#include "eval.hh"
#include "parser.hh"
EvalState::EvalState()
: normalForms(32768, 50)
{
blackHole = ATmake("BlackHole()");
if (!blackHole) throw Error("cannot build black hole");
nrEvaluated = nrCached = 0;
addPrimOps();
}
void EvalState::addPrimOp(const string & name,
unsigned int arity, PrimOp primOp)
{
primOps.set(name, ATmake("(<int>, <term>)",
arity, ATmakeBlob(0, (void *) primOp)));
}
/* Substitute an argument set into the body of a function. */
static Expr substArgs(Expr body, ATermList formals, Expr arg)
{
ATMatcher m;
ATermMap subs;
Expr undefined = ATmake("Undefined");
/* Get the formal arguments. */
for (ATermIterator i(formals); i; ++i) {
Expr name, def;
if (atMatch(m, *i) >> "NoDefFormal" >> name)
subs.set(name, undefined);
else if (atMatch(m, *i) >> "DefFormal" >> name >> def)
subs.set(name, def);
else abort(); /* can't happen */
}
/* Get the actual arguments, and check that they match with the
formals. */
ATermMap args;
queryAllAttrs(arg, args);
for (ATermIterator i(args.keys()); i; ++i) {
Expr key = *i;
Expr cur = subs.get(key);
if (!cur)
throw Error(format("unexpected function argument `%1%'")
% aterm2String(key));
subs.set(key, args.get(key));
}
/* Check that all arguments are defined. */
for (ATermIterator i(subs.keys()); i; ++i)
if (subs.get(*i) == undefined)
throw Error(format("required function argument `%1%' missing")
% aterm2String(*i));
return substitute(subs, body);
}
/* Transform a mutually recursive set into a non-recursive set. Each
attribute is transformed into an expression that has all references
to attributes substituted with selection expressions on the
original set. E.g., e = `rec {x = f x y; y = x;}' becomes `{x = f
(e.x) (e.y); y = e.x;}'. */
ATerm expandRec(ATerm e, ATermList rbnds, ATermList nrbnds)
{
ATMatcher m;
ATerm name;
Expr e2;
/* Create the substitution list. */
ATermMap subs;
for (ATermIterator i(rbnds); i; ++i) {
if (!(atMatch(m, *i) >> "Bind" >> name >> e2))
abort(); /* can't happen */
subs.set(name, ATmake("Select(<term>, <term>)", e, name));
}
for (ATermIterator i(nrbnds); i; ++i) {
if (!(atMatch(m, *i) >> "Bind" >> name >> e2))
abort(); /* can't happen */
subs.set(name, e2);
}
/* Create the non-recursive set. */
ATermMap as;
for (ATermIterator i(rbnds); i; ++i) {
ATerm pos;
if (!(atMatch(m, *i) >> "Bind" >> name >> e2 >> pos))
abort(); /* can't happen */
as.set(name, ATmake("(<term>, <term>)", substitute(subs, e2), pos));
}
/* Copy the non-recursive bindings. !!! inefficient */
for (ATermIterator i(nrbnds); i; ++i) {
ATerm pos;
if (!(atMatch(m, *i) >> "Bind" >> name >> e2 >> pos))
abort(); /* can't happen */
as.set(name, ATmake("(<term>, <term>)", e2, pos));
}
return makeAttrs(as);
}
static Expr updateAttrs(Expr e1, Expr e2)
{
/* Note: e1 and e2 should be in normal form. */
ATermMap attrs;
queryAllAttrs(e1, attrs, true);
queryAllAttrs(e2, attrs, true);
return makeAttrs(attrs);
}
string evalString(EvalState & state, Expr e)
{
e = evalExpr(state, e);
ATMatcher m;
string s;
if (!(atMatch(m, e) >> "Str" >> s))
throw Error("string expected");
return s;
}
Path evalPath(EvalState & state, Expr e)
{
e = evalExpr(state, e);
ATMatcher m;
string s;
if (!(atMatch(m, e) >> "Path" >> s))
throw Error("path expected");
return s;
}
bool evalBool(EvalState & state, Expr e)
{
e = evalExpr(state, e);
ATMatcher m;
if (atMatch(m, e) >> "Bool" >> "True") return true;
else if (atMatch(m, e) >> "Bool" >> "False") return false;
else throw Error("boolean expected");
}
Expr evalExpr2(EvalState & state, Expr e)
{
ATMatcher m;
Expr e1, e2, e3, e4;
ATerm name, pos;
/* Normal forms. */
string cons;
if (atMatch(m, e) >> cons &&
(cons == "Str" ||
cons == "Path" ||
cons == "SubPath" ||
cons == "Uri" ||
cons == "Null" ||
cons == "Int" ||
cons == "Bool" ||
cons == "Function" ||
cons == "Function1" ||
cons == "Attrs" ||
cons == "List" ||
cons == "PrimOp"))
return e;
/* The `Closed' constructor is just a way to prevent substitutions
into expressions not containing free variables. */
if (atMatch(m, e) >> "Closed" >> e1)
return evalExpr(state, e1);
/* Any encountered variables must be primops (since undefined
variables are detected after parsing). */
if (atMatch(m, e) >> "Var" >> name) {
ATerm primOp = state.primOps.get(name);
if (!primOp)
throw Error(format("impossible: undefined variable `%1%'") % name);
int arity;
ATerm fun;
if (!(atMatch(m, primOp) >> "" >> arity >> fun)) abort();
if (arity == 0)
return ((PrimOp) ATgetBlobData((ATermBlob) fun))
(state, ATermVector());
else
return ATmake("PrimOp(<int>, <term>, <term>)",
arity, fun, ATempty);
}
/* Function application. */
if (atMatch(m, e) >> "Call" >> e1 >> e2) {
ATermList formals;
ATerm pos;
/* Evaluate the left-hand side. */
e1 = evalExpr(state, e1);
/* Is it a primop or a function? */
int arity;
ATerm fun;
ATermList args;
if (atMatch(m, e1) >> "PrimOp" >> arity >> fun >> args) {
args = ATinsert(args, e2);
if (ATgetLength(args) == arity) {
/* Put the arguments in a vector in reverse (i.e.,
actual) order. */
ATermVector args2(arity);
for (ATermIterator i(args); i; ++i)
args2[--arity] = *i;
return ((PrimOp) ATgetBlobData((ATermBlob) fun))
(state, args2);
} else
/* Need more arguments, so propagate the primop. */
return ATmake("PrimOp(<int>, <term>, <term>)",
arity, fun, args);
}
else if (atMatch(m, e1) >> "Function" >> formals >> e4 >> pos) {
e2 = evalExpr(state, e2);
try {
return evalExpr(state, substArgs(e4, formals, e2));
} catch (Error & e) {
throw Error(format("while evaluating function at %1%:\n%2%")
% showPos(pos) % e.msg());
}
}
else if (atMatch(m, e1) >> "Function1" >> name >> e4 >> pos) {
try {
ATermMap subs;
subs.set(name, e2);
return evalExpr(state, substitute(subs, e4));
} catch (Error & e) {
throw Error(format("while evaluating function at %1%:\n%2%")
% showPos(pos) % e.msg());
}
}
else throw Error("function or primop expected in function call");
}
/* Attribute selection. */
string s1;
if (atMatch(m, e) >> "Select" >> e1 >> s1) {
ATerm pos;
Expr a = queryAttr(evalExpr(state, e1), s1, pos);
if (!a) throw Error(format("attribute `%1%' missing") % s1);
try {
return evalExpr(state, a);
} catch (Error & e) {
throw Error(format("while evaluating attribute `%1%' at %2%:\n%3%")
% s1 % showPos(pos) % e.msg());
}
}
/* Mutually recursive sets. */
ATermList rbnds, nrbnds;
if (atMatch(m, e) >> "Rec" >> rbnds >> nrbnds)
return expandRec(e, rbnds, nrbnds);
/* Conditionals. */
if (atMatch(m, e) >> "If" >> e1 >> e2 >> e3) {
if (evalBool(state, e1))
return evalExpr(state, e2);
else
return evalExpr(state, e3);
}
/* Assertions. */
if (atMatch(m, e) >> "Assert" >> e1 >> e2 >> pos) {
if (!evalBool(state, e1))
throw Error(format("assertion failed at %1%") % showPos(pos));
return evalExpr(state, e2);
}
/* Generic equality. */
if (atMatch(m, e) >> "OpEq" >> e1 >> e2)
return makeBool(evalExpr(state, e1) == evalExpr(state, e2));
/* Generic inequality. */
if (atMatch(m, e) >> "OpNEq" >> e1 >> e2)
return makeBool(evalExpr(state, e1) != evalExpr(state, e2));
/* Negation. */
if (atMatch(m, e) >> "OpNot" >> e1)
return makeBool(!evalBool(state, e1));
/* Implication. */
if (atMatch(m, e) >> "OpImpl" >> e1 >> e2)
return makeBool(!evalBool(state, e1) || evalBool(state, e2));
/* Conjunction (logical AND). */
if (atMatch(m, e) >> "OpAnd" >> e1 >> e2)
return makeBool(evalBool(state, e1) && evalBool(state, e2));
/* Disjunction (logical OR). */
if (atMatch(m, e) >> "OpOr" >> e1 >> e2)
return makeBool(evalBool(state, e1) || evalBool(state, e2));
/* Attribute set update (//). */
if (atMatch(m, e) >> "OpUpdate" >> e1 >> e2)
return updateAttrs(evalExpr(state, e1), evalExpr(state, e2));
/* Attribute existence test (?). */
if (atMatch(m, e) >> "OpHasAttr" >> e1 >> name) {
ATermMap attrs;
queryAllAttrs(evalExpr(state, e1), attrs);
return makeBool(attrs.get(name) != 0);
}
/* Barf. */
throw badTerm("invalid expression", e);
}
Expr evalExpr(EvalState & state, Expr e)
{
checkInterrupt();
startNest(nest, lvlVomit,
format("evaluating expression: %1%") % e);
state.nrEvaluated++;
/* Consult the memo table to quickly get the normal form of
previously evaluated expressions. */
Expr nf = state.normalForms.get(e);
if (nf) {
if (nf == state.blackHole)
throw Error("infinite recursion encountered");
state.nrCached++;
return nf;
}
/* Otherwise, evaluate and memoize. */
state.normalForms.set(e, state.blackHole);
nf = evalExpr2(state, e);
state.normalForms.set(e, nf);
return nf;
}
Expr evalFile(EvalState & state, const Path & path)
{
startNest(nest, lvlTalkative, format("evaluating file `%1%'") % path);
Expr e = parseExprFromFile(state, path);
try {
return evalExpr(state, e);
} catch (Error & e) {
throw Error(format("while evaluating file `%1%':\n%2%")
% path % e.msg());
}
}
void printEvalStats(EvalState & state)
{
debug(format("evaluated %1% expressions, %2% cache hits, %3%%% efficiency")
% state.nrEvaluated % state.nrCached
% ((float) state.nrCached / (float) state.nrEvaluated * 100));
}