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#ifndef Py_INTERNAL_CODE_H #define Py_INTERNAL_CODE_H #ifdef __cplusplus extern "C" { #endif /* PEP 659 * Specialization and quickening structs and helper functions */ // Inline caches. If you change the number of cache entries for an instruction, // you must *also* update the number of cache entries in Lib/opcode.py and bump // the magic number in Lib/importlib/_bootstrap_external.py! #define CACHE_ENTRIES(cache) (sizeof(cache)/sizeof(_Py_CODEUNIT)) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT index; _Py_CODEUNIT module_keys_version[2]; _Py_CODEUNIT builtin_keys_version; } _PyLoadGlobalCache; #define INLINE_CACHE_ENTRIES_LOAD_GLOBAL CACHE_ENTRIES(_PyLoadGlobalCache) typedef struct { _Py_CODEUNIT counter; } _PyBinaryOpCache; #define INLINE_CACHE_ENTRIES_BINARY_OP CACHE_ENTRIES(_PyBinaryOpCache) typedef struct { _Py_CODEUNIT counter; } _PyUnpackSequenceCache; #define INLINE_CACHE_ENTRIES_UNPACK_SEQUENCE \ CACHE_ENTRIES(_PyUnpackSequenceCache) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT mask; } _PyCompareOpCache; #define INLINE_CACHE_ENTRIES_COMPARE_OP CACHE_ENTRIES(_PyCompareOpCache) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT type_version[2]; _Py_CODEUNIT func_version; } _PyBinarySubscrCache; #define INLINE_CACHE_ENTRIES_BINARY_SUBSCR CACHE_ENTRIES(_PyBinarySubscrCache) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT version[2]; _Py_CODEUNIT index; } _PyAttrCache; #define INLINE_CACHE_ENTRIES_LOAD_ATTR CACHE_ENTRIES(_PyAttrCache) #define INLINE_CACHE_ENTRIES_STORE_ATTR CACHE_ENTRIES(_PyAttrCache) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT type_version[2]; _Py_CODEUNIT dict_offset; _Py_CODEUNIT keys_version[2]; _Py_CODEUNIT descr[4]; } _PyLoadMethodCache; #define INLINE_CACHE_ENTRIES_LOAD_METHOD CACHE_ENTRIES(_PyLoadMethodCache) typedef struct { _Py_CODEUNIT counter; _Py_CODEUNIT func_version[2]; _Py_CODEUNIT min_args; } _PyCallCache; #define INLINE_CACHE_ENTRIES_CALL CACHE_ENTRIES(_PyCallCache) typedef struct { _Py_CODEUNIT counter; } _PyPrecallCache; #define INLINE_CACHE_ENTRIES_PRECALL CACHE_ENTRIES(_PyPrecallCache) typedef struct { _Py_CODEUNIT counter; } _PyStoreSubscrCache; #define INLINE_CACHE_ENTRIES_STORE_SUBSCR CACHE_ENTRIES(_PyStoreSubscrCache) #define QUICKENING_WARMUP_DELAY 8 /* We want to compare to zero for efficiency, so we offset values accordingly */ #define QUICKENING_INITIAL_WARMUP_VALUE (-QUICKENING_WARMUP_DELAY) void _PyCode_Quicken(PyCodeObject *code); static inline void _PyCode_Warmup(PyCodeObject *code) { if (code->co_warmup != 0) { code->co_warmup++; if (code->co_warmup == 0) { _PyCode_Quicken(code); } } } extern uint8_t _PyOpcode_Adaptive[256]; extern Py_ssize_t _Py_QuickenedCount; // Borrowed references to common callables: struct callable_cache { PyObject *isinstance; PyObject *len; PyObject *list_append; }; /* "Locals plus" for a code object is the set of locals + cell vars + * free vars. This relates to variable names as well as offsets into * the "fast locals" storage array of execution frames. The compiler * builds the list of names, their offsets, and the corresponding * kind of local. * * Those kinds represent the source of the initial value and the * variable's scope (as related to closures). A "local" is an * argument or other variable defined in the current scope. A "free" * variable is one that is defined in an outer scope and comes from * the function's closure. A "cell" variable is a local that escapes * into an inner function as part of a closure, and thus must be * wrapped in a cell. Any "local" can also be a "cell", but the * "free" kind is mutually exclusive with both. */ // Note that these all fit within a byte, as do combinations. // Later, we will use the smaller numbers to differentiate the different // kinds of locals (e.g. pos-only arg, varkwargs, local-only). #define CO_FAST_LOCAL 0x20 #define CO_FAST_CELL 0x40 #define CO_FAST_FREE 0x80 typedef unsigned char _PyLocals_Kind; static inline _PyLocals_Kind _PyLocals_GetKind(PyObject *kinds, int i) { assert(PyBytes_Check(kinds)); assert(0 <= i && i < PyBytes_GET_SIZE(kinds)); char *ptr = PyBytes_AS_STRING(kinds); return (_PyLocals_Kind)(ptr[i]); } static inline void _PyLocals_SetKind(PyObject *kinds, int i, _PyLocals_Kind kind) { assert(PyBytes_Check(kinds)); assert(0 <= i && i < PyBytes_GET_SIZE(kinds)); char *ptr = PyBytes_AS_STRING(kinds); ptr[i] = (char) kind; } struct _PyCodeConstructor { /* metadata */ PyObject *filename; PyObject *name; PyObject *qualname; int flags; /* the code */ PyObject *code; int firstlineno; PyObject *linetable; /* used by the code */ PyObject *consts; PyObject *names; /* mapping frame offsets to information */ PyObject *localsplusnames; // Tuple of strings PyObject *localspluskinds; // Bytes object, one byte per variable /* args (within varnames) */ int argcount; int posonlyargcount; // XXX Replace argcount with posorkwargcount (argcount - posonlyargcount). int kwonlyargcount; /* needed to create the frame */ int stacksize; /* used by the eval loop */ PyObject *exceptiontable; }; // Using an "arguments struct" like this is helpful for maintainability // in a case such as this with many parameters. It does bear a risk: // if the struct changes and callers are not updated properly then the // compiler will not catch problems (like a missing argument). This can // cause hard-to-debug problems. The risk is mitigated by the use of // check_code() in codeobject.c. However, we may decide to switch // back to a regular function signature. Regardless, this approach // wouldn't be appropriate if this weren't a strictly internal API. // (See the comments in https://github.com/python/cpython/pull/26258.) PyAPI_FUNC(int) _PyCode_Validate(struct _PyCodeConstructor *); PyAPI_FUNC(PyCodeObject *) _PyCode_New(struct _PyCodeConstructor *); /* Private API */ /* Getters for internal PyCodeObject data. */ extern PyObject* _PyCode_GetVarnames(PyCodeObject *); extern PyObject* _PyCode_GetCellvars(PyCodeObject *); extern PyObject* _PyCode_GetFreevars(PyCodeObject *); extern PyObject* _PyCode_GetCode(PyCodeObject *); /** API for initializing the line number tables. */ extern int _PyCode_InitAddressRange(PyCodeObject* co, PyCodeAddressRange *bounds); /** Out of process API for initializing the location table. */ extern void _PyLineTable_InitAddressRange( const char *linetable, Py_ssize_t length, int firstlineno, PyCodeAddressRange *range); /** API for traversing the line number table. */ extern int _PyLineTable_NextAddressRange(PyCodeAddressRange *range); extern int _PyLineTable_PreviousAddressRange(PyCodeAddressRange *range); /* Specialization functions */ extern int _Py_Specialize_LoadAttr(PyObject *owner, _Py_CODEUNIT *instr, PyObject *name); extern int _Py_Specialize_StoreAttr(PyObject *owner, _Py_CODEUNIT *instr, PyObject *name); extern int _Py_Specialize_LoadGlobal(PyObject *globals, PyObject *builtins, _Py_CODEUNIT *instr, PyObject *name); extern int _Py_Specialize_LoadMethod(PyObject *owner, _Py_CODEUNIT *instr, PyObject *name); extern int _Py_Specialize_BinarySubscr(PyObject *sub, PyObject *container, _Py_CODEUNIT *instr); extern int _Py_Specialize_StoreSubscr(PyObject *container, PyObject *sub, _Py_CODEUNIT *instr); extern int _Py_Specialize_Call(PyObject *callable, _Py_CODEUNIT *instr, int nargs, PyObject *kwnames); extern int _Py_Specialize_Precall(PyObject *callable, _Py_CODEUNIT *instr, int nargs, PyObject *kwnames, int oparg); extern void _Py_Specialize_BinaryOp(PyObject *lhs, PyObject *rhs, _Py_CODEUNIT *instr, int oparg, PyObject **locals); extern void _Py_Specialize_CompareOp(PyObject *lhs, PyObject *rhs, _Py_CODEUNIT *instr, int oparg); extern void _Py_Specialize_UnpackSequence(PyObject *seq, _Py_CODEUNIT *instr, int oparg); /* Deallocator function for static codeobjects used in deepfreeze.py */ extern void _PyStaticCode_Dealloc(PyCodeObject *co); /* Function to intern strings of codeobjects */ extern int _PyStaticCode_InternStrings(PyCodeObject *co); #ifdef Py_STATS #define SPECIALIZATION_FAILURE_KINDS 30 typedef struct _specialization_stats { uint64_t success; uint64_t failure; uint64_t hit; uint64_t deferred; uint64_t miss; uint64_t deopt; uint64_t failure_kinds[SPECIALIZATION_FAILURE_KINDS]; } SpecializationStats; typedef struct _opcode_stats { SpecializationStats specialization; uint64_t execution_count; uint64_t pair_count[256]; } OpcodeStats; typedef struct _call_stats { uint64_t inlined_py_calls; uint64_t pyeval_calls; uint64_t frames_pushed; uint64_t frame_objects_created; } CallStats; typedef struct _object_stats { uint64_t allocations; uint64_t allocations512; uint64_t allocations4k; uint64_t allocations_big; uint64_t frees; uint64_t to_freelist; uint64_t from_freelist; uint64_t new_values; uint64_t dict_materialized_on_request; uint64_t dict_materialized_new_key; uint64_t dict_materialized_too_big; uint64_t dict_materialized_str_subclass; } ObjectStats; typedef struct _stats { OpcodeStats opcode_stats[256]; CallStats call_stats; ObjectStats object_stats; } PyStats; extern PyStats _py_stats; #define STAT_INC(opname, name) _py_stats.opcode_stats[opname].specialization.name++ #define STAT_DEC(opname, name) _py_stats.opcode_stats[opname].specialization.name-- #define OPCODE_EXE_INC(opname) _py_stats.opcode_stats[opname].execution_count++ #define CALL_STAT_INC(name) _py_stats.call_stats.name++ #define OBJECT_STAT_INC(name) _py_stats.object_stats.name++ #define OBJECT_STAT_INC_COND(name, cond) \ do { if (cond) _py_stats.object_stats.name++; } while (0) extern void _Py_PrintSpecializationStats(int to_file); // Used by the _opcode extension which is built as a shared library PyAPI_FUNC(PyObject*) _Py_GetSpecializationStats(void); #else #define STAT_INC(opname, name) ((void)0) #define STAT_DEC(opname, name) ((void)0) #define OPCODE_EXE_INC(opname) ((void)0) #define CALL_STAT_INC(name) ((void)0) #define OBJECT_STAT_INC(name) ((void)0) #define OBJECT_STAT_INC_COND(name, cond) ((void)0) #endif // !Py_STATS // Cache values are only valid in memory, so use native endianness. #ifdef WORDS_BIGENDIAN static inline void write_u32(uint16_t *p, uint32_t val) { p[0] = (uint16_t)(val >> 16); p[1] = (uint16_t)(val >> 0); } static inline void write_u64(uint16_t *p, uint64_t val) { p[0] = (uint16_t)(val >> 48); p[1] = (uint16_t)(val >> 32); p[2] = (uint16_t)(val >> 16); p[3] = (uint16_t)(val >> 0); } static inline uint32_t read_u32(uint16_t *p) { uint32_t val = 0; val |= (uint32_t)p[0] << 16; val |= (uint32_t)p[1] << 0; return val; } static inline uint64_t read_u64(uint16_t *p) { uint64_t val = 0; val |= (uint64_t)p[0] << 48; val |= (uint64_t)p[1] << 32; val |= (uint64_t)p[2] << 16; val |= (uint64_t)p[3] << 0; return val; } #else static inline void write_u32(uint16_t *p, uint32_t val) { p[0] = (uint16_t)(val >> 0); p[1] = (uint16_t)(val >> 16); } static inline void write_u64(uint16_t *p, uint64_t val) { p[0] = (uint16_t)(val >> 0); p[1] = (uint16_t)(val >> 16); p[2] = (uint16_t)(val >> 32); p[3] = (uint16_t)(val >> 48); } static inline uint32_t read_u32(uint16_t *p) { uint32_t val = 0; val |= (uint32_t)p[0] << 0; val |= (uint32_t)p[1] << 16; return val; } static inline uint64_t read_u64(uint16_t *p) { uint64_t val = 0; val |= (uint64_t)p[0] << 0; val |= (uint64_t)p[1] << 16; val |= (uint64_t)p[2] << 32; val |= (uint64_t)p[3] << 48; return val; } #endif static inline void write_obj(uint16_t *p, PyObject *obj) { uintptr_t val = (uintptr_t)obj; #if SIZEOF_VOID_P == 8 write_u64(p, val); #elif SIZEOF_VOID_P == 4 write_u32(p, val); #else #error "SIZEOF_VOID_P must be 4 or 8" #endif } static inline PyObject * read_obj(uint16_t *p) { uintptr_t val; #if SIZEOF_VOID_P == 8 val = read_u64(p); #elif SIZEOF_VOID_P == 4 val = read_u32(p); #else #error "SIZEOF_VOID_P must be 4 or 8" #endif return (PyObject *)val; } /* See Objects/exception_handling_notes.txt for details. */ static inline unsigned char * parse_varint(unsigned char *p, int *result) { int val = p[0] & 63; while (p[0] & 64) { p++; val = (val << 6) | (p[0] & 63); } *result = val; return p+1; } static inline int write_varint(uint8_t *ptr, unsigned int val) { int written = 1; while (val >= 64) { *ptr++ = 64 | (val & 63); val >>= 6; written++; } *ptr = val; return written; } static inline int write_signed_varint(uint8_t *ptr, int val) { if (val < 0) { val = ((-val)<<1) | 1; } else { val = val << 1; } return write_varint(ptr, val); } static inline int write_location_entry_start(uint8_t *ptr, int code, int length) { assert((code & 15) == code); *ptr = 128 | (code << 3) | (length - 1); return 1; } /** Counters * The first 16-bit value in each inline cache is a counter. * When counting misses, the counter is treated as a simple unsigned value. * * When counting executions until the next specialization attempt, * exponential backoff is used to reduce the number of specialization failures. * The high 12 bits store the counter, the low 4 bits store the backoff exponent. * On a specialization failure, the backoff exponent is incremented and the * counter set to (2**backoff - 1). * Backoff == 6 -> starting counter == 63, backoff == 10 -> starting counter == 1023. */ /* With a 16-bit counter, we have 12 bits for the counter value, and 4 bits for the backoff */ #define ADAPTIVE_BACKOFF_BITS 4 /* The initial counter value is 31 == 2**ADAPTIVE_BACKOFF_START - 1 */ #define ADAPTIVE_BACKOFF_START 5 #define MAX_BACKOFF_VALUE (16 - ADAPTIVE_BACKOFF_BITS) static inline uint16_t adaptive_counter_bits(int value, int backoff) { return (value << ADAPTIVE_BACKOFF_BITS) | (backoff & ((1<<ADAPTIVE_BACKOFF_BITS)-1)); } static inline uint16_t adaptive_counter_start(void) { unsigned int value = (1 << ADAPTIVE_BACKOFF_START) - 1; return adaptive_counter_bits(value, ADAPTIVE_BACKOFF_START); } static inline uint16_t adaptive_counter_backoff(uint16_t counter) { unsigned int backoff = counter & ((1<<ADAPTIVE_BACKOFF_BITS)-1); backoff++; if (backoff > MAX_BACKOFF_VALUE) { backoff = MAX_BACKOFF_VALUE; } unsigned int value = (1 << backoff) - 1; return adaptive_counter_bits(value, backoff); } /* Line array cache for tracing */ extern int _PyCode_CreateLineArray(PyCodeObject *co); static inline int _PyCode_InitLineArray(PyCodeObject *co) { if (co->_co_linearray) { return 0; } return _PyCode_CreateLineArray(co); } static inline int _PyCode_LineNumberFromArray(PyCodeObject *co, int index) { assert(co->_co_linearray != NULL); assert(index >= 0); assert(index < Py_SIZE(co)); if (co->_co_linearray_entry_size == 2) { return ((int16_t *)co->_co_linearray)[index]; } else { assert(co->_co_linearray_entry_size == 4); return ((int32_t *)co->_co_linearray)[index]; } } #ifdef __cplusplus } #endif #endif /* !Py_INTERNAL_CODE_H */