opentofu/config/hcl2_shim_util_test.go

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package config
import (
"testing"
hcl2 "github.com/hashicorp/hcl2/hcl"
hcl2syntax "github.com/hashicorp/hcl2/hcl/hclsyntax"
"github.com/zclconf/go-cty/cty"
)
func TestHCL2InterpolationFuncs(t *testing.T) {
// This is not a comprehensive test of all the functions (they are tested
// in interpolation_funcs_test.go already) but rather just calling a
// representative set via the HCL2 API to verify that the HCL2-to-HIL
// function shim is working as expected.
tests := []struct {
Expr string
Want cty.Value
Err bool
}{
{
`upper("hello")`,
cty.StringVal("HELLO"),
false,
},
{
`abs(-2)`,
cty.NumberIntVal(2),
false,
},
{
`abs(-2.5)`,
cty.NumberFloatVal(2.5),
false,
},
{
`cidrsubnet("")`,
cty.DynamicVal,
true, // not enough arguments
},
{
`cidrsubnet("10.1.0.0/16", 8, 2)`,
cty.StringVal("10.1.2.0/24"),
false,
},
{
`concat([])`,
// Since HIL doesn't maintain element type information for list
// types, HCL2 can't either without elements to sniff.
cty.ListValEmpty(cty.DynamicPseudoType),
false,
},
{
`concat([], [])`,
cty.ListValEmpty(cty.DynamicPseudoType),
false,
},
{
`concat(["a"], ["b", "c"])`,
cty.ListVal([]cty.Value{
cty.StringVal("a"),
cty.StringVal("b"),
cty.StringVal("c"),
}),
false,
},
{
`list()`,
cty.ListValEmpty(cty.DynamicPseudoType),
false,
},
{
`list("a", "b", "c")`,
cty.ListVal([]cty.Value{
cty.StringVal("a"),
cty.StringVal("b"),
cty.StringVal("c"),
}),
false,
},
{
`list(list("a"), list("b"), list("c"))`,
// The types emerge here in a bit of a strange tangle because of
// the guesswork we do when trying to recover lost information from
// HIL, but the rest of the language doesn't really care whether
// we use lists or tuples here as long as we are consistent with
// the type system invariants.
cty.ListVal([]cty.Value{
cty.TupleVal([]cty.Value{cty.StringVal("a")}),
cty.TupleVal([]cty.Value{cty.StringVal("b")}),
cty.TupleVal([]cty.Value{cty.StringVal("c")}),
}),
false,
},
{
`list(list("a"), "b")`,
cty.DynamicVal,
true, // inconsistent types
},
{
`length([])`,
cty.NumberIntVal(0),
false,
},
{
`length([2])`,
cty.NumberIntVal(1),
false,
},
{
`jsonencode(2)`,
cty.StringVal(`2`),
false,
},
{
`jsonencode(true)`,
cty.StringVal(`true`),
false,
},
{
`jsonencode("foo")`,
cty.StringVal(`"foo"`),
false,
},
{
`jsonencode({})`,
cty.StringVal(`{}`),
false,
},
{
`jsonencode([1])`,
cty.StringVal(`[1]`),
false,
},
{
`jsondecode("{}")`,
cty.EmptyObjectVal,
false,
},
{
`jsondecode("[5, true]")[0]`,
cty.NumberIntVal(5),
false,
},
}
for _, test := range tests {
t.Run(test.Expr, func(t *testing.T) {
expr, diags := hcl2syntax.ParseExpression([]byte(test.Expr), "", hcl2.Pos{Line: 1, Column: 1})
if len(diags) != 0 {
for _, diag := range diags {
t.Logf("- %s", diag)
}
t.Fatalf("unexpected diagnostics while parsing expression")
}
got, diags := expr.Value(&hcl2.EvalContext{
Functions: hcl2InterpolationFuncs(),
})
gotErr := diags.HasErrors()
if gotErr != test.Err {
if test.Err {
t.Errorf("expected errors but got none")
} else {
t.Errorf("unexpected errors")
for _, diag := range diags {
t.Logf("- %s", diag)
}
}
}
if !got.RawEquals(test.Want) {
t.Errorf("wrong result\nexpr: %s\ngot: %#v\nwant: %#v", test.Expr, got, test.Want)
}
})
}
}