233 lines
7.9 KiB
Python
233 lines
7.9 KiB
Python
from typing import *
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import textwrap
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import re
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import copy
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import json
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from collections import defaultdict
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from re import Pattern
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from agast import *
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global i
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i = 0
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def gensym(prefix: str = "", suffix: str = "") -> str:
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global i
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presan = re.sub("[^0-9a-zA-Z]+", "_", prefix)
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sufsan = re.sub("[^0-9a-zA-Z]+", "_", suffix)
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i += 1
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return f"{presan}{i}{sufsan}"
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class NodeDesc:
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def __init__(self, node: Node):
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self.node = node
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self.name = node.name
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self.nonterminal = node.name.lower()
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class ParseEquation:
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def __init__(self, name: str, syms: List[str], ty: str):
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self.name = name
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self.syms = syms
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self.ty = ty
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class GenResult:
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def __init__(self, pd: str = "", ex: str = ""):
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self.literals: Dict[str, str] = dict()
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self.parse_rules: defaultdict[str, List[ParseEquation]] = defaultdict(list)
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self.starts: Set[str] = set()
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self.extra = ex
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self.trans: List[str] = list()
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@property
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def transdef(self) -> str:
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s = self.trans
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for name, rules in self.parse_rules.items():
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n = name.lstrip("?")
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for equation in rules:
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code = f"""
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def {equation.name}(self, items: Any) -> Thunk[{equation.ty}]:
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return Thunk(lambda: {equation.ty}())
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""".strip().replace("\n", "")
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code = re.sub(r"\s+", " ", code)
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s.append(code)
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if not s:
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s = ["pass"]
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return "\n" + "\n".join(map(lambda c: f" {c}", s))
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@property
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def parser_data(self) -> str:
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s = []
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for sym, pat in self.literals.items():
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s.append(f"{sym}: {pat}")
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for name, rules in self.parse_rules.items():
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names = []
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for rule in rules:
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names.append(rule.name)
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s.append(f"{rule.name}: {' '.join(rule.syms)}")
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s.append(f"{name}: {' | '.join(names)}")
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s.append("%import common.WS")
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s.append("%ignore WS")
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return "\n".join(s)
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def gen(program: List[Decl]) -> GenResult:
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res = GenResult()
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def v(name: str) -> str:
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return f"__ag_{name}"
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# builtins
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builtins: Dict[str, str] = {
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"parseInt": "",
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}
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# collect a list of name -> iface declarations
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ifaces: Dict[str, Iface] = dict(
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map(
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lambda c: (c.name, cast(Iface, c)),
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filter(lambda c: isinstance(c, Iface), program),
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)
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)
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# list of node -> iface mappings
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what_ifaces: Dict[str, Set[str]] = dict()
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what_fields: Dict[str, Dict[str, str]] = dict()
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for node in filter(lambda c: isinstance(c, Node), program):
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node = cast(Node, node)
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# all_fields = dict()
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what_ifaces[node.name] = set(node.ifaces)
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this_fields = dict()
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for iface in node.ifaces:
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fields = ifaces[iface].fields
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for field in fields:
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if field.name in this_fields:
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raise Exception("duplicate field name")
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this_fields[field.name] = field.ty
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what_fields[node.name] = this_fields
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print("what_ifaces:", what_ifaces)
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print("what_fields:", what_fields)
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# a high-level dictionary of productions; this has sub-productions
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# that should be further expanded at a later step before converting
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# into lark code
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productions_hi: Dict[str, Union[str, List[str]]] = dict()
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# TODO: this should probably not be inlined here, but i'll move it
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# out once i get more info into the 'env'
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def collect_required_thunks(
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env: List[Tuple[str, NodeRef]], expr: Expr
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) -> Dict[str, str]:
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names = dict(env)
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print(f"collect_required_thunks({expr})", expr.__class__)
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if isinstance(expr, ExprDot):
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return collect_required_thunks(env, expr.left)
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elif isinstance(expr, ExprMul):
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a = collect_required_thunks(env, expr.left)
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b = collect_required_thunks(env, expr.right)
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a.update(b)
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return a
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elif isinstance(expr, ExprAdd):
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a = collect_required_thunks(env, expr.left)
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b = collect_required_thunks(env, expr.right)
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a.update(b)
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return a
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elif isinstance(expr, ExprCall):
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return collect_required_thunks(env, expr.func)
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elif isinstance(expr, ExprName):
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if expr.name not in names and expr.name not in builtins:
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raise Exception(f"unbound name '{expr.name}'")
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return dict()
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raise Exception(f"unhandled {expr.__class__}")
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node_map: Dict[str, NodeDesc] = dict(
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map(
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lambda n: (n.name, NodeDesc(cast(Node, n))),
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filter(lambda c: isinstance(c, Node), program),
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)
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)
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for node_desc in node_map.values():
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assert isinstance(node_desc, NodeDesc)
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res.starts.add(node_desc.name.lower())
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# res.parse_rules[f"?{node_desc.name.lower()}"].append(
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# ParseEquation(
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# node_desc.name.lower(), [node_desc.nonterminal], node_desc.nonterminal
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# )
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# )
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class_decl = textwrap.dedent(
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f"""
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class {node_desc.nonterminal}: pass
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"""
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)
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res.extra += class_decl
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print(node_desc.name, node_desc.node.ifaces)
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for variant in node_desc.node.variants:
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v_class_name = gensym(f"{node_desc.nonterminal}_var")
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class_decl = textwrap.dedent(
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f"""
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class {v_class_name}({node_desc.nonterminal}):
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''' '''
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pass
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"""
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)
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res.extra += class_decl
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prod_name = gensym(node_desc.nonterminal + "_")
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print("PRODUCTION", prod_name, variant.prod)
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# resolving a production just means checking to make sure it's a
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# type that exists or it's a regex
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def resolve_production(sym: Sym) -> str:
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print(f"resolve_production({sym})")
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if isinstance(sym, SymRename):
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if isinstance(sym.ty, NodeRefByName):
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if sym.ty.name in node_map:
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return node_map[sym.ty.name].nonterminal
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else:
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raise Exception(
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f"unresolved name {sym.ty.name} in production"
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)
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elif isinstance(sym.ty, NodeRegex):
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sym_name = gensym("sym")
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res.literals[sym_name] = f"/{sym.ty.pat.pattern}/"
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return sym_name
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elif isinstance(sym, SymLit):
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sym_name = gensym("lit")
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# hack to make repr have double quotes
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res.literals[sym_name] = json.dumps(sym.lit)
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return sym_name
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raise Exception(f"unhandled {sym.__class__}")
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seq = []
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for sym in variant.prod:
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n = resolve_production(sym)
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seq.append(n)
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res.parse_rules[node_desc.nonterminal].append(ParseEquation(prod_name, seq, v_class_name))
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# create an environment for checking the equations based on
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# the production
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env: List[Tuple[str, NodeRef]] = list()
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for sym in variant.prod:
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if isinstance(sym, SymRename):
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env.append((sym.name, sym.ty))
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print(env)
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# for each of the equations, find out what the equation is
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# trying to compute, and generate a thunk corresponding to
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# that value.
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for eq in variant.equations:
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eq_name = gensym(f"eq_{node_desc.name}")
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thunk_name = gensym(f"thunk_{node_desc.name}")
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print("RHS", eq.rhs, eq.rhs.id)
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collect_required_thunks(copy.deepcopy(env), eq.rhs)
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return res
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