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gtn/.venv/Lib/site-packages/mypyc/test/test_emitfunc.py

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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
from __future__ import annotations
import unittest
from mypy.test.helpers import assert_string_arrays_equal
from mypyc.codegen.emit import Emitter, EmitterContext
from mypyc.codegen.emitfunc import FunctionEmitterVisitor, generate_native_function
from mypyc.common import PLATFORM_SIZE
from mypyc.ir.class_ir import ClassIR
from mypyc.ir.func_ir import FuncDecl, FuncIR, FuncSignature, RuntimeArg
from mypyc.ir.ops import (
ERR_NEVER,
Assign,
AssignMulti,
BasicBlock,
Box,
Branch,
Call,
CallC,
Cast,
ComparisonOp,
DecRef,
Extend,
GetAttr,
GetElementPtr,
Goto,
IncRef,
Integer,
IntOp,
LoadAddress,
LoadMem,
Op,
Register,
Return,
SetAttr,
SetMem,
TupleGet,
Unbox,
Unreachable,
Value,
)
from mypyc.ir.pprint import generate_names_for_ir
from mypyc.ir.rtypes import (
RArray,
RInstance,
RStruct,
RTuple,
RType,
bool_rprimitive,
c_int_rprimitive,
dict_rprimitive,
int32_rprimitive,
int64_rprimitive,
int_rprimitive,
list_rprimitive,
object_rprimitive,
pointer_rprimitive,
short_int_rprimitive,
)
from mypyc.irbuild.vtable import compute_vtable
from mypyc.namegen import NameGenerator
from mypyc.primitives.dict_ops import (
dict_get_item_op,
dict_new_op,
dict_set_item_op,
dict_update_op,
)
from mypyc.primitives.int_ops import int_neg_op
from mypyc.primitives.list_ops import list_append_op, list_get_item_op, list_set_item_op
from mypyc.primitives.misc_ops import none_object_op
from mypyc.primitives.registry import binary_ops
from mypyc.subtype import is_subtype
class TestFunctionEmitterVisitor(unittest.TestCase):
"""Test generation of fragments of C from individual IR ops."""
def setUp(self) -> None:
self.registers: list[Register] = []
def add_local(name: str, rtype: RType) -> Register:
reg = Register(rtype, name)
self.registers.append(reg)
return reg
self.n = add_local("n", int_rprimitive)
self.m = add_local("m", int_rprimitive)
self.k = add_local("k", int_rprimitive)
self.l = add_local("l", list_rprimitive)
self.ll = add_local("ll", list_rprimitive)
self.o = add_local("o", object_rprimitive)
self.o2 = add_local("o2", object_rprimitive)
self.d = add_local("d", dict_rprimitive)
self.b = add_local("b", bool_rprimitive)
self.s1 = add_local("s1", short_int_rprimitive)
self.s2 = add_local("s2", short_int_rprimitive)
self.i32 = add_local("i32", int32_rprimitive)
self.i32_1 = add_local("i32_1", int32_rprimitive)
self.i64 = add_local("i64", int64_rprimitive)
self.i64_1 = add_local("i64_1", int64_rprimitive)
self.ptr = add_local("ptr", pointer_rprimitive)
self.t = add_local("t", RTuple([int_rprimitive, bool_rprimitive]))
self.tt = add_local(
"tt", RTuple([RTuple([int_rprimitive, bool_rprimitive]), bool_rprimitive])
)
ir = ClassIR("A", "mod")
ir.attributes = {
"x": bool_rprimitive,
"y": int_rprimitive,
"i1": int64_rprimitive,
"i2": int32_rprimitive,
}
ir.bitmap_attrs = ["i1", "i2"]
compute_vtable(ir)
ir.mro = [ir]
self.r = add_local("r", RInstance(ir))
self.context = EmitterContext(NameGenerator([["mod"]]))
def test_goto(self) -> None:
self.assert_emit(Goto(BasicBlock(2)), "goto CPyL2;")
def test_goto_next_block(self) -> None:
next_block = BasicBlock(2)
self.assert_emit(Goto(next_block), "", next_block=next_block)
def test_return(self) -> None:
self.assert_emit(Return(self.m), "return cpy_r_m;")
def test_integer(self) -> None:
self.assert_emit(Assign(self.n, Integer(5)), "cpy_r_n = 10;")
self.assert_emit(Assign(self.i32, Integer(5, c_int_rprimitive)), "cpy_r_i32 = 5;")
def test_tuple_get(self) -> None:
self.assert_emit(TupleGet(self.t, 1, 0), "cpy_r_r0 = cpy_r_t.f1;")
def test_load_None(self) -> None:
self.assert_emit(
LoadAddress(none_object_op.type, none_object_op.src, 0),
"cpy_r_r0 = (PyObject *)&_Py_NoneStruct;",
)
def test_assign_int(self) -> None:
self.assert_emit(Assign(self.m, self.n), "cpy_r_m = cpy_r_n;")
def test_int_add(self) -> None:
self.assert_emit_binary_op(
"+", self.n, self.m, self.k, "cpy_r_r0 = CPyTagged_Add(cpy_r_m, cpy_r_k);"
)
def test_int_sub(self) -> None:
self.assert_emit_binary_op(
"-", self.n, self.m, self.k, "cpy_r_r0 = CPyTagged_Subtract(cpy_r_m, cpy_r_k);"
)
def test_int_neg(self) -> None:
self.assert_emit(
CallC(
int_neg_op.c_function_name,
[self.m],
int_neg_op.return_type,
int_neg_op.steals,
int_neg_op.is_borrowed,
int_neg_op.is_borrowed,
int_neg_op.error_kind,
55,
),
"cpy_r_r0 = CPyTagged_Negate(cpy_r_m);",
)
def test_branch(self) -> None:
self.assert_emit(
Branch(self.b, BasicBlock(8), BasicBlock(9), Branch.BOOL),
"""if (cpy_r_b) {
goto CPyL8;
} else
goto CPyL9;
""",
)
b = Branch(self.b, BasicBlock(8), BasicBlock(9), Branch.BOOL)
b.negated = True
self.assert_emit(
b,
"""if (!cpy_r_b) {
goto CPyL8;
} else
goto CPyL9;
""",
)
def test_branch_no_else(self) -> None:
next_block = BasicBlock(9)
b = Branch(self.b, BasicBlock(8), next_block, Branch.BOOL)
self.assert_emit(b, """if (cpy_r_b) goto CPyL8;""", next_block=next_block)
next_block = BasicBlock(9)
b = Branch(self.b, BasicBlock(8), next_block, Branch.BOOL)
b.negated = True
self.assert_emit(b, """if (!cpy_r_b) goto CPyL8;""", next_block=next_block)
def test_branch_no_else_negated(self) -> None:
next_block = BasicBlock(1)
b = Branch(self.b, next_block, BasicBlock(2), Branch.BOOL)
self.assert_emit(b, """if (!cpy_r_b) goto CPyL2;""", next_block=next_block)
next_block = BasicBlock(1)
b = Branch(self.b, next_block, BasicBlock(2), Branch.BOOL)
b.negated = True
self.assert_emit(b, """if (cpy_r_b) goto CPyL2;""", next_block=next_block)
def test_branch_is_error(self) -> None:
b = Branch(self.b, BasicBlock(8), BasicBlock(9), Branch.IS_ERROR)
self.assert_emit(
b,
"""if (cpy_r_b == 2) {
goto CPyL8;
} else
goto CPyL9;
""",
)
b = Branch(self.b, BasicBlock(8), BasicBlock(9), Branch.IS_ERROR)
b.negated = True
self.assert_emit(
b,
"""if (cpy_r_b != 2) {
goto CPyL8;
} else
goto CPyL9;
""",
)
def test_branch_is_error_next_block(self) -> None:
next_block = BasicBlock(8)
b = Branch(self.b, next_block, BasicBlock(9), Branch.IS_ERROR)
self.assert_emit(b, """if (cpy_r_b != 2) goto CPyL9;""", next_block=next_block)
b = Branch(self.b, next_block, BasicBlock(9), Branch.IS_ERROR)
b.negated = True
self.assert_emit(b, """if (cpy_r_b == 2) goto CPyL9;""", next_block=next_block)
def test_branch_rare(self) -> None:
self.assert_emit(
Branch(self.b, BasicBlock(8), BasicBlock(9), Branch.BOOL, rare=True),
"""if (unlikely(cpy_r_b)) {
goto CPyL8;
} else
goto CPyL9;
""",
)
next_block = BasicBlock(9)
self.assert_emit(
Branch(self.b, BasicBlock(8), next_block, Branch.BOOL, rare=True),
"""if (unlikely(cpy_r_b)) goto CPyL8;""",
next_block=next_block,
)
next_block = BasicBlock(8)
b = Branch(self.b, next_block, BasicBlock(9), Branch.BOOL, rare=True)
self.assert_emit(b, """if (likely(!cpy_r_b)) goto CPyL9;""", next_block=next_block)
next_block = BasicBlock(8)
b = Branch(self.b, next_block, BasicBlock(9), Branch.BOOL, rare=True)
b.negated = True
self.assert_emit(b, """if (likely(cpy_r_b)) goto CPyL9;""", next_block=next_block)
def test_call(self) -> None:
decl = FuncDecl(
"myfn", None, "mod", FuncSignature([RuntimeArg("m", int_rprimitive)], int_rprimitive)
)
self.assert_emit(Call(decl, [self.m], 55), "cpy_r_r0 = CPyDef_myfn(cpy_r_m);")
def test_call_two_args(self) -> None:
decl = FuncDecl(
"myfn",
None,
"mod",
FuncSignature(
[RuntimeArg("m", int_rprimitive), RuntimeArg("n", int_rprimitive)], int_rprimitive
),
)
self.assert_emit(
Call(decl, [self.m, self.k], 55), "cpy_r_r0 = CPyDef_myfn(cpy_r_m, cpy_r_k);"
)
def test_inc_ref(self) -> None:
self.assert_emit(IncRef(self.o), "CPy_INCREF(cpy_r_o);")
self.assert_emit(IncRef(self.o), "CPy_INCREF(cpy_r_o);", rare=True)
def test_dec_ref(self) -> None:
self.assert_emit(DecRef(self.o), "CPy_DECREF(cpy_r_o);")
self.assert_emit(DecRef(self.o), "CPy_DecRef(cpy_r_o);", rare=True)
def test_inc_ref_int(self) -> None:
self.assert_emit(IncRef(self.m), "CPyTagged_INCREF(cpy_r_m);")
self.assert_emit(IncRef(self.m), "CPyTagged_IncRef(cpy_r_m);", rare=True)
def test_dec_ref_int(self) -> None:
self.assert_emit(DecRef(self.m), "CPyTagged_DECREF(cpy_r_m);")
self.assert_emit(DecRef(self.m), "CPyTagged_DecRef(cpy_r_m);", rare=True)
def test_dec_ref_tuple(self) -> None:
self.assert_emit(DecRef(self.t), "CPyTagged_DECREF(cpy_r_t.f0);")
def test_dec_ref_tuple_nested(self) -> None:
self.assert_emit(DecRef(self.tt), "CPyTagged_DECREF(cpy_r_tt.f0.f0);")
def test_list_get_item(self) -> None:
self.assert_emit(
CallC(
list_get_item_op.c_function_name,
[self.m, self.k],
list_get_item_op.return_type,
list_get_item_op.steals,
list_get_item_op.is_borrowed,
list_get_item_op.error_kind,
55,
),
"""cpy_r_r0 = CPyList_GetItem(cpy_r_m, cpy_r_k);""",
)
def test_list_set_item(self) -> None:
self.assert_emit(
CallC(
list_set_item_op.c_function_name,
[self.l, self.n, self.o],
list_set_item_op.return_type,
list_set_item_op.steals,
list_set_item_op.is_borrowed,
list_set_item_op.error_kind,
55,
),
"""cpy_r_r0 = CPyList_SetItem(cpy_r_l, cpy_r_n, cpy_r_o);""",
)
def test_box_int(self) -> None:
self.assert_emit(Box(self.n), """cpy_r_r0 = CPyTagged_StealAsObject(cpy_r_n);""")
def test_unbox_int(self) -> None:
self.assert_emit(
Unbox(self.m, int_rprimitive, 55),
"""if (likely(PyLong_Check(cpy_r_m)))
cpy_r_r0 = CPyTagged_FromObject(cpy_r_m);
else {
CPy_TypeError("int", cpy_r_m); cpy_r_r0 = CPY_INT_TAG;
}
""",
)
def test_box_i64(self) -> None:
self.assert_emit(Box(self.i64), """cpy_r_r0 = PyLong_FromLongLong(cpy_r_i64);""")
def test_unbox_i64(self) -> None:
self.assert_emit(
Unbox(self.o, int64_rprimitive, 55), """cpy_r_r0 = CPyLong_AsInt64(cpy_r_o);"""
)
def test_list_append(self) -> None:
self.assert_emit(
CallC(
list_append_op.c_function_name,
[self.l, self.o],
list_append_op.return_type,
list_append_op.steals,
list_append_op.is_borrowed,
list_append_op.error_kind,
1,
),
"""cpy_r_r0 = PyList_Append(cpy_r_l, cpy_r_o);""",
)
def test_get_attr(self) -> None:
self.assert_emit(
GetAttr(self.r, "y", 1),
"""cpy_r_r0 = ((mod___AObject *)cpy_r_r)->_y;
if (unlikely(cpy_r_r0 == CPY_INT_TAG)) {
PyErr_SetString(PyExc_AttributeError, "attribute 'y' of 'A' undefined");
} else {
CPyTagged_INCREF(cpy_r_r0);
}
""",
)
def test_get_attr_non_refcounted(self) -> None:
self.assert_emit(
GetAttr(self.r, "x", 1),
"""cpy_r_r0 = ((mod___AObject *)cpy_r_r)->_x;
if (unlikely(cpy_r_r0 == 2)) {
PyErr_SetString(PyExc_AttributeError, "attribute 'x' of 'A' undefined");
}
""",
)
def test_get_attr_merged(self) -> None:
op = GetAttr(self.r, "y", 1)
branch = Branch(op, BasicBlock(8), BasicBlock(9), Branch.IS_ERROR)
branch.traceback_entry = ("foobar", 123)
self.assert_emit(
op,
"""\
cpy_r_r0 = ((mod___AObject *)cpy_r_r)->_y;
if (unlikely(cpy_r_r0 == CPY_INT_TAG)) {
CPy_AttributeError("prog.py", "foobar", "A", "y", 123, CPyStatic_prog___globals);
goto CPyL8;
}
CPyTagged_INCREF(cpy_r_r0);
goto CPyL9;
""",
next_branch=branch,
skip_next=True,
)
def test_get_attr_with_bitmap(self) -> None:
self.assert_emit(
GetAttr(self.r, "i1", 1),
"""cpy_r_r0 = ((mod___AObject *)cpy_r_r)->_i1;
if (unlikely(cpy_r_r0 == -113) && !(((mod___AObject *)cpy_r_r)->bitmap & 1)) {
PyErr_SetString(PyExc_AttributeError, "attribute 'i1' of 'A' undefined");
}
""",
)
def test_set_attr(self) -> None:
self.assert_emit(
SetAttr(self.r, "y", self.m, 1),
"""if (((mod___AObject *)cpy_r_r)->_y != CPY_INT_TAG) {
CPyTagged_DECREF(((mod___AObject *)cpy_r_r)->_y);
}
((mod___AObject *)cpy_r_r)->_y = cpy_r_m;
cpy_r_r0 = 1;
""",
)
def test_set_attr_non_refcounted(self) -> None:
self.assert_emit(
SetAttr(self.r, "x", self.b, 1),
"""((mod___AObject *)cpy_r_r)->_x = cpy_r_b;
cpy_r_r0 = 1;
""",
)
def test_set_attr_no_error(self) -> None:
op = SetAttr(self.r, "y", self.m, 1)
op.error_kind = ERR_NEVER
self.assert_emit(
op,
"""if (((mod___AObject *)cpy_r_r)->_y != CPY_INT_TAG) {
CPyTagged_DECREF(((mod___AObject *)cpy_r_r)->_y);
}
((mod___AObject *)cpy_r_r)->_y = cpy_r_m;
""",
)
def test_set_attr_non_refcounted_no_error(self) -> None:
op = SetAttr(self.r, "x", self.b, 1)
op.error_kind = ERR_NEVER
self.assert_emit(
op,
"""((mod___AObject *)cpy_r_r)->_x = cpy_r_b;
""",
)
def test_set_attr_with_bitmap(self) -> None:
# For some rtypes the error value overlaps a valid value, so we need
# to use a separate bitmap to track defined attributes.
self.assert_emit(
SetAttr(self.r, "i1", self.i64, 1),
"""if (unlikely(cpy_r_i64 == -113)) {
((mod___AObject *)cpy_r_r)->bitmap |= 1;
}
((mod___AObject *)cpy_r_r)->_i1 = cpy_r_i64;
cpy_r_r0 = 1;
""",
)
self.assert_emit(
SetAttr(self.r, "i2", self.i32, 1),
"""if (unlikely(cpy_r_i32 == -113)) {
((mod___AObject *)cpy_r_r)->bitmap |= 2;
}
((mod___AObject *)cpy_r_r)->_i2 = cpy_r_i32;
cpy_r_r0 = 1;
""",
)
def test_set_attr_init_with_bitmap(self) -> None:
op = SetAttr(self.r, "i1", self.i64, 1)
op.is_init = True
self.assert_emit(
op,
"""if (unlikely(cpy_r_i64 == -113)) {
((mod___AObject *)cpy_r_r)->bitmap |= 1;
}
((mod___AObject *)cpy_r_r)->_i1 = cpy_r_i64;
cpy_r_r0 = 1;
""",
)
def test_dict_get_item(self) -> None:
self.assert_emit(
CallC(
dict_get_item_op.c_function_name,
[self.d, self.o2],
dict_get_item_op.return_type,
dict_get_item_op.steals,
dict_get_item_op.is_borrowed,
dict_get_item_op.error_kind,
1,
),
"""cpy_r_r0 = CPyDict_GetItem(cpy_r_d, cpy_r_o2);""",
)
def test_dict_set_item(self) -> None:
self.assert_emit(
CallC(
dict_set_item_op.c_function_name,
[self.d, self.o, self.o2],
dict_set_item_op.return_type,
dict_set_item_op.steals,
dict_set_item_op.is_borrowed,
dict_set_item_op.error_kind,
1,
),
"""cpy_r_r0 = CPyDict_SetItem(cpy_r_d, cpy_r_o, cpy_r_o2);""",
)
def test_dict_update(self) -> None:
self.assert_emit(
CallC(
dict_update_op.c_function_name,
[self.d, self.o],
dict_update_op.return_type,
dict_update_op.steals,
dict_update_op.is_borrowed,
dict_update_op.error_kind,
1,
),
"""cpy_r_r0 = CPyDict_Update(cpy_r_d, cpy_r_o);""",
)
def test_new_dict(self) -> None:
self.assert_emit(
CallC(
dict_new_op.c_function_name,
[],
dict_new_op.return_type,
dict_new_op.steals,
dict_new_op.is_borrowed,
dict_new_op.error_kind,
1,
),
"""cpy_r_r0 = PyDict_New();""",
)
def test_dict_contains(self) -> None:
self.assert_emit_binary_op(
"in", self.b, self.o, self.d, """cpy_r_r0 = PyDict_Contains(cpy_r_d, cpy_r_o);"""
)
def test_int_op(self) -> None:
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.ADD, 1),
"""cpy_r_r0 = cpy_r_s1 + cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.SUB, 1),
"""cpy_r_r0 = cpy_r_s1 - cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.MUL, 1),
"""cpy_r_r0 = cpy_r_s1 * cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.DIV, 1),
"""cpy_r_r0 = cpy_r_s1 / cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.MOD, 1),
"""cpy_r_r0 = cpy_r_s1 % cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.AND, 1),
"""cpy_r_r0 = cpy_r_s1 & cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.OR, 1),
"""cpy_r_r0 = cpy_r_s1 | cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.XOR, 1),
"""cpy_r_r0 = cpy_r_s1 ^ cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.LEFT_SHIFT, 1),
"""cpy_r_r0 = cpy_r_s1 << cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.s1, self.s2, IntOp.RIGHT_SHIFT, 1),
"""cpy_r_r0 = (Py_ssize_t)cpy_r_s1 >> (Py_ssize_t)cpy_r_s2;""",
)
self.assert_emit(
IntOp(short_int_rprimitive, self.i64, self.i64_1, IntOp.RIGHT_SHIFT, 1),
"""cpy_r_r0 = cpy_r_i64 >> cpy_r_i64_1;""",
)
def test_comparison_op(self) -> None:
# signed
self.assert_emit(
ComparisonOp(self.s1, self.s2, ComparisonOp.SLT, 1),
"""cpy_r_r0 = (Py_ssize_t)cpy_r_s1 < (Py_ssize_t)cpy_r_s2;""",
)
self.assert_emit(
ComparisonOp(self.i32, self.i32_1, ComparisonOp.SLT, 1),
"""cpy_r_r0 = cpy_r_i32 < cpy_r_i32_1;""",
)
self.assert_emit(
ComparisonOp(self.i64, self.i64_1, ComparisonOp.SLT, 1),
"""cpy_r_r0 = cpy_r_i64 < cpy_r_i64_1;""",
)
# unsigned
self.assert_emit(
ComparisonOp(self.s1, self.s2, ComparisonOp.ULT, 1),
"""cpy_r_r0 = cpy_r_s1 < cpy_r_s2;""",
)
self.assert_emit(
ComparisonOp(self.i32, self.i32_1, ComparisonOp.ULT, 1),
"""cpy_r_r0 = (uint32_t)cpy_r_i32 < (uint32_t)cpy_r_i32_1;""",
)
self.assert_emit(
ComparisonOp(self.i64, self.i64_1, ComparisonOp.ULT, 1),
"""cpy_r_r0 = (uint64_t)cpy_r_i64 < (uint64_t)cpy_r_i64_1;""",
)
# object type
self.assert_emit(
ComparisonOp(self.o, self.o2, ComparisonOp.EQ, 1),
"""cpy_r_r0 = cpy_r_o == cpy_r_o2;""",
)
self.assert_emit(
ComparisonOp(self.o, self.o2, ComparisonOp.NEQ, 1),
"""cpy_r_r0 = cpy_r_o != cpy_r_o2;""",
)
def test_load_mem(self) -> None:
self.assert_emit(LoadMem(bool_rprimitive, self.ptr), """cpy_r_r0 = *(char *)cpy_r_ptr;""")
def test_set_mem(self) -> None:
self.assert_emit(
SetMem(bool_rprimitive, self.ptr, self.b), """*(char *)cpy_r_ptr = cpy_r_b;"""
)
def test_get_element_ptr(self) -> None:
r = RStruct(
"Foo", ["b", "i32", "i64"], [bool_rprimitive, int32_rprimitive, int64_rprimitive]
)
self.assert_emit(
GetElementPtr(self.o, r, "b"), """cpy_r_r0 = (CPyPtr)&((Foo *)cpy_r_o)->b;"""
)
self.assert_emit(
GetElementPtr(self.o, r, "i32"), """cpy_r_r0 = (CPyPtr)&((Foo *)cpy_r_o)->i32;"""
)
self.assert_emit(
GetElementPtr(self.o, r, "i64"), """cpy_r_r0 = (CPyPtr)&((Foo *)cpy_r_o)->i64;"""
)
def test_load_address(self) -> None:
self.assert_emit(
LoadAddress(object_rprimitive, "PyDict_Type"),
"""cpy_r_r0 = (PyObject *)&PyDict_Type;""",
)
def test_assign_multi(self) -> None:
t = RArray(object_rprimitive, 2)
a = Register(t, "a")
self.registers.append(a)
self.assert_emit(
AssignMulti(a, [self.o, self.o2]), """PyObject *cpy_r_a[2] = {cpy_r_o, cpy_r_o2};"""
)
def test_long_unsigned(self) -> None:
a = Register(int64_rprimitive, "a")
self.assert_emit(
Assign(a, Integer(1 << 31, int64_rprimitive)), """cpy_r_a = 2147483648LL;"""
)
self.assert_emit(
Assign(a, Integer((1 << 31) - 1, int64_rprimitive)), """cpy_r_a = 2147483647;"""
)
def test_long_signed(self) -> None:
a = Register(int64_rprimitive, "a")
self.assert_emit(
Assign(a, Integer(-(1 << 31) + 1, int64_rprimitive)), """cpy_r_a = -2147483647;"""
)
self.assert_emit(
Assign(a, Integer(-(1 << 31), int64_rprimitive)), """cpy_r_a = -2147483648LL;"""
)
def test_cast_and_branch_merge(self) -> None:
op = Cast(self.r, dict_rprimitive, 1)
next_block = BasicBlock(9)
branch = Branch(op, BasicBlock(8), next_block, Branch.IS_ERROR)
branch.traceback_entry = ("foobar", 123)
self.assert_emit(
op,
"""\
if (likely(PyDict_Check(cpy_r_r)))
cpy_r_r0 = cpy_r_r;
else {
CPy_TypeErrorTraceback("prog.py", "foobar", 123, CPyStatic_prog___globals, "dict", cpy_r_r);
goto CPyL8;
}
""",
next_block=next_block,
next_branch=branch,
skip_next=True,
)
def test_cast_and_branch_no_merge_1(self) -> None:
op = Cast(self.r, dict_rprimitive, 1)
branch = Branch(op, BasicBlock(8), BasicBlock(9), Branch.IS_ERROR)
branch.traceback_entry = ("foobar", 123)
self.assert_emit(
op,
"""\
if (likely(PyDict_Check(cpy_r_r)))
cpy_r_r0 = cpy_r_r;
else {
CPy_TypeError("dict", cpy_r_r);
cpy_r_r0 = NULL;
}
""",
next_block=BasicBlock(10),
next_branch=branch,
skip_next=False,
)
def test_cast_and_branch_no_merge_2(self) -> None:
op = Cast(self.r, dict_rprimitive, 1)
next_block = BasicBlock(9)
branch = Branch(op, BasicBlock(8), next_block, Branch.IS_ERROR)
branch.negated = True
branch.traceback_entry = ("foobar", 123)
self.assert_emit(
op,
"""\
if (likely(PyDict_Check(cpy_r_r)))
cpy_r_r0 = cpy_r_r;
else {
CPy_TypeError("dict", cpy_r_r);
cpy_r_r0 = NULL;
}
""",
next_block=next_block,
next_branch=branch,
)
def test_cast_and_branch_no_merge_3(self) -> None:
op = Cast(self.r, dict_rprimitive, 1)
next_block = BasicBlock(9)
branch = Branch(op, BasicBlock(8), next_block, Branch.BOOL)
branch.traceback_entry = ("foobar", 123)
self.assert_emit(
op,
"""\
if (likely(PyDict_Check(cpy_r_r)))
cpy_r_r0 = cpy_r_r;
else {
CPy_TypeError("dict", cpy_r_r);
cpy_r_r0 = NULL;
}
""",
next_block=next_block,
next_branch=branch,
)
def test_cast_and_branch_no_merge_4(self) -> None:
op = Cast(self.r, dict_rprimitive, 1)
next_block = BasicBlock(9)
branch = Branch(op, BasicBlock(8), next_block, Branch.IS_ERROR)
self.assert_emit(
op,
"""\
if (likely(PyDict_Check(cpy_r_r)))
cpy_r_r0 = cpy_r_r;
else {
CPy_TypeError("dict", cpy_r_r);
cpy_r_r0 = NULL;
}
""",
next_block=next_block,
next_branch=branch,
)
def test_extend(self) -> None:
a = Register(int32_rprimitive, "a")
self.assert_emit(Extend(a, int64_rprimitive, signed=True), """cpy_r_r0 = cpy_r_a;""")
self.assert_emit(
Extend(a, int64_rprimitive, signed=False), """cpy_r_r0 = (uint32_t)cpy_r_a;"""
)
if PLATFORM_SIZE == 4:
self.assert_emit(
Extend(self.n, int64_rprimitive, signed=True),
"""cpy_r_r0 = (Py_ssize_t)cpy_r_n;""",
)
self.assert_emit(
Extend(self.n, int64_rprimitive, signed=False), """cpy_r_r0 = cpy_r_n;"""
)
if PLATFORM_SIZE == 8:
self.assert_emit(Extend(a, int_rprimitive, signed=True), """cpy_r_r0 = cpy_r_a;""")
self.assert_emit(
Extend(a, int_rprimitive, signed=False), """cpy_r_r0 = (uint32_t)cpy_r_a;"""
)
def assert_emit(
self,
op: Op,
expected: str,
next_block: BasicBlock | None = None,
*,
rare: bool = False,
next_branch: Branch | None = None,
skip_next: bool = False,
) -> None:
block = BasicBlock(0)
block.ops.append(op)
value_names = generate_names_for_ir(self.registers, [block])
emitter = Emitter(self.context, value_names)
declarations = Emitter(self.context, value_names)
emitter.fragments = []
declarations.fragments = []
visitor = FunctionEmitterVisitor(emitter, declarations, "prog.py", "prog")
visitor.next_block = next_block
visitor.rare = rare
if next_branch:
visitor.ops = [op, next_branch]
else:
visitor.ops = [op]
visitor.op_index = 0
op.accept(visitor)
frags = declarations.fragments + emitter.fragments
actual_lines = [line.strip(" ") for line in frags]
assert all(line.endswith("\n") for line in actual_lines)
actual_lines = [line.rstrip("\n") for line in actual_lines]
if not expected.strip():
expected_lines = []
else:
expected_lines = expected.rstrip().split("\n")
expected_lines = [line.strip(" ") for line in expected_lines]
assert_string_arrays_equal(expected_lines, actual_lines, msg="Generated code unexpected")
if skip_next:
assert visitor.op_index == 1
else:
assert visitor.op_index == 0
def assert_emit_binary_op(
self, op: str, dest: Value, left: Value, right: Value, expected: str
) -> None:
if op in binary_ops:
ops = binary_ops[op]
for desc in ops:
if is_subtype(left.type, desc.arg_types[0]) and is_subtype(
right.type, desc.arg_types[1]
):
args = [left, right]
if desc.ordering is not None:
args = [args[i] for i in desc.ordering]
self.assert_emit(
CallC(
desc.c_function_name,
args,
desc.return_type,
desc.steals,
desc.is_borrowed,
desc.error_kind,
55,
),
expected,
)
return
else:
assert False, "Could not find matching op"
class TestGenerateFunction(unittest.TestCase):
def setUp(self) -> None:
self.arg = RuntimeArg("arg", int_rprimitive)
self.reg = Register(int_rprimitive, "arg")
self.block = BasicBlock(0)
def test_simple(self) -> None:
self.block.ops.append(Return(self.reg))
fn = FuncIR(
FuncDecl("myfunc", None, "mod", FuncSignature([self.arg], int_rprimitive)),
[self.reg],
[self.block],
)
value_names = generate_names_for_ir(fn.arg_regs, fn.blocks)
emitter = Emitter(EmitterContext(NameGenerator([["mod"]])), value_names)
generate_native_function(fn, emitter, "prog.py", "prog")
result = emitter.fragments
assert_string_arrays_equal(
["CPyTagged CPyDef_myfunc(CPyTagged cpy_r_arg) {\n", " return cpy_r_arg;\n", "}\n"],
result,
msg="Generated code invalid",
)
def test_register(self) -> None:
reg = Register(int_rprimitive)
op = Assign(reg, Integer(5))
self.block.ops.append(op)
self.block.ops.append(Unreachable())
fn = FuncIR(
FuncDecl("myfunc", None, "mod", FuncSignature([self.arg], list_rprimitive)),
[self.reg],
[self.block],
)
value_names = generate_names_for_ir(fn.arg_regs, fn.blocks)
emitter = Emitter(EmitterContext(NameGenerator([["mod"]])), value_names)
generate_native_function(fn, emitter, "prog.py", "prog")
result = emitter.fragments
assert_string_arrays_equal(
[
"PyObject *CPyDef_myfunc(CPyTagged cpy_r_arg) {\n",
" CPyTagged cpy_r_r0;\n",
" cpy_r_r0 = 10;\n",
" CPy_Unreachable();\n",
"}\n",
],
result,
msg="Generated code invalid",
)
Reference in a new issue Copy permalink