[[ud]]) // DEVICE-NEXT: call void @_ZN3ECDD1Ev(%struct.ECD* {{[^,]*}} %[[ecd]]) // DEVICE-NEXT: call void @_ZN2EDD1Ev(%struct.ED* {{[^,]*}} %[[ed]]) // DEVICE-NEXT: ret void } // We should not emit global init function. // DEVICE-NOT: @_GLOBAL__sub_I