nix-super/tests/unit/libexpr/primops.cc

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#include <gmock/gmock.h>
#include <gtest/gtest.h>
#include "eval-settings.hh"
#include "memory-input-accessor.hh"
#include "tests/libexpr.hh"
namespace nix {
class CaptureLogger : public Logger
{
std::ostringstream oss;
public:
CaptureLogger() {}
std::string get() const {
return oss.str();
}
void log(Verbosity lvl, std::string_view s) override {
oss << s << std::endl;
}
void logEI(const ErrorInfo & ei) override {
showErrorInfo(oss, ei, loggerSettings.showTrace.get());
}
};
class CaptureLogging {
Logger * oldLogger;
std::unique_ptr<CaptureLogger> tempLogger;
public:
CaptureLogging() : tempLogger(std::make_unique<CaptureLogger>()) {
oldLogger = logger;
logger = tempLogger.get();
}
~CaptureLogging() {
logger = oldLogger;
}
std::string get() const {
return tempLogger->get();
}
};
// Testing eval of PrimOp's
class PrimOpTest : public LibExprTest {};
TEST_F(PrimOpTest, throw) {
ASSERT_THROW(eval("throw \"foo\""), ThrownError);
}
TEST_F(PrimOpTest, abort) {
ASSERT_THROW(eval("abort \"abort\""), Abort);
}
TEST_F(PrimOpTest, ceil) {
auto v = eval("builtins.ceil 1.9");
ASSERT_THAT(v, IsIntEq(2));
}
TEST_F(PrimOpTest, floor) {
auto v = eval("builtins.floor 1.9");
ASSERT_THAT(v, IsIntEq(1));
}
TEST_F(PrimOpTest, tryEvalFailure) {
auto v = eval("builtins.tryEval (throw \"\")");
ASSERT_THAT(v, IsAttrsOfSize(2));
auto s = createSymbol("success");
auto p = v.attrs->get(s);
ASSERT_NE(p, nullptr);
ASSERT_THAT(*p->value, IsFalse());
}
TEST_F(PrimOpTest, tryEvalSuccess) {
auto v = eval("builtins.tryEval 123");
ASSERT_THAT(v, IsAttrs());
auto s = createSymbol("success");
auto p = v.attrs->get(s);
ASSERT_NE(p, nullptr);
ASSERT_THAT(*p->value, IsTrue());
s = createSymbol("value");
p = v.attrs->get(s);
ASSERT_NE(p, nullptr);
ASSERT_THAT(*p->value, IsIntEq(123));
}
TEST_F(PrimOpTest, getEnv) {
setEnv("_NIX_UNIT_TEST_ENV_VALUE", "test value");
auto v = eval("builtins.getEnv \"_NIX_UNIT_TEST_ENV_VALUE\"");
ASSERT_THAT(v, IsStringEq("test value"));
}
TEST_F(PrimOpTest, seq) {
ASSERT_THROW(eval("let x = throw \"test\"; in builtins.seq x { }"), ThrownError);
}
TEST_F(PrimOpTest, seqNotDeep) {
auto v = eval("let x = { z = throw \"test\"; }; in builtins.seq x { }");
ASSERT_THAT(v, IsAttrs());
}
TEST_F(PrimOpTest, deepSeq) {
ASSERT_THROW(eval("let x = { z = throw \"test\"; }; in builtins.deepSeq x { }"), ThrownError);
}
TEST_F(PrimOpTest, trace) {
CaptureLogging l;
auto v = eval("builtins.trace \"test string 123\" 123");
ASSERT_THAT(v, IsIntEq(123));
auto text = l.get();
ASSERT_NE(text.find("test string 123"), std::string::npos);
}
TEST_F(PrimOpTest, placeholder) {
auto v = eval("builtins.placeholder \"out\"");
ASSERT_THAT(v, IsStringEq("/1rz4g4znpzjwh1xymhjpm42vipw92pr73vdgl6xs1hycac8kf2n9"));
}
TEST_F(PrimOpTest, baseNameOf) {
auto v = eval("builtins.baseNameOf /some/path");
ASSERT_THAT(v, IsStringEq("path"));
}
TEST_F(PrimOpTest, dirOf) {
auto v = eval("builtins.dirOf /some/path");
ASSERT_THAT(v, IsPathEq("/some"));
}
TEST_F(PrimOpTest, attrValues) {
auto v = eval("builtins.attrValues { x = \"foo\"; a = 1; }");
ASSERT_THAT(v, IsListOfSize(2));
ASSERT_THAT(*v.listElems()[0], IsIntEq(1));
ASSERT_THAT(*v.listElems()[1], IsStringEq("foo"));
}
TEST_F(PrimOpTest, getAttr) {
auto v = eval("builtins.getAttr \"x\" { x = \"foo\"; }");
ASSERT_THAT(v, IsStringEq("foo"));
}
TEST_F(PrimOpTest, getAttrNotFound) {
// FIXME: TypeError is really bad here, also the error wording is worse
// than on Nix <=2.3
ASSERT_THROW(eval("builtins.getAttr \"y\" { }"), TypeError);
}
TEST_F(PrimOpTest, unsafeGetAttrPos) {
use byte indexed locations for PosIdx we now keep not a table of all positions, but a table of all origins and their sizes. position indices are now direct pointers into the virtual concatenation of all parsed contents. this slightly reduces memory usage and time spent in the parser, at the cost of not being able to report positions if the total input size exceeds 4GiB. this limit is not unique to nix though, rustc and clang also limit their input to 4GiB (although at least clang refuses to process inputs that are larger, we will not). this new 4GiB limit probably will not cause any problems for quite a while, all of nixpkgs together is less than 100MiB in size and already needs over 700MiB of memory and multiple seconds just to parse. 4GiB worth of input will easily take multiple minutes and over 30GiB of memory without even evaluating anything. if problems *do* arise we can probably recover the old table-based system by adding some tracking to Pos::Origin (or increasing the size of PosIdx outright), but for time being this looks like more complexity than it's worth. since we now need to read the entire input again to determine the line/column of a position we'll make unsafeGetAttrPos slightly lazy: mostly the set it returns is only used to determine the file of origin of an attribute, not its exact location. the thunks do not add measurable runtime overhead. notably this change is necessary to allow changing the parser since apparently nothing supports nix's very idiosyncratic line ending choice of "anything goes", making it very hard to calculate line/column positions in the parser (while byte offsets are very easy).
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state.corepkgsFS->addFile(CanonPath("foo.nix"), "\n\r\n\r{ y = \"x\"; }");
auto expr = "builtins.unsafeGetAttrPos \"y\" (import <nix/foo.nix>)";
auto v = eval(expr);
ASSERT_THAT(v, IsAttrsOfSize(3));
auto file = v.attrs->find(createSymbol("file"));
ASSERT_NE(file, nullptr);
ASSERT_THAT(*file->value, IsString());
auto s = baseNameOf(file->value->string_view());
ASSERT_EQ(s, "foo.nix");
auto line = v.attrs->find(createSymbol("line"));
ASSERT_NE(line, nullptr);
use byte indexed locations for PosIdx we now keep not a table of all positions, but a table of all origins and their sizes. position indices are now direct pointers into the virtual concatenation of all parsed contents. this slightly reduces memory usage and time spent in the parser, at the cost of not being able to report positions if the total input size exceeds 4GiB. this limit is not unique to nix though, rustc and clang also limit their input to 4GiB (although at least clang refuses to process inputs that are larger, we will not). this new 4GiB limit probably will not cause any problems for quite a while, all of nixpkgs together is less than 100MiB in size and already needs over 700MiB of memory and multiple seconds just to parse. 4GiB worth of input will easily take multiple minutes and over 30GiB of memory without even evaluating anything. if problems *do* arise we can probably recover the old table-based system by adding some tracking to Pos::Origin (or increasing the size of PosIdx outright), but for time being this looks like more complexity than it's worth. since we now need to read the entire input again to determine the line/column of a position we'll make unsafeGetAttrPos slightly lazy: mostly the set it returns is only used to determine the file of origin of an attribute, not its exact location. the thunks do not add measurable runtime overhead. notably this change is necessary to allow changing the parser since apparently nothing supports nix's very idiosyncratic line ending choice of "anything goes", making it very hard to calculate line/column positions in the parser (while byte offsets are very easy).
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state.forceValue(*line->value, noPos);
ASSERT_THAT(*line->value, IsIntEq(4));
auto column = v.attrs->find(createSymbol("column"));
ASSERT_NE(column, nullptr);
use byte indexed locations for PosIdx we now keep not a table of all positions, but a table of all origins and their sizes. position indices are now direct pointers into the virtual concatenation of all parsed contents. this slightly reduces memory usage and time spent in the parser, at the cost of not being able to report positions if the total input size exceeds 4GiB. this limit is not unique to nix though, rustc and clang also limit their input to 4GiB (although at least clang refuses to process inputs that are larger, we will not). this new 4GiB limit probably will not cause any problems for quite a while, all of nixpkgs together is less than 100MiB in size and already needs over 700MiB of memory and multiple seconds just to parse. 4GiB worth of input will easily take multiple minutes and over 30GiB of memory without even evaluating anything. if problems *do* arise we can probably recover the old table-based system by adding some tracking to Pos::Origin (or increasing the size of PosIdx outright), but for time being this looks like more complexity than it's worth. since we now need to read the entire input again to determine the line/column of a position we'll make unsafeGetAttrPos slightly lazy: mostly the set it returns is only used to determine the file of origin of an attribute, not its exact location. the thunks do not add measurable runtime overhead. notably this change is necessary to allow changing the parser since apparently nothing supports nix's very idiosyncratic line ending choice of "anything goes", making it very hard to calculate line/column positions in the parser (while byte offsets are very easy).
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state.forceValue(*column->value, noPos);
ASSERT_THAT(*column->value, IsIntEq(3));
}
TEST_F(PrimOpTest, hasAttr) {
auto v = eval("builtins.hasAttr \"x\" { x = 1; }");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, hasAttrNotFound) {
auto v = eval("builtins.hasAttr \"x\" { }");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, isAttrs) {
auto v = eval("builtins.isAttrs {}");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, isAttrsFalse) {
auto v = eval("builtins.isAttrs null");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, removeAttrs) {
auto v = eval("builtins.removeAttrs { x = 1; } [\"x\"]");
ASSERT_THAT(v, IsAttrsOfSize(0));
}
TEST_F(PrimOpTest, removeAttrsRetains) {
auto v = eval("builtins.removeAttrs { x = 1; y = 2; } [\"x\"]");
ASSERT_THAT(v, IsAttrsOfSize(1));
ASSERT_NE(v.attrs->find(createSymbol("y")), nullptr);
}
TEST_F(PrimOpTest, listToAttrsEmptyList) {
auto v = eval("builtins.listToAttrs []");
ASSERT_THAT(v, IsAttrsOfSize(0));
ASSERT_EQ(v.type(), nAttrs);
ASSERT_EQ(v.attrs->size(), 0);
}
TEST_F(PrimOpTest, listToAttrsNotFieldName) {
ASSERT_THROW(eval("builtins.listToAttrs [{}]"), Error);
}
TEST_F(PrimOpTest, listToAttrs) {
auto v = eval("builtins.listToAttrs [ { name = \"key\"; value = 123; } ]");
ASSERT_THAT(v, IsAttrsOfSize(1));
auto key = v.attrs->find(createSymbol("key"));
ASSERT_NE(key, nullptr);
ASSERT_THAT(*key->value, IsIntEq(123));
}
TEST_F(PrimOpTest, intersectAttrs) {
auto v = eval("builtins.intersectAttrs { a = 1; b = 2; } { b = 3; c = 4; }");
ASSERT_THAT(v, IsAttrsOfSize(1));
auto b = v.attrs->find(createSymbol("b"));
ASSERT_NE(b, nullptr);
ASSERT_THAT(*b->value, IsIntEq(3));
}
TEST_F(PrimOpTest, catAttrs) {
auto v = eval("builtins.catAttrs \"a\" [{a = 1;} {b = 0;} {a = 2;}]");
ASSERT_THAT(v, IsListOfSize(2));
ASSERT_THAT(*v.listElems()[0], IsIntEq(1));
ASSERT_THAT(*v.listElems()[1], IsIntEq(2));
}
TEST_F(PrimOpTest, functionArgs) {
auto v = eval("builtins.functionArgs ({ x, y ? 123}: 1)");
ASSERT_THAT(v, IsAttrsOfSize(2));
auto x = v.attrs->find(createSymbol("x"));
ASSERT_NE(x, nullptr);
ASSERT_THAT(*x->value, IsFalse());
auto y = v.attrs->find(createSymbol("y"));
ASSERT_NE(y, nullptr);
ASSERT_THAT(*y->value, IsTrue());
}
TEST_F(PrimOpTest, mapAttrs) {
auto v = eval("builtins.mapAttrs (name: value: value * 10) { a = 1; b = 2; }");
ASSERT_THAT(v, IsAttrsOfSize(2));
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, IsIntEq(10));
auto b = v.attrs->find(createSymbol("b"));
ASSERT_NE(b, nullptr);
ASSERT_THAT(*b->value, IsThunk());
state.forceValue(*b->value, noPos);
ASSERT_THAT(*b->value, IsIntEq(20));
}
TEST_F(PrimOpTest, isList) {
auto v = eval("builtins.isList []");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, isListFalse) {
auto v = eval("builtins.isList null");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, elemtAt) {
auto v = eval("builtins.elemAt [0 1 2 3] 3");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, elemtAtOutOfBounds) {
ASSERT_THROW(eval("builtins.elemAt [0 1 2 3] 5"), Error);
}
TEST_F(PrimOpTest, head) {
auto v = eval("builtins.head [ 3 2 1 0 ]");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, headEmpty) {
ASSERT_THROW(eval("builtins.head [ ]"), Error);
}
TEST_F(PrimOpTest, headWrongType) {
ASSERT_THROW(eval("builtins.head { }"), Error);
}
TEST_F(PrimOpTest, tail) {
auto v = eval("builtins.tail [ 3 2 1 0 ]");
ASSERT_THAT(v, IsListOfSize(3));
for (const auto [n, elem] : enumerate(v.listItems()))
ASSERT_THAT(*elem, IsIntEq(2 - static_cast<int>(n)));
}
TEST_F(PrimOpTest, tailEmpty) {
ASSERT_THROW(eval("builtins.tail []"), Error);
}
TEST_F(PrimOpTest, map) {
auto v = eval("map (x: \"foo\" + x) [ \"bar\" \"bla\" \"abc\" ]");
ASSERT_THAT(v, IsListOfSize(3));
auto elem = v.listElems()[0];
ASSERT_THAT(*elem, IsThunk());
state.forceValue(*elem, noPos);
ASSERT_THAT(*elem, IsStringEq("foobar"));
elem = v.listElems()[1];
ASSERT_THAT(*elem, IsThunk());
state.forceValue(*elem, noPos);
ASSERT_THAT(*elem, IsStringEq("foobla"));
elem = v.listElems()[2];
ASSERT_THAT(*elem, IsThunk());
state.forceValue(*elem, noPos);
ASSERT_THAT(*elem, IsStringEq("fooabc"));
}
TEST_F(PrimOpTest, filter) {
auto v = eval("builtins.filter (x: x == 2) [ 3 2 3 2 3 2 ]");
ASSERT_THAT(v, IsListOfSize(3));
for (const auto elem : v.listItems())
ASSERT_THAT(*elem, IsIntEq(2));
}
TEST_F(PrimOpTest, elemTrue) {
auto v = eval("builtins.elem 3 [ 1 2 3 4 5 ]");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, elemFalse) {
auto v = eval("builtins.elem 6 [ 1 2 3 4 5 ]");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, concatLists) {
auto v = eval("builtins.concatLists [[1 2] [3 4]]");
ASSERT_THAT(v, IsListOfSize(4));
for (const auto [i, elem] : enumerate(v.listItems()))
ASSERT_THAT(*elem, IsIntEq(static_cast<int>(i)+1));
}
TEST_F(PrimOpTest, length) {
auto v = eval("builtins.length [ 1 2 3 ]");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, foldStrict) {
auto v = eval("builtins.foldl' (a: b: a + b) 0 [1 2 3]");
ASSERT_THAT(v, IsIntEq(6));
}
TEST_F(PrimOpTest, anyTrue) {
auto v = eval("builtins.any (x: x == 2) [ 1 2 3 ]");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, anyFalse) {
auto v = eval("builtins.any (x: x == 5) [ 1 2 3 ]");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, allTrue) {
auto v = eval("builtins.all (x: x > 0) [ 1 2 3 ]");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, allFalse) {
auto v = eval("builtins.all (x: x <= 0) [ 1 2 3 ]");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, genList) {
auto v = eval("builtins.genList (x: x + 1) 3");
ASSERT_EQ(v.type(), nList);
ASSERT_EQ(v.listSize(), 3);
for (const auto [i, elem] : enumerate(v.listItems())) {
ASSERT_THAT(*elem, IsThunk());
state.forceValue(*elem, noPos);
ASSERT_THAT(*elem, IsIntEq(static_cast<int>(i)+1));
}
}
TEST_F(PrimOpTest, sortLessThan) {
auto v = eval("builtins.sort builtins.lessThan [ 483 249 526 147 42 77 ]");
ASSERT_EQ(v.type(), nList);
ASSERT_EQ(v.listSize(), 6);
const std::vector<int> numbers = { 42, 77, 147, 249, 483, 526 };
for (const auto [n, elem] : enumerate(v.listItems()))
ASSERT_THAT(*elem, IsIntEq(numbers[n]));
}
TEST_F(PrimOpTest, partition) {
auto v = eval("builtins.partition (x: x > 10) [1 23 9 3 42]");
ASSERT_THAT(v, IsAttrsOfSize(2));
auto right = v.attrs->get(createSymbol("right"));
ASSERT_NE(right, nullptr);
ASSERT_THAT(*right->value, IsListOfSize(2));
ASSERT_THAT(*right->value->listElems()[0], IsIntEq(23));
ASSERT_THAT(*right->value->listElems()[1], IsIntEq(42));
auto wrong = v.attrs->get(createSymbol("wrong"));
ASSERT_NE(wrong, nullptr);
ASSERT_EQ(wrong->value->type(), nList);
ASSERT_EQ(wrong->value->listSize(), 3);
ASSERT_THAT(*wrong->value, IsListOfSize(3));
ASSERT_THAT(*wrong->value->listElems()[0], IsIntEq(1));
ASSERT_THAT(*wrong->value->listElems()[1], IsIntEq(9));
ASSERT_THAT(*wrong->value->listElems()[2], IsIntEq(3));
}
TEST_F(PrimOpTest, concatMap) {
auto v = eval("builtins.concatMap (x: x ++ [0]) [ [1 2] [3 4] ]");
ASSERT_EQ(v.type(), nList);
ASSERT_EQ(v.listSize(), 6);
const std::vector<int> numbers = { 1, 2, 0, 3, 4, 0 };
for (const auto [n, elem] : enumerate(v.listItems()))
ASSERT_THAT(*elem, IsIntEq(numbers[n]));
}
TEST_F(PrimOpTest, addInt) {
auto v = eval("builtins.add 3 5");
ASSERT_THAT(v, IsIntEq(8));
}
TEST_F(PrimOpTest, addFloat) {
auto v = eval("builtins.add 3.0 5.0");
ASSERT_THAT(v, IsFloatEq(8.0));
}
TEST_F(PrimOpTest, addFloatToInt) {
auto v = eval("builtins.add 3.0 5");
ASSERT_THAT(v, IsFloatEq(8.0));
v = eval("builtins.add 3 5.0");
ASSERT_THAT(v, IsFloatEq(8.0));
}
TEST_F(PrimOpTest, subInt) {
auto v = eval("builtins.sub 5 2");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, subFloat) {
auto v = eval("builtins.sub 5.0 2.0");
ASSERT_THAT(v, IsFloatEq(3.0));
}
TEST_F(PrimOpTest, subFloatFromInt) {
auto v = eval("builtins.sub 5.0 2");
ASSERT_THAT(v, IsFloatEq(3.0));
v = eval("builtins.sub 4 2.0");
ASSERT_THAT(v, IsFloatEq(2.0));
}
TEST_F(PrimOpTest, mulInt) {
auto v = eval("builtins.mul 3 5");
ASSERT_THAT(v, IsIntEq(15));
}
TEST_F(PrimOpTest, mulFloat) {
auto v = eval("builtins.mul 3.0 5.0");
ASSERT_THAT(v, IsFloatEq(15.0));
}
TEST_F(PrimOpTest, mulFloatMixed) {
auto v = eval("builtins.mul 3 5.0");
ASSERT_THAT(v, IsFloatEq(15.0));
v = eval("builtins.mul 2.0 5");
ASSERT_THAT(v, IsFloatEq(10.0));
}
TEST_F(PrimOpTest, divInt) {
auto v = eval("builtins.div 5 (-1)");
ASSERT_THAT(v, IsIntEq(-5));
}
TEST_F(PrimOpTest, divIntZero) {
ASSERT_THROW(eval("builtins.div 5 0"), EvalError);
}
TEST_F(PrimOpTest, divFloat) {
auto v = eval("builtins.div 5.0 (-1)");
ASSERT_THAT(v, IsFloatEq(-5.0));
}
TEST_F(PrimOpTest, divFloatZero) {
ASSERT_THROW(eval("builtins.div 5.0 0.0"), EvalError);
}
TEST_F(PrimOpTest, bitOr) {
auto v = eval("builtins.bitOr 1 2");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, bitXor) {
auto v = eval("builtins.bitXor 3 2");
ASSERT_THAT(v, IsIntEq(1));
}
TEST_F(PrimOpTest, lessThanFalse) {
auto v = eval("builtins.lessThan 3 1");
ASSERT_THAT(v, IsFalse());
}
TEST_F(PrimOpTest, lessThanTrue) {
auto v = eval("builtins.lessThan 1 3");
ASSERT_THAT(v, IsTrue());
}
TEST_F(PrimOpTest, toStringAttrsThrows) {
ASSERT_THROW(eval("builtins.toString {}"), EvalError);
}
TEST_F(PrimOpTest, toStringLambdaThrows) {
ASSERT_THROW(eval("builtins.toString (x: x)"), EvalError);
}
class ToStringPrimOpTest :
public PrimOpTest,
public testing::WithParamInterface<std::tuple<std::string, std::string_view>>
{};
TEST_P(ToStringPrimOpTest, toString) {
const auto [input, output] = GetParam();
auto v = eval(input);
ASSERT_THAT(v, IsStringEq(output));
}
#define CASE(input, output) (std::make_tuple(std::string_view("builtins.toString " input), std::string_view(output)))
INSTANTIATE_TEST_SUITE_P(
toString,
ToStringPrimOpTest,
testing::Values(
CASE(R"("foo")", "foo"),
CASE(R"(1)", "1"),
CASE(R"([1 2 3])", "1 2 3"),
CASE(R"(.123)", "0.123000"),
CASE(R"(true)", "1"),
CASE(R"(false)", ""),
CASE(R"(null)", ""),
CASE(R"({ v = "bar"; __toString = self: self.v; })", "bar"),
CASE(R"({ v = "bar"; __toString = self: self.v; outPath = "foo"; })", "bar"),
CASE(R"({ outPath = "foo"; })", "foo"),
CASE(R"(./test)", "/test")
)
);
#undef CASE
TEST_F(PrimOpTest, substring){
auto v = eval("builtins.substring 0 3 \"nixos\"");
ASSERT_THAT(v, IsStringEq("nix"));
}
TEST_F(PrimOpTest, substringSmallerString){
auto v = eval("builtins.substring 0 3 \"n\"");
ASSERT_THAT(v, IsStringEq("n"));
}
TEST_F(PrimOpTest, substringEmptyString){
auto v = eval("builtins.substring 1 3 \"\"");
ASSERT_THAT(v, IsStringEq(""));
}
TEST_F(PrimOpTest, stringLength) {
auto v = eval("builtins.stringLength \"123\"");
ASSERT_THAT(v, IsIntEq(3));
}
TEST_F(PrimOpTest, hashStringMd5) {
auto v = eval("builtins.hashString \"md5\" \"asdf\"");
ASSERT_THAT(v, IsStringEq("912ec803b2ce49e4a541068d495ab570"));
}
TEST_F(PrimOpTest, hashStringSha1) {
auto v = eval("builtins.hashString \"sha1\" \"asdf\"");
ASSERT_THAT(v, IsStringEq("3da541559918a808c2402bba5012f6c60b27661c"));
}
TEST_F(PrimOpTest, hashStringSha256) {
auto v = eval("builtins.hashString \"sha256\" \"asdf\"");
ASSERT_THAT(v, IsStringEq("f0e4c2f76c58916ec258f246851bea091d14d4247a2fc3e18694461b1816e13b"));
}
TEST_F(PrimOpTest, hashStringSha512) {
auto v = eval("builtins.hashString \"sha512\" \"asdf\"");
ASSERT_THAT(v, IsStringEq("401b09eab3c013d4ca54922bb802bec8fd5318192b0a75f201d8b3727429080fb337591abd3e44453b954555b7a0812e1081c39b740293f765eae731f5a65ed1"));
}
TEST_F(PrimOpTest, hashStringInvalidHashAlgorithm) {
ASSERT_THROW(eval("builtins.hashString \"foobar\" \"asdf\""), Error);
}
TEST_F(PrimOpTest, nixPath) {
auto v = eval("builtins.nixPath");
ASSERT_EQ(v.type(), nList);
// We can't test much more as currently the EvalSettings are a global
// that we can't easily swap / replace
}
TEST_F(PrimOpTest, langVersion) {
auto v = eval("builtins.langVersion");
ASSERT_EQ(v.type(), nInt);
}
TEST_F(PrimOpTest, storeDir) {
auto v = eval("builtins.storeDir");
ASSERT_THAT(v, IsStringEq(settings.nixStore));
}
TEST_F(PrimOpTest, nixVersion) {
auto v = eval("builtins.nixVersion");
ASSERT_THAT(v, IsStringEq(nixVersion));
}
TEST_F(PrimOpTest, currentSystem) {
auto v = eval("builtins.currentSystem");
ASSERT_THAT(v, IsStringEq(evalSettings.getCurrentSystem()));
}
TEST_F(PrimOpTest, derivation) {
auto v = eval("derivation");
ASSERT_EQ(v.type(), nFunction);
ASSERT_TRUE(v.isLambda());
ASSERT_NE(v.lambda.fun, nullptr);
ASSERT_TRUE(v.lambda.fun->hasFormals());
}
TEST_F(PrimOpTest, currentTime) {
auto v = eval("builtins.currentTime");
ASSERT_EQ(v.type(), nInt);
ASSERT_TRUE(v.integer > 0);
}
TEST_F(PrimOpTest, splitVersion) {
auto v = eval("builtins.splitVersion \"1.2.3git\"");
ASSERT_THAT(v, IsListOfSize(4));
const std::vector<std::string_view> strings = { "1", "2", "3", "git" };
for (const auto [n, p] : enumerate(v.listItems()))
ASSERT_THAT(*p, IsStringEq(strings[n]));
}
class CompareVersionsPrimOpTest :
public PrimOpTest,
public testing::WithParamInterface<std::tuple<std::string, const int>>
{};
TEST_P(CompareVersionsPrimOpTest, compareVersions) {
auto [expression, expectation] = GetParam();
auto v = eval(expression);
ASSERT_THAT(v, IsIntEq(expectation));
}
#define CASE(a, b, expected) (std::make_tuple("builtins.compareVersions \"" #a "\" \"" #b "\"", expected))
INSTANTIATE_TEST_SUITE_P(
compareVersions,
CompareVersionsPrimOpTest,
testing::Values(
// The first two are weird cases. Intuition tells they should
// be the same but they aren't.
CASE(1.0, 1.0.0, -1),
CASE(1.0.0, 1.0, 1),
// the following are from the nix-env manual:
CASE(1.0, 2.3, -1),
CASE(2.1, 2.3, -1),
CASE(2.3, 2.3, 0),
CASE(2.5, 2.3, 1),
CASE(3.1, 2.3, 1),
CASE(2.3.1, 2.3, 1),
CASE(2.3.1, 2.3a, 1),
CASE(2.3pre1, 2.3, -1),
CASE(2.3pre3, 2.3pre12, -1),
CASE(2.3a, 2.3c, -1),
CASE(2.3pre1, 2.3c, -1),
CASE(2.3pre1, 2.3q, -1)
)
);
#undef CASE
class ParseDrvNamePrimOpTest :
public PrimOpTest,
public testing::WithParamInterface<std::tuple<std::string, std::string_view, std::string_view>>
{};
TEST_P(ParseDrvNamePrimOpTest, parseDrvName) {
auto [input, expectedName, expectedVersion] = GetParam();
const auto expr = fmt("builtins.parseDrvName \"%1%\"", input);
auto v = eval(expr);
ASSERT_THAT(v, IsAttrsOfSize(2));
auto name = v.attrs->find(createSymbol("name"));
ASSERT_TRUE(name);
ASSERT_THAT(*name->value, IsStringEq(expectedName));
auto version = v.attrs->find(createSymbol("version"));
ASSERT_TRUE(version);
ASSERT_THAT(*version->value, IsStringEq(expectedVersion));
}
INSTANTIATE_TEST_SUITE_P(
parseDrvName,
ParseDrvNamePrimOpTest,
testing::Values(
std::make_tuple("nix-0.12pre12876", "nix", "0.12pre12876"),
std::make_tuple("a-b-c-1234pre5+git", "a-b-c", "1234pre5+git")
)
);
TEST_F(PrimOpTest, replaceStrings) {
// FIXME: add a test that verifies the string context is as expected
auto v = eval("builtins.replaceStrings [\"oo\" \"a\"] [\"a\" \"i\"] \"foobar\"");
ASSERT_EQ(v.type(), nString);
ASSERT_EQ(v.string_view(), "fabir");
}
TEST_F(PrimOpTest, concatStringsSep) {
// FIXME: add a test that verifies the string context is as expected
auto v = eval("builtins.concatStringsSep \"%\" [\"foo\" \"bar\" \"baz\"]");
ASSERT_EQ(v.type(), nString);
ASSERT_EQ(v.string_view(), "foo%bar%baz");
}
TEST_F(PrimOpTest, split1) {
// v = [ "" [ "a" ] "c" ]
auto v = eval("builtins.split \"(a)b\" \"abc\"");
ASSERT_THAT(v, IsListOfSize(3));
ASSERT_THAT(*v.listElems()[0], IsStringEq(""));
ASSERT_THAT(*v.listElems()[1], IsListOfSize(1));
ASSERT_THAT(*v.listElems()[1]->listElems()[0], IsStringEq("a"));
ASSERT_THAT(*v.listElems()[2], IsStringEq("c"));
}
TEST_F(PrimOpTest, split2) {
// v is expected to be a list [ "" [ "a" ] "b" [ "c"] "" ]
auto v = eval("builtins.split \"([ac])\" \"abc\"");
ASSERT_THAT(v, IsListOfSize(5));
ASSERT_THAT(*v.listElems()[0], IsStringEq(""));
ASSERT_THAT(*v.listElems()[1], IsListOfSize(1));
ASSERT_THAT(*v.listElems()[1]->listElems()[0], IsStringEq("a"));
ASSERT_THAT(*v.listElems()[2], IsStringEq("b"));
ASSERT_THAT(*v.listElems()[3], IsListOfSize(1));
ASSERT_THAT(*v.listElems()[3]->listElems()[0], IsStringEq("c"));
ASSERT_THAT(*v.listElems()[4], IsStringEq(""));
}
TEST_F(PrimOpTest, split3) {
auto v = eval("builtins.split \"(a)|(c)\" \"abc\"");
ASSERT_THAT(v, IsListOfSize(5));
// First list element
ASSERT_THAT(*v.listElems()[0], IsStringEq(""));
// 2nd list element is a list [ "" null ]
ASSERT_THAT(*v.listElems()[1], IsListOfSize(2));
ASSERT_THAT(*v.listElems()[1]->listElems()[0], IsStringEq("a"));
ASSERT_THAT(*v.listElems()[1]->listElems()[1], IsNull());
// 3rd element
ASSERT_THAT(*v.listElems()[2], IsStringEq("b"));
// 4th element is a list: [ null "c" ]
ASSERT_THAT(*v.listElems()[3], IsListOfSize(2));
ASSERT_THAT(*v.listElems()[3]->listElems()[0], IsNull());
ASSERT_THAT(*v.listElems()[3]->listElems()[1], IsStringEq("c"));
// 5th element is the empty string
ASSERT_THAT(*v.listElems()[4], IsStringEq(""));
}
TEST_F(PrimOpTest, split4) {
auto v = eval("builtins.split \"([[:upper:]]+)\" \" FOO \"");
ASSERT_THAT(v, IsListOfSize(3));
auto first = v.listElems()[0];
auto second = v.listElems()[1];
auto third = v.listElems()[2];
ASSERT_THAT(*first, IsStringEq(" "));
ASSERT_THAT(*second, IsListOfSize(1));
ASSERT_THAT(*second->listElems()[0], IsStringEq("FOO"));
ASSERT_THAT(*third, IsStringEq(" "));
}
TEST_F(PrimOpTest, match1) {
auto v = eval("builtins.match \"ab\" \"abc\"");
ASSERT_THAT(v, IsNull());
}
TEST_F(PrimOpTest, match2) {
auto v = eval("builtins.match \"abc\" \"abc\"");
ASSERT_THAT(v, IsListOfSize(0));
}
TEST_F(PrimOpTest, match3) {
auto v = eval("builtins.match \"a(b)(c)\" \"abc\"");
ASSERT_THAT(v, IsListOfSize(2));
ASSERT_THAT(*v.listElems()[0], IsStringEq("b"));
ASSERT_THAT(*v.listElems()[1], IsStringEq("c"));
}
TEST_F(PrimOpTest, match4) {
auto v = eval("builtins.match \"[[:space:]]+([[:upper:]]+)[[:space:]]+\" \" FOO \"");
ASSERT_THAT(v, IsListOfSize(1));
ASSERT_THAT(*v.listElems()[0], IsStringEq("FOO"));
}
2023-12-01 02:39:52 +02:00
TEST_F(PrimOpTest, match5) {
// The regex "\\{}" is valid and matches the string "{}".
// Caused a regression before when trying to switch from std::regex to boost::regex.
// See https://github.com/NixOS/nix/pull/7762#issuecomment-1834303659
auto v = eval("builtins.match \"\\\\{}\" \"{}\"");
ASSERT_THAT(v, IsListOfSize(0));
}
TEST_F(PrimOpTest, attrNames) {
auto v = eval("builtins.attrNames { x = 1; y = 2; z = 3; a = 2; }");
ASSERT_THAT(v, IsListOfSize(4));
// ensure that the list is sorted
const std::vector<std::string_view> expected { "a", "x", "y", "z" };
for (const auto [n, elem] : enumerate(v.listItems()))
ASSERT_THAT(*elem, IsStringEq(expected[n]));
}
TEST_F(PrimOpTest, genericClosure_not_strict) {
// Operator should not be used when startSet is empty
auto v = eval("builtins.genericClosure { startSet = []; }");
ASSERT_THAT(v, IsListOfSize(0));
}
} /* namespace nix */