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Diffstat (limited to 'openmp/runtime/src/kmp_atomic.cpp')
| -rw-r--r-- | openmp/runtime/src/kmp_atomic.cpp | 3120 |
1 files changed, 3120 insertions, 0 deletions
diff --git a/openmp/runtime/src/kmp_atomic.cpp b/openmp/runtime/src/kmp_atomic.cpp new file mode 100644 index 00000000000..fec2f88c6c0 --- /dev/null +++ b/openmp/runtime/src/kmp_atomic.cpp @@ -0,0 +1,3120 @@ +/* + * kmp_atomic.c -- ATOMIC implementation routines + */ + + +//===----------------------------------------------------------------------===// +// +// The LLVM Compiler Infrastructure +// +// This file is dual licensed under the MIT and the University of Illinois Open +// Source Licenses. See LICENSE.txt for details. +// +//===----------------------------------------------------------------------===// + + +#include "kmp_atomic.h" +#include "kmp.h" // TRUE, asm routines prototypes + +typedef unsigned char uchar; +typedef unsigned short ushort; + +/*! +@defgroup ATOMIC_OPS Atomic Operations +These functions are used for implementing the many different varieties of atomic operations. + +The compiler is at liberty to inline atomic operations that are naturally supported +by the target architecture. For instance on IA-32 architecture an atomic like this can be inlined +@code +static int s = 0; +#pragma omp atomic + s++; +@endcode +using the single instruction: `lock; incl s` + +However the runtime does provide entrypoints for these operations to support compilers that choose +not to inline them. (For instance, `__kmpc_atomic_fixed4_add` could be used to perform the +increment above.) + +The names of the functions are encoded by using the data type name and the operation name, as in these tables. + +Data Type | Data type encoding +-----------|--------------- +int8_t | `fixed1` +uint8_t | `fixed1u` +int16_t | `fixed2` +uint16_t | `fixed2u` +int32_t | `fixed4` +uint32_t | `fixed4u` +int32_t | `fixed8` +uint32_t | `fixed8u` +float | `float4` +double | `float8` +float 10 (8087 eighty bit float) | `float10` +complex<float> | `cmplx4` +complex<double> | `cmplx8` +complex<float10> | `cmplx10` +<br> + +Operation | Operation encoding +----------|------------------- ++ | add +- | sub +\* | mul +/ | div +& | andb +<< | shl +\>\> | shr +\| | orb +^ | xor +&& | andl +\|\| | orl +maximum | max +minimum | min +.eqv. | eqv +.neqv. | neqv + +<br> +For non-commutative operations, `_rev` can also be added for the reversed operation. +For the functions that capture the result, the suffix `_cpt` is added. + +Update Functions +================ +The general form of an atomic function that just performs an update (without a `capture`) +@code +void __kmpc_atomic_<datatype>_<operation>( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs ); +@endcode +@param ident_t a pointer to source location +@param gtid the global thread id +@param lhs a pointer to the left operand +@param rhs the right operand + +`capture` functions +=================== +The capture functions perform an atomic update and return a result, which is either the value +before the capture, or that after. They take an additional argument to determine which result is returned. +Their general form is therefore +@code +TYPE __kmpc_atomic_<datatype>_<operation>_cpt( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs, int flag ); +@endcode +@param ident_t a pointer to source location +@param gtid the global thread id +@param lhs a pointer to the left operand +@param rhs the right operand +@param flag one if the result is to be captured *after* the operation, zero if captured *before*. + +The one set of exceptions to this is the `complex<float>` type where the value is not returned, +rather an extra argument pointer is passed. + +They look like +@code +void __kmpc_atomic_cmplx4_<op>_cpt( ident_t *id_ref, int gtid, kmp_cmplx32 * lhs, kmp_cmplx32 rhs, kmp_cmplx32 * out, int flag ); +@endcode + +Read and Write Operations +========================= +The OpenMP<sup>*</sup> standard now supports atomic operations that simply ensure that the +value is read or written atomically, with no modification +performed. In many cases on IA-32 architecture these operations can be inlined since +the architecture guarantees that no tearing occurs on aligned objects +accessed with a single memory operation of up to 64 bits in size. + +The general form of the read operations is +@code +TYPE __kmpc_atomic_<type>_rd ( ident_t *id_ref, int gtid, TYPE * loc ); +@endcode + +For the write operations the form is +@code +void __kmpc_atomic_<type>_wr ( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs ); +@endcode + +Full list of functions +====================== +This leads to the generation of 376 atomic functions, as follows. + +Functons for integers +--------------------- +There are versions here for integers of size 1,2,4 and 8 bytes both signed and unsigned (where that matters). +@code + __kmpc_atomic_fixed1_add + __kmpc_atomic_fixed1_add_cpt + __kmpc_atomic_fixed1_add_fp + __kmpc_atomic_fixed1_andb + __kmpc_atomic_fixed1_andb_cpt + __kmpc_atomic_fixed1_andl + __kmpc_atomic_fixed1_andl_cpt + __kmpc_atomic_fixed1_div + __kmpc_atomic_fixed1_div_cpt + __kmpc_atomic_fixed1_div_cpt_rev + __kmpc_atomic_fixed1_div_float8 + __kmpc_atomic_fixed1_div_fp + __kmpc_atomic_fixed1_div_rev + __kmpc_atomic_fixed1_eqv + __kmpc_atomic_fixed1_eqv_cpt + __kmpc_atomic_fixed1_max + __kmpc_atomic_fixed1_max_cpt + __kmpc_atomic_fixed1_min + __kmpc_atomic_fixed1_min_cpt + __kmpc_atomic_fixed1_mul + __kmpc_atomic_fixed1_mul_cpt + __kmpc_atomic_fixed1_mul_float8 + __kmpc_atomic_fixed1_mul_fp + __kmpc_atomic_fixed1_neqv + __kmpc_atomic_fixed1_neqv_cpt + __kmpc_atomic_fixed1_orb + __kmpc_atomic_fixed1_orb_cpt + __kmpc_atomic_fixed1_orl + __kmpc_atomic_fixed1_orl_cpt + __kmpc_atomic_fixed1_rd + __kmpc_atomic_fixed1_shl + __kmpc_atomic_fixed1_shl_cpt + __kmpc_atomic_fixed1_shl_cpt_rev + __kmpc_atomic_fixed1_shl_rev + __kmpc_atomic_fixed1_shr + __kmpc_atomic_fixed1_shr_cpt + __kmpc_atomic_fixed1_shr_cpt_rev + __kmpc_atomic_fixed1_shr_rev + __kmpc_atomic_fixed1_sub + __kmpc_atomic_fixed1_sub_cpt + __kmpc_atomic_fixed1_sub_cpt_rev + __kmpc_atomic_fixed1_sub_fp + __kmpc_atomic_fixed1_sub_rev + __kmpc_atomic_fixed1_swp + __kmpc_atomic_fixed1_wr + __kmpc_atomic_fixed1_xor + __kmpc_atomic_fixed1_xor_cpt + __kmpc_atomic_fixed1u_add_fp + __kmpc_atomic_fixed1u_sub_fp + __kmpc_atomic_fixed1u_mul_fp + __kmpc_atomic_fixed1u_div + __kmpc_atomic_fixed1u_div_cpt + __kmpc_atomic_fixed1u_div_cpt_rev + __kmpc_atomic_fixed1u_div_fp + __kmpc_atomic_fixed1u_div_rev + __kmpc_atomic_fixed1u_shr + __kmpc_atomic_fixed1u_shr_cpt + __kmpc_atomic_fixed1u_shr_cpt_rev + __kmpc_atomic_fixed1u_shr_rev + __kmpc_atomic_fixed2_add + __kmpc_atomic_fixed2_add_cpt + __kmpc_atomic_fixed2_add_fp + __kmpc_atomic_fixed2_andb + __kmpc_atomic_fixed2_andb_cpt + __kmpc_atomic_fixed2_andl + __kmpc_atomic_fixed2_andl_cpt + __kmpc_atomic_fixed2_div + __kmpc_atomic_fixed2_div_cpt + __kmpc_atomic_fixed2_div_cpt_rev + __kmpc_atomic_fixed2_div_float8 + __kmpc_atomic_fixed2_div_fp + __kmpc_atomic_fixed2_div_rev + __kmpc_atomic_fixed2_eqv + __kmpc_atomic_fixed2_eqv_cpt + __kmpc_atomic_fixed2_max + __kmpc_atomic_fixed2_max_cpt + __kmpc_atomic_fixed2_min + __kmpc_atomic_fixed2_min_cpt + __kmpc_atomic_fixed2_mul + __kmpc_atomic_fixed2_mul_cpt + __kmpc_atomic_fixed2_mul_float8 + __kmpc_atomic_fixed2_mul_fp + __kmpc_atomic_fixed2_neqv + __kmpc_atomic_fixed2_neqv_cpt + __kmpc_atomic_fixed2_orb + __kmpc_atomic_fixed2_orb_cpt + __kmpc_atomic_fixed2_orl + __kmpc_atomic_fixed2_orl_cpt + __kmpc_atomic_fixed2_rd + __kmpc_atomic_fixed2_shl + __kmpc_atomic_fixed2_shl_cpt + __kmpc_atomic_fixed2_shl_cpt_rev + __kmpc_atomic_fixed2_shl_rev + __kmpc_atomic_fixed2_shr + __kmpc_atomic_fixed2_shr_cpt + __kmpc_atomic_fixed2_shr_cpt_rev + __kmpc_atomic_fixed2_shr_rev + __kmpc_atomic_fixed2_sub + __kmpc_atomic_fixed2_sub_cpt + __kmpc_atomic_fixed2_sub_cpt_rev + __kmpc_atomic_fixed2_sub_fp + __kmpc_atomic_fixed2_sub_rev + __kmpc_atomic_fixed2_swp + __kmpc_atomic_fixed2_wr + __kmpc_atomic_fixed2_xor + __kmpc_atomic_fixed2_xor_cpt + __kmpc_atomic_fixed2u_add_fp + __kmpc_atomic_fixed2u_sub_fp + __kmpc_atomic_fixed2u_mul_fp + __kmpc_atomic_fixed2u_div + __kmpc_atomic_fixed2u_div_cpt + __kmpc_atomic_fixed2u_div_cpt_rev + __kmpc_atomic_fixed2u_div_fp + __kmpc_atomic_fixed2u_div_rev + __kmpc_atomic_fixed2u_shr + __kmpc_atomic_fixed2u_shr_cpt + __kmpc_atomic_fixed2u_shr_cpt_rev + __kmpc_atomic_fixed2u_shr_rev + __kmpc_atomic_fixed4_add + __kmpc_atomic_fixed4_add_cpt + __kmpc_atomic_fixed4_add_fp + __kmpc_atomic_fixed4_andb + __kmpc_atomic_fixed4_andb_cpt + __kmpc_atomic_fixed4_andl + __kmpc_atomic_fixed4_andl_cpt + __kmpc_atomic_fixed4_div + __kmpc_atomic_fixed4_div_cpt + __kmpc_atomic_fixed4_div_cpt_rev + __kmpc_atomic_fixed4_div_float8 + __kmpc_atomic_fixed4_div_fp + __kmpc_atomic_fixed4_div_rev + __kmpc_atomic_fixed4_eqv + __kmpc_atomic_fixed4_eqv_cpt + __kmpc_atomic_fixed4_max + __kmpc_atomic_fixed4_max_cpt + __kmpc_atomic_fixed4_min + __kmpc_atomic_fixed4_min_cpt + __kmpc_atomic_fixed4_mul + __kmpc_atomic_fixed4_mul_cpt + __kmpc_atomic_fixed4_mul_float8 + __kmpc_atomic_fixed4_mul_fp + __kmpc_atomic_fixed4_neqv + __kmpc_atomic_fixed4_neqv_cpt + __kmpc_atomic_fixed4_orb + __kmpc_atomic_fixed4_orb_cpt + __kmpc_atomic_fixed4_orl + __kmpc_atomic_fixed4_orl_cpt + __kmpc_atomic_fixed4_rd + __kmpc_atomic_fixed4_shl + __kmpc_atomic_fixed4_shl_cpt + __kmpc_atomic_fixed4_shl_cpt_rev + __kmpc_atomic_fixed4_shl_rev + __kmpc_atomic_fixed4_shr + __kmpc_atomic_fixed4_shr_cpt + __kmpc_atomic_fixed4_shr_cpt_rev + __kmpc_atomic_fixed4_shr_rev + __kmpc_atomic_fixed4_sub + __kmpc_atomic_fixed4_sub_cpt + __kmpc_atomic_fixed4_sub_cpt_rev + __kmpc_atomic_fixed4_sub_fp + __kmpc_atomic_fixed4_sub_rev + __kmpc_atomic_fixed4_swp + __kmpc_atomic_fixed4_wr + __kmpc_atomic_fixed4_xor + __kmpc_atomic_fixed4_xor_cpt + __kmpc_atomic_fixed4u_add_fp + __kmpc_atomic_fixed4u_sub_fp + __kmpc_atomic_fixed4u_mul_fp + __kmpc_atomic_fixed4u_div + __kmpc_atomic_fixed4u_div_cpt + __kmpc_atomic_fixed4u_div_cpt_rev + __kmpc_atomic_fixed4u_div_fp + __kmpc_atomic_fixed4u_div_rev + __kmpc_atomic_fixed4u_shr + __kmpc_atomic_fixed4u_shr_cpt + __kmpc_atomic_fixed4u_shr_cpt_rev + __kmpc_atomic_fixed4u_shr_rev + __kmpc_atomic_fixed8_add + __kmpc_atomic_fixed8_add_cpt + __kmpc_atomic_fixed8_add_fp + __kmpc_atomic_fixed8_andb + __kmpc_atomic_fixed8_andb_cpt + __kmpc_atomic_fixed8_andl + __kmpc_atomic_fixed8_andl_cpt + __kmpc_atomic_fixed8_div + __kmpc_atomic_fixed8_div_cpt + __kmpc_atomic_fixed8_div_cpt_rev + __kmpc_atomic_fixed8_div_float8 + __kmpc_atomic_fixed8_div_fp + __kmpc_atomic_fixed8_div_rev + __kmpc_atomic_fixed8_eqv + __kmpc_atomic_fixed8_eqv_cpt + __kmpc_atomic_fixed8_max + __kmpc_atomic_fixed8_max_cpt + __kmpc_atomic_fixed8_min + __kmpc_atomic_fixed8_min_cpt + __kmpc_atomic_fixed8_mul + __kmpc_atomic_fixed8_mul_cpt + __kmpc_atomic_fixed8_mul_float8 + __kmpc_atomic_fixed8_mul_fp + __kmpc_atomic_fixed8_neqv + __kmpc_atomic_fixed8_neqv_cpt + __kmpc_atomic_fixed8_orb + __kmpc_atomic_fixed8_orb_cpt + __kmpc_atomic_fixed8_orl + __kmpc_atomic_fixed8_orl_cpt + __kmpc_atomic_fixed8_rd + __kmpc_atomic_fixed8_shl + __kmpc_atomic_fixed8_shl_cpt + __kmpc_atomic_fixed8_shl_cpt_rev + __kmpc_atomic_fixed8_shl_rev + __kmpc_atomic_fixed8_shr + __kmpc_atomic_fixed8_shr_cpt + __kmpc_atomic_fixed8_shr_cpt_rev + __kmpc_atomic_fixed8_shr_rev + __kmpc_atomic_fixed8_sub + __kmpc_atomic_fixed8_sub_cpt + __kmpc_atomic_fixed8_sub_cpt_rev + __kmpc_atomic_fixed8_sub_fp + __kmpc_atomic_fixed8_sub_rev + __kmpc_atomic_fixed8_swp + __kmpc_atomic_fixed8_wr + __kmpc_atomic_fixed8_xor + __kmpc_atomic_fixed8_xor_cpt + __kmpc_atomic_fixed8u_add_fp + __kmpc_atomic_fixed8u_sub_fp + __kmpc_atomic_fixed8u_mul_fp + __kmpc_atomic_fixed8u_div + __kmpc_atomic_fixed8u_div_cpt + __kmpc_atomic_fixed8u_div_cpt_rev + __kmpc_atomic_fixed8u_div_fp + __kmpc_atomic_fixed8u_div_rev + __kmpc_atomic_fixed8u_shr + __kmpc_atomic_fixed8u_shr_cpt + __kmpc_atomic_fixed8u_shr_cpt_rev + __kmpc_atomic_fixed8u_shr_rev +@endcode + +Functions for floating point +---------------------------- +There are versions here for floating point numbers of size 4, 8, 10 and 16 bytes. +(Ten byte floats are used by X87, but are now rare). +@code + __kmpc_atomic_float4_add + __kmpc_atomic_float4_add_cpt + __kmpc_atomic_float4_add_float8 + __kmpc_atomic_float4_add_fp + __kmpc_atomic_float4_div + __kmpc_atomic_float4_div_cpt + __kmpc_atomic_float4_div_cpt_rev + __kmpc_atomic_float4_div_float8 + __kmpc_atomic_float4_div_fp + __kmpc_atomic_float4_div_rev + __kmpc_atomic_float4_max + __kmpc_atomic_float4_max_cpt + __kmpc_atomic_float4_min + __kmpc_atomic_float4_min_cpt + __kmpc_atomic_float4_mul + __kmpc_atomic_float4_mul_cpt + __kmpc_atomic_float4_mul_float8 + __kmpc_atomic_float4_mul_fp + __kmpc_atomic_float4_rd + __kmpc_atomic_float4_sub + __kmpc_atomic_float4_sub_cpt + __kmpc_atomic_float4_sub_cpt_rev + __kmpc_atomic_float4_sub_float8 + __kmpc_atomic_float4_sub_fp + __kmpc_atomic_float4_sub_rev + __kmpc_atomic_float4_swp + __kmpc_atomic_float4_wr + __kmpc_atomic_float8_add + __kmpc_atomic_float8_add_cpt + __kmpc_atomic_float8_add_fp + __kmpc_atomic_float8_div + __kmpc_atomic_float8_div_cpt + __kmpc_atomic_float8_div_cpt_rev + __kmpc_atomic_float8_div_fp + __kmpc_atomic_float8_div_rev + __kmpc_atomic_float8_max + __kmpc_atomic_float8_max_cpt + __kmpc_atomic_float8_min + __kmpc_atomic_float8_min_cpt + __kmpc_atomic_float8_mul + __kmpc_atomic_float8_mul_cpt + __kmpc_atomic_float8_mul_fp + __kmpc_atomic_float8_rd + __kmpc_atomic_float8_sub + __kmpc_atomic_float8_sub_cpt + __kmpc_atomic_float8_sub_cpt_rev + __kmpc_atomic_float8_sub_fp + __kmpc_atomic_float8_sub_rev + __kmpc_atomic_float8_swp + __kmpc_atomic_float8_wr + __kmpc_atomic_float10_add + __kmpc_atomic_float10_add_cpt + __kmpc_atomic_float10_add_fp + __kmpc_atomic_float10_div + __kmpc_atomic_float10_div_cpt + __kmpc_atomic_float10_div_cpt_rev + __kmpc_atomic_float10_div_fp + __kmpc_atomic_float10_div_rev + __kmpc_atomic_float10_mul + __kmpc_atomic_float10_mul_cpt + __kmpc_atomic_float10_mul_fp + __kmpc_atomic_float10_rd + __kmpc_atomic_float10_sub + __kmpc_atomic_float10_sub_cpt + __kmpc_atomic_float10_sub_cpt_rev + __kmpc_atomic_float10_sub_fp + __kmpc_atomic_float10_sub_rev + __kmpc_atomic_float10_swp + __kmpc_atomic_float10_wr + __kmpc_atomic_float16_add + __kmpc_atomic_float16_add_cpt + __kmpc_atomic_float16_div + __kmpc_atomic_float16_div_cpt + __kmpc_atomic_float16_div_cpt_rev + __kmpc_atomic_float16_div_rev + __kmpc_atomic_float16_max + __kmpc_atomic_float16_max_cpt + __kmpc_atomic_float16_min + __kmpc_atomic_float16_min_cpt + __kmpc_atomic_float16_mul + __kmpc_atomic_float16_mul_cpt + __kmpc_atomic_float16_rd + __kmpc_atomic_float16_sub + __kmpc_atomic_float16_sub_cpt + __kmpc_atomic_float16_sub_cpt_rev + __kmpc_atomic_float16_sub_rev + __kmpc_atomic_float16_swp + __kmpc_atomic_float16_wr +@endcode + +Functions for Complex types +--------------------------- +Functions for complex types whose component floating point variables are of size 4,8,10 or 16 bytes. +The names here are based on the size of the component float, *not* the size of the complex type. So +`__kmpc_atomc_cmplx8_add` is an operation on a `complex<double>` or `complex(kind=8)`, *not* `complex<float>`. + +@code + __kmpc_atomic_cmplx4_add + __kmpc_atomic_cmplx4_add_cmplx8 + __kmpc_atomic_cmplx4_add_cpt + __kmpc_atomic_cmplx4_div + __kmpc_atomic_cmplx4_div_cmplx8 + __kmpc_atomic_cmplx4_div_cpt + __kmpc_atomic_cmplx4_div_cpt_rev + __kmpc_atomic_cmplx4_div_rev + __kmpc_atomic_cmplx4_mul + __kmpc_atomic_cmplx4_mul_cmplx8 + __kmpc_atomic_cmplx4_mul_cpt + __kmpc_atomic_cmplx4_rd + __kmpc_atomic_cmplx4_sub + __kmpc_atomic_cmplx4_sub_cmplx8 + __kmpc_atomic_cmplx4_sub_cpt + __kmpc_atomic_cmplx4_sub_cpt_rev + __kmpc_atomic_cmplx4_sub_rev + __kmpc_atomic_cmplx4_swp + __kmpc_atomic_cmplx4_wr + __kmpc_atomic_cmplx8_add + __kmpc_atomic_cmplx8_add_cpt + __kmpc_atomic_cmplx8_div + __kmpc_atomic_cmplx8_div_cpt + __kmpc_atomic_cmplx8_div_cpt_rev + __kmpc_atomic_cmplx8_div_rev + __kmpc_atomic_cmplx8_mul + __kmpc_atomic_cmplx8_mul_cpt + __kmpc_atomic_cmplx8_rd + __kmpc_atomic_cmplx8_sub + __kmpc_atomic_cmplx8_sub_cpt + __kmpc_atomic_cmplx8_sub_cpt_rev + __kmpc_atomic_cmplx8_sub_rev + __kmpc_atomic_cmplx8_swp + __kmpc_atomic_cmplx8_wr + __kmpc_atomic_cmplx10_add + __kmpc_atomic_cmplx10_add_cpt + __kmpc_atomic_cmplx10_div + __kmpc_atomic_cmplx10_div_cpt + __kmpc_atomic_cmplx10_div_cpt_rev + __kmpc_atomic_cmplx10_div_rev + __kmpc_atomic_cmplx10_mul + __kmpc_atomic_cmplx10_mul_cpt + __kmpc_atomic_cmplx10_rd + __kmpc_atomic_cmplx10_sub + __kmpc_atomic_cmplx10_sub_cpt + __kmpc_atomic_cmplx10_sub_cpt_rev + __kmpc_atomic_cmplx10_sub_rev + __kmpc_atomic_cmplx10_swp + __kmpc_atomic_cmplx10_wr + __kmpc_atomic_cmplx16_add + __kmpc_atomic_cmplx16_add_cpt + __kmpc_atomic_cmplx16_div + __kmpc_atomic_cmplx16_div_cpt + __kmpc_atomic_cmplx16_div_cpt_rev + __kmpc_atomic_cmplx16_div_rev + __kmpc_atomic_cmplx16_mul + __kmpc_atomic_cmplx16_mul_cpt + __kmpc_atomic_cmplx16_rd + __kmpc_atomic_cmplx16_sub + __kmpc_atomic_cmplx16_sub_cpt + __kmpc_atomic_cmplx16_sub_cpt_rev + __kmpc_atomic_cmplx16_swp + __kmpc_atomic_cmplx16_wr +@endcode +*/ + +/*! +@ingroup ATOMIC_OPS +@{ +*/ + +/* + * Global vars + */ + +#ifndef KMP_GOMP_COMPAT +int __kmp_atomic_mode = 1; // Intel perf +#else +int __kmp_atomic_mode = 2; // GOMP compatibility +#endif /* KMP_GOMP_COMPAT */ + +KMP_ALIGN(128) + +kmp_atomic_lock_t __kmp_atomic_lock; /* Control access to all user coded atomics in Gnu compat mode */ +kmp_atomic_lock_t __kmp_atomic_lock_1i; /* Control access to all user coded atomics for 1-byte fixed data types */ +kmp_atomic_lock_t __kmp_atomic_lock_2i; /* Control access to all user coded atomics for 2-byte fixed data types */ +kmp_atomic_lock_t __kmp_atomic_lock_4i; /* Control access to all user coded atomics for 4-byte fixed data types */ +kmp_atomic_lock_t __kmp_atomic_lock_4r; /* Control access to all user coded atomics for kmp_real32 data type */ +kmp_atomic_lock_t __kmp_atomic_lock_8i; /* Control access to all user coded atomics for 8-byte fixed data types */ +kmp_atomic_lock_t __kmp_atomic_lock_8r; /* Control access to all user coded atomics for kmp_real64 data type */ +kmp_atomic_lock_t __kmp_atomic_lock_8c; /* Control access to all user coded atomics for complex byte data type */ +kmp_atomic_lock_t __kmp_atomic_lock_10r; /* Control access to all user coded atomics for long double data type */ +kmp_atomic_lock_t __kmp_atomic_lock_16r; /* Control access to all user coded atomics for _Quad data type */ +kmp_atomic_lock_t __kmp_atomic_lock_16c; /* Control access to all user coded atomics for double complex data type*/ +kmp_atomic_lock_t __kmp_atomic_lock_20c; /* Control access to all user coded atomics for long double complex type*/ +kmp_atomic_lock_t __kmp_atomic_lock_32c; /* Control access to all user coded atomics for _Quad complex data type */ + + +/* + 2007-03-02: + Without "volatile" specifier in OP_CMPXCHG and MIN_MAX_CMPXCHG we have a + bug on *_32 and *_32e. This is just a temporary workaround for the problem. + It seems the right solution is writing OP_CMPXCHG and MIN_MAX_CMPXCHG + routines in assembler language. +*/ +#define KMP_ATOMIC_VOLATILE volatile + +#if ( KMP_ARCH_X86 ) && KMP_HAVE_QUAD + + static inline void operator +=( Quad_a4_t & lhs, Quad_a4_t & rhs ) { lhs.q += rhs.q; }; + static inline void operator -=( Quad_a4_t & lhs, Quad_a4_t & rhs ) { lhs.q -= rhs.q; }; + static inline void operator *=( Quad_a4_t & lhs, Quad_a4_t & rhs ) { lhs.q *= rhs.q; }; + static inline void operator /=( Quad_a4_t & lhs, Quad_a4_t & rhs ) { lhs.q /= rhs.q; }; + static inline bool operator < ( Quad_a4_t & lhs, Quad_a4_t & rhs ) { return lhs.q < rhs.q; } + static inline bool operator > ( Quad_a4_t & lhs, Quad_a4_t & rhs ) { return lhs.q > rhs.q; } + + static inline void operator +=( Quad_a16_t & lhs, Quad_a16_t & rhs ) { lhs.q += rhs.q; }; + static inline void operator -=( Quad_a16_t & lhs, Quad_a16_t & rhs ) { lhs.q -= rhs.q; }; + static inline void operator *=( Quad_a16_t & lhs, Quad_a16_t & rhs ) { lhs.q *= rhs.q; }; + static inline void operator /=( Quad_a16_t & lhs, Quad_a16_t & rhs ) { lhs.q /= rhs.q; }; + static inline bool operator < ( Quad_a16_t & lhs, Quad_a16_t & rhs ) { return lhs.q < rhs.q; } + static inline bool operator > ( Quad_a16_t & lhs, Quad_a16_t & rhs ) { return lhs.q > rhs.q; } + + static inline void operator +=( kmp_cmplx128_a4_t & lhs, kmp_cmplx128_a4_t & rhs ) { lhs.q += rhs.q; }; + static inline void operator -=( kmp_cmplx128_a4_t & lhs, kmp_cmplx128_a4_t & rhs ) { lhs.q -= rhs.q; }; + static inline void operator *=( kmp_cmplx128_a4_t & lhs, kmp_cmplx128_a4_t & rhs ) { lhs.q *= rhs.q; }; + static inline void operator /=( kmp_cmplx128_a4_t & lhs, kmp_cmplx128_a4_t & rhs ) { lhs.q /= rhs.q; }; + + static inline void operator +=( kmp_cmplx128_a16_t & lhs, kmp_cmplx128_a16_t & rhs ) { lhs.q += rhs.q; }; + static inline void operator -=( kmp_cmplx128_a16_t & lhs, kmp_cmplx128_a16_t & rhs ) { lhs.q -= rhs.q; }; + static inline void operator *=( kmp_cmplx128_a16_t & lhs, kmp_cmplx128_a16_t & rhs ) { lhs.q *= rhs.q; }; + static inline void operator /=( kmp_cmplx128_a16_t & lhs, kmp_cmplx128_a16_t & rhs ) { lhs.q /= rhs.q; }; + +#endif + +/* ------------------------------------------------------------------------ */ +/* ATOMIC implementation routines */ +/* one routine for each operation and operand type */ +/* ------------------------------------------------------------------------ */ + +// All routines declarations looks like +// void __kmpc_atomic_RTYPE_OP( ident_t*, int, TYPE *lhs, TYPE rhs ); +// ------------------------------------------------------------------------ + +#define KMP_CHECK_GTID \ + if ( gtid == KMP_GTID_UNKNOWN ) { \ + gtid = __kmp_entry_gtid(); \ + } // check and get gtid when needed + +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +#define ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE, RET_TYPE) \ +RET_TYPE __kmpc_atomic_##TYPE_ID##_##OP_ID( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------ +// Lock variables used for critical sections for various size operands +#define ATOMIC_LOCK0 __kmp_atomic_lock // all types, for Gnu compat +#define ATOMIC_LOCK1i __kmp_atomic_lock_1i // char +#define ATOMIC_LOCK2i __kmp_atomic_lock_2i // short +#define ATOMIC_LOCK4i __kmp_atomic_lock_4i // long int +#define ATOMIC_LOCK4r __kmp_atomic_lock_4r // float +#define ATOMIC_LOCK8i __kmp_atomic_lock_8i // long long int +#define ATOMIC_LOCK8r __kmp_atomic_lock_8r // double +#define ATOMIC_LOCK8c __kmp_atomic_lock_8c // float complex +#define ATOMIC_LOCK10r __kmp_atomic_lock_10r // long double +#define ATOMIC_LOCK16r __kmp_atomic_lock_16r // _Quad +#define ATOMIC_LOCK16c __kmp_atomic_lock_16c // double complex +#define ATOMIC_LOCK20c __kmp_atomic_lock_20c // long double complex +#define ATOMIC_LOCK32c __kmp_atomic_lock_32c // _Quad complex + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + (*lhs) OP (rhs); \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); + +// ------------------------------------------------------------------------ +// For GNU compatibility, we may need to use a critical section, +// even though it is not required by the ISA. +// +// On IA-32 architecture, all atomic operations except for fixed 4 byte add, +// sub, and bitwise logical ops, and 1 & 2 byte logical ops use a common +// critical section. On Intel(R) 64, all atomic operations are done with fetch +// and add or compare and exchange. Therefore, the FLAG parameter to this +// macro is either KMP_ARCH_X86 or 0 (or 1, for Intel-specific extension which +// require a critical section, where we predict that they will be implemented +// in the Gnu codegen by calling GOMP_atomic_start() / GOMP_atomic_end()). +// +// When the OP_GOMP_CRITICAL macro is used in a *CRITICAL* macro construct, +// the FLAG parameter should always be 1. If we know that we will be using +// a critical section, then we want to make certain that we use the generic +// lock __kmp_atomic_lock to protect the atomic update, and not of of the +// locks that are specialized based upon the size or type of the data. +// +// If FLAG is 0, then we are relying on dead code elimination by the build +// compiler to get rid of the useless block of code, and save a needless +// branch at runtime. +// + +#ifdef KMP_GOMP_COMPAT +# define OP_GOMP_CRITICAL(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL( OP, 0 ); \ + return; \ + } +# else +# define OP_GOMP_CRITICAL(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +#if KMP_MIC +# define KMP_DO_PAUSE _mm_delay_32( 1 ) +#else +# define KMP_DO_PAUSE KMP_CPU_PAUSE() +#endif /* KMP_MIC */ + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +#define OP_CMPXCHG(TYPE,BITS,OP) \ + { \ + TYPE old_value, new_value; \ + old_value = *(TYPE volatile *)lhs; \ + new_value = old_value OP rhs; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_DO_PAUSE; \ + \ + old_value = *(TYPE volatile *)lhs; \ + new_value = old_value OP rhs; \ + } \ + } + +#if USE_CMPXCHG_FIX +// 2007-06-25: +// workaround for C78287 (complex(kind=4) data type) +// lin_32, lin_32e, win_32 and win_32e are affected (I verified the asm) +// Compiler ignores the volatile qualifier of the temp_val in the OP_CMPXCHG macro. +// This is a problem of the compiler. +// Related tracker is C76005, targeted to 11.0. +// I verified the asm of the workaround. +#define OP_CMPXCHG_WORKAROUND(TYPE,BITS,OP) \ + { \ + struct _sss { \ + TYPE cmp; \ + kmp_int##BITS *vvv; \ + }; \ + struct _sss old_value, new_value; \ + old_value.vvv = ( kmp_int##BITS * )&old_value.cmp; \ + new_value.vvv = ( kmp_int##BITS * )&new_value.cmp; \ + *old_value.vvv = * ( volatile kmp_int##BITS * ) lhs; \ + new_value.cmp = old_value.cmp OP rhs; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) old_value.vvv, \ + *VOLATILE_CAST(kmp_int##BITS *) new_value.vvv ) ) \ + { \ + KMP_DO_PAUSE; \ + \ + *old_value.vvv = * ( volatile kmp_int##BITS * ) lhs; \ + new_value.cmp = old_value.cmp OP rhs; \ + } \ + } +// end of the first part of the workaround for C78287 +#endif // USE_CMPXCHG_FIX + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +// ------------------------------------------------------------------------ +// X86 or X86_64: no alignment problems ==================================== +#define ATOMIC_FIXED_ADD(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + /* OP used as a sign for subtraction: (lhs-rhs) --> (lhs+-rhs) */ \ + KMP_TEST_THEN_ADD##BITS( lhs, OP rhs ); \ +} +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + OP_CMPXCHG(TYPE,BITS,OP) \ +} +#if USE_CMPXCHG_FIX +// ------------------------------------------------------------------------- +// workaround for C78287 (complex(kind=4) data type) +#define ATOMIC_CMPXCHG_WORKAROUND(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + OP_CMPXCHG_WORKAROUND(TYPE,BITS,OP) \ +} +// end of the second part of the workaround for C78287 +#endif + +#else +// ------------------------------------------------------------------------- +// Code for other architectures that don't handle unaligned accesses. +#define ATOMIC_FIXED_ADD(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + /* OP used as a sign for subtraction: (lhs-rhs) --> (lhs+-rhs) */ \ + KMP_TEST_THEN_ADD##BITS( lhs, OP rhs ); \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(OP##=,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(OP##=,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +#if USE_CMPXCHG_FIX +// ------------------------------------------------------------------------- +// workaround for C78287 (complex(kind=4) data type) +#define ATOMIC_CMPXCHG_WORKAROUND(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(OP##=,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +// end of the second part of the workaround for C78287 +#endif // USE_CMPXCHG_FIX +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +// Routines for ATOMIC 4-byte operands addition and subtraction +ATOMIC_FIXED_ADD( fixed4, add, kmp_int32, 32, +, 4i, 3, 0 ) // __kmpc_atomic_fixed4_add +ATOMIC_FIXED_ADD( fixed4, sub, kmp_int32, 32, -, 4i, 3, 0 ) // __kmpc_atomic_fixed4_sub + +ATOMIC_CMPXCHG( float4, add, kmp_real32, 32, +, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_add +ATOMIC_CMPXCHG( float4, sub, kmp_real32, 32, -, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub + +// Routines for ATOMIC 8-byte operands addition and subtraction +ATOMIC_FIXED_ADD( fixed8, add, kmp_int64, 64, +, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_add +ATOMIC_FIXED_ADD( fixed8, sub, kmp_int64, 64, -, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub + +ATOMIC_CMPXCHG( float8, add, kmp_real64, 64, +, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_add +ATOMIC_CMPXCHG( float8, sub, kmp_real64, 64, -, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub + +// ------------------------------------------------------------------------ +// Entries definition for integer operands +// TYPE_ID - operands type and size (fixed4, float4) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operand type +// BITS - size in bits, used to distinguish low level calls +// OP - operator (used in critical section) +// LCK_ID - lock identifier, used to possibly distinguish lock variable +// MASK - used for alignment check + +// TYPE_ID,OP_ID, TYPE, BITS,OP,LCK_ID,MASK,GOMP_FLAG +// ------------------------------------------------------------------------ +// Routines for ATOMIC integer operands, other operators +// ------------------------------------------------------------------------ +// TYPE_ID,OP_ID, TYPE, OP, LCK_ID, GOMP_FLAG +ATOMIC_CMPXCHG( fixed1, add, kmp_int8, 8, +, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_add +ATOMIC_CMPXCHG( fixed1, andb, kmp_int8, 8, &, 1i, 0, 0 ) // __kmpc_atomic_fixed1_andb +ATOMIC_CMPXCHG( fixed1, div, kmp_int8, 8, /, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div +ATOMIC_CMPXCHG( fixed1u, div, kmp_uint8, 8, /, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div +ATOMIC_CMPXCHG( fixed1, mul, kmp_int8, 8, *, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_mul +ATOMIC_CMPXCHG( fixed1, orb, kmp_int8, 8, |, 1i, 0, 0 ) // __kmpc_atomic_fixed1_orb +ATOMIC_CMPXCHG( fixed1, shl, kmp_int8, 8, <<, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shl +ATOMIC_CMPXCHG( fixed1, shr, kmp_int8, 8, >>, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shr +ATOMIC_CMPXCHG( fixed1u, shr, kmp_uint8, 8, >>, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_shr +ATOMIC_CMPXCHG( fixed1, sub, kmp_int8, 8, -, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub +ATOMIC_CMPXCHG( fixed1, xor, kmp_int8, 8, ^, 1i, 0, 0 ) // __kmpc_atomic_fixed1_xor +ATOMIC_CMPXCHG( fixed2, add, kmp_int16, 16, +, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_add +ATOMIC_CMPXCHG( fixed2, andb, kmp_int16, 16, &, 2i, 1, 0 ) // __kmpc_atomic_fixed2_andb +ATOMIC_CMPXCHG( fixed2, div, kmp_int16, 16, /, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div +ATOMIC_CMPXCHG( fixed2u, div, kmp_uint16, 16, /, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div +ATOMIC_CMPXCHG( fixed2, mul, kmp_int16, 16, *, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_mul +ATOMIC_CMPXCHG( fixed2, orb, kmp_int16, 16, |, 2i, 1, 0 ) // __kmpc_atomic_fixed2_orb +ATOMIC_CMPXCHG( fixed2, shl, kmp_int16, 16, <<, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shl +ATOMIC_CMPXCHG( fixed2, shr, kmp_int16, 16, >>, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shr +ATOMIC_CMPXCHG( fixed2u, shr, kmp_uint16, 16, >>, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_shr +ATOMIC_CMPXCHG( fixed2, sub, kmp_int16, 16, -, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub +ATOMIC_CMPXCHG( fixed2, xor, kmp_int16, 16, ^, 2i, 1, 0 ) // __kmpc_atomic_fixed2_xor +ATOMIC_CMPXCHG( fixed4, andb, kmp_int32, 32, &, 4i, 3, 0 ) // __kmpc_atomic_fixed4_andb +ATOMIC_CMPXCHG( fixed4, div, kmp_int32, 32, /, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_div +ATOMIC_CMPXCHG( fixed4u, div, kmp_uint32, 32, /, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_div +ATOMIC_CMPXCHG( fixed4, mul, kmp_int32, 32, *, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_mul +ATOMIC_CMPXCHG( fixed4, orb, kmp_int32, 32, |, 4i, 3, 0 ) // __kmpc_atomic_fixed4_orb +ATOMIC_CMPXCHG( fixed4, shl, kmp_int32, 32, <<, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shl +ATOMIC_CMPXCHG( fixed4, shr, kmp_int32, 32, >>, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shr +ATOMIC_CMPXCHG( fixed4u, shr, kmp_uint32, 32, >>, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_shr +ATOMIC_CMPXCHG( fixed4, xor, kmp_int32, 32, ^, 4i, 3, 0 ) // __kmpc_atomic_fixed4_xor +ATOMIC_CMPXCHG( fixed8, andb, kmp_int64, 64, &, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_andb +ATOMIC_CMPXCHG( fixed8, div, kmp_int64, 64, /, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div +ATOMIC_CMPXCHG( fixed8u, div, kmp_uint64, 64, /, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div +ATOMIC_CMPXCHG( fixed8, mul, kmp_int64, 64, *, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_mul +ATOMIC_CMPXCHG( fixed8, orb, kmp_int64, 64, |, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_orb +ATOMIC_CMPXCHG( fixed8, shl, kmp_int64, 64, <<, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shl +ATOMIC_CMPXCHG( fixed8, shr, kmp_int64, 64, >>, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shr +ATOMIC_CMPXCHG( fixed8u, shr, kmp_uint64, 64, >>, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_shr +ATOMIC_CMPXCHG( fixed8, xor, kmp_int64, 64, ^, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_xor +ATOMIC_CMPXCHG( float4, div, kmp_real32, 32, /, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div +ATOMIC_CMPXCHG( float4, mul, kmp_real32, 32, *, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_mul +ATOMIC_CMPXCHG( float8, div, kmp_real64, 64, /, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div +ATOMIC_CMPXCHG( float8, mul, kmp_real64, 64, *, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_mul +// TYPE_ID,OP_ID, TYPE, OP, LCK_ID, GOMP_FLAG + + +/* ------------------------------------------------------------------------ */ +/* Routines for C/C++ Reduction operators && and || */ +/* ------------------------------------------------------------------------ */ + +// ------------------------------------------------------------------------ +// Need separate macros for &&, || because there is no combined assignment +// TODO: eliminate ATOMIC_CRIT_{L,EQV} macros as not used +#define ATOMIC_CRIT_L(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL( = *lhs OP, GOMP_FLAG ) \ + OP_CRITICAL( = *lhs OP, LCK_ID ) \ +} + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +// ------------------------------------------------------------------------ +// X86 or X86_64: no alignment problems =================================== +#define ATOMIC_CMPX_L(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL( = *lhs OP, GOMP_FLAG ) \ + OP_CMPXCHG(TYPE,BITS,OP) \ +} + +#else +// ------------------------------------------------------------------------ +// Code for other architectures that don't handle unaligned accesses. +#define ATOMIC_CMPX_L(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(= *lhs OP,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(= *lhs OP,LCK_ID) /* unaligned - use critical */ \ + } \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +ATOMIC_CMPX_L( fixed1, andl, char, 8, &&, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_andl +ATOMIC_CMPX_L( fixed1, orl, char, 8, ||, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_orl +ATOMIC_CMPX_L( fixed2, andl, short, 16, &&, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_andl +ATOMIC_CMPX_L( fixed2, orl, short, 16, ||, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_orl +ATOMIC_CMPX_L( fixed4, andl, kmp_int32, 32, &&, 4i, 3, 0 ) // __kmpc_atomic_fixed4_andl +ATOMIC_CMPX_L( fixed4, orl, kmp_int32, 32, ||, 4i, 3, 0 ) // __kmpc_atomic_fixed4_orl +ATOMIC_CMPX_L( fixed8, andl, kmp_int64, 64, &&, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_andl +ATOMIC_CMPX_L( fixed8, orl, kmp_int64, 64, ||, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_orl + + +/* ------------------------------------------------------------------------- */ +/* Routines for Fortran operators that matched no one in C: */ +/* MAX, MIN, .EQV., .NEQV. */ +/* Operators .AND., .OR. are covered by __kmpc_atomic_*_{andl,orl} */ +/* Intrinsics IAND, IOR, IEOR are covered by __kmpc_atomic_*_{andb,orb,xor} */ +/* ------------------------------------------------------------------------- */ + +// ------------------------------------------------------------------------- +// MIN and MAX need separate macros +// OP - operator to check if we need any actions? +#define MIN_MAX_CRITSECT(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if ( *lhs OP rhs ) { /* still need actions? */ \ + *lhs = rhs; \ + } \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); + +// ------------------------------------------------------------------------- +#ifdef KMP_GOMP_COMPAT +#define GOMP_MIN_MAX_CRITSECT(OP,FLAG) \ + if (( FLAG ) && ( __kmp_atomic_mode == 2 )) { \ + KMP_CHECK_GTID; \ + MIN_MAX_CRITSECT( OP, 0 ); \ + return; \ + } +#else +#define GOMP_MIN_MAX_CRITSECT(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------- +#define MIN_MAX_CMPXCHG(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + while ( old_value OP rhs && /* still need actions? */ \ + ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &rhs ) ) \ + { \ + KMP_CPU_PAUSE(); \ + temp_val = *lhs; \ + old_value = temp_val; \ + } \ + } + +// ------------------------------------------------------------------------- +// 1-byte, 2-byte operands - use critical section +#define MIN_MAX_CRITICAL(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + if ( *lhs OP rhs ) { /* need actions? */ \ + GOMP_MIN_MAX_CRITSECT(OP,GOMP_FLAG) \ + MIN_MAX_CRITSECT(OP,LCK_ID) \ + } \ +} + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +// ------------------------------------------------------------------------- +// X86 or X86_64: no alignment problems ==================================== +#define MIN_MAX_COMPXCHG(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + if ( *lhs OP rhs ) { \ + GOMP_MIN_MAX_CRITSECT(OP,GOMP_FLAG) \ + MIN_MAX_CMPXCHG(TYPE,BITS,OP) \ + } \ +} + +#else +// ------------------------------------------------------------------------- +// Code for other architectures that don't handle unaligned accesses. +#define MIN_MAX_COMPXCHG(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + if ( *lhs OP rhs ) { \ + GOMP_MIN_MAX_CRITSECT(OP,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + MIN_MAX_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + MIN_MAX_CRITSECT(OP,LCK_ID) /* unaligned address */ \ + } \ + } \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +MIN_MAX_COMPXCHG( fixed1, max, char, 8, <, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_max +MIN_MAX_COMPXCHG( fixed1, min, char, 8, >, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_min +MIN_MAX_COMPXCHG( fixed2, max, short, 16, <, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_max +MIN_MAX_COMPXCHG( fixed2, min, short, 16, >, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_min +MIN_MAX_COMPXCHG( fixed4, max, kmp_int32, 32, <, 4i, 3, 0 ) // __kmpc_atomic_fixed4_max +MIN_MAX_COMPXCHG( fixed4, min, kmp_int32, 32, >, 4i, 3, 0 ) // __kmpc_atomic_fixed4_min +MIN_MAX_COMPXCHG( fixed8, max, kmp_int64, 64, <, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_max +MIN_MAX_COMPXCHG( fixed8, min, kmp_int64, 64, >, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_min +MIN_MAX_COMPXCHG( float4, max, kmp_real32, 32, <, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_max +MIN_MAX_COMPXCHG( float4, min, kmp_real32, 32, >, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_min +MIN_MAX_COMPXCHG( float8, max, kmp_real64, 64, <, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_max +MIN_MAX_COMPXCHG( float8, min, kmp_real64, 64, >, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_min +#if KMP_HAVE_QUAD +MIN_MAX_CRITICAL( float16, max, QUAD_LEGACY, <, 16r, 1 ) // __kmpc_atomic_float16_max +MIN_MAX_CRITICAL( float16, min, QUAD_LEGACY, >, 16r, 1 ) // __kmpc_atomic_float16_min +#if ( KMP_ARCH_X86 ) + MIN_MAX_CRITICAL( float16, max_a16, Quad_a16_t, <, 16r, 1 ) // __kmpc_atomic_float16_max_a16 + MIN_MAX_CRITICAL( float16, min_a16, Quad_a16_t, >, 16r, 1 ) // __kmpc_atomic_float16_min_a16 +#endif +#endif +// ------------------------------------------------------------------------ +// Need separate macros for .EQV. because of the need of complement (~) +// OP ignored for critical sections, ^=~ used instead +#define ATOMIC_CRIT_EQV(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(^=~,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL(^=~,LCK_ID) /* send assignment and complement */ \ +} + +// ------------------------------------------------------------------------ +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 +// ------------------------------------------------------------------------ +// X86 or X86_64: no alignment problems =================================== +#define ATOMIC_CMPX_EQV(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(^=~,GOMP_FLAG) /* send assignment */ \ + OP_CMPXCHG(TYPE,BITS,OP) \ +} +// ------------------------------------------------------------------------ +#else +// ------------------------------------------------------------------------ +// Code for other architectures that don't handle unaligned accesses. +#define ATOMIC_CMPX_EQV(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(^=~,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(^=~,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +ATOMIC_CMPXCHG( fixed1, neqv, kmp_int8, 8, ^, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_neqv +ATOMIC_CMPXCHG( fixed2, neqv, kmp_int16, 16, ^, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_neqv +ATOMIC_CMPXCHG( fixed4, neqv, kmp_int32, 32, ^, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_neqv +ATOMIC_CMPXCHG( fixed8, neqv, kmp_int64, 64, ^, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_neqv +ATOMIC_CMPX_EQV( fixed1, eqv, kmp_int8, 8, ^~, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_eqv +ATOMIC_CMPX_EQV( fixed2, eqv, kmp_int16, 16, ^~, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_eqv +ATOMIC_CMPX_EQV( fixed4, eqv, kmp_int32, 32, ^~, 4i, 3, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_eqv +ATOMIC_CMPX_EQV( fixed8, eqv, kmp_int64, 64, ^~, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_eqv + + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL(OP##=,LCK_ID) /* send assignment */ \ +} + +/* ------------------------------------------------------------------------- */ +// routines for long double type +ATOMIC_CRITICAL( float10, add, long double, +, 10r, 1 ) // __kmpc_atomic_float10_add +ATOMIC_CRITICAL( float10, sub, long double, -, 10r, 1 ) // __kmpc_atomic_float10_sub +ATOMIC_CRITICAL( float10, mul, long double, *, 10r, 1 ) // __kmpc_atomic_float10_mul +ATOMIC_CRITICAL( float10, div, long double, /, 10r, 1 ) // __kmpc_atomic_float10_div +#if KMP_HAVE_QUAD +// routines for _Quad type +ATOMIC_CRITICAL( float16, add, QUAD_LEGACY, +, 16r, 1 ) // __kmpc_atomic_float16_add +ATOMIC_CRITICAL( float16, sub, QUAD_LEGACY, -, 16r, 1 ) // __kmpc_atomic_float16_sub +ATOMIC_CRITICAL( float16, mul, QUAD_LEGACY, *, 16r, 1 ) // __kmpc_atomic_float16_mul +ATOMIC_CRITICAL( float16, div, QUAD_LEGACY, /, 16r, 1 ) // __kmpc_atomic_float16_div +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL( float16, add_a16, Quad_a16_t, +, 16r, 1 ) // __kmpc_atomic_float16_add_a16 + ATOMIC_CRITICAL( float16, sub_a16, Quad_a16_t, -, 16r, 1 ) // __kmpc_atomic_float16_sub_a16 + ATOMIC_CRITICAL( float16, mul_a16, Quad_a16_t, *, 16r, 1 ) // __kmpc_atomic_float16_mul_a16 + ATOMIC_CRITICAL( float16, div_a16, Quad_a16_t, /, 16r, 1 ) // __kmpc_atomic_float16_div_a16 +#endif +#endif +// routines for complex types + +#if USE_CMPXCHG_FIX +// workaround for C78287 (complex(kind=4) data type) +ATOMIC_CMPXCHG_WORKAROUND( cmplx4, add, kmp_cmplx32, 64, +, 8c, 7, 1 ) // __kmpc_atomic_cmplx4_add +ATOMIC_CMPXCHG_WORKAROUND( cmplx4, sub, kmp_cmplx32, 64, -, 8c, 7, 1 ) // __kmpc_atomic_cmplx4_sub +ATOMIC_CMPXCHG_WORKAROUND( cmplx4, mul, kmp_cmplx32, 64, *, 8c, 7, 1 ) // __kmpc_atomic_cmplx4_mul +ATOMIC_CMPXCHG_WORKAROUND( cmplx4, div, kmp_cmplx32, 64, /, 8c, 7, 1 ) // __kmpc_atomic_cmplx4_div +// end of the workaround for C78287 +#else +ATOMIC_CRITICAL( cmplx4, add, kmp_cmplx32, +, 8c, 1 ) // __kmpc_atomic_cmplx4_add +ATOMIC_CRITICAL( cmplx4, sub, kmp_cmplx32, -, 8c, 1 ) // __kmpc_atomic_cmplx4_sub +ATOMIC_CRITICAL( cmplx4, mul, kmp_cmplx32, *, 8c, 1 ) // __kmpc_atomic_cmplx4_mul +ATOMIC_CRITICAL( cmplx4, div, kmp_cmplx32, /, 8c, 1 ) // __kmpc_atomic_cmplx4_div +#endif // USE_CMPXCHG_FIX + +ATOMIC_CRITICAL( cmplx8, add, kmp_cmplx64, +, 16c, 1 ) // __kmpc_atomic_cmplx8_add +ATOMIC_CRITICAL( cmplx8, sub, kmp_cmplx64, -, 16c, 1 ) // __kmpc_atomic_cmplx8_sub +ATOMIC_CRITICAL( cmplx8, mul, kmp_cmplx64, *, 16c, 1 ) // __kmpc_atomic_cmplx8_mul +ATOMIC_CRITICAL( cmplx8, div, kmp_cmplx64, /, 16c, 1 ) // __kmpc_atomic_cmplx8_div +ATOMIC_CRITICAL( cmplx10, add, kmp_cmplx80, +, 20c, 1 ) // __kmpc_atomic_cmplx10_add +ATOMIC_CRITICAL( cmplx10, sub, kmp_cmplx80, -, 20c, 1 ) // __kmpc_atomic_cmplx10_sub +ATOMIC_CRITICAL( cmplx10, mul, kmp_cmplx80, *, 20c, 1 ) // __kmpc_atomic_cmplx10_mul +ATOMIC_CRITICAL( cmplx10, div, kmp_cmplx80, /, 20c, 1 ) // __kmpc_atomic_cmplx10_div +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL( cmplx16, add, CPLX128_LEG, +, 32c, 1 ) // __kmpc_atomic_cmplx16_add +ATOMIC_CRITICAL( cmplx16, sub, CPLX128_LEG, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub +ATOMIC_CRITICAL( cmplx16, mul, CPLX128_LEG, *, 32c, 1 ) // __kmpc_atomic_cmplx16_mul +ATOMIC_CRITICAL( cmplx16, div, CPLX128_LEG, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL( cmplx16, add_a16, kmp_cmplx128_a16_t, +, 32c, 1 ) // __kmpc_atomic_cmplx16_add_a16 + ATOMIC_CRITICAL( cmplx16, sub_a16, kmp_cmplx128_a16_t, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_a16 + ATOMIC_CRITICAL( cmplx16, mul_a16, kmp_cmplx128_a16_t, *, 32c, 1 ) // __kmpc_atomic_cmplx16_mul_a16 + ATOMIC_CRITICAL( cmplx16, div_a16, kmp_cmplx128_a16_t, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_a16 +#endif +#endif + +#if OMP_40_ENABLED + +// OpenMP 4.0: x = expr binop x for non-commutative operations. +// Supported only on IA-32 architecture and Intel(R) 64 +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL_REV(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + (*lhs) = (rhs) OP (*lhs); \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); + +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_REV(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_REV( OP, 0 ); \ + return; \ + } +#else +#define OP_GOMP_CRITICAL_REV(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + + +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +#define ATOMIC_BEGIN_REV(TYPE_ID,OP_ID,TYPE, RET_TYPE) \ +RET_TYPE __kmpc_atomic_##TYPE_ID##_##OP_ID##_rev( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID "_rev: T#%d\n", gtid )); + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +// Note: temp_val introduced in order to force the compiler to read +// *lhs only once (w/o it the compiler reads *lhs twice) +#define OP_CMPXCHG_REV(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value, new_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs OP old_value; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_DO_PAUSE; \ + \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs OP old_value; \ + } \ + } + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_REV(TYPE_ID,OP_ID,TYPE,BITS,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_REV(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL_REV(OP,GOMP_FLAG) \ + OP_CMPXCHG_REV(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------ +// Entries definition for integer operands +// TYPE_ID - operands type and size (fixed4, float4) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operand type +// BITS - size in bits, used to distinguish low level calls +// OP - operator (used in critical section) +// LCK_ID - lock identifier, used to possibly distinguish lock variable + +// TYPE_ID,OP_ID, TYPE, BITS,OP,LCK_ID,GOMP_FLAG +// ------------------------------------------------------------------------ +// Routines for ATOMIC integer operands, other operators +// ------------------------------------------------------------------------ +// TYPE_ID,OP_ID, TYPE, BITS, OP, LCK_ID, GOMP_FLAG +ATOMIC_CMPXCHG_REV( fixed1, div, kmp_int8, 8, /, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_rev +ATOMIC_CMPXCHG_REV( fixed1u, div, kmp_uint8, 8, /, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_rev +ATOMIC_CMPXCHG_REV( fixed1, shl, kmp_int8, 8, <<, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shl_rev +ATOMIC_CMPXCHG_REV( fixed1, shr, kmp_int8, 8, >>, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shr_rev +ATOMIC_CMPXCHG_REV( fixed1u, shr, kmp_uint8, 8, >>, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_shr_rev +ATOMIC_CMPXCHG_REV( fixed1, sub, kmp_int8, 8, -, 1i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_rev + +ATOMIC_CMPXCHG_REV( fixed2, div, kmp_int16, 16, /, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_rev +ATOMIC_CMPXCHG_REV( fixed2u, div, kmp_uint16, 16, /, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_rev +ATOMIC_CMPXCHG_REV( fixed2, shl, kmp_int16, 16, <<, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shl_rev +ATOMIC_CMPXCHG_REV( fixed2, shr, kmp_int16, 16, >>, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shr_rev +ATOMIC_CMPXCHG_REV( fixed2u, shr, kmp_uint16, 16, >>, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_shr_rev +ATOMIC_CMPXCHG_REV( fixed2, sub, kmp_int16, 16, -, 2i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_rev + +ATOMIC_CMPXCHG_REV( fixed4, div, kmp_int32, 32, /, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_div_rev +ATOMIC_CMPXCHG_REV( fixed4u, div, kmp_uint32, 32, /, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_div_rev +ATOMIC_CMPXCHG_REV( fixed4, shl, kmp_int32, 32, <<, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shl_rev +ATOMIC_CMPXCHG_REV( fixed4, shr, kmp_int32, 32, >>, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shr_rev +ATOMIC_CMPXCHG_REV( fixed4u, shr, kmp_uint32, 32, >>, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_shr_rev +ATOMIC_CMPXCHG_REV( fixed4, sub, kmp_int32, 32, -, 4i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_sub_rev + +ATOMIC_CMPXCHG_REV( fixed8, div, kmp_int64, 64, /, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_rev +ATOMIC_CMPXCHG_REV( fixed8u, div, kmp_uint64, 64, /, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_rev +ATOMIC_CMPXCHG_REV( fixed8, shl, kmp_int64, 64, <<, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shl_rev +ATOMIC_CMPXCHG_REV( fixed8, shr, kmp_int64, 64, >>, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shr_rev +ATOMIC_CMPXCHG_REV( fixed8u, shr, kmp_uint64, 64, >>, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_shr_rev +ATOMIC_CMPXCHG_REV( fixed8, sub, kmp_int64, 64, -, 8i, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_rev + +ATOMIC_CMPXCHG_REV( float4, div, kmp_real32, 32, /, 4r, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_rev +ATOMIC_CMPXCHG_REV( float4, sub, kmp_real32, 32, -, 4r, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_rev + +ATOMIC_CMPXCHG_REV( float8, div, kmp_real64, 64, /, 8r, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_rev +ATOMIC_CMPXCHG_REV( float8, sub, kmp_real64, 64, -, 8r, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_rev +// TYPE_ID,OP_ID, TYPE, BITS,OP,LCK_ID, GOMP_FLAG + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL_REV(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_REV(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL_REV(OP,GOMP_FLAG) \ + OP_CRITICAL_REV(OP,LCK_ID) \ +} + +/* ------------------------------------------------------------------------- */ +// routines for long double type +ATOMIC_CRITICAL_REV( float10, sub, long double, -, 10r, 1 ) // __kmpc_atomic_float10_sub_rev +ATOMIC_CRITICAL_REV( float10, div, long double, /, 10r, 1 ) // __kmpc_atomic_float10_div_rev +#if KMP_HAVE_QUAD +// routines for _Quad type +ATOMIC_CRITICAL_REV( float16, sub, QUAD_LEGACY, -, 16r, 1 ) // __kmpc_atomic_float16_sub_rev +ATOMIC_CRITICAL_REV( float16, div, QUAD_LEGACY, /, 16r, 1 ) // __kmpc_atomic_float16_div_rev +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_REV( float16, sub_a16, Quad_a16_t, -, 16r, 1 ) // __kmpc_atomic_float16_sub_a16_rev + ATOMIC_CRITICAL_REV( float16, div_a16, Quad_a16_t, /, 16r, 1 ) // __kmpc_atomic_float16_div_a16_rev +#endif +#endif + +// routines for complex types +ATOMIC_CRITICAL_REV( cmplx4, sub, kmp_cmplx32, -, 8c, 1 ) // __kmpc_atomic_cmplx4_sub_rev +ATOMIC_CRITICAL_REV( cmplx4, div, kmp_cmplx32, /, 8c, 1 ) // __kmpc_atomic_cmplx4_div_rev +ATOMIC_CRITICAL_REV( cmplx8, sub, kmp_cmplx64, -, 16c, 1 ) // __kmpc_atomic_cmplx8_sub_rev +ATOMIC_CRITICAL_REV( cmplx8, div, kmp_cmplx64, /, 16c, 1 ) // __kmpc_atomic_cmplx8_div_rev +ATOMIC_CRITICAL_REV( cmplx10, sub, kmp_cmplx80, -, 20c, 1 ) // __kmpc_atomic_cmplx10_sub_rev +ATOMIC_CRITICAL_REV( cmplx10, div, kmp_cmplx80, /, 20c, 1 ) // __kmpc_atomic_cmplx10_div_rev +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_REV( cmplx16, sub, CPLX128_LEG, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_rev +ATOMIC_CRITICAL_REV( cmplx16, div, CPLX128_LEG, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_rev +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_REV( cmplx16, sub_a16, kmp_cmplx128_a16_t, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_a16_rev + ATOMIC_CRITICAL_REV( cmplx16, div_a16, kmp_cmplx128_a16_t, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_a16_rev +#endif +#endif + + +#endif //KMP_ARCH_X86 || KMP_ARCH_X86_64 +// End of OpenMP 4.0: x = expr binop x for non-commutative operations. + +#endif //OMP_40_ENABLED + + +/* ------------------------------------------------------------------------ */ +/* Routines for mixed types of LHS and RHS, when RHS is "larger" */ +/* Note: in order to reduce the total number of types combinations */ +/* it is supposed that compiler converts RHS to longest floating type,*/ +/* that is _Quad, before call to any of these routines */ +/* Conversion to _Quad will be done by the compiler during calculation, */ +/* conversion back to TYPE - before the assignment, like: */ +/* *lhs = (TYPE)( (_Quad)(*lhs) OP rhs ) */ +/* Performance penalty expected because of SW emulation use */ +/* ------------------------------------------------------------------------ */ + +#define ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ +void __kmpc_atomic_##TYPE_ID##_##OP_ID##_##RTYPE_ID( ident_t *id_ref, int gtid, TYPE * lhs, RTYPE rhs ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID "_" #RTYPE_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------- +#define ATOMIC_CRITICAL_FP(TYPE_ID,TYPE,OP_ID,OP,RTYPE_ID,RTYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL(OP##=,LCK_ID) /* send assignment */ \ +} + +// ------------------------------------------------------------------------- +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 +// ------------------------------------------------------------------------- +// X86 or X86_64: no alignment problems ==================================== +#define ATOMIC_CMPXCHG_MIX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + OP_CMPXCHG(TYPE,BITS,OP) \ +} +// ------------------------------------------------------------------------- +#else +// ------------------------------------------------------------------------ +// Code for other architectures that don't handle unaligned accesses. +#define ATOMIC_CMPXCHG_MIX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(OP##=,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +// ------------------------------------------------------------------------- +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_REV_MIX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL_REV(OP,GOMP_FLAG) \ + OP_CMPXCHG_REV(TYPE,BITS,OP) \ +} +#define ATOMIC_CRITICAL_REV_FP(TYPE_ID,TYPE,OP_ID,OP,RTYPE_ID,RTYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL_REV(OP,GOMP_FLAG) \ + OP_CRITICAL_REV(OP,LCK_ID) \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +// RHS=float8 +ATOMIC_CMPXCHG_MIX( fixed1, char, mul, 8, *, float8, kmp_real64, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_mul_float8 +ATOMIC_CMPXCHG_MIX( fixed1, char, div, 8, /, float8, kmp_real64, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_float8 +ATOMIC_CMPXCHG_MIX( fixed2, short, mul, 16, *, float8, kmp_real64, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_mul_float8 +ATOMIC_CMPXCHG_MIX( fixed2, short, div, 16, /, float8, kmp_real64, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_float8 +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, mul, 32, *, float8, kmp_real64, 4i, 3, 0 ) // __kmpc_atomic_fixed4_mul_float8 +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, div, 32, /, float8, kmp_real64, 4i, 3, 0 ) // __kmpc_atomic_fixed4_div_float8 +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, mul, 64, *, float8, kmp_real64, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_mul_float8 +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, div, 64, /, float8, kmp_real64, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_float8 +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, add, 32, +, float8, kmp_real64, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_add_float8 +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, sub, 32, -, float8, kmp_real64, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_float8 +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, mul, 32, *, float8, kmp_real64, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_mul_float8 +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, div, 32, /, float8, kmp_real64, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_float8 + +// RHS=float16 (deprecated, to be removed when we are sure the compiler does not use them) +#if KMP_HAVE_QUAD +ATOMIC_CMPXCHG_MIX( fixed1, char, add, 8, +, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_add_fp +ATOMIC_CMPXCHG_MIX( fixed1u, uchar, add, 8, +, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_add_fp +ATOMIC_CMPXCHG_MIX( fixed1, char, sub, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_fp +ATOMIC_CMPXCHG_MIX( fixed1u, uchar, sub, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_sub_fp +ATOMIC_CMPXCHG_MIX( fixed1, char, mul, 8, *, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_mul_fp +ATOMIC_CMPXCHG_MIX( fixed1u, uchar, mul, 8, *, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_mul_fp +ATOMIC_CMPXCHG_MIX( fixed1, char, div, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_fp +ATOMIC_CMPXCHG_MIX( fixed1u, uchar, div, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_fp + +ATOMIC_CMPXCHG_MIX( fixed2, short, add, 16, +, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_add_fp +ATOMIC_CMPXCHG_MIX( fixed2u, ushort, add, 16, +, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_add_fp +ATOMIC_CMPXCHG_MIX( fixed2, short, sub, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_fp +ATOMIC_CMPXCHG_MIX( fixed2u, ushort, sub, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_sub_fp +ATOMIC_CMPXCHG_MIX( fixed2, short, mul, 16, *, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_mul_fp +ATOMIC_CMPXCHG_MIX( fixed2u, ushort, mul, 16, *, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_mul_fp +ATOMIC_CMPXCHG_MIX( fixed2, short, div, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_fp +ATOMIC_CMPXCHG_MIX( fixed2u, ushort, div, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_fp + +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, add, 32, +, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_add_fp +ATOMIC_CMPXCHG_MIX( fixed4u, kmp_uint32, add, 32, +, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_add_fp +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, sub, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_sub_fp +ATOMIC_CMPXCHG_MIX( fixed4u, kmp_uint32, sub, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_sub_fp +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, mul, 32, *, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_mul_fp +ATOMIC_CMPXCHG_MIX( fixed4u, kmp_uint32, mul, 32, *, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_mul_fp +ATOMIC_CMPXCHG_MIX( fixed4, kmp_int32, div, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_div_fp +ATOMIC_CMPXCHG_MIX( fixed4u, kmp_uint32, div, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_div_fp + +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, add, 64, +, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_add_fp +ATOMIC_CMPXCHG_MIX( fixed8u, kmp_uint64, add, 64, +, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_add_fp +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, sub, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_fp +ATOMIC_CMPXCHG_MIX( fixed8u, kmp_uint64, sub, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_sub_fp +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, mul, 64, *, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_mul_fp +ATOMIC_CMPXCHG_MIX( fixed8u, kmp_uint64, mul, 64, *, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_mul_fp +ATOMIC_CMPXCHG_MIX( fixed8, kmp_int64, div, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_fp +ATOMIC_CMPXCHG_MIX( fixed8u, kmp_uint64, div, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_fp + +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, add, 32, +, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_add_fp +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, sub, 32, -, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_fp +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, mul, 32, *, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_mul_fp +ATOMIC_CMPXCHG_MIX( float4, kmp_real32, div, 32, /, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_fp + +ATOMIC_CMPXCHG_MIX( float8, kmp_real64, add, 64, +, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_add_fp +ATOMIC_CMPXCHG_MIX( float8, kmp_real64, sub, 64, -, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_fp +ATOMIC_CMPXCHG_MIX( float8, kmp_real64, mul, 64, *, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_mul_fp +ATOMIC_CMPXCHG_MIX( float8, kmp_real64, div, 64, /, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_fp + +ATOMIC_CRITICAL_FP( float10, long double, add, +, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_add_fp +ATOMIC_CRITICAL_FP( float10, long double, sub, -, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_sub_fp +ATOMIC_CRITICAL_FP( float10, long double, mul, *, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_mul_fp +ATOMIC_CRITICAL_FP( float10, long double, div, /, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_div_fp + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 +// Reverse operations +ATOMIC_CMPXCHG_REV_MIX( fixed1, char, sub_rev, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed1u, uchar, sub_rev, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed1, char, div_rev, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed1u, uchar, div_rev, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_rev_fp + +ATOMIC_CMPXCHG_REV_MIX( fixed2, short, sub_rev, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed2u, ushort, sub_rev, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed2, short, div_rev, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed2u, ushort, div_rev, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_rev_fp + +ATOMIC_CMPXCHG_REV_MIX( fixed4, kmp_int32, sub_rev, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed4u, kmp_uint32, sub_rev, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed4, kmp_int32, div_rev, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_div_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed4u, kmp_uint32, div_rev, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_div_rev_fp + +ATOMIC_CMPXCHG_REV_MIX( fixed8, kmp_int64, sub_rev, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed8u, kmp_uint64, sub_rev, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed8, kmp_int64, div_rev, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_rev_fp +ATOMIC_CMPXCHG_REV_MIX( fixed8u, kmp_uint64, div_rev, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_rev_fp + +ATOMIC_CMPXCHG_REV_MIX( float4, kmp_real32, sub_rev, 32, -, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( float4, kmp_real32, div_rev, 32, /, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_rev_fp + +ATOMIC_CMPXCHG_REV_MIX( float8, kmp_real64, sub_rev, 64, -, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_rev_fp +ATOMIC_CMPXCHG_REV_MIX( float8, kmp_real64, div_rev, 64, /, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_rev_fp + +ATOMIC_CRITICAL_REV_FP( float10, long double, sub_rev, -, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_sub_rev_fp +ATOMIC_CRITICAL_REV_FP( float10, long double, div_rev, /, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_div_rev_fp +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +#endif + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 +// ------------------------------------------------------------------------ +// X86 or X86_64: no alignment problems ==================================== +#if USE_CMPXCHG_FIX +// workaround for C78287 (complex(kind=4) data type) +#define ATOMIC_CMPXCHG_CMPLX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + OP_CMPXCHG_WORKAROUND(TYPE,BITS,OP) \ +} +// end of the second part of the workaround for C78287 +#else +#define ATOMIC_CMPXCHG_CMPLX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + OP_CMPXCHG(TYPE,BITS,OP) \ +} +#endif // USE_CMPXCHG_FIX +#else +// ------------------------------------------------------------------------ +// Code for other architectures that don't handle unaligned accesses. +#define ATOMIC_CMPXCHG_CMPLX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_MIX(TYPE_ID,TYPE,OP_ID,RTYPE_ID,RTYPE) \ + OP_GOMP_CRITICAL(OP##=,GOMP_FLAG) \ + if ( ! ( (kmp_uintptr_t) lhs & 0x##MASK) ) { \ + OP_CMPXCHG(TYPE,BITS,OP) /* aligned address */ \ + } else { \ + KMP_CHECK_GTID; \ + OP_CRITICAL(OP##=,LCK_ID) /* unaligned address - use critical */ \ + } \ +} +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +ATOMIC_CMPXCHG_CMPLX( cmplx4, kmp_cmplx32, add, 64, +, cmplx8, kmp_cmplx64, 8c, 7, KMP_ARCH_X86 ) // __kmpc_atomic_cmplx4_add_cmplx8 +ATOMIC_CMPXCHG_CMPLX( cmplx4, kmp_cmplx32, sub, 64, -, cmplx8, kmp_cmplx64, 8c, 7, KMP_ARCH_X86 ) // __kmpc_atomic_cmplx4_sub_cmplx8 +ATOMIC_CMPXCHG_CMPLX( cmplx4, kmp_cmplx32, mul, 64, *, cmplx8, kmp_cmplx64, 8c, 7, KMP_ARCH_X86 ) // __kmpc_atomic_cmplx4_mul_cmplx8 +ATOMIC_CMPXCHG_CMPLX( cmplx4, kmp_cmplx32, div, 64, /, cmplx8, kmp_cmplx64, 8c, 7, KMP_ARCH_X86 ) // __kmpc_atomic_cmplx4_div_cmplx8 + +// READ, WRITE, CAPTURE are supported only on IA-32 architecture and Intel(R) 64 +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +////////////////////////////////////////////////////////////////////////////////////////////////////// +// ------------------------------------------------------------------------ +// Atomic READ routines +// ------------------------------------------------------------------------ + +// ------------------------------------------------------------------------ +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +#define ATOMIC_BEGIN_READ(TYPE_ID,OP_ID,TYPE, RET_TYPE) \ +RET_TYPE __kmpc_atomic_##TYPE_ID##_##OP_ID( ident_t *id_ref, int gtid, TYPE * loc ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store_ret" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +// Note: temp_val introduced in order to force the compiler to read +// *lhs only once (w/o it the compiler reads *lhs twice) +// TODO: check if it is still necessary +// Return old value regardless of the result of "compare & swap# operation + +#define OP_CMPXCHG_READ(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + union f_i_union { \ + TYPE f_val; \ + kmp_int##BITS i_val; \ + }; \ + union f_i_union old_value; \ + temp_val = *loc; \ + old_value.f_val = temp_val; \ + old_value.i_val = KMP_COMPARE_AND_STORE_RET##BITS( (kmp_int##BITS *) loc, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value.i_val, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value.i_val ); \ + new_value = old_value.f_val; \ + return new_value; \ + } + +// ------------------------------------------------------------------------- +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL_READ(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + new_value = (*loc); \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); + +// ------------------------------------------------------------------------- +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_READ(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_READ( OP, 0 ); \ + return new_value; \ + } +#else +#define OP_GOMP_CRITICAL_READ(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------- +#define ATOMIC_FIXED_READ(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_READ(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_READ(OP##=,GOMP_FLAG) \ + new_value = KMP_TEST_THEN_ADD##BITS( loc, OP 0 ); \ + return new_value; \ +} +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_READ(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_READ(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_READ(OP##=,GOMP_FLAG) \ + OP_CMPXCHG_READ(TYPE,BITS,OP) \ +} +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL_READ(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_READ(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_READ(OP##=,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL_READ(OP,LCK_ID) /* send assignment */ \ + return new_value; \ +} + +// ------------------------------------------------------------------------ +// Fix for cmplx4 read (CQ220361) on Windows* OS. Regular routine with return value doesn't work. +// Let's return the read value through the additional parameter. + +#if ( KMP_OS_WINDOWS ) + +#define OP_CRITICAL_READ_WRK(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + (*out) = (*loc); \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_READ_WRK(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_READ_WRK( OP, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_READ_WRK(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ +// ------------------------------------------------------------------------ +#define ATOMIC_BEGIN_READ_WRK(TYPE_ID,OP_ID,TYPE) \ +void __kmpc_atomic_##TYPE_ID##_##OP_ID( TYPE * out, ident_t *id_ref, int gtid, TYPE * loc ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------ +#define ATOMIC_CRITICAL_READ_WRK(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_READ_WRK(TYPE_ID,OP_ID,TYPE) \ + OP_GOMP_CRITICAL_READ_WRK(OP##=,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL_READ_WRK(OP,LCK_ID) /* send assignment */ \ +} + +#endif // KMP_OS_WINDOWS + +// ------------------------------------------------------------------------ +// TYPE_ID,OP_ID, TYPE, OP, GOMP_FLAG +ATOMIC_FIXED_READ( fixed4, rd, kmp_int32, 32, +, 0 ) // __kmpc_atomic_fixed4_rd +ATOMIC_FIXED_READ( fixed8, rd, kmp_int64, 64, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_rd +ATOMIC_CMPXCHG_READ( float4, rd, kmp_real32, 32, +, KMP_ARCH_X86 ) // __kmpc_atomic_float4_rd +ATOMIC_CMPXCHG_READ( float8, rd, kmp_real64, 64, +, KMP_ARCH_X86 ) // __kmpc_atomic_float8_rd + +// !!! TODO: Remove lock operations for "char" since it can't be non-atomic +ATOMIC_CMPXCHG_READ( fixed1, rd, kmp_int8, 8, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_rd +ATOMIC_CMPXCHG_READ( fixed2, rd, kmp_int16, 16, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_rd + +ATOMIC_CRITICAL_READ( float10, rd, long double, +, 10r, 1 ) // __kmpc_atomic_float10_rd +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_READ( float16, rd, QUAD_LEGACY, +, 16r, 1 ) // __kmpc_atomic_float16_rd +#endif // KMP_HAVE_QUAD + +// Fix for CQ220361 on Windows* OS +#if ( KMP_OS_WINDOWS ) + ATOMIC_CRITICAL_READ_WRK( cmplx4, rd, kmp_cmplx32, +, 8c, 1 ) // __kmpc_atomic_cmplx4_rd +#else + ATOMIC_CRITICAL_READ( cmplx4, rd, kmp_cmplx32, +, 8c, 1 ) // __kmpc_atomic_cmplx4_rd +#endif +ATOMIC_CRITICAL_READ( cmplx8, rd, kmp_cmplx64, +, 16c, 1 ) // __kmpc_atomic_cmplx8_rd +ATOMIC_CRITICAL_READ( cmplx10, rd, kmp_cmplx80, +, 20c, 1 ) // __kmpc_atomic_cmplx10_rd +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_READ( cmplx16, rd, CPLX128_LEG, +, 32c, 1 ) // __kmpc_atomic_cmplx16_rd +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_READ( float16, a16_rd, Quad_a16_t, +, 16r, 1 ) // __kmpc_atomic_float16_a16_rd + ATOMIC_CRITICAL_READ( cmplx16, a16_rd, kmp_cmplx128_a16_t, +, 32c, 1 ) // __kmpc_atomic_cmplx16_a16_rd +#endif +#endif + + +// ------------------------------------------------------------------------ +// Atomic WRITE routines +// ------------------------------------------------------------------------ + +#define ATOMIC_XCHG_WR(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP,GOMP_FLAG) \ + KMP_XCHG_FIXED##BITS( lhs, rhs ); \ +} +// ------------------------------------------------------------------------ +#define ATOMIC_XCHG_FLOAT_WR(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP,GOMP_FLAG) \ + KMP_XCHG_REAL##BITS( lhs, rhs ); \ +} + + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +// Note: temp_val introduced in order to force the compiler to read +// *lhs only once (w/o it the compiler reads *lhs twice) +#define OP_CMPXCHG_WR(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value, new_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_CPU_PAUSE(); \ + \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs; \ + } \ + } + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_WR(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP,GOMP_FLAG) \ + OP_CMPXCHG_WR(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL_WR(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN(TYPE_ID,OP_ID,TYPE,void) \ + OP_GOMP_CRITICAL(OP,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL(OP,LCK_ID) /* send assignment */ \ +} +// ------------------------------------------------------------------------- + +ATOMIC_XCHG_WR( fixed1, wr, kmp_int8, 8, =, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_wr +ATOMIC_XCHG_WR( fixed2, wr, kmp_int16, 16, =, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_wr +ATOMIC_XCHG_WR( fixed4, wr, kmp_int32, 32, =, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_wr +#if ( KMP_ARCH_X86 ) + ATOMIC_CMPXCHG_WR( fixed8, wr, kmp_int64, 64, =, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_wr +#else + ATOMIC_XCHG_WR( fixed8, wr, kmp_int64, 64, =, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_wr +#endif + +ATOMIC_XCHG_FLOAT_WR( float4, wr, kmp_real32, 32, =, KMP_ARCH_X86 ) // __kmpc_atomic_float4_wr +#if ( KMP_ARCH_X86 ) + ATOMIC_CMPXCHG_WR( float8, wr, kmp_real64, 64, =, KMP_ARCH_X86 ) // __kmpc_atomic_float8_wr +#else + ATOMIC_XCHG_FLOAT_WR( float8, wr, kmp_real64, 64, =, KMP_ARCH_X86 ) // __kmpc_atomic_float8_wr +#endif + +ATOMIC_CRITICAL_WR( float10, wr, long double, =, 10r, 1 ) // __kmpc_atomic_float10_wr +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_WR( float16, wr, QUAD_LEGACY, =, 16r, 1 ) // __kmpc_atomic_float16_wr +#endif +ATOMIC_CRITICAL_WR( cmplx4, wr, kmp_cmplx32, =, 8c, 1 ) // __kmpc_atomic_cmplx4_wr +ATOMIC_CRITICAL_WR( cmplx8, wr, kmp_cmplx64, =, 16c, 1 ) // __kmpc_atomic_cmplx8_wr +ATOMIC_CRITICAL_WR( cmplx10, wr, kmp_cmplx80, =, 20c, 1 ) // __kmpc_atomic_cmplx10_wr +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_WR( cmplx16, wr, CPLX128_LEG, =, 32c, 1 ) // __kmpc_atomic_cmplx16_wr +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_WR( float16, a16_wr, Quad_a16_t, =, 16r, 1 ) // __kmpc_atomic_float16_a16_wr + ATOMIC_CRITICAL_WR( cmplx16, a16_wr, kmp_cmplx128_a16_t, =, 32c, 1 ) // __kmpc_atomic_cmplx16_a16_wr +#endif +#endif + + +// ------------------------------------------------------------------------ +// Atomic CAPTURE routines +// ------------------------------------------------------------------------ + +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +#define ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,RET_TYPE) \ +RET_TYPE __kmpc_atomic_##TYPE_ID##_##OP_ID( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs, int flag ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------- +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL_CPT(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if( flag ) { \ + (*lhs) OP rhs; \ + new_value = (*lhs); \ + } else { \ + new_value = (*lhs); \ + (*lhs) OP rhs; \ + } \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return new_value; + +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_CPT(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_CPT( OP##=, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_CPT(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +// Note: temp_val introduced in order to force the compiler to read +// *lhs only once (w/o it the compiler reads *lhs twice) +#define OP_CMPXCHG_CPT(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value, new_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = old_value OP rhs; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_CPU_PAUSE(); \ + \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = old_value OP rhs; \ + } \ + if( flag ) { \ + return new_value; \ + } else \ + return old_value; \ + } + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_CPT(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT(OP,GOMP_FLAG) \ + OP_CMPXCHG_CPT(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------- +#define ATOMIC_FIXED_ADD_CPT(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE old_value, new_value; \ + OP_GOMP_CRITICAL_CPT(OP,GOMP_FLAG) \ + /* OP used as a sign for subtraction: (lhs-rhs) --> (lhs+-rhs) */ \ + old_value = KMP_TEST_THEN_ADD##BITS( lhs, OP rhs ); \ + if( flag ) { \ + return old_value OP rhs; \ + } else \ + return old_value; \ +} +// ------------------------------------------------------------------------- + +ATOMIC_FIXED_ADD_CPT( fixed4, add_cpt, kmp_int32, 32, +, 0 ) // __kmpc_atomic_fixed4_add_cpt +ATOMIC_FIXED_ADD_CPT( fixed4, sub_cpt, kmp_int32, 32, -, 0 ) // __kmpc_atomic_fixed4_sub_cpt +ATOMIC_FIXED_ADD_CPT( fixed8, add_cpt, kmp_int64, 64, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_add_cpt +ATOMIC_FIXED_ADD_CPT( fixed8, sub_cpt, kmp_int64, 64, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_cpt + +ATOMIC_CMPXCHG_CPT( float4, add_cpt, kmp_real32, 32, +, KMP_ARCH_X86 ) // __kmpc_atomic_float4_add_cpt +ATOMIC_CMPXCHG_CPT( float4, sub_cpt, kmp_real32, 32, -, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_cpt +ATOMIC_CMPXCHG_CPT( float8, add_cpt, kmp_real64, 64, +, KMP_ARCH_X86 ) // __kmpc_atomic_float8_add_cpt +ATOMIC_CMPXCHG_CPT( float8, sub_cpt, kmp_real64, 64, -, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_cpt + +// ------------------------------------------------------------------------ +// Entries definition for integer operands +// TYPE_ID - operands type and size (fixed4, float4) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operand type +// BITS - size in bits, used to distinguish low level calls +// OP - operator (used in critical section) +// TYPE_ID,OP_ID, TYPE, BITS,OP,GOMP_FLAG +// ------------------------------------------------------------------------ +// Routines for ATOMIC integer operands, other operators +// ------------------------------------------------------------------------ +// TYPE_ID,OP_ID, TYPE, OP, GOMP_FLAG +ATOMIC_CMPXCHG_CPT( fixed1, add_cpt, kmp_int8, 8, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_add_cpt +ATOMIC_CMPXCHG_CPT( fixed1, andb_cpt, kmp_int8, 8, &, 0 ) // __kmpc_atomic_fixed1_andb_cpt +ATOMIC_CMPXCHG_CPT( fixed1, div_cpt, kmp_int8, 8, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_cpt +ATOMIC_CMPXCHG_CPT( fixed1u, div_cpt, kmp_uint8, 8, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_cpt +ATOMIC_CMPXCHG_CPT( fixed1, mul_cpt, kmp_int8, 8, *, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_mul_cpt +ATOMIC_CMPXCHG_CPT( fixed1, orb_cpt, kmp_int8, 8, |, 0 ) // __kmpc_atomic_fixed1_orb_cpt +ATOMIC_CMPXCHG_CPT( fixed1, shl_cpt, kmp_int8, 8, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shl_cpt +ATOMIC_CMPXCHG_CPT( fixed1, shr_cpt, kmp_int8, 8, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed1u, shr_cpt, kmp_uint8, 8, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed1, sub_cpt, kmp_int8, 8, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_cpt +ATOMIC_CMPXCHG_CPT( fixed1, xor_cpt, kmp_int8, 8, ^, 0 ) // __kmpc_atomic_fixed1_xor_cpt +ATOMIC_CMPXCHG_CPT( fixed2, add_cpt, kmp_int16, 16, +, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_add_cpt +ATOMIC_CMPXCHG_CPT( fixed2, andb_cpt, kmp_int16, 16, &, 0 ) // __kmpc_atomic_fixed2_andb_cpt +ATOMIC_CMPXCHG_CPT( fixed2, div_cpt, kmp_int16, 16, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_cpt +ATOMIC_CMPXCHG_CPT( fixed2u, div_cpt, kmp_uint16, 16, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_cpt +ATOMIC_CMPXCHG_CPT( fixed2, mul_cpt, kmp_int16, 16, *, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_mul_cpt +ATOMIC_CMPXCHG_CPT( fixed2, orb_cpt, kmp_int16, 16, |, 0 ) // __kmpc_atomic_fixed2_orb_cpt +ATOMIC_CMPXCHG_CPT( fixed2, shl_cpt, kmp_int16, 16, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shl_cpt +ATOMIC_CMPXCHG_CPT( fixed2, shr_cpt, kmp_int16, 16, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed2u, shr_cpt, kmp_uint16, 16, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed2, sub_cpt, kmp_int16, 16, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_cpt +ATOMIC_CMPXCHG_CPT( fixed2, xor_cpt, kmp_int16, 16, ^, 0 ) // __kmpc_atomic_fixed2_xor_cpt +ATOMIC_CMPXCHG_CPT( fixed4, andb_cpt, kmp_int32, 32, &, 0 ) // __kmpc_atomic_fixed4_andb_cpt +ATOMIC_CMPXCHG_CPT( fixed4, div_cpt, kmp_int32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_div_cpt +ATOMIC_CMPXCHG_CPT( fixed4u, div_cpt, kmp_uint32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_div_cpt +ATOMIC_CMPXCHG_CPT( fixed4, mul_cpt, kmp_int32, 32, *, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_mul_cpt +ATOMIC_CMPXCHG_CPT( fixed4, orb_cpt, kmp_int32, 32, |, 0 ) // __kmpc_atomic_fixed4_orb_cpt +ATOMIC_CMPXCHG_CPT( fixed4, shl_cpt, kmp_int32, 32, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shl_cpt +ATOMIC_CMPXCHG_CPT( fixed4, shr_cpt, kmp_int32, 32, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed4u, shr_cpt, kmp_uint32, 32, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed4, xor_cpt, kmp_int32, 32, ^, 0 ) // __kmpc_atomic_fixed4_xor_cpt +ATOMIC_CMPXCHG_CPT( fixed8, andb_cpt, kmp_int64, 64, &, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_andb_cpt +ATOMIC_CMPXCHG_CPT( fixed8, div_cpt, kmp_int64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_cpt +ATOMIC_CMPXCHG_CPT( fixed8u, div_cpt, kmp_uint64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_cpt +ATOMIC_CMPXCHG_CPT( fixed8, mul_cpt, kmp_int64, 64, *, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_mul_cpt +ATOMIC_CMPXCHG_CPT( fixed8, orb_cpt, kmp_int64, 64, |, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_orb_cpt +ATOMIC_CMPXCHG_CPT( fixed8, shl_cpt, kmp_int64, 64, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shl_cpt +ATOMIC_CMPXCHG_CPT( fixed8, shr_cpt, kmp_int64, 64, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed8u, shr_cpt, kmp_uint64, 64, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_shr_cpt +ATOMIC_CMPXCHG_CPT( fixed8, xor_cpt, kmp_int64, 64, ^, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_xor_cpt +ATOMIC_CMPXCHG_CPT( float4, div_cpt, kmp_real32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_cpt +ATOMIC_CMPXCHG_CPT( float4, mul_cpt, kmp_real32, 32, *, KMP_ARCH_X86 ) // __kmpc_atomic_float4_mul_cpt +ATOMIC_CMPXCHG_CPT( float8, div_cpt, kmp_real64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_cpt +ATOMIC_CMPXCHG_CPT( float8, mul_cpt, kmp_real64, 64, *, KMP_ARCH_X86 ) // __kmpc_atomic_float8_mul_cpt +// TYPE_ID,OP_ID, TYPE, OP, GOMP_FLAG + +////////////////////////////////// + +// CAPTURE routines for mixed types RHS=float16 +#if KMP_HAVE_QUAD + +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +#define ATOMIC_BEGIN_CPT_MIX(TYPE_ID,OP_ID,TYPE,RTYPE_ID,RTYPE) \ +TYPE __kmpc_atomic_##TYPE_ID##_##OP_ID##_##RTYPE_ID( ident_t *id_ref, int gtid, TYPE * lhs, RTYPE rhs, int flag ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID "_" #RTYPE_ID ": T#%d\n", gtid )); + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_CPT_MIX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT_MIX(TYPE_ID,OP_ID,TYPE,RTYPE_ID,RTYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT(OP,GOMP_FLAG) \ + OP_CMPXCHG_CPT(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------- +#define ATOMIC_CRITICAL_CPT_MIX(TYPE_ID,TYPE,OP_ID,OP,RTYPE_ID,RTYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT_MIX(TYPE_ID,OP_ID,TYPE,RTYPE_ID,RTYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT(OP,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL_CPT(OP##=,LCK_ID) /* send assignment */ \ +} + +ATOMIC_CMPXCHG_CPT_MIX( fixed1, char, add_cpt, 8, +, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1u, uchar, add_cpt, 8, +, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1, char, sub_cpt, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1u, uchar, sub_cpt, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1, char, mul_cpt, 8, *, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1u, uchar, mul_cpt, 8, *, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1, char, div_cpt, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed1u, uchar, div_cpt, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_cpt_fp + +ATOMIC_CMPXCHG_CPT_MIX( fixed2, short, add_cpt, 16, +, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2u, ushort, add_cpt, 16, +, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2, short, sub_cpt, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2u, ushort, sub_cpt, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2, short, mul_cpt, 16, *, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2u, ushort, mul_cpt, 16, *, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2, short, div_cpt, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed2u, ushort, div_cpt, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_cpt_fp + +ATOMIC_CMPXCHG_CPT_MIX( fixed4, kmp_int32, add_cpt, 32, +, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4u, kmp_uint32, add_cpt, 32, +, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4, kmp_int32, sub_cpt, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4u, kmp_uint32, sub_cpt, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4, kmp_int32, mul_cpt, 32, *, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4u, kmp_uint32, mul_cpt, 32, *, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4, kmp_int32, div_cpt, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_div_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed4u, kmp_uint32, div_cpt, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_div_cpt_fp + +ATOMIC_CMPXCHG_CPT_MIX( fixed8, kmp_int64, add_cpt, 64, +, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8u, kmp_uint64, add_cpt, 64, +, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8, kmp_int64, sub_cpt, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8u, kmp_uint64, sub_cpt, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8, kmp_int64, mul_cpt, 64, *, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8u, kmp_uint64, mul_cpt, 64, *, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8, kmp_int64, div_cpt, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( fixed8u, kmp_uint64, div_cpt, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_cpt_fp + +ATOMIC_CMPXCHG_CPT_MIX( float4, kmp_real32, add_cpt, 32, +, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float4, kmp_real32, sub_cpt, 32, -, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float4, kmp_real32, mul_cpt, 32, *, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float4, kmp_real32, div_cpt, 32, /, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_cpt_fp + +ATOMIC_CMPXCHG_CPT_MIX( float8, kmp_real64, add_cpt, 64, +, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_add_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float8, kmp_real64, sub_cpt, 64, -, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float8, kmp_real64, mul_cpt, 64, *, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_mul_cpt_fp +ATOMIC_CMPXCHG_CPT_MIX( float8, kmp_real64, div_cpt, 64, /, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_cpt_fp + +ATOMIC_CRITICAL_CPT_MIX( float10, long double, add_cpt, +, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_add_cpt_fp +ATOMIC_CRITICAL_CPT_MIX( float10, long double, sub_cpt, -, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_sub_cpt_fp +ATOMIC_CRITICAL_CPT_MIX( float10, long double, mul_cpt, *, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_mul_cpt_fp +ATOMIC_CRITICAL_CPT_MIX( float10, long double, div_cpt, /, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_div_cpt_fp + +#endif //KMP_HAVE_QUAD + +/////////////////////////////////// + +// ------------------------------------------------------------------------ +// Routines for C/C++ Reduction operators && and || +// ------------------------------------------------------------------------ + +// ------------------------------------------------------------------------- +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL_L_CPT(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if( flag ) { \ + new_value OP rhs; \ + } else \ + new_value = (*lhs); \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); + +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_L_CPT(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_L_CPT( OP, 0 ); \ + return new_value; \ + } +#else +#define OP_GOMP_CRITICAL_L_CPT(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------ +// Need separate macros for &&, || because there is no combined assignment +#define ATOMIC_CMPX_L_CPT(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_L_CPT( = *lhs OP, GOMP_FLAG ) \ + OP_CMPXCHG_CPT(TYPE,BITS,OP) \ +} + +ATOMIC_CMPX_L_CPT( fixed1, andl_cpt, char, 8, &&, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_andl_cpt +ATOMIC_CMPX_L_CPT( fixed1, orl_cpt, char, 8, ||, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_orl_cpt +ATOMIC_CMPX_L_CPT( fixed2, andl_cpt, short, 16, &&, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_andl_cpt +ATOMIC_CMPX_L_CPT( fixed2, orl_cpt, short, 16, ||, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_orl_cpt +ATOMIC_CMPX_L_CPT( fixed4, andl_cpt, kmp_int32, 32, &&, 0 ) // __kmpc_atomic_fixed4_andl_cpt +ATOMIC_CMPX_L_CPT( fixed4, orl_cpt, kmp_int32, 32, ||, 0 ) // __kmpc_atomic_fixed4_orl_cpt +ATOMIC_CMPX_L_CPT( fixed8, andl_cpt, kmp_int64, 64, &&, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_andl_cpt +ATOMIC_CMPX_L_CPT( fixed8, orl_cpt, kmp_int64, 64, ||, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_orl_cpt + + +// ------------------------------------------------------------------------- +// Routines for Fortran operators that matched no one in C: +// MAX, MIN, .EQV., .NEQV. +// Operators .AND., .OR. are covered by __kmpc_atomic_*_{andl,orl}_cpt +// Intrinsics IAND, IOR, IEOR are covered by __kmpc_atomic_*_{andb,orb,xor}_cpt +// ------------------------------------------------------------------------- + +// ------------------------------------------------------------------------- +// MIN and MAX need separate macros +// OP - operator to check if we need any actions? +#define MIN_MAX_CRITSECT_CPT(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if ( *lhs OP rhs ) { /* still need actions? */ \ + old_value = *lhs; \ + *lhs = rhs; \ + if ( flag ) \ + new_value = rhs; \ + else \ + new_value = old_value; \ + } \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return new_value; \ + +// ------------------------------------------------------------------------- +#ifdef KMP_GOMP_COMPAT +#define GOMP_MIN_MAX_CRITSECT_CPT(OP,FLAG) \ + if (( FLAG ) && ( __kmp_atomic_mode == 2 )) { \ + KMP_CHECK_GTID; \ + MIN_MAX_CRITSECT_CPT( OP, 0 ); \ + } +#else +#define GOMP_MIN_MAX_CRITSECT_CPT(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------- +#define MIN_MAX_CMPXCHG_CPT(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + /*TYPE old_value; */ \ + temp_val = *lhs; \ + old_value = temp_val; \ + while ( old_value OP rhs && /* still need actions? */ \ + ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &rhs ) ) \ + { \ + KMP_CPU_PAUSE(); \ + temp_val = *lhs; \ + old_value = temp_val; \ + } \ + if( flag ) \ + return rhs; \ + else \ + return old_value; \ + } + +// ------------------------------------------------------------------------- +// 1-byte, 2-byte operands - use critical section +#define MIN_MAX_CRITICAL_CPT(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value, old_value; \ + if ( *lhs OP rhs ) { /* need actions? */ \ + GOMP_MIN_MAX_CRITSECT_CPT(OP,GOMP_FLAG) \ + MIN_MAX_CRITSECT_CPT(OP,LCK_ID) \ + } \ + return *lhs; \ +} + +#define MIN_MAX_COMPXCHG_CPT(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value, old_value; \ + if ( *lhs OP rhs ) { \ + GOMP_MIN_MAX_CRITSECT_CPT(OP,GOMP_FLAG) \ + MIN_MAX_CMPXCHG_CPT(TYPE,BITS,OP) \ + } \ + return *lhs; \ +} + + +MIN_MAX_COMPXCHG_CPT( fixed1, max_cpt, char, 8, <, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_max_cpt +MIN_MAX_COMPXCHG_CPT( fixed1, min_cpt, char, 8, >, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_min_cpt +MIN_MAX_COMPXCHG_CPT( fixed2, max_cpt, short, 16, <, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_max_cpt +MIN_MAX_COMPXCHG_CPT( fixed2, min_cpt, short, 16, >, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_min_cpt +MIN_MAX_COMPXCHG_CPT( fixed4, max_cpt, kmp_int32, 32, <, 0 ) // __kmpc_atomic_fixed4_max_cpt +MIN_MAX_COMPXCHG_CPT( fixed4, min_cpt, kmp_int32, 32, >, 0 ) // __kmpc_atomic_fixed4_min_cpt +MIN_MAX_COMPXCHG_CPT( fixed8, max_cpt, kmp_int64, 64, <, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_max_cpt +MIN_MAX_COMPXCHG_CPT( fixed8, min_cpt, kmp_int64, 64, >, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_min_cpt +MIN_MAX_COMPXCHG_CPT( float4, max_cpt, kmp_real32, 32, <, KMP_ARCH_X86 ) // __kmpc_atomic_float4_max_cpt +MIN_MAX_COMPXCHG_CPT( float4, min_cpt, kmp_real32, 32, >, KMP_ARCH_X86 ) // __kmpc_atomic_float4_min_cpt +MIN_MAX_COMPXCHG_CPT( float8, max_cpt, kmp_real64, 64, <, KMP_ARCH_X86 ) // __kmpc_atomic_float8_max_cpt +MIN_MAX_COMPXCHG_CPT( float8, min_cpt, kmp_real64, 64, >, KMP_ARCH_X86 ) // __kmpc_atomic_float8_min_cpt +#if KMP_HAVE_QUAD +MIN_MAX_CRITICAL_CPT( float16, max_cpt, QUAD_LEGACY, <, 16r, 1 ) // __kmpc_atomic_float16_max_cpt +MIN_MAX_CRITICAL_CPT( float16, min_cpt, QUAD_LEGACY, >, 16r, 1 ) // __kmpc_atomic_float16_min_cpt +#if ( KMP_ARCH_X86 ) + MIN_MAX_CRITICAL_CPT( float16, max_a16_cpt, Quad_a16_t, <, 16r, 1 ) // __kmpc_atomic_float16_max_a16_cpt + MIN_MAX_CRITICAL_CPT( float16, min_a16_cpt, Quad_a16_t, >, 16r, 1 ) // __kmpc_atomic_float16_mix_a16_cpt +#endif +#endif + +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_EQV_CPT(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_CPT( OP, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_EQV_CPT(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ +// ------------------------------------------------------------------------ +#define ATOMIC_CMPX_EQV_CPT(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_EQV_CPT(^=~,GOMP_FLAG) /* send assignment */ \ + OP_CMPXCHG_CPT(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------ + +ATOMIC_CMPXCHG_CPT( fixed1, neqv_cpt, kmp_int8, 8, ^, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_neqv_cpt +ATOMIC_CMPXCHG_CPT( fixed2, neqv_cpt, kmp_int16, 16, ^, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_neqv_cpt +ATOMIC_CMPXCHG_CPT( fixed4, neqv_cpt, kmp_int32, 32, ^, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_neqv_cpt +ATOMIC_CMPXCHG_CPT( fixed8, neqv_cpt, kmp_int64, 64, ^, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_neqv_cpt +ATOMIC_CMPX_EQV_CPT( fixed1, eqv_cpt, kmp_int8, 8, ^~, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_eqv_cpt +ATOMIC_CMPX_EQV_CPT( fixed2, eqv_cpt, kmp_int16, 16, ^~, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_eqv_cpt +ATOMIC_CMPX_EQV_CPT( fixed4, eqv_cpt, kmp_int32, 32, ^~, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_eqv_cpt +ATOMIC_CMPX_EQV_CPT( fixed8, eqv_cpt, kmp_int64, 64, ^~, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_eqv_cpt + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL_CPT(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT(OP,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL_CPT(OP##=,LCK_ID) /* send assignment */ \ +} + +// ------------------------------------------------------------------------ + +// Workaround for cmplx4. Regular routines with return value don't work +// on Win_32e. Let's return captured values through the additional parameter. +#define OP_CRITICAL_CPT_WRK(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if( flag ) { \ + (*lhs) OP rhs; \ + (*out) = (*lhs); \ + } else { \ + (*out) = (*lhs); \ + (*lhs) OP rhs; \ + } \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return; +// ------------------------------------------------------------------------ + +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_CPT_WRK(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_CPT_WRK( OP##=, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_CPT_WRK(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ +// ------------------------------------------------------------------------ + +#define ATOMIC_BEGIN_WRK(TYPE_ID,OP_ID,TYPE) \ +void __kmpc_atomic_##TYPE_ID##_##OP_ID( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs, TYPE * out, int flag ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_" #OP_ID ": T#%d\n", gtid )); +// ------------------------------------------------------------------------ + +#define ATOMIC_CRITICAL_CPT_WRK(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_WRK(TYPE_ID,OP_ID,TYPE) \ + OP_GOMP_CRITICAL_CPT_WRK(OP,GOMP_FLAG) \ + OP_CRITICAL_CPT_WRK(OP##=,LCK_ID) \ +} +// The end of workaround for cmplx4 + +/* ------------------------------------------------------------------------- */ +// routines for long double type +ATOMIC_CRITICAL_CPT( float10, add_cpt, long double, +, 10r, 1 ) // __kmpc_atomic_float10_add_cpt +ATOMIC_CRITICAL_CPT( float10, sub_cpt, long double, -, 10r, 1 ) // __kmpc_atomic_float10_sub_cpt +ATOMIC_CRITICAL_CPT( float10, mul_cpt, long double, *, 10r, 1 ) // __kmpc_atomic_float10_mul_cpt +ATOMIC_CRITICAL_CPT( float10, div_cpt, long double, /, 10r, 1 ) // __kmpc_atomic_float10_div_cpt +#if KMP_HAVE_QUAD +// routines for _Quad type +ATOMIC_CRITICAL_CPT( float16, add_cpt, QUAD_LEGACY, +, 16r, 1 ) // __kmpc_atomic_float16_add_cpt +ATOMIC_CRITICAL_CPT( float16, sub_cpt, QUAD_LEGACY, -, 16r, 1 ) // __kmpc_atomic_float16_sub_cpt +ATOMIC_CRITICAL_CPT( float16, mul_cpt, QUAD_LEGACY, *, 16r, 1 ) // __kmpc_atomic_float16_mul_cpt +ATOMIC_CRITICAL_CPT( float16, div_cpt, QUAD_LEGACY, /, 16r, 1 ) // __kmpc_atomic_float16_div_cpt +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_CPT( float16, add_a16_cpt, Quad_a16_t, +, 16r, 1 ) // __kmpc_atomic_float16_add_a16_cpt + ATOMIC_CRITICAL_CPT( float16, sub_a16_cpt, Quad_a16_t, -, 16r, 1 ) // __kmpc_atomic_float16_sub_a16_cpt + ATOMIC_CRITICAL_CPT( float16, mul_a16_cpt, Quad_a16_t, *, 16r, 1 ) // __kmpc_atomic_float16_mul_a16_cpt + ATOMIC_CRITICAL_CPT( float16, div_a16_cpt, Quad_a16_t, /, 16r, 1 ) // __kmpc_atomic_float16_div_a16_cpt +#endif +#endif + +// routines for complex types + +// cmplx4 routines to return void +ATOMIC_CRITICAL_CPT_WRK( cmplx4, add_cpt, kmp_cmplx32, +, 8c, 1 ) // __kmpc_atomic_cmplx4_add_cpt +ATOMIC_CRITICAL_CPT_WRK( cmplx4, sub_cpt, kmp_cmplx32, -, 8c, 1 ) // __kmpc_atomic_cmplx4_sub_cpt +ATOMIC_CRITICAL_CPT_WRK( cmplx4, mul_cpt, kmp_cmplx32, *, 8c, 1 ) // __kmpc_atomic_cmplx4_mul_cpt +ATOMIC_CRITICAL_CPT_WRK( cmplx4, div_cpt, kmp_cmplx32, /, 8c, 1 ) // __kmpc_atomic_cmplx4_div_cpt + +ATOMIC_CRITICAL_CPT( cmplx8, add_cpt, kmp_cmplx64, +, 16c, 1 ) // __kmpc_atomic_cmplx8_add_cpt +ATOMIC_CRITICAL_CPT( cmplx8, sub_cpt, kmp_cmplx64, -, 16c, 1 ) // __kmpc_atomic_cmplx8_sub_cpt +ATOMIC_CRITICAL_CPT( cmplx8, mul_cpt, kmp_cmplx64, *, 16c, 1 ) // __kmpc_atomic_cmplx8_mul_cpt +ATOMIC_CRITICAL_CPT( cmplx8, div_cpt, kmp_cmplx64, /, 16c, 1 ) // __kmpc_atomic_cmplx8_div_cpt +ATOMIC_CRITICAL_CPT( cmplx10, add_cpt, kmp_cmplx80, +, 20c, 1 ) // __kmpc_atomic_cmplx10_add_cpt +ATOMIC_CRITICAL_CPT( cmplx10, sub_cpt, kmp_cmplx80, -, 20c, 1 ) // __kmpc_atomic_cmplx10_sub_cpt +ATOMIC_CRITICAL_CPT( cmplx10, mul_cpt, kmp_cmplx80, *, 20c, 1 ) // __kmpc_atomic_cmplx10_mul_cpt +ATOMIC_CRITICAL_CPT( cmplx10, div_cpt, kmp_cmplx80, /, 20c, 1 ) // __kmpc_atomic_cmplx10_div_cpt +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_CPT( cmplx16, add_cpt, CPLX128_LEG, +, 32c, 1 ) // __kmpc_atomic_cmplx16_add_cpt +ATOMIC_CRITICAL_CPT( cmplx16, sub_cpt, CPLX128_LEG, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_cpt +ATOMIC_CRITICAL_CPT( cmplx16, mul_cpt, CPLX128_LEG, *, 32c, 1 ) // __kmpc_atomic_cmplx16_mul_cpt +ATOMIC_CRITICAL_CPT( cmplx16, div_cpt, CPLX128_LEG, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_cpt +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_CPT( cmplx16, add_a16_cpt, kmp_cmplx128_a16_t, +, 32c, 1 ) // __kmpc_atomic_cmplx16_add_a16_cpt + ATOMIC_CRITICAL_CPT( cmplx16, sub_a16_cpt, kmp_cmplx128_a16_t, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_a16_cpt + ATOMIC_CRITICAL_CPT( cmplx16, mul_a16_cpt, kmp_cmplx128_a16_t, *, 32c, 1 ) // __kmpc_atomic_cmplx16_mul_a16_cpt + ATOMIC_CRITICAL_CPT( cmplx16, div_a16_cpt, kmp_cmplx128_a16_t, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_a16_cpt +#endif +#endif + +#if OMP_40_ENABLED + +// OpenMP 4.0: v = x = expr binop x; { v = x; x = expr binop x; } { x = expr binop x; v = x; } for non-commutative operations. +// Supported only on IA-32 architecture and Intel(R) 64 + +// ------------------------------------------------------------------------- +// Operation on *lhs, rhs bound by critical section +// OP - operator (it's supposed to contain an assignment) +// LCK_ID - lock identifier +// Note: don't check gtid as it should always be valid +// 1, 2-byte - expect valid parameter, other - check before this macro +#define OP_CRITICAL_CPT_REV(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if( flag ) { \ + /*temp_val = (*lhs);*/\ + (*lhs) = (rhs) OP (*lhs); \ + new_value = (*lhs); \ + } else { \ + new_value = (*lhs);\ + (*lhs) = (rhs) OP (*lhs); \ + } \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return new_value; + +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_CPT_REV(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_CPT_REV( OP, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_CPT_REV(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ + +// ------------------------------------------------------------------------ +// Operation on *lhs, rhs using "compare_and_store" routine +// TYPE - operands' type +// BITS - size in bits, used to distinguish low level calls +// OP - operator +// Note: temp_val introduced in order to force the compiler to read +// *lhs only once (w/o it the compiler reads *lhs twice) +#define OP_CMPXCHG_CPT_REV(TYPE,BITS,OP) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value, new_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs OP old_value; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_CPU_PAUSE(); \ + \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs OP old_value; \ + } \ + if( flag ) { \ + return new_value; \ + } else \ + return old_value; \ + } + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_CPT_REV(TYPE_ID,OP_ID,TYPE,BITS,OP,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + OP_GOMP_CRITICAL_CPT_REV(OP,GOMP_FLAG) \ + OP_CMPXCHG_CPT_REV(TYPE,BITS,OP) \ +} + + +ATOMIC_CMPXCHG_CPT_REV( fixed1, div_cpt_rev, kmp_int8, 8, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed1u, div_cpt_rev, kmp_uint8, 8, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed1, shl_cpt_rev, kmp_int8, 8, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shl_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed1, shr_cpt_rev, kmp_int8, 8, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed1u, shr_cpt_rev, kmp_uint8, 8, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed1, sub_cpt_rev, kmp_int8, 8, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2, div_cpt_rev, kmp_int16, 16, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2u, div_cpt_rev, kmp_uint16, 16, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2, shl_cpt_rev, kmp_int16, 16, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shl_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2, shr_cpt_rev, kmp_int16, 16, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2u, shr_cpt_rev, kmp_uint16, 16, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed2, sub_cpt_rev, kmp_int16, 16, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4, div_cpt_rev, kmp_int32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4u, div_cpt_rev, kmp_uint32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4, shl_cpt_rev, kmp_int32, 32, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shl_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4, shr_cpt_rev, kmp_int32, 32, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4u, shr_cpt_rev, kmp_uint32, 32, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4u_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed4, sub_cpt_rev, kmp_int32, 32, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_sub_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8, div_cpt_rev, kmp_int64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8u, div_cpt_rev, kmp_uint64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8, shl_cpt_rev, kmp_int64, 64, <<, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shl_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8, shr_cpt_rev, kmp_int64, 64, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8u, shr_cpt_rev, kmp_uint64, 64, >>, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_shr_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( fixed8, sub_cpt_rev, kmp_int64, 64, -, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( float4, div_cpt_rev, kmp_real32, 32, /, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( float4, sub_cpt_rev, kmp_real32, 32, -, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( float8, div_cpt_rev, kmp_real64, 64, /, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_cpt_rev +ATOMIC_CMPXCHG_CPT_REV( float8, sub_cpt_rev, kmp_real64, 64, -, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_cpt_rev +// TYPE_ID,OP_ID, TYPE, OP, GOMP_FLAG + + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +// TYPE_ID, OP_ID, TYPE - detailed above +// OP - operator +// LCK_ID - lock identifier, used to possibly distinguish lock variable +#define ATOMIC_CRITICAL_CPT_REV(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT(TYPE_ID,OP_ID,TYPE,TYPE) \ + TYPE new_value; \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + /*printf("__kmp_atomic_mode = %d\n", __kmp_atomic_mode);*/\ + OP_GOMP_CRITICAL_CPT_REV(OP,GOMP_FLAG) \ + OP_CRITICAL_CPT_REV(OP,LCK_ID) \ +} + + +/* ------------------------------------------------------------------------- */ +// routines for long double type +ATOMIC_CRITICAL_CPT_REV( float10, sub_cpt_rev, long double, -, 10r, 1 ) // __kmpc_atomic_float10_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV( float10, div_cpt_rev, long double, /, 10r, 1 ) // __kmpc_atomic_float10_div_cpt_rev +#if KMP_HAVE_QUAD +// routines for _Quad type +ATOMIC_CRITICAL_CPT_REV( float16, sub_cpt_rev, QUAD_LEGACY, -, 16r, 1 ) // __kmpc_atomic_float16_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV( float16, div_cpt_rev, QUAD_LEGACY, /, 16r, 1 ) // __kmpc_atomic_float16_div_cpt_rev +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_CPT_REV( float16, sub_a16_cpt_rev, Quad_a16_t, -, 16r, 1 ) // __kmpc_atomic_float16_sub_a16_cpt_rev + ATOMIC_CRITICAL_CPT_REV( float16, div_a16_cpt_rev, Quad_a16_t, /, 16r, 1 ) // __kmpc_atomic_float16_div_a16_cpt_rev +#endif +#endif + +// routines for complex types + +// ------------------------------------------------------------------------ + +// Workaround for cmplx4. Regular routines with return value don't work +// on Win_32e. Let's return captured values through the additional parameter. +#define OP_CRITICAL_CPT_REV_WRK(OP,LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + if( flag ) { \ + (*lhs) = (rhs) OP (*lhs); \ + (*out) = (*lhs); \ + } else { \ + (*out) = (*lhs); \ + (*lhs) = (rhs) OP (*lhs); \ + } \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return; +// ------------------------------------------------------------------------ + +#ifdef KMP_GOMP_COMPAT +#define OP_GOMP_CRITICAL_CPT_REV_WRK(OP,FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + OP_CRITICAL_CPT_REV_WRK( OP, 0 ); \ + } +#else +#define OP_GOMP_CRITICAL_CPT_REV_WRK(OP,FLAG) +#endif /* KMP_GOMP_COMPAT */ +// ------------------------------------------------------------------------ + +#define ATOMIC_CRITICAL_CPT_REV_WRK(TYPE_ID,OP_ID,TYPE,OP,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_WRK(TYPE_ID,OP_ID,TYPE) \ + OP_GOMP_CRITICAL_CPT_REV_WRK(OP,GOMP_FLAG) \ + OP_CRITICAL_CPT_REV_WRK(OP,LCK_ID) \ +} +// The end of workaround for cmplx4 + + +// !!! TODO: check if we need to return void for cmplx4 routines +// cmplx4 routines to return void +ATOMIC_CRITICAL_CPT_REV_WRK( cmplx4, sub_cpt_rev, kmp_cmplx32, -, 8c, 1 ) // __kmpc_atomic_cmplx4_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV_WRK( cmplx4, div_cpt_rev, kmp_cmplx32, /, 8c, 1 ) // __kmpc_atomic_cmplx4_div_cpt_rev + +ATOMIC_CRITICAL_CPT_REV( cmplx8, sub_cpt_rev, kmp_cmplx64, -, 16c, 1 ) // __kmpc_atomic_cmplx8_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV( cmplx8, div_cpt_rev, kmp_cmplx64, /, 16c, 1 ) // __kmpc_atomic_cmplx8_div_cpt_rev +ATOMIC_CRITICAL_CPT_REV( cmplx10, sub_cpt_rev, kmp_cmplx80, -, 20c, 1 ) // __kmpc_atomic_cmplx10_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV( cmplx10, div_cpt_rev, kmp_cmplx80, /, 20c, 1 ) // __kmpc_atomic_cmplx10_div_cpt_rev +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_CPT_REV( cmplx16, sub_cpt_rev, CPLX128_LEG, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_cpt_rev +ATOMIC_CRITICAL_CPT_REV( cmplx16, div_cpt_rev, CPLX128_LEG, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_cpt_rev +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_CPT_REV( cmplx16, sub_a16_cpt_rev, kmp_cmplx128_a16_t, -, 32c, 1 ) // __kmpc_atomic_cmplx16_sub_a16_cpt_rev + ATOMIC_CRITICAL_CPT_REV( cmplx16, div_a16_cpt_rev, kmp_cmplx128_a16_t, /, 32c, 1 ) // __kmpc_atomic_cmplx16_div_a16_cpt_rev +#endif +#endif + +// Capture reverse for mixed type: RHS=float16 +#if KMP_HAVE_QUAD + +// Beginning of a definition (provides name, parameters, gebug trace) +// TYPE_ID - operands type and size (fixed*, fixed*u for signed, unsigned fixed) +// OP_ID - operation identifier (add, sub, mul, ...) +// TYPE - operands' type +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_CPT_REV_MIX(TYPE_ID,TYPE,OP_ID,BITS,OP,RTYPE_ID,RTYPE,LCK_ID,MASK,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT_MIX(TYPE_ID,OP_ID,TYPE,RTYPE_ID,RTYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT_REV(OP,GOMP_FLAG) \ + OP_CMPXCHG_CPT_REV(TYPE,BITS,OP) \ +} + +// ------------------------------------------------------------------------- +#define ATOMIC_CRITICAL_CPT_REV_MIX(TYPE_ID,TYPE,OP_ID,OP,RTYPE_ID,RTYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_CPT_MIX(TYPE_ID,OP_ID,TYPE,RTYPE_ID,RTYPE) \ + TYPE new_value; \ + OP_GOMP_CRITICAL_CPT_REV(OP,GOMP_FLAG) /* send assignment */ \ + OP_CRITICAL_CPT_REV(OP,LCK_ID) /* send assignment */ \ +} + +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed1, char, sub_cpt_rev, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed1u, uchar, sub_cpt_rev, 8, -, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed1, char, div_cpt_rev, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_div_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed1u, uchar, div_cpt_rev, 8, /, fp, _Quad, 1i, 0, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1u_div_cpt_rev_fp + +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed2, short, sub_cpt_rev, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed2u, ushort, sub_cpt_rev, 16, -, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed2, short, div_cpt_rev, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_div_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed2u, ushort, div_cpt_rev, 16, /, fp, _Quad, 2i, 1, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2u_div_cpt_rev_fp + +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed4, kmp_int32, sub_cpt_rev, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed4u, kmp_uint32, sub_cpt_rev, 32, -, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed4, kmp_int32, div_cpt_rev, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4_div_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed4u, kmp_uint32, div_cpt_rev, 32, /, fp, _Quad, 4i, 3, 0 ) // __kmpc_atomic_fixed4u_div_cpt_rev_fp + +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed8, kmp_int64, sub_cpt_rev, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed8u, kmp_uint64, sub_cpt_rev, 64, -, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed8, kmp_int64, div_cpt_rev, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_div_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( fixed8u, kmp_uint64, div_cpt_rev, 64, /, fp, _Quad, 8i, 7, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8u_div_cpt_rev_fp + +ATOMIC_CMPXCHG_CPT_REV_MIX( float4, kmp_real32, sub_cpt_rev, 32, -, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( float4, kmp_real32, div_cpt_rev, 32, /, fp, _Quad, 4r, 3, KMP_ARCH_X86 ) // __kmpc_atomic_float4_div_cpt_rev_fp + +ATOMIC_CMPXCHG_CPT_REV_MIX( float8, kmp_real64, sub_cpt_rev, 64, -, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_sub_cpt_rev_fp +ATOMIC_CMPXCHG_CPT_REV_MIX( float8, kmp_real64, div_cpt_rev, 64, /, fp, _Quad, 8r, 7, KMP_ARCH_X86 ) // __kmpc_atomic_float8_div_cpt_rev_fp + +ATOMIC_CRITICAL_CPT_REV_MIX( float10, long double, sub_cpt_rev, -, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_sub_cpt_rev_fp +ATOMIC_CRITICAL_CPT_REV_MIX( float10, long double, div_cpt_rev, /, fp, _Quad, 10r, 1 ) // __kmpc_atomic_float10_div_cpt_rev_fp + +#endif //KMP_HAVE_QUAD + + +// OpenMP 4.0 Capture-write (swap): {v = x; x = expr;} + +#define ATOMIC_BEGIN_SWP(TYPE_ID,TYPE) \ +TYPE __kmpc_atomic_##TYPE_ID##_swp( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_swp: T#%d\n", gtid )); + +#define CRITICAL_SWP(LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + old_value = (*lhs); \ + (*lhs) = rhs; \ + \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return old_value; + +// ------------------------------------------------------------------------ +#ifdef KMP_GOMP_COMPAT +#define GOMP_CRITICAL_SWP(FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + CRITICAL_SWP( 0 ); \ + } +#else +#define GOMP_CRITICAL_SWP(FLAG) +#endif /* KMP_GOMP_COMPAT */ + + +#define ATOMIC_XCHG_SWP(TYPE_ID,TYPE,BITS,GOMP_FLAG) \ +ATOMIC_BEGIN_SWP(TYPE_ID,TYPE) \ + TYPE old_value; \ + GOMP_CRITICAL_SWP(GOMP_FLAG) \ + old_value = KMP_XCHG_FIXED##BITS( lhs, rhs ); \ + return old_value; \ +} +// ------------------------------------------------------------------------ +#define ATOMIC_XCHG_FLOAT_SWP(TYPE_ID,TYPE,BITS,GOMP_FLAG) \ +ATOMIC_BEGIN_SWP(TYPE_ID,TYPE) \ + TYPE old_value; \ + GOMP_CRITICAL_SWP(GOMP_FLAG) \ + old_value = KMP_XCHG_REAL##BITS( lhs, rhs ); \ + return old_value; \ +} + +// ------------------------------------------------------------------------ +#define CMPXCHG_SWP(TYPE,BITS) \ + { \ + TYPE KMP_ATOMIC_VOLATILE temp_val; \ + TYPE old_value, new_value; \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs; \ + while ( ! KMP_COMPARE_AND_STORE_ACQ##BITS( (kmp_int##BITS *) lhs, \ + *VOLATILE_CAST(kmp_int##BITS *) &old_value, \ + *VOLATILE_CAST(kmp_int##BITS *) &new_value ) ) \ + { \ + KMP_CPU_PAUSE(); \ + \ + temp_val = *lhs; \ + old_value = temp_val; \ + new_value = rhs; \ + } \ + return old_value; \ + } + +// ------------------------------------------------------------------------- +#define ATOMIC_CMPXCHG_SWP(TYPE_ID,TYPE,BITS,GOMP_FLAG) \ +ATOMIC_BEGIN_SWP(TYPE_ID,TYPE) \ + TYPE old_value; \ + GOMP_CRITICAL_SWP(GOMP_FLAG) \ + CMPXCHG_SWP(TYPE,BITS) \ +} + +ATOMIC_XCHG_SWP( fixed1, kmp_int8, 8, KMP_ARCH_X86 ) // __kmpc_atomic_fixed1_swp +ATOMIC_XCHG_SWP( fixed2, kmp_int16, 16, KMP_ARCH_X86 ) // __kmpc_atomic_fixed2_swp +ATOMIC_XCHG_SWP( fixed4, kmp_int32, 32, KMP_ARCH_X86 ) // __kmpc_atomic_fixed4_swp + +ATOMIC_XCHG_FLOAT_SWP( float4, kmp_real32, 32, KMP_ARCH_X86 ) // __kmpc_atomic_float4_swp + +#if ( KMP_ARCH_X86 ) + ATOMIC_CMPXCHG_SWP( fixed8, kmp_int64, 64, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_swp + ATOMIC_CMPXCHG_SWP( float8, kmp_real64, 64, KMP_ARCH_X86 ) // __kmpc_atomic_float8_swp +#else + ATOMIC_XCHG_SWP( fixed8, kmp_int64, 64, KMP_ARCH_X86 ) // __kmpc_atomic_fixed8_swp + ATOMIC_XCHG_FLOAT_SWP( float8, kmp_real64, 64, KMP_ARCH_X86 ) // __kmpc_atomic_float8_swp +#endif + +// ------------------------------------------------------------------------ +// Routines for Extended types: long double, _Quad, complex flavours (use critical section) +#define ATOMIC_CRITICAL_SWP(TYPE_ID,TYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_SWP(TYPE_ID,TYPE) \ + TYPE old_value; \ + GOMP_CRITICAL_SWP(GOMP_FLAG) \ + CRITICAL_SWP(LCK_ID) \ +} + +// ------------------------------------------------------------------------ + +// !!! TODO: check if we need to return void for cmplx4 routines +// Workaround for cmplx4. Regular routines with return value don't work +// on Win_32e. Let's return captured values through the additional parameter. + +#define ATOMIC_BEGIN_SWP_WRK(TYPE_ID,TYPE) \ +void __kmpc_atomic_##TYPE_ID##_swp( ident_t *id_ref, int gtid, TYPE * lhs, TYPE rhs, TYPE * out ) \ +{ \ + KMP_DEBUG_ASSERT( __kmp_init_serial ); \ + KA_TRACE(100,("__kmpc_atomic_" #TYPE_ID "_swp: T#%d\n", gtid )); + + +#define CRITICAL_SWP_WRK(LCK_ID) \ + __kmp_acquire_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + \ + tmp = (*lhs); \ + (*lhs) = (rhs); \ + (*out) = tmp; \ + __kmp_release_atomic_lock( & ATOMIC_LOCK##LCK_ID, gtid ); \ + return; + +// ------------------------------------------------------------------------ + +#ifdef KMP_GOMP_COMPAT +#define GOMP_CRITICAL_SWP_WRK(FLAG) \ + if ( (FLAG) && (__kmp_atomic_mode == 2) ) { \ + KMP_CHECK_GTID; \ + CRITICAL_SWP_WRK( 0 ); \ + } +#else +#define GOMP_CRITICAL_SWP_WRK(FLAG) +#endif /* KMP_GOMP_COMPAT */ +// ------------------------------------------------------------------------ + +#define ATOMIC_CRITICAL_SWP_WRK(TYPE_ID, TYPE,LCK_ID,GOMP_FLAG) \ +ATOMIC_BEGIN_SWP_WRK(TYPE_ID,TYPE) \ + TYPE tmp; \ + GOMP_CRITICAL_SWP_WRK(GOMP_FLAG) \ + CRITICAL_SWP_WRK(LCK_ID) \ +} +// The end of workaround for cmplx4 + + +ATOMIC_CRITICAL_SWP( float10, long double, 10r, 1 ) // __kmpc_atomic_float10_swp +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_SWP( float16, QUAD_LEGACY, 16r, 1 ) // __kmpc_atomic_float16_swp +#endif +// cmplx4 routine to return void +ATOMIC_CRITICAL_SWP_WRK( cmplx4, kmp_cmplx32, 8c, 1 ) // __kmpc_atomic_cmplx4_swp + +//ATOMIC_CRITICAL_SWP( cmplx4, kmp_cmplx32, 8c, 1 ) // __kmpc_atomic_cmplx4_swp + + +ATOMIC_CRITICAL_SWP( cmplx8, kmp_cmplx64, 16c, 1 ) // __kmpc_atomic_cmplx8_swp +ATOMIC_CRITICAL_SWP( cmplx10, kmp_cmplx80, 20c, 1 ) // __kmpc_atomic_cmplx10_swp +#if KMP_HAVE_QUAD +ATOMIC_CRITICAL_SWP( cmplx16, CPLX128_LEG, 32c, 1 ) // __kmpc_atomic_cmplx16_swp +#if ( KMP_ARCH_X86 ) + ATOMIC_CRITICAL_SWP( float16_a16, Quad_a16_t, 16r, 1 ) // __kmpc_atomic_float16_a16_swp + ATOMIC_CRITICAL_SWP( cmplx16_a16, kmp_cmplx128_a16_t, 32c, 1 ) // __kmpc_atomic_cmplx16_a16_swp +#endif +#endif + + +// End of OpenMP 4.0 Capture + +#endif //OMP_40_ENABLED + +#endif //KMP_ARCH_X86 || KMP_ARCH_X86_64 + + +#undef OP_CRITICAL + +/* ------------------------------------------------------------------------ */ +/* Generic atomic routines */ +/* ------------------------------------------------------------------------ */ + +void +__kmpc_atomic_1( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + + if ( +#if KMP_ARCH_X86 && defined(KMP_GOMP_COMPAT) + FALSE /* must use lock */ +#else + TRUE +#endif + ) + { + kmp_int8 old_value, new_value; + + old_value = *(kmp_int8 *) lhs; + (*f)( &new_value, &old_value, rhs ); + + /* TODO: Should this be acquire or release? */ + while ( ! KMP_COMPARE_AND_STORE_ACQ8 ( (kmp_int8 *) lhs, + *(kmp_int8 *) &old_value, *(kmp_int8 *) &new_value ) ) + { + KMP_CPU_PAUSE(); + + old_value = *(kmp_int8 *) lhs; + (*f)( &new_value, &old_value, rhs ); + } + + return; + } + else { + // + // All 1-byte data is of integer data type. + // + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_1i, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_1i, gtid ); + } +} + +void +__kmpc_atomic_2( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + if ( +#if KMP_ARCH_X86 && defined(KMP_GOMP_COMPAT) + FALSE /* must use lock */ +#elif KMP_ARCH_X86 || KMP_ARCH_X86_64 + TRUE /* no alignment problems */ +#else + ! ( (kmp_uintptr_t) lhs & 0x1) /* make sure address is 2-byte aligned */ +#endif + ) + { + kmp_int16 old_value, new_value; + + old_value = *(kmp_int16 *) lhs; + (*f)( &new_value, &old_value, rhs ); + + /* TODO: Should this be acquire or release? */ + while ( ! KMP_COMPARE_AND_STORE_ACQ16 ( (kmp_int16 *) lhs, + *(kmp_int16 *) &old_value, *(kmp_int16 *) &new_value ) ) + { + KMP_CPU_PAUSE(); + + old_value = *(kmp_int16 *) lhs; + (*f)( &new_value, &old_value, rhs ); + } + + return; + } + else { + // + // All 2-byte data is of integer data type. + // + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_2i, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_2i, gtid ); + } +} + +void +__kmpc_atomic_4( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + + if ( + // + // FIXME: On IA-32 architecture, gcc uses cmpxchg only for 4-byte ints. + // Gomp compatibility is broken if this routine is called for floats. + // +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + TRUE /* no alignment problems */ +#else + ! ( (kmp_uintptr_t) lhs & 0x3) /* make sure address is 4-byte aligned */ +#endif + ) + { + kmp_int32 old_value, new_value; + + old_value = *(kmp_int32 *) lhs; + (*f)( &new_value, &old_value, rhs ); + + /* TODO: Should this be acquire or release? */ + while ( ! KMP_COMPARE_AND_STORE_ACQ32 ( (kmp_int32 *) lhs, + *(kmp_int32 *) &old_value, *(kmp_int32 *) &new_value ) ) + { + KMP_CPU_PAUSE(); + + old_value = *(kmp_int32 *) lhs; + (*f)( &new_value, &old_value, rhs ); + } + + return; + } + else { + // + // Use __kmp_atomic_lock_4i for all 4-byte data, + // even if it isn't of integer data type. + // + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_4i, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_4i, gtid ); + } +} + +void +__kmpc_atomic_8( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + if ( + +#if KMP_ARCH_X86 && defined(KMP_GOMP_COMPAT) + FALSE /* must use lock */ +#elif KMP_ARCH_X86 || KMP_ARCH_X86_64 + TRUE /* no alignment problems */ +#else + ! ( (kmp_uintptr_t) lhs & 0x7) /* make sure address is 8-byte aligned */ +#endif + ) + { + kmp_int64 old_value, new_value; + + old_value = *(kmp_int64 *) lhs; + (*f)( &new_value, &old_value, rhs ); + /* TODO: Should this be acquire or release? */ + while ( ! KMP_COMPARE_AND_STORE_ACQ64 ( (kmp_int64 *) lhs, + *(kmp_int64 *) &old_value, + *(kmp_int64 *) &new_value ) ) + { + KMP_CPU_PAUSE(); + + old_value = *(kmp_int64 *) lhs; + (*f)( &new_value, &old_value, rhs ); + } + + return; + } else { + // + // Use __kmp_atomic_lock_8i for all 8-byte data, + // even if it isn't of integer data type. + // + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_8i, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_8i, gtid ); + } +} + +void +__kmpc_atomic_10( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_10r, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_10r, gtid ); +} + +void +__kmpc_atomic_16( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_16c, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_16c, gtid ); +} + +void +__kmpc_atomic_20( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_20c, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_20c, gtid ); +} + +void +__kmpc_atomic_32( ident_t *id_ref, int gtid, void* lhs, void* rhs, void (*f)( void *, void *, void * ) ) +{ + KMP_DEBUG_ASSERT( __kmp_init_serial ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_acquire_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_acquire_atomic_lock( & __kmp_atomic_lock_32c, gtid ); + + (*f)( lhs, lhs, rhs ); + +#ifdef KMP_GOMP_COMPAT + if ( __kmp_atomic_mode == 2 ) { + __kmp_release_atomic_lock( & __kmp_atomic_lock, gtid ); + } + else +#endif /* KMP_GOMP_COMPAT */ + __kmp_release_atomic_lock( & __kmp_atomic_lock_32c, gtid ); +} + +// AC: same two routines as GOMP_atomic_start/end, but will be called by our compiler +// duplicated in order to not use 3-party names in pure Intel code +// TODO: consider adding GTID parameter after consultation with Ernesto/Xinmin. +void +__kmpc_atomic_start(void) +{ + int gtid = __kmp_entry_gtid(); + KA_TRACE(20, ("__kmpc_atomic_start: T#%d\n", gtid)); + __kmp_acquire_atomic_lock(&__kmp_atomic_lock, gtid); +} + + +void +__kmpc_atomic_end(void) +{ + int gtid = __kmp_get_gtid(); + KA_TRACE(20, ("__kmpc_atomic_end: T#%d\n", gtid)); + __kmp_release_atomic_lock(&__kmp_atomic_lock, gtid); +} + +/* ------------------------------------------------------------------------ */ +/* ------------------------------------------------------------------------ */ +/*! +@} +*/ + +// end of file |
