ladybird/Meta/generate-libwasm-spec-test.py
Diego 524e09dda1 LibWasm: Check for correct NaN bit patterns in tests
Some spec-tests check the bit pattern of a returned `NaN` (i.e.
`nan:canonical`, `nan:arithmetic`, or something like `nan:0x200000`).
Previously, we just accepted any `NaN`.
2024-07-12 18:27:47 +02:00

442 lines
12 KiB
Python

import json
import sys
import struct
import subprocess
from dataclasses import dataclass
from pathlib import Path
from typing import Union, Literal, Any
class ParseException(Exception):
pass
class GenerateException(Exception):
pass
@dataclass
class WasmValue:
kind: Literal["i32", "i64", "f32", "f64", "externref", "funcref", "v128"]
value: str
@dataclass
class ModuleCommand:
line: int
file_name: Path
name: str | None
@dataclass
class Invoke:
field: str
args: list[WasmValue]
module: str | None
@dataclass
class Get:
field: str
module: str | None
Action = Union[Invoke, Get]
@dataclass
class Register:
line: int
name: str | None
as_: str
@dataclass
class AssertReturn:
line: int
action: Action
expected: WasmValue | None
@dataclass
class AssertTrap:
line: int
messsage: str
action: Action
@dataclass
class ActionCommand:
line: int
action: Action
@dataclass
class AssertInvalid:
line: int
filename: str
message: str
Command = Union[
ModuleCommand,
AssertReturn,
AssertTrap,
ActionCommand,
AssertInvalid,
Register,
]
@dataclass
class ArithmeticNan:
num_bits: int
@dataclass
class CanonicalNan:
num_bits: int
GeneratedValue = Union[str, ArithmeticNan, CanonicalNan]
@dataclass
class WastDescription:
source_filename: str
commands: list[Command]
@dataclass
class Context:
current_module_name: str
has_unclosed: bool
def parse_value(arg: dict[str, str]) -> WasmValue:
type_ = arg["type"]
match type_:
case "i32" | "i64" | "f32" | "f64" | "externref" | "funcref":
payload = arg["value"]
case "v128":
def reverse_endianness(hex_str):
if len(hex_str) % 2 != 0:
hex_str = "0" + hex_str
bytes_list = [hex_str[i:i + 2] for i in range(0, len(hex_str), 2)]
reversed_hex_str = "".join(bytes_list[::-1])
return reversed_hex_str
size = int(arg["lane_type"][1:]) // 4
parts = []
for raw_val in arg["value"]:
match raw_val:
case "nan:canonical":
hex_repr = "7fc".ljust(size, "0")
case "nan:arithmetic":
hex_repr = "7ff".ljust(size, "0")
case "nan:signaling":
hex_repr = "7ff8".ljust(size, "0")
case _:
hex_repr = hex(int(raw_val))[2:].zfill(size)
parts.append(hex_repr)
payload = "0x" + reverse_endianness("".join(reversed(parts))) + "n"
case _:
raise ParseException(f"Unknown value type: {type_}")
return WasmValue(type_, payload)
def parse_args(raw_args: list[dict[str, str]]) -> list[WasmValue]:
return [parse_value(arg) for arg in raw_args]
def parse_action(action: dict[str, Any]) -> Action:
match action["type"]:
case "invoke":
return Invoke(
action["field"], parse_args(action["args"]), action.get("module")
)
case "get":
return Get(action["field"], action.get("module"))
case _:
raise ParseException(f"Action not implemented: {action['type']}")
def parse(raw: dict[str, Any]) -> WastDescription:
commands: list[Command] = []
for raw_cmd in raw["commands"]:
line = raw_cmd["line"]
cmd: Command
match raw_cmd["type"]:
case "module":
cmd = ModuleCommand(
line, Path(raw_cmd["filename"]), raw_cmd.get("name")
)
case "action":
cmd = ActionCommand(line, parse_action(raw_cmd["action"]))
case "register":
cmd = Register(line, raw_cmd.get("name"), raw_cmd["as"])
case "assert_return":
cmd = AssertReturn(
line,
parse_action(raw_cmd["action"]),
parse_value(raw_cmd["expected"][0])
if len(raw_cmd["expected"]) == 1
else None,
)
case "assert_trap" | "assert_exhaustion":
cmd = AssertTrap(line, raw_cmd["text"], parse_action(raw_cmd["action"]))
case "assert_invalid" | "assert_malformed" | "assert_uninstantiable" | "assert_unlinkable":
if raw_cmd.get("module_type") == "text":
continue
cmd = AssertInvalid(line, raw_cmd["filename"], raw_cmd["text"])
case _:
raise ParseException(f"Unknown command type: {raw_cmd['type']}")
commands.append(cmd)
return WastDescription(raw["source_filename"], commands)
def escape(s: str) -> str:
return s.replace('"', '\\"')
def make_description(input_path: Path, name: str, out_path: Path) -> WastDescription:
out_json_path = out_path / f"{name}.json"
result = subprocess.run(
["wast2json", input_path, f"--output={out_json_path}", "--no-check"],
)
result.check_returncode()
with open(out_json_path, "r") as f:
description = json.load(f)
return parse(description)
def gen_value_arg(value: WasmValue) -> str:
def unsigned_to_signed(uint: int, bits: int) -> int:
max_value = 2**bits
if uint >= 2 ** (bits - 1):
signed_int = uint - max_value
else:
signed_int = uint
return signed_int
def int_to_float_bitcast(uint: int) -> float:
b = struct.pack("I", uint)
f = struct.unpack("f", b)[0]
return f
def int_to_float64_bitcast(uint: int) -> float:
uint64 = uint & 0xFFFFFFFFFFFFFFFF
b = struct.pack("Q", uint64)
f = struct.unpack("d", b)[0]
return f
def float_to_str(bits: int, *, double=False) -> str:
f = int_to_float64_bitcast(bits) if double else int_to_float_bitcast(bits)
return str(f)
if value.value.startswith("nan"):
raise GenerateException("Should not get indeterminate nan value as an argument")
if value.value == "inf":
return "Infinity"
if value.value == "-inf":
return "-Infinity"
match value.kind:
case "i32":
return str(unsigned_to_signed(int(value.value), 32))
case "i64":
return str(unsigned_to_signed(int(value.value), 64)) + "n"
case "f32":
return str(int(value.value)) + f" /* {float_to_str(int(value.value))} */"
case "f64":
return (
str(int(value.value))
+ f"n /* {float_to_str(int(value.value), double=True)} */"
)
case "externref" | "funcref" | "v128":
return value.value
case _:
raise GenerateException(f"Not implemented: {value.kind}")
def gen_value_result(value: WasmValue) -> GeneratedValue:
if (value.kind == "f32" or value.kind == "f64") and value.value.startswith("nan"):
num_bits = int(value.kind[1:])
match value.value:
case "nan:canonical":
return CanonicalNan(num_bits)
case "nan:arithmetic":
return ArithmeticNan(num_bits)
case _:
raise GenerateException(f"Unknown indeterminate nan: {value.value}")
return gen_value_arg(value)
def gen_args(args: list[WasmValue]) -> str:
return ",".join(gen_value_arg(arg) for arg in args)
def gen_module_command(command: ModuleCommand, ctx: Context):
if ctx.has_unclosed:
print("});")
print(
f"""describe("{command.file_name.stem}", () => {{
let _test = test;
let content, module;
try {{
content = readBinaryWasmFile("Fixtures/SpecTests/{command.file_name}");
module = parseWebAssemblyModule(content, globalImportObject);
}} catch (e) {{
_test("parse", () => expect().fail(e));
_test = test.skip;
_test.skip = test.skip;
}}
"""
)
if command.name is not None:
print(f'namedModules["{command.name}"] = module;')
ctx.current_module_name = command.file_name.stem
ctx.has_unclosed = True
def gen_invalid(invalid: AssertInvalid, ctx: Context):
if ctx.has_unclosed:
print("});")
ctx.has_unclosed = False
stem = Path(invalid.filename).stem
print(
f"""
describe("{stem}", () => {{
let _test = test;
_test("parse of {stem} (line {invalid.line})", () => {{
content = readBinaryWasmFile("Fixtures/SpecTests/{invalid.filename}");
expect(() => parseWebAssemblyModule(content, globalImportObject)).toThrow(Error, "{invalid.message}");
}});
}});"""
)
def gen_invoke(
line: int,
invoke: Invoke,
result: WasmValue | None,
ctx: Context,
*,
fail_msg: str | None = None,
):
if not ctx.has_unclosed:
print(f'describe("inline (line {line}))", () => {{\nlet _test = test;\n')
module = "module"
if invoke.module is not None:
module = f'namedModules["{invoke.module}"]'
utf8 = (
str(invoke.field.encode("utf8"))[2:-1]
.replace("\\'", "'")
.replace("`", "${'`'}")
)
print(
f"""_test(`execution of {ctx.current_module_name}: {utf8} (line {line})`, () => {{
let _field = {module}.getExport(decodeURIComponent(escape(`{utf8}`)));
expect(_field).not.toBeUndefined();"""
)
if fail_msg is not None:
print(f'expect(() => {module}.invoke(_field)).toThrow(Error, "{fail_msg}");')
else:
print(f"let _result = {module}.invoke(_field, {gen_args(invoke.args)});")
if result is not None:
gen_result = gen_value_result(result)
match gen_result:
case str():
print(f"expect(_result).toBe({gen_result});")
case ArithmeticNan():
print(
f"expect(isArithmeticNaN{gen_result.num_bits}(_result)).toBe(true);"
)
case CanonicalNan():
print(
f"expect(isCanonicalNaN{gen_result.num_bits}(_result)).toBe(true);"
)
print("});")
if not ctx.has_unclosed:
print("});")
def gen_get(line: int, get: Get, result: WasmValue | None, ctx: Context):
module = "module"
if get.module is not None:
module = f'namedModules["{get.module}"]'
print(
f"""_test("execution of {ctx.current_module_name}: get-{get.field} (line {line})", () => {{
let _field = {module}.getExport("{get.field}");"""
)
if result is not None:
print(f"expect(_field).toBe({gen_value_result(result)});")
print("});")
def gen_register(register: Register, _: Context):
module = "module"
if register.name is not None:
module = f'namedModules["{register.name}"]'
print(f'globalImportObject["{register.as_}"] = {module};')
def gen_command(command: Command, ctx: Context):
match command:
case ModuleCommand():
gen_module_command(command, ctx)
case ActionCommand():
if isinstance(command.action, Invoke):
gen_invoke(command.line, command.action, None, ctx)
else:
raise GenerateException(
f"Not implemented: top-level {type(command.action)}"
)
case AssertInvalid():
gen_invalid(command, ctx)
case Register():
gen_register(command, ctx)
case AssertReturn():
match command.action:
case Invoke():
gen_invoke(command.line, command.action, command.expected, ctx)
case Get():
gen_get(command.line, command.action, command.expected, ctx)
case AssertTrap():
if not isinstance(command.action, Invoke):
raise GenerateException(f"Not implemented: {type(command.action)}")
gen_invoke(
command.line, command.action, None, ctx, fail_msg=command.messsage
)
def generate(description: WastDescription):
print("let globalImportObject = {};\nlet namedModules = {};\n")
ctx = Context("", False)
for command in description.commands:
gen_command(command, ctx)
if ctx.has_unclosed:
print("});")
def clean_up(path: Path):
for file in path.iterdir():
if file.suffix in ("wat", "json"):
file.unlink()
def main():
input_path = Path(sys.argv[1])
name = sys.argv[2]
out_path = Path(sys.argv[3])
description = make_description(input_path, name, out_path)
generate(description)
clean_up(out_path)
if __name__ == "__main__":
main()