nix/tests/unit/libexpr/trivial.cc
Eelco Dolstra 8c0590fa32 Never update values after setting the type
Thunks are now overwritten by a helper function
`Value::finishValue(newType, payload)` (where `payload` is the
original anonymous union inside `Value`). This helps to ensure we
never update a value elsewhere, since that would be incompatible with
parallel evaluation (i.e. after a value has transitioned from being a
thunk to being a non-thunk, it should be immutable).

There were two places where this happened: `Value::mkString()` and
`ExprAttrs::eval()`.

This PR also adds a bunch of accessor functions for value contents,
like `Value::integer()` to access the integer field in the union.
2024-03-25 19:21:25 +01:00

197 lines
5.7 KiB
C++

#include "tests/libexpr.hh"
namespace nix {
// Testing of trivial expressions
class TrivialExpressionTest : public LibExprTest {};
TEST_F(TrivialExpressionTest, true) {
auto v = eval("true");
ASSERT_THAT(v, IsTrue());
}
TEST_F(TrivialExpressionTest, false) {
auto v = eval("false");
ASSERT_THAT(v, IsFalse());
}
TEST_F(TrivialExpressionTest, null) {
auto v = eval("null");
ASSERT_THAT(v, IsNull());
}
TEST_F(TrivialExpressionTest, 1) {
auto v = eval("1");
ASSERT_THAT(v, IsIntEq(1));
}
TEST_F(TrivialExpressionTest, 1plus1) {
auto v = eval("1+1");
ASSERT_THAT(v, IsIntEq(2));
}
TEST_F(TrivialExpressionTest, minus1) {
auto v = eval("-1");
ASSERT_THAT(v, IsIntEq(-1));
}
TEST_F(TrivialExpressionTest, 1minus1) {
auto v = eval("1-1");
ASSERT_THAT(v, IsIntEq(0));
}
TEST_F(TrivialExpressionTest, lambdaAdd) {
auto v = eval("let add = a: b: a + b; in add 1 2");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(TrivialExpressionTest, list) {
auto v = eval("[]");
ASSERT_THAT(v, IsListOfSize(0));
}
TEST_F(TrivialExpressionTest, attrs) {
auto v = eval("{}");
ASSERT_THAT(v, IsAttrsOfSize(0));
}
TEST_F(TrivialExpressionTest, float) {
auto v = eval("1.234");
ASSERT_THAT(v, IsFloatEq(1.234));
}
TEST_F(TrivialExpressionTest, updateAttrs) {
auto v = eval("{ a = 1; } // { b = 2; a = 3; }");
ASSERT_THAT(v, IsAttrsOfSize(2));
auto a = v.attrs()->find(createSymbol("a"));
ASSERT_NE(a, nullptr);
ASSERT_THAT(*a->value, IsIntEq(3));
auto b = v.attrs()->find(createSymbol("b"));
ASSERT_NE(b, nullptr);
ASSERT_THAT(*b->value, IsIntEq(2));
}
TEST_F(TrivialExpressionTest, hasAttrOpFalse) {
auto v = eval("{} ? a");
ASSERT_THAT(v, IsFalse());
}
TEST_F(TrivialExpressionTest, hasAttrOpTrue) {
auto v = eval("{ a = 123; } ? a");
ASSERT_THAT(v, IsTrue());
}
TEST_F(TrivialExpressionTest, withFound) {
auto v = eval("with { a = 23; }; a");
ASSERT_THAT(v, IsIntEq(23));
}
TEST_F(TrivialExpressionTest, withNotFound) {
ASSERT_THROW(eval("with {}; a"), Error);
}
TEST_F(TrivialExpressionTest, withOverride) {
auto v = eval("with { a = 23; }; with { a = 42; }; a");
ASSERT_THAT(v, IsIntEq(42));
}
TEST_F(TrivialExpressionTest, letOverWith) {
auto v = eval("let a = 23; in with { a = 1; }; a");
ASSERT_THAT(v, IsIntEq(23));
}
TEST_F(TrivialExpressionTest, multipleLet) {
auto v = eval("let a = 23; in let a = 42; in a");
ASSERT_THAT(v, IsIntEq(42));
}
TEST_F(TrivialExpressionTest, defaultFunctionArgs) {
auto v = eval("({ a ? 123 }: a) {}");
ASSERT_THAT(v, IsIntEq(123));
}
TEST_F(TrivialExpressionTest, defaultFunctionArgsOverride) {
auto v = eval("({ a ? 123 }: a) { a = 5; }");
ASSERT_THAT(v, IsIntEq(5));
}
TEST_F(TrivialExpressionTest, defaultFunctionArgsCaptureBack) {
auto v = eval("({ a ? 123 }@args: args) {}");
ASSERT_THAT(v, IsAttrsOfSize(0));
}
TEST_F(TrivialExpressionTest, defaultFunctionArgsCaptureFront) {
auto v = eval("(args@{ a ? 123 }: args) {}");
ASSERT_THAT(v, IsAttrsOfSize(0));
}
TEST_F(TrivialExpressionTest, assertThrows) {
ASSERT_THROW(eval("let x = arg: assert arg == 1; 123; in x 2"), Error);
}
TEST_F(TrivialExpressionTest, assertPassed) {
auto v = eval("let x = arg: assert arg == 1; 123; in x 1");
ASSERT_THAT(v, IsIntEq(123));
}
class AttrSetMergeTrvialExpressionTest :
public TrivialExpressionTest,
public testing::WithParamInterface<const char*>
{};
TEST_P(AttrSetMergeTrvialExpressionTest, attrsetMergeLazy) {
// Usually Nix rejects duplicate keys in an attrset but it does allow
// so if it is an attribute set that contains disjoint sets of keys.
// The below is equivalent to `{a.b = 1; a.c = 2; }`.
// The attribute set `a` will be a Thunk at first as the attribuets
// have to be merged (or otherwise computed) and that is done in a lazy
// manner.
auto expr = GetParam();
auto v = eval(expr);
ASSERT_THAT(v, IsAttrsOfSize(1));
auto a = v.attrs()->find(createSymbol("a"));
ASSERT_NE(a, nullptr);
ASSERT_THAT(*a->value, IsThunk());
state.forceValue(*a->value, noPos);
ASSERT_THAT(*a->value, IsAttrsOfSize(2));
auto b = a->value->attrs()->find(createSymbol("b"));
ASSERT_NE(b, nullptr);
ASSERT_THAT(*b->value, IsIntEq(1));
auto c = a->value->attrs()->find(createSymbol("c"));
ASSERT_NE(c, nullptr);
ASSERT_THAT(*c->value, IsIntEq(2));
}
INSTANTIATE_TEST_SUITE_P(
attrsetMergeLazy,
AttrSetMergeTrvialExpressionTest,
testing::Values(
"{ a.b = 1; a.c = 2; }",
"{ a = { b = 1; }; a = { c = 2; }; }"
)
);
TEST_F(TrivialExpressionTest, functor) {
auto v = eval("{ __functor = self: arg: self.v + arg; v = 10; } 5");
ASSERT_THAT(v, IsIntEq(15));
}
TEST_F(TrivialExpressionTest, bindOr) {
auto v = eval("{ or = 1; }");
ASSERT_THAT(v, IsAttrsOfSize(1));
auto b = v.attrs()->find(createSymbol("or"));
ASSERT_NE(b, nullptr);
ASSERT_THAT(*b->value, IsIntEq(1));
}
TEST_F(TrivialExpressionTest, orCantBeUsed) {
ASSERT_THROW(eval("let or = 1; in or"), Error);
}
} /* namespace nix */