langchain/libs/community/langchain_community/tools/e2b_data_analysis/unparse.py

# mypy: disable-error-code=no-untyped-def
# Because Python >3.9 doesn't support ast.unparse,
# we copied the unparse functionality from here:
# https://github.com/python/cpython/blob/3.8/Tools/parser/unparse.py
"Usage: unparse.py <path to source file>"
import ast
import io
import sys
import tokenize

# Large float and imaginary literals get turned into infinities in the AST.
# We unparse those infinities to INFSTR.
INFSTR = "1e" + repr(sys.float_info.max_10_exp + 1)


def interleave(inter, f, seq):
    """Call f on each item in seq, calling inter() in between."""
    seq = iter(seq)
    try:
        f(next(seq))
    except StopIteration:
        pass
    else:
        for x in seq:
            inter()
            f(x)


class Unparser:
    """Methods in this class recursively traverse an AST and
    output source code for the abstract syntax; original formatting
    is disregarded."""

    def __init__(self, tree, file=sys.stdout):
        """Unparser(tree, file=sys.stdout) -> None.
        Print the source for tree to file."""
        self.f = file
        self._indent = 0
        self.dispatch(tree)
        self.f.flush()

    def fill(self, text=""):
        "Indent a piece of text, according to the current indentation level"
        self.f.write("\n" + "    " * self._indent + text)

    def write(self, text):
        "Append a piece of text to the current line."
        self.f.write(text)

    def enter(self):
        "Print ':', and increase the indentation."
        self.write(":")
        self._indent += 1

    def leave(self):
        "Decrease the indentation level."
        self._indent -= 1

    def dispatch(self, tree):
        "Dispatcher function, dispatching tree type T to method _T."
        if isinstance(tree, list):
            for t in tree:
                self.dispatch(t)
            return
        meth = getattr(self, "_" + tree.__class__.__name__)
        meth(tree)

    ############### Unparsing methods ######################
    # There should be one method per concrete grammar type #
    # Constructors should be grouped by sum type. Ideally, #
    # this would follow the order in the grammar, but      #
    # currently doesn't.                                   #
    ########################################################

    def _Module(self, tree):
        for stmt in tree.body:
            self.dispatch(stmt)

    # stmt
    def _Expr(self, tree):
        self.fill()
        self.dispatch(tree.value)

    def _NamedExpr(self, tree):
        self.write("(")
        self.dispatch(tree.target)
        self.write(" := ")
        self.dispatch(tree.value)
        self.write(")")

    def _Import(self, t):
        self.fill("import ")
        interleave(lambda: self.write(", "), self.dispatch, t.names)

    def _ImportFrom(self, t):
        self.fill("from ")
        self.write("." * t.level)
        if t.module:
            self.write(t.module)
        self.write(" import ")
        interleave(lambda: self.write(", "), self.dispatch, t.names)

    def _Assign(self, t):
        self.fill()
        for target in t.targets:
            self.dispatch(target)
            self.write(" = ")
        self.dispatch(t.value)

    def _AugAssign(self, t):
        self.fill()
        self.dispatch(t.target)
        self.write(" " + self.binop[t.op.__class__.__name__] + "= ")
        self.dispatch(t.value)

    def _AnnAssign(self, t):
        self.fill()
        if not t.simple and isinstance(t.target, ast.Name):
            self.write("(")
        self.dispatch(t.target)
        if not t.simple and isinstance(t.target, ast.Name):
            self.write(")")
        self.write(": ")
        self.dispatch(t.annotation)
        if t.value:
            self.write(" = ")
            self.dispatch(t.value)

    def _Return(self, t):
        self.fill("return")
        if t.value:
            self.write(" ")
            self.dispatch(t.value)

    def _Pass(self, t):
        self.fill("pass")

    def _Break(self, t):
        self.fill("break")

    def _Continue(self, t):
        self.fill("continue")

    def _Delete(self, t):
        self.fill("del ")
        interleave(lambda: self.write(", "), self.dispatch, t.targets)

    def _Assert(self, t):
        self.fill("assert ")
        self.dispatch(t.test)
        if t.msg:
            self.write(", ")
            self.dispatch(t.msg)

    def _Global(self, t):
        self.fill("global ")
        interleave(lambda: self.write(", "), self.write, t.names)

    def _Nonlocal(self, t):
        self.fill("nonlocal ")
        interleave(lambda: self.write(", "), self.write, t.names)

    def _Await(self, t):
        self.write("(")
        self.write("await")
        if t.value:
            self.write(" ")
            self.dispatch(t.value)
        self.write(")")

    def _Yield(self, t):
        self.write("(")
        self.write("yield")
        if t.value:
            self.write(" ")
            self.dispatch(t.value)
        self.write(")")

    def _YieldFrom(self, t):
        self.write("(")
        self.write("yield from")
        if t.value:
            self.write(" ")
            self.dispatch(t.value)
        self.write(")")

    def _Raise(self, t):
        self.fill("raise")
        if not t.exc:
            assert not t.cause
            return
        self.write(" ")
        self.dispatch(t.exc)
        if t.cause:
            self.write(" from ")
            self.dispatch(t.cause)

    def _Try(self, t):
        self.fill("try")
        self.enter()
        self.dispatch(t.body)
        self.leave()
        for ex in t.handlers:
            self.dispatch(ex)
        if t.orelse:
            self.fill("else")
            self.enter()
            self.dispatch(t.orelse)
            self.leave()
        if t.finalbody:
            self.fill("finally")
            self.enter()
            self.dispatch(t.finalbody)
            self.leave()

    def _ExceptHandler(self, t):
        self.fill("except")
        if t.type:
            self.write(" ")
            self.dispatch(t.type)
        if t.name:
            self.write(" as ")
            self.write(t.name)
        self.enter()
        self.dispatch(t.body)
        self.leave()

    def _ClassDef(self, t):
        self.write("\n")
        for deco in t.decorator_list:
            self.fill("@")
            self.dispatch(deco)
        self.fill("class " + t.name)
        self.write("(")
        comma = False
        for e in t.bases:
            if comma:
                self.write(", ")
            else:
                comma = True
            self.dispatch(e)
        for e in t.keywords:
            if comma:
                self.write(", ")
            else:
                comma = True
            self.dispatch(e)
        self.write(")")

        self.enter()
        self.dispatch(t.body)
        self.leave()

    def _FunctionDef(self, t):
        self.__FunctionDef_helper(t, "def")

    def _AsyncFunctionDef(self, t):
        self.__FunctionDef_helper(t, "async def")

    def __FunctionDef_helper(self, t, fill_suffix):
        self.write("\n")
        for deco in t.decorator_list:
            self.fill("@")
            self.dispatch(deco)
        def_str = fill_suffix + " " + t.name + "("
        self.fill(def_str)
        self.dispatch(t.args)
        self.write(")")
        if t.returns:
            self.write(" -> ")
            self.dispatch(t.returns)
        self.enter()
        self.dispatch(t.body)
        self.leave()

    def _For(self, t):
        self.__For_helper("for ", t)

    def _AsyncFor(self, t):
        self.__For_helper("async for ", t)

    def __For_helper(self, fill, t):
        self.fill(fill)
        self.dispatch(t.target)
        self.write(" in ")
        self.dispatch(t.iter)
        self.enter()
        self.dispatch(t.body)
        self.leave()
        if t.orelse:
            self.fill("else")
            self.enter()
            self.dispatch(t.orelse)
            self.leave()

    def _If(self, t):
        self.fill("if ")
        self.dispatch(t.test)
        self.enter()
        self.dispatch(t.body)
        self.leave()
        # collapse nested ifs into equivalent elifs.
        while t.orelse and len(t.orelse) == 1 and isinstance(t.orelse[0], ast.If):
            t = t.orelse[0]
            self.fill("elif ")
            self.dispatch(t.test)
            self.enter()
            self.dispatch(t.body)
            self.leave()
        # final else
        if t.orelse:
            self.fill("else")
            self.enter()
            self.dispatch(t.orelse)
            self.leave()

    def _While(self, t):
        self.fill("while ")
        self.dispatch(t.test)
        self.enter()
        self.dispatch(t.body)
        self.leave()
        if t.orelse:
            self.fill("else")
            self.enter()
            self.dispatch(t.orelse)
            self.leave()

    def _With(self, t):
        self.fill("with ")
        interleave(lambda: self.write(", "), self.dispatch, t.items)
        self.enter()
        self.dispatch(t.body)
        self.leave()

    def _AsyncWith(self, t):
        self.fill("async with ")
        interleave(lambda: self.write(", "), self.dispatch, t.items)
        self.enter()
        self.dispatch(t.body)
        self.leave()

    # expr
    def _JoinedStr(self, t):
        self.write("f")
        string = io.StringIO()
        self._fstring_JoinedStr(t, string.write)
        self.write(repr(string.getvalue()))

    def _FormattedValue(self, t):
        self.write("f")
        string = io.StringIO()
        self._fstring_FormattedValue(t, string.write)
        self.write(repr(string.getvalue()))

    def _fstring_JoinedStr(self, t, write):
        for value in t.values:
            meth = getattr(self, "_fstring_" + type(value).__name__)
            meth(value, write)

    def _fstring_Constant(self, t, write):
        assert isinstance(t.value, str)
        value = t.value.replace("{", "{{").replace("}", "}}")
        write(value)

    def _fstring_FormattedValue(self, t, write):
        write("{")
        expr = io.StringIO()
        Unparser(t.value, expr)
        expr = expr.getvalue().rstrip("\n")
        if expr.startswith("{"):
            write(" ")  # Separate pair of opening brackets as "{ {"
        write(expr)
        if t.conversion != -1:
            conversion = chr(t.conversion)
            assert conversion in "sra"
            write(f"!{conversion}")
        if t.format_spec:
            write(":")
            meth = getattr(self, "_fstring_" + type(t.format_spec).__name__)
            meth(t.format_spec, write)
        write("}")

    def _Name(self, t):
        self.write(t.id)

    def _write_constant(self, value):
        if isinstance(value, (float, complex)):
            # Substitute overflowing decimal literal for AST infinities.
            self.write(repr(value).replace("inf", INFSTR))
        else:
            self.write(repr(value))

    def _Constant(self, t):
        value = t.value
        if isinstance(value, tuple):
            self.write("(")
            if len(value) == 1:
                self._write_constant(value[0])
                self.write(",")
            else:
                interleave(lambda: self.write(", "), self._write_constant, value)
            self.write(")")
        elif value is ...:
            self.write("...")
        else:
            if t.kind == "u":
                self.write("u")
            self._write_constant(t.value)

    def _List(self, t):
        self.write("[")
        interleave(lambda: self.write(", "), self.dispatch, t.elts)
        self.write("]")

    def _ListComp(self, t):
        self.write("[")
        self.dispatch(t.elt)
        for gen in t.generators:
            self.dispatch(gen)
        self.write("]")

    def _GeneratorExp(self, t):
        self.write("(")
        self.dispatch(t.elt)
        for gen in t.generators:
            self.dispatch(gen)
        self.write(")")

    def _SetComp(self, t):
        self.write("{")
        self.dispatch(t.elt)
        for gen in t.generators:
            self.dispatch(gen)
        self.write("}")

    def _DictComp(self, t):
        self.write("{")
        self.dispatch(t.key)
        self.write(": ")
        self.dispatch(t.value)
        for gen in t.generators:
            self.dispatch(gen)
        self.write("}")

    def _comprehension(self, t):
        if t.is_async:
            self.write(" async for ")
        else:
            self.write(" for ")
        self.dispatch(t.target)
        self.write(" in ")
        self.dispatch(t.iter)
        for if_clause in t.ifs:
            self.write(" if ")
            self.dispatch(if_clause)

    def _IfExp(self, t):
        self.write("(")
        self.dispatch(t.body)
        self.write(" if ")
        self.dispatch(t.test)
        self.write(" else ")
        self.dispatch(t.orelse)
        self.write(")")

    def _Set(self, t):
        assert t.elts  # should be at least one element
        self.write("{")
        interleave(lambda: self.write(", "), self.dispatch, t.elts)
        self.write("}")

    def _Dict(self, t):
        self.write("{")

        def write_key_value_pair(k, v):
            self.dispatch(k)
            self.write(": ")
            self.dispatch(v)

        def write_item(item):
            k, v = item
            if k is None:
                # for dictionary unpacking operator in dicts {**{'y': 2}}
                # see PEP 448 for details
                self.write("**")
                self.dispatch(v)
            else:
                write_key_value_pair(k, v)

        interleave(lambda: self.write(", "), write_item, zip(t.keys, t.values))
        self.write("}")

    def _Tuple(self, t):
        self.write("(")
        if len(t.elts) == 1:
            elt = t.elts[0]
            self.dispatch(elt)
            self.write(",")
        else:
            interleave(lambda: self.write(", "), self.dispatch, t.elts)
        self.write(")")

    unop = {"Invert": "~", "Not": "not", "UAdd": "+", "USub": "-"}

    def _UnaryOp(self, t):
        self.write("(")
        self.write(self.unop[t.op.__class__.__name__])
        self.write(" ")
        self.dispatch(t.operand)
        self.write(")")

    binop = {
        "Add": "+",
        "Sub": "-",
        "Mult": "*",
        "MatMult": "@",
        "Div": "/",
        "Mod": "%",
        "LShift": "<<",
        "RShift": ">>",
        "BitOr": "|",
        "BitXor": "^",
        "BitAnd": "&",
        "FloorDiv": "//",
        "Pow": "**",
    }

    def _BinOp(self, t):
        self.write("(")
        self.dispatch(t.left)
        self.write(" " + self.binop[t.op.__class__.__name__] + " ")
        self.dispatch(t.right)
        self.write(")")

    cmpops = {
        "Eq": "==",
        "NotEq": "!=",
        "Lt": "<",
        "LtE": "<=",
        "Gt": ">",
        "GtE": ">=",
        "Is": "is",
        "IsNot": "is not",
        "In": "in",
        "NotIn": "not in",
    }

    def _Compare(self, t):
        self.write("(")
        self.dispatch(t.left)
        for o, e in zip(t.ops, t.comparators):
            self.write(" " + self.cmpops[o.__class__.__name__] + " ")
            self.dispatch(e)
        self.write(")")

    boolops = {ast.And: "and", ast.Or: "or"}

    def _BoolOp(self, t):
        self.write("(")
        s = " %s " % self.boolops[t.op.__class__]
        interleave(lambda: self.write(s), self.dispatch, t.values)
        self.write(")")

    def _Attribute(self, t):
        self.dispatch(t.value)
        # Special case: 3.__abs__() is a syntax error, so if t.value
        # is an integer literal then we need to either parenthesize
        # it or add an extra space to get 3 .__abs__().
        if isinstance(t.value, ast.Constant) and isinstance(t.value.value, int):
            self.write(" ")
        self.write(".")
        self.write(t.attr)

    def _Call(self, t):
        self.dispatch(t.func)
        self.write("(")
        comma = False
        for e in t.args:
            if comma:
                self.write(", ")
            else:
                comma = True
            self.dispatch(e)
        for e in t.keywords:
            if comma:
                self.write(", ")
            else:
                comma = True
            self.dispatch(e)
        self.write(")")

    def _Subscript(self, t):
        self.dispatch(t.value)
        self.write("[")
        if (
            isinstance(t.slice, ast.Index)
            and isinstance(t.slice.value, ast.Tuple)
            and t.slice.value.elts
        ):
            if len(t.slice.value.elts) == 1:
                elt = t.slice.value.elts[0]
                self.dispatch(elt)
                self.write(",")
            else:
                interleave(lambda: self.write(", "), self.dispatch, t.slice.value.elts)
        else:
            self.dispatch(t.slice)
        self.write("]")

    def _Starred(self, t):
        self.write("*")
        self.dispatch(t.value)

    # slice
    def _Ellipsis(self, t):
        self.write("...")

    def _Index(self, t):
        self.dispatch(t.value)

    def _Slice(self, t):
        if t.lower:
            self.dispatch(t.lower)
        self.write(":")
        if t.upper:
            self.dispatch(t.upper)
        if t.step:
            self.write(":")
            self.dispatch(t.step)

    def _ExtSlice(self, t):
        if len(t.dims) == 1:
            elt = t.dims[0]
            self.dispatch(elt)
            self.write(",")
        else:
            interleave(lambda: self.write(", "), self.dispatch, t.dims)

    # argument
    def _arg(self, t):
        self.write(t.arg)
        if t.annotation:
            self.write(": ")
            self.dispatch(t.annotation)

    # others
    def _arguments(self, t):
        first = True
        # normal arguments
        all_args = t.posonlyargs + t.args
        defaults = [None] * (len(all_args) - len(t.defaults)) + t.defaults
        for index, elements in enumerate(zip(all_args, defaults), 1):
            a, d = elements
            if first:
                first = False
            else:
                self.write(", ")
            self.dispatch(a)
            if d:
                self.write("=")
                self.dispatch(d)
            if index == len(t.posonlyargs):
                self.write(", /")

        # varargs, or bare '*' if no varargs but keyword-only arguments present
        if t.vararg or t.kwonlyargs:
            if first:
                first = False
            else:
                self.write(", ")
            self.write("*")
            if t.vararg:
                self.write(t.vararg.arg)
                if t.vararg.annotation:
                    self.write(": ")
                    self.dispatch(t.vararg.annotation)

        # keyword-only arguments
        if t.kwonlyargs:
            for a, d in zip(t.kwonlyargs, t.kw_defaults):
                if first:
                    first = False
                else:
                    self.write(", ")
                self.dispatch(a)
                if d:
                    self.write("=")
                    self.dispatch(d)

        # kwargs
        if t.kwarg:
            if first:
                first = False
            else:
                self.write(", ")
            self.write("**" + t.kwarg.arg)
            if t.kwarg.annotation:
                self.write(": ")
                self.dispatch(t.kwarg.annotation)

    def _keyword(self, t):
        if t.arg is None:
            self.write("**")
        else:
            self.write(t.arg)
            self.write("=")
        self.dispatch(t.value)

    def _Lambda(self, t):
        self.write("(")
        self.write("lambda ")
        self.dispatch(t.args)
        self.write(": ")
        self.dispatch(t.body)
        self.write(")")

    def _alias(self, t):
        self.write(t.name)
        if t.asname:
            self.write(" as " + t.asname)

    def _withitem(self, t):
        self.dispatch(t.context_expr)
        if t.optional_vars:
            self.write(" as ")
            self.dispatch(t.optional_vars)


def roundtrip(filename, output=sys.stdout):
    with open(filename, "rb") as pyfile:
        encoding = tokenize.detect_encoding(pyfile.readline)[0]
    with open(filename, "r", encoding=encoding) as pyfile:
        source = pyfile.read()
    tree = compile(source, filename, "exec", ast.PyCF_ONLY_AST)
    Unparser(tree, output)