gtn/.venv/Lib/site-packages/mypyc/primitives/int_ops.py

"""Arbitrary-precision integer primitive ops.

These mostly operate on (usually) unboxed integers that use a tagged pointer
representation (CPyTagged) and correspond to the Python 'int' type.

See also the documentation for mypyc.rtypes.int_rprimitive.

Use mypyc.ir.ops.IntOp for operations on fixed-width/C integers.
"""

from __future__ import annotations

from typing import NamedTuple

from mypyc.ir.ops import ERR_ALWAYS, ERR_MAGIC, ERR_MAGIC_OVERLAPPING, ERR_NEVER, ComparisonOp
from mypyc.ir.rtypes import (
    RType,
    bit_rprimitive,
    bool_rprimitive,
    c_pyssize_t_rprimitive,
    float_rprimitive,
    int16_rprimitive,
    int32_rprimitive,
    int64_rprimitive,
    int_rprimitive,
    object_rprimitive,
    str_rprimitive,
    void_rtype,
)
from mypyc.primitives.registry import (
    CFunctionDescription,
    binary_op,
    custom_op,
    function_op,
    load_address_op,
    unary_op,
)

# Constructors for builtins.int and native int types have the same behavior. In
# interpreted mode, native int types are just aliases to 'int'.
for int_name in (
    "builtins.int",
    "mypy_extensions.i64",
    "mypy_extensions.i32",
    "mypy_extensions.i16",
    "mypy_extensions.u8",
):
    # These int constructors produce object_rprimitives that then need to be unboxed
    # I guess unboxing ourselves would save a check and branch though?

    # Get the type object for 'builtins.int' or a native int type.
    # For ordinary calls to int() we use a load_address to the type.
    # Native ints don't have a separate type object -- we just use 'builtins.int'.
    load_address_op(name=int_name, type=object_rprimitive, src="PyLong_Type")

    # int(float). We could do a bit better directly.
    function_op(
        name=int_name,
        arg_types=[float_rprimitive],
        return_type=int_rprimitive,
        c_function_name="CPyTagged_FromFloat",
        error_kind=ERR_MAGIC,
    )

    # int(string)
    function_op(
        name=int_name,
        arg_types=[str_rprimitive],
        return_type=object_rprimitive,
        c_function_name="CPyLong_FromStr",
        error_kind=ERR_MAGIC,
    )

    # int(string, base)
    function_op(
        name=int_name,
        arg_types=[str_rprimitive, int_rprimitive],
        return_type=object_rprimitive,
        c_function_name="CPyLong_FromStrWithBase",
        error_kind=ERR_MAGIC,
    )

# str(int)
int_to_str_op = function_op(
    name="builtins.str",
    arg_types=[int_rprimitive],
    return_type=str_rprimitive,
    c_function_name="CPyTagged_Str",
    error_kind=ERR_MAGIC,
    priority=2,
)

# We need a specialization for str on bools also since the int one is wrong...
function_op(
    name="builtins.str",
    arg_types=[bool_rprimitive],
    return_type=str_rprimitive,
    c_function_name="CPyBool_Str",
    error_kind=ERR_MAGIC,
    priority=3,
)


def int_binary_op(
    name: str,
    c_function_name: str,
    return_type: RType = int_rprimitive,
    error_kind: int = ERR_NEVER,
) -> None:
    binary_op(
        name=name,
        arg_types=[int_rprimitive, int_rprimitive],
        return_type=return_type,
        c_function_name=c_function_name,
        error_kind=error_kind,
    )


# Binary, unary and augmented assignment operations that operate on CPyTagged ints
# are implemented as C functions.

int_binary_op("+", "CPyTagged_Add")
int_binary_op("-", "CPyTagged_Subtract")
int_binary_op("*", "CPyTagged_Multiply")
int_binary_op("&", "CPyTagged_And")
int_binary_op("|", "CPyTagged_Or")
int_binary_op("^", "CPyTagged_Xor")
# Divide and remainder we honestly propagate errors from because they
# can raise ZeroDivisionError
int_binary_op("//", "CPyTagged_FloorDivide", error_kind=ERR_MAGIC)
int_binary_op("%", "CPyTagged_Remainder", error_kind=ERR_MAGIC)
# Negative shift counts raise an exception
int_binary_op(">>", "CPyTagged_Rshift", error_kind=ERR_MAGIC)
int_binary_op("<<", "CPyTagged_Lshift", error_kind=ERR_MAGIC)

int_binary_op(
    "/", "CPyTagged_TrueDivide", return_type=float_rprimitive, error_kind=ERR_MAGIC_OVERLAPPING
)

# This should work because assignment operators are parsed differently
# and the code in irbuild that handles it does the assignment
# regardless of whether or not the operator works in place anyway.
int_binary_op("+=", "CPyTagged_Add")
int_binary_op("-=", "CPyTagged_Subtract")
int_binary_op("*=", "CPyTagged_Multiply")
int_binary_op("&=", "CPyTagged_And")
int_binary_op("|=", "CPyTagged_Or")
int_binary_op("^=", "CPyTagged_Xor")
int_binary_op("//=", "CPyTagged_FloorDivide", error_kind=ERR_MAGIC)
int_binary_op("%=", "CPyTagged_Remainder", error_kind=ERR_MAGIC)
int_binary_op(">>=", "CPyTagged_Rshift", error_kind=ERR_MAGIC)
int_binary_op("<<=", "CPyTagged_Lshift", error_kind=ERR_MAGIC)


def int_unary_op(name: str, c_function_name: str) -> CFunctionDescription:
    return unary_op(
        name=name,
        arg_type=int_rprimitive,
        return_type=int_rprimitive,
        c_function_name=c_function_name,
        error_kind=ERR_NEVER,
    )


int_neg_op = int_unary_op("-", "CPyTagged_Negate")
int_invert_op = int_unary_op("~", "CPyTagged_Invert")


# Primitives related to integer comparison operations:


# Description for building int comparison ops
#
# Fields:
#   binary_op_variant: identify which IntOp to use when operands are short integers
#   c_func_description: the C function to call when operands are tagged integers
#   c_func_negated: whether to negate the C function call's result
#   c_func_swap_operands: whether to swap lhs and rhs when call the function
class IntComparisonOpDescription(NamedTuple):
    binary_op_variant: int
    c_func_description: CFunctionDescription
    c_func_negated: bool
    c_func_swap_operands: bool


# Equals operation on two boxed tagged integers
int_equal_ = custom_op(
    arg_types=[int_rprimitive, int_rprimitive],
    return_type=bit_rprimitive,
    c_function_name="CPyTagged_IsEq_",
    error_kind=ERR_NEVER,
)

# Less than operation on two boxed tagged integers
int_less_than_ = custom_op(
    arg_types=[int_rprimitive, int_rprimitive],
    return_type=bit_rprimitive,
    c_function_name="CPyTagged_IsLt_",
    error_kind=ERR_NEVER,
)

# Provide mapping from textual op to short int's op variant and boxed int's description.
# Note that these are not complete implementations and require extra IR.
int_comparison_op_mapping: dict[str, IntComparisonOpDescription] = {
    "==": IntComparisonOpDescription(ComparisonOp.EQ, int_equal_, False, False),
    "!=": IntComparisonOpDescription(ComparisonOp.NEQ, int_equal_, True, False),
    "<": IntComparisonOpDescription(ComparisonOp.SLT, int_less_than_, False, False),
    "<=": IntComparisonOpDescription(ComparisonOp.SLE, int_less_than_, True, True),
    ">": IntComparisonOpDescription(ComparisonOp.SGT, int_less_than_, False, True),
    ">=": IntComparisonOpDescription(ComparisonOp.SGE, int_less_than_, True, False),
}

int64_divide_op = custom_op(
    arg_types=[int64_rprimitive, int64_rprimitive],
    return_type=int64_rprimitive,
    c_function_name="CPyInt64_Divide",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int64_mod_op = custom_op(
    arg_types=[int64_rprimitive, int64_rprimitive],
    return_type=int64_rprimitive,
    c_function_name="CPyInt64_Remainder",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int32_divide_op = custom_op(
    arg_types=[int32_rprimitive, int32_rprimitive],
    return_type=int32_rprimitive,
    c_function_name="CPyInt32_Divide",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int32_mod_op = custom_op(
    arg_types=[int32_rprimitive, int32_rprimitive],
    return_type=int32_rprimitive,
    c_function_name="CPyInt32_Remainder",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int16_divide_op = custom_op(
    arg_types=[int16_rprimitive, int16_rprimitive],
    return_type=int16_rprimitive,
    c_function_name="CPyInt16_Divide",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int16_mod_op = custom_op(
    arg_types=[int16_rprimitive, int16_rprimitive],
    return_type=int16_rprimitive,
    c_function_name="CPyInt16_Remainder",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

# Convert tagged int (as PyObject *) to i64
int_to_int64_op = custom_op(
    arg_types=[object_rprimitive],
    return_type=int64_rprimitive,
    c_function_name="CPyLong_AsInt64",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

ssize_t_to_int_op = custom_op(
    arg_types=[c_pyssize_t_rprimitive],
    return_type=int_rprimitive,
    c_function_name="CPyTagged_FromSsize_t",
    error_kind=ERR_MAGIC,
)

int64_to_int_op = custom_op(
    arg_types=[int64_rprimitive],
    return_type=int_rprimitive,
    c_function_name="CPyTagged_FromInt64",
    error_kind=ERR_MAGIC,
)

# Convert tagged int (as PyObject *) to i32
int_to_int32_op = custom_op(
    arg_types=[object_rprimitive],
    return_type=int32_rprimitive,
    c_function_name="CPyLong_AsInt32",
    error_kind=ERR_MAGIC_OVERLAPPING,
)

int32_overflow = custom_op(
    arg_types=[],
    return_type=void_rtype,
    c_function_name="CPyInt32_Overflow",
    error_kind=ERR_ALWAYS,
)

int16_overflow = custom_op(
    arg_types=[],
    return_type=void_rtype,
    c_function_name="CPyInt16_Overflow",
    error_kind=ERR_ALWAYS,
)

uint8_overflow = custom_op(
    arg_types=[],
    return_type=void_rtype,
    c_function_name="CPyUInt8_Overflow",
    error_kind=ERR_ALWAYS,
)
Ajout d'un environement de développement. Cela permet de ne pas avoir de problèmes de compatibilité car python est dans le git. 2023-10-26 13:33:03 +00:00			`"""Arbitrary-precision integer primitive ops.`

			`These mostly operate on (usually) unboxed integers that use a tagged pointer`
			`representation (CPyTagged) and correspond to the Python 'int' type.`

			`See also the documentation for mypyc.rtypes.int_rprimitive.`

			`Use mypyc.ir.ops.IntOp for operations on fixed-width/C integers.`
			`"""`

			`from __future__ import annotations`

			`from typing import NamedTuple`

			`from mypyc.ir.ops import ERR_ALWAYS, ERR_MAGIC, ERR_MAGIC_OVERLAPPING, ERR_NEVER, ComparisonOp`
			`from mypyc.ir.rtypes import (`
			`RType,`
			`bit_rprimitive,`
			`bool_rprimitive,`
			`c_pyssize_t_rprimitive,`
			`float_rprimitive,`
			`int16_rprimitive,`
			`int32_rprimitive,`
			`int64_rprimitive,`
			`int_rprimitive,`
			`object_rprimitive,`
			`str_rprimitive,`
			`void_rtype,`
			`)`
			`from mypyc.primitives.registry import (`
			`CFunctionDescription,`
			`binary_op,`
			`custom_op,`
			`function_op,`
			`load_address_op,`
			`unary_op,`
			`)`

			`# Constructors for builtins.int and native int types have the same behavior. In`
			`# interpreted mode, native int types are just aliases to 'int'.`
			`for int_name in (`
			`"builtins.int",`
			`"mypy_extensions.i64",`
			`"mypy_extensions.i32",`
			`"mypy_extensions.i16",`
			`"mypy_extensions.u8",`
			`):`
			`# These int constructors produce object_rprimitives that then need to be unboxed`
			`# I guess unboxing ourselves would save a check and branch though?`

			`# Get the type object for 'builtins.int' or a native int type.`
			`# For ordinary calls to int() we use a load_address to the type.`
			`# Native ints don't have a separate type object -- we just use 'builtins.int'.`
			`load_address_op(name=int_name, type=object_rprimitive, src="PyLong_Type")`

			`# int(float). We could do a bit better directly.`
			`function_op(`
			`name=int_name,`
			`arg_types=[float_rprimitive],`
			`return_type=int_rprimitive,`
			`c_function_name="CPyTagged_FromFloat",`
			`error_kind=ERR_MAGIC,`
			`)`

			`# int(string)`
			`function_op(`
			`name=int_name,`
			`arg_types=[str_rprimitive],`
			`return_type=object_rprimitive,`
			`c_function_name="CPyLong_FromStr",`
			`error_kind=ERR_MAGIC,`
			`)`

			`# int(string, base)`
			`function_op(`
			`name=int_name,`
			`arg_types=[str_rprimitive, int_rprimitive],`
			`return_type=object_rprimitive,`
			`c_function_name="CPyLong_FromStrWithBase",`
			`error_kind=ERR_MAGIC,`
			`)`

			`# str(int)`
			`int_to_str_op = function_op(`
			`name="builtins.str",`
			`arg_types=[int_rprimitive],`
			`return_type=str_rprimitive,`
			`c_function_name="CPyTagged_Str",`
			`error_kind=ERR_MAGIC,`
			`priority=2,`
			`)`

			`# We need a specialization for str on bools also since the int one is wrong...`
			`function_op(`
			`name="builtins.str",`
			`arg_types=[bool_rprimitive],`
			`return_type=str_rprimitive,`
			`c_function_name="CPyBool_Str",`
			`error_kind=ERR_MAGIC,`
			`priority=3,`
			`)`


			`def int_binary_op(`
			`name: str,`
			`c_function_name: str,`
			`return_type: RType = int_rprimitive,`
			`error_kind: int = ERR_NEVER,`
			`) -> None:`
			`binary_op(`
			`name=name,`
			`arg_types=[int_rprimitive, int_rprimitive],`
			`return_type=return_type,`
			`c_function_name=c_function_name,`
			`error_kind=error_kind,`
			`)`


			`# Binary, unary and augmented assignment operations that operate on CPyTagged ints`
			`# are implemented as C functions.`

			`int_binary_op("+", "CPyTagged_Add")`
			`int_binary_op("-", "CPyTagged_Subtract")`
			`int_binary_op("*", "CPyTagged_Multiply")`
			`int_binary_op("&", "CPyTagged_And")`
			`int_binary_op("\|", "CPyTagged_Or")`
			`int_binary_op("^", "CPyTagged_Xor")`
			`# Divide and remainder we honestly propagate errors from because they`
			`# can raise ZeroDivisionError`
			`int_binary_op("//", "CPyTagged_FloorDivide", error_kind=ERR_MAGIC)`
			`int_binary_op("%", "CPyTagged_Remainder", error_kind=ERR_MAGIC)`
			`# Negative shift counts raise an exception`
			`int_binary_op(">>", "CPyTagged_Rshift", error_kind=ERR_MAGIC)`
			`int_binary_op("<<", "CPyTagged_Lshift", error_kind=ERR_MAGIC)`

			`int_binary_op(`
			`"/", "CPyTagged_TrueDivide", return_type=float_rprimitive, error_kind=ERR_MAGIC_OVERLAPPING`
			`)`

			`# This should work because assignment operators are parsed differently`
			`# and the code in irbuild that handles it does the assignment`
			`# regardless of whether or not the operator works in place anyway.`
			`int_binary_op("+=", "CPyTagged_Add")`
			`int_binary_op("-=", "CPyTagged_Subtract")`
			`int_binary_op("*=", "CPyTagged_Multiply")`
			`int_binary_op("&=", "CPyTagged_And")`
			`int_binary_op("\|=", "CPyTagged_Or")`
			`int_binary_op("^=", "CPyTagged_Xor")`
			`int_binary_op("//=", "CPyTagged_FloorDivide", error_kind=ERR_MAGIC)`
			`int_binary_op("%=", "CPyTagged_Remainder", error_kind=ERR_MAGIC)`
			`int_binary_op(">>=", "CPyTagged_Rshift", error_kind=ERR_MAGIC)`
			`int_binary_op("<<=", "CPyTagged_Lshift", error_kind=ERR_MAGIC)`


			`def int_unary_op(name: str, c_function_name: str) -> CFunctionDescription:`
			`return unary_op(`
			`name=name,`
			`arg_type=int_rprimitive,`
			`return_type=int_rprimitive,`
			`c_function_name=c_function_name,`
			`error_kind=ERR_NEVER,`
			`)`


			`int_neg_op = int_unary_op("-", "CPyTagged_Negate")`
			`int_invert_op = int_unary_op("~", "CPyTagged_Invert")`


			`# Primitives related to integer comparison operations:`


			`# Description for building int comparison ops`
			`#`
			`# Fields:`
			`# binary_op_variant: identify which IntOp to use when operands are short integers`
			`# c_func_description: the C function to call when operands are tagged integers`
			`# c_func_negated: whether to negate the C function call's result`
			`# c_func_swap_operands: whether to swap lhs and rhs when call the function`
			`class IntComparisonOpDescription(NamedTuple):`
			`binary_op_variant: int`
			`c_func_description: CFunctionDescription`
			`c_func_negated: bool`
			`c_func_swap_operands: bool`


			`# Equals operation on two boxed tagged integers`
			`int_equal_ = custom_op(`
			`arg_types=[int_rprimitive, int_rprimitive],`
			`return_type=bit_rprimitive,`
			`c_function_name="CPyTagged_IsEq_",`
			`error_kind=ERR_NEVER,`
			`)`

			`# Less than operation on two boxed tagged integers`
			`int_less_than_ = custom_op(`
			`arg_types=[int_rprimitive, int_rprimitive],`
			`return_type=bit_rprimitive,`
			`c_function_name="CPyTagged_IsLt_",`
			`error_kind=ERR_NEVER,`
			`)`

			`# Provide mapping from textual op to short int's op variant and boxed int's description.`
			`# Note that these are not complete implementations and require extra IR.`
			`int_comparison_op_mapping: dict[str, IntComparisonOpDescription] = {`
			`"==": IntComparisonOpDescription(ComparisonOp.EQ, int_equal_, False, False),`
			`"!=": IntComparisonOpDescription(ComparisonOp.NEQ, int_equal_, True, False),`
			`"<": IntComparisonOpDescription(ComparisonOp.SLT, int_less_than_, False, False),`
			`"<=": IntComparisonOpDescription(ComparisonOp.SLE, int_less_than_, True, True),`
			`">": IntComparisonOpDescription(ComparisonOp.SGT, int_less_than_, False, True),`
			`">=": IntComparisonOpDescription(ComparisonOp.SGE, int_less_than_, True, False),`
			`}`

			`int64_divide_op = custom_op(`
			`arg_types=[int64_rprimitive, int64_rprimitive],`
			`return_type=int64_rprimitive,`
			`c_function_name="CPyInt64_Divide",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int64_mod_op = custom_op(`
			`arg_types=[int64_rprimitive, int64_rprimitive],`
			`return_type=int64_rprimitive,`
			`c_function_name="CPyInt64_Remainder",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int32_divide_op = custom_op(`
			`arg_types=[int32_rprimitive, int32_rprimitive],`
			`return_type=int32_rprimitive,`
			`c_function_name="CPyInt32_Divide",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int32_mod_op = custom_op(`
			`arg_types=[int32_rprimitive, int32_rprimitive],`
			`return_type=int32_rprimitive,`
			`c_function_name="CPyInt32_Remainder",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int16_divide_op = custom_op(`
			`arg_types=[int16_rprimitive, int16_rprimitive],`
			`return_type=int16_rprimitive,`
			`c_function_name="CPyInt16_Divide",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int16_mod_op = custom_op(`
			`arg_types=[int16_rprimitive, int16_rprimitive],`
			`return_type=int16_rprimitive,`
			`c_function_name="CPyInt16_Remainder",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`# Convert tagged int (as PyObject *) to i64`
			`int_to_int64_op = custom_op(`
			`arg_types=[object_rprimitive],`
			`return_type=int64_rprimitive,`
			`c_function_name="CPyLong_AsInt64",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`ssize_t_to_int_op = custom_op(`
			`arg_types=[c_pyssize_t_rprimitive],`
			`return_type=int_rprimitive,`
			`c_function_name="CPyTagged_FromSsize_t",`
			`error_kind=ERR_MAGIC,`
			`)`

			`int64_to_int_op = custom_op(`
			`arg_types=[int64_rprimitive],`
			`return_type=int_rprimitive,`
			`c_function_name="CPyTagged_FromInt64",`
			`error_kind=ERR_MAGIC,`
			`)`

			`# Convert tagged int (as PyObject *) to i32`
			`int_to_int32_op = custom_op(`
			`arg_types=[object_rprimitive],`
			`return_type=int32_rprimitive,`
			`c_function_name="CPyLong_AsInt32",`
			`error_kind=ERR_MAGIC_OVERLAPPING,`
			`)`

			`int32_overflow = custom_op(`
			`arg_types=[],`
			`return_type=void_rtype,`
			`c_function_name="CPyInt32_Overflow",`
			`error_kind=ERR_ALWAYS,`
			`)`

			`int16_overflow = custom_op(`
			`arg_types=[],`
			`return_type=void_rtype,`
			`c_function_name="CPyInt16_Overflow",`
			`error_kind=ERR_ALWAYS,`
			`)`

			`uint8_overflow = custom_op(`
			`arg_types=[],`
			`return_type=void_rtype,`
			`c_function_name="CPyUInt8_Overflow",`
			`error_kind=ERR_ALWAYS,`
			`)`