package config import ( "fmt" "io/ioutil" "os" "reflect" "testing" "github.com/hashicorp/hil" "github.com/hashicorp/hil/ast" ) func TestInterpolateFuncCompact(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // empty string within array { `${compact(split(",", "a,,b"))}`, NewStringList([]string{"a", "b"}).String(), false, }, // empty string at the end of array { `${compact(split(",", "a,b,"))}`, NewStringList([]string{"a", "b"}).String(), false, }, // single empty string { `${compact(split(",", ""))}`, NewStringList([]string{}).String(), false, }, }, }) } func TestInterpolateFuncCidrHost(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${cidrhost("192.168.1.0/24", 5)}`, "192.168.1.5", false, }, { `${cidrhost("192.168.1.0/30", 255)}`, nil, true, // 255 doesn't fit in two bits }, { `${cidrhost("not-a-cidr", 6)}`, nil, true, // not a valid CIDR mask }, { `${cidrhost("10.256.0.0/8", 6)}`, nil, true, // can't have an octet >255 }, }, }) } func TestInterpolateFuncCidrNetmask(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${cidrnetmask("192.168.1.0/24")}`, "255.255.255.0", false, }, { `${cidrnetmask("192.168.1.0/32")}`, "255.255.255.255", false, }, { `${cidrnetmask("0.0.0.0/0")}`, "0.0.0.0", false, }, { // This doesn't really make sense for IPv6 networks // but it ought to do something sensible anyway. `${cidrnetmask("1::/64")}`, "ffff:ffff:ffff:ffff::", false, }, { `${cidrnetmask("not-a-cidr")}`, nil, true, // not a valid CIDR mask }, { `${cidrnetmask("10.256.0.0/8")}`, nil, true, // can't have an octet >255 }, }, }) } func TestInterpolateFuncCidrSubnet(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${cidrsubnet("192.168.2.0/20", 4, 6)}`, "192.168.6.0/24", false, }, { `${cidrsubnet("fe80::/48", 16, 6)}`, "fe80:0:0:6::/64", false, }, { // IPv4 address encoded in IPv6 syntax gets normalized `${cidrsubnet("::ffff:192.168.0.0/112", 8, 6)}`, "192.168.6.0/24", false, }, { `${cidrsubnet("192.168.0.0/30", 4, 6)}`, nil, true, // not enough bits left }, { `${cidrsubnet("192.168.0.0/16", 2, 16)}`, nil, true, // can't encode 16 in 2 bits }, { `${cidrsubnet("not-a-cidr", 4, 6)}`, nil, true, // not a valid CIDR mask }, { `${cidrsubnet("10.256.0.0/8", 4, 6)}`, nil, true, // can't have an octet >255 }, }, }) } func TestInterpolateFuncCoalesce(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${coalesce("first", "second", "third")}`, "first", false, }, { `${coalesce("", "second", "third")}`, "second", false, }, { `${coalesce("", "", "")}`, "", false, }, { `${coalesce("foo")}`, nil, true, }, }, }) } func TestInterpolateFuncDeprecatedConcat(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${concat("foo", "bar")}`, "foobar", false, }, { `${concat("foo")}`, "foo", false, }, { `${concat()}`, nil, true, }, }, }) } func TestInterpolateFuncConcat(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // String + list { `${concat("a", split(",", "b,c"))}`, NewStringList([]string{"a", "b", "c"}).String(), false, }, // List + string { `${concat(split(",", "a,b"), "c")}`, NewStringList([]string{"a", "b", "c"}).String(), false, }, // Single list { `${concat(split(",", ",foo,"))}`, NewStringList([]string{"", "foo", ""}).String(), false, }, { `${concat(split(",", "a,b,c"))}`, NewStringList([]string{"a", "b", "c"}).String(), false, }, // Two lists { `${concat(split(",", "a,b,c"), split(",", "d,e"))}`, NewStringList([]string{"a", "b", "c", "d", "e"}).String(), false, }, // Two lists with different separators { `${concat(split(",", "a,b,c"), split(" ", "d e"))}`, NewStringList([]string{"a", "b", "c", "d", "e"}).String(), false, }, // More lists { `${concat(split(",", "a,b"), split(",", "c,d"), split(",", "e,f"), split(",", "0,1"))}`, NewStringList([]string{"a", "b", "c", "d", "e", "f", "0", "1"}).String(), false, }, }, }) } func TestInterpolateFuncFile(t *testing.T) { tf, err := ioutil.TempFile("", "tf") if err != nil { t.Fatalf("err: %s", err) } path := tf.Name() tf.Write([]byte("foo")) tf.Close() defer os.Remove(path) testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { fmt.Sprintf(`${file("%s")}`, path), "foo", false, }, // Invalid path { `${file("/i/dont/exist")}`, nil, true, }, // Too many args { `${file("foo", "bar")}`, nil, true, }, }, }) } func TestInterpolateFuncFormat(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${format("hello")}`, "hello", false, }, { `${format("hello %s", "world")}`, "hello world", false, }, { `${format("hello %d", 42)}`, "hello 42", false, }, { `${format("hello %05d", 42)}`, "hello 00042", false, }, { `${format("hello %05d", 12345)}`, "hello 12345", false, }, }, }) } func TestInterpolateFuncFormatList(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // formatlist requires at least one list { `${formatlist("hello")}`, nil, true, }, { `${formatlist("hello %s", "world")}`, nil, true, }, // formatlist applies to each list element in turn { `${formatlist("<%s>", split(",", "A,B"))}`, NewStringList([]string{"", ""}).String(), false, }, // formatlist repeats scalar elements { `${join(", ", formatlist("%s=%s", "x", split(",", "A,B,C")))}`, "x=A, x=B, x=C", false, }, // Multiple lists are walked in parallel { `${join(", ", formatlist("%s=%s", split(",", "A,B,C"), split(",", "1,2,3")))}`, "A=1, B=2, C=3", false, }, // Mismatched list lengths generate an error { `${formatlist("%s=%2s", split(",", "A,B,C,D"), split(",", "1,2,3"))}`, nil, true, }, // Works with lists of length 1 [GH-2240] { `${formatlist("%s.id", split(",", "demo-rest-elb"))}`, NewStringList([]string{"demo-rest-elb.id"}).String(), false, }, }, }) } func TestInterpolateFuncIndex(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${index("test", "")}`, nil, true, }, { fmt.Sprintf(`${index("%s", "foo")}`, NewStringList([]string{"notfoo", "stillnotfoo", "bar"}).String()), nil, true, }, { fmt.Sprintf(`${index("%s", "foo")}`, NewStringList([]string{"foo"}).String()), "0", false, }, { fmt.Sprintf(`${index("%s", "bar")}`, NewStringList([]string{"foo", "spam", "bar", "eggs"}).String()), "2", false, }, }, }) } func TestInterpolateFuncJoin(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${join(",")}`, nil, true, }, { fmt.Sprintf(`${join(",", "%s")}`, NewStringList([]string{"foo"}).String()), "foo", false, }, /* TODO { `${join(",", "foo", "bar")}`, "foo,bar", false, }, */ { fmt.Sprintf(`${join(".", "%s")}`, NewStringList([]string{"foo", "bar", "baz"}).String()), "foo.bar.baz", false, }, }, }) } func TestInterpolateFuncReplace(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // Regular search and replace { `${replace("hello", "hel", "bel")}`, "bello", false, }, // Search string doesn't match { `${replace("hello", "nope", "bel")}`, "hello", false, }, // Regular expression { `${replace("hello", "/l/", "L")}`, "heLLo", false, }, { `${replace("helo", "/(l)/", "$1$1")}`, "hello", false, }, // Bad regexp { `${replace("helo", "/(l/", "$1$1")}`, nil, true, }, }, }) } func TestInterpolateFuncLength(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // Raw strings { `${length("")}`, "0", false, }, { `${length("a")}`, "1", false, }, { `${length(" ")}`, "1", false, }, { `${length(" a ,")}`, "4", false, }, { `${length("aaa")}`, "3", false, }, // Lists { `${length(split(",", "a"))}`, "1", false, }, { `${length(split(",", "foo,"))}`, "2", false, }, { `${length(split(",", ",foo,"))}`, "3", false, }, { `${length(split(",", "foo,bar"))}`, "2", false, }, { `${length(split(".", "one.two.three.four.five"))}`, "5", false, }, // Want length 0 if we split an empty string then compact { `${length(compact(split(",", "")))}`, "0", false, }, }, }) } func TestInterpolateFuncSignum(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${signum()}`, nil, true, }, { `${signum("")}`, nil, true, }, { `${signum(0)}`, "0", false, }, { `${signum(15)}`, "1", false, }, { `${signum(-29)}`, "-1", false, }, }, }) } func TestInterpolateFuncSplit(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${split(",")}`, nil, true, }, { `${split(",", "")}`, NewStringList([]string{""}).String(), false, }, { `${split(",", "foo")}`, NewStringList([]string{"foo"}).String(), false, }, { `${split(",", ",,,")}`, NewStringList([]string{"", "", "", ""}).String(), false, }, { `${split(",", "foo,")}`, NewStringList([]string{"foo", ""}).String(), false, }, { `${split(",", ",foo,")}`, NewStringList([]string{"", "foo", ""}).String(), false, }, { `${split(".", "foo.bar.baz")}`, NewStringList([]string{"foo", "bar", "baz"}).String(), false, }, }, }) } func TestInterpolateFuncLookup(t *testing.T) { testFunction(t, testFunctionConfig{ Vars: map[string]ast.Variable{ "var.foo.bar": ast.Variable{ Value: "baz", Type: ast.TypeString, }, }, Cases: []testFunctionCase{ { `${lookup("foo", "bar")}`, "baz", false, }, // Invalid key { `${lookup("foo", "baz")}`, nil, true, }, // Too many args { `${lookup("foo", "bar", "baz")}`, nil, true, }, }, }) } func TestInterpolateFuncKeys(t *testing.T) { testFunction(t, testFunctionConfig{ Vars: map[string]ast.Variable{ "var.foo.bar": ast.Variable{ Value: "baz", Type: ast.TypeString, }, "var.foo.qux": ast.Variable{ Value: "quack", Type: ast.TypeString, }, "var.str": ast.Variable{ Value: "astring", Type: ast.TypeString, }, }, Cases: []testFunctionCase{ { `${keys("foo")}`, NewStringList([]string{"bar", "qux"}).String(), false, }, // Invalid key { `${keys("not")}`, nil, true, }, // Too many args { `${keys("foo", "bar")}`, nil, true, }, // Not a map { `${keys("str")}`, nil, true, }, }, }) } func TestInterpolateFuncValues(t *testing.T) { testFunction(t, testFunctionConfig{ Vars: map[string]ast.Variable{ "var.foo.bar": ast.Variable{ Value: "quack", Type: ast.TypeString, }, "var.foo.qux": ast.Variable{ Value: "baz", Type: ast.TypeString, }, "var.str": ast.Variable{ Value: "astring", Type: ast.TypeString, }, }, Cases: []testFunctionCase{ { `${values("foo")}`, NewStringList([]string{"quack", "baz"}).String(), false, }, // Invalid key { `${values("not")}`, nil, true, }, // Too many args { `${values("foo", "bar")}`, nil, true, }, // Not a map { `${values("str")}`, nil, true, }, }, }) } func TestInterpolateFuncElement(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { fmt.Sprintf(`${element("%s", "1")}`, NewStringList([]string{"foo", "baz"}).String()), "baz", false, }, { fmt.Sprintf(`${element("%s", "0")}`, NewStringList([]string{"foo"}).String()), "foo", false, }, // Invalid index should wrap vs. out-of-bounds { fmt.Sprintf(`${element("%s", "2")}`, NewStringList([]string{"foo", "baz"}).String()), "foo", false, }, // Negative number should fail { fmt.Sprintf(`${element("%s", "-1")}`, NewStringList([]string{"foo"}).String()), nil, true, }, // Too many args { fmt.Sprintf(`${element("%s", "0", "2")}`, NewStringList([]string{"foo", "baz"}).String()), nil, true, }, }, }) } func TestInterpolateFuncBase64Encode(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // Regular base64 encoding { `${base64encode("abc123!?$*&()'-=@~")}`, "YWJjMTIzIT8kKiYoKSctPUB+", false, }, }, }) } func TestInterpolateFuncBase64Decode(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ // Regular base64 decoding { `${base64decode("YWJjMTIzIT8kKiYoKSctPUB+")}`, "abc123!?$*&()'-=@~", false, }, // Invalid base64 data decoding { `${base64decode("this-is-an-invalid-base64-data")}`, nil, true, }, }, }) } func TestInterpolateFuncLower(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${lower("HELLO")}`, "hello", false, }, { `${lower("")}`, "", false, }, { `${lower()}`, nil, true, }, }, }) } func TestInterpolateFuncUpper(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${upper("hello")}`, "HELLO", false, }, { `${upper("")}`, "", false, }, { `${upper()}`, nil, true, }, }, }) } func TestInterpolateFuncSha1(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${sha1("test")}`, "a94a8fe5ccb19ba61c4c0873d391e987982fbbd3", false, }, }, }) } func TestInterpolateFuncSha256(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { // hexadecimal representation of sha256 sum `${sha256("test")}`, "9f86d081884c7d659a2feaa0c55ad015a3bf4f1b2b0b822cd15d6c15b0f00a08", false, }, }, }) } func TestInterpolateFuncTrimSpace(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${trimspace(" test ")}`, "test", false, }, }, }) } func TestInterpolateFuncBase64Sha256(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${base64sha256("test")}`, "n4bQgYhMfWWaL+qgxVrQFaO/TxsrC4Is0V1sFbDwCgg=", false, }, { // This will differ because we're base64-encoding hex represantiation, not raw bytes `${base64encode(sha256("test"))}`, "OWY4NmQwODE4ODRjN2Q2NTlhMmZlYWEwYzU1YWQwMTVhM2JmNGYxYjJiMGI4MjJjZDE1ZDZjMTViMGYwMGEwOA==", false, }, }, }) } func TestInterpolateFuncMd5(t *testing.T) { testFunction(t, testFunctionConfig{ Cases: []testFunctionCase{ { `${md5("tada")}`, "ce47d07243bb6eaf5e1322c81baf9bbf", false, }, { // Confirm that we're not trimming any whitespaces `${md5(" tada ")}`, "aadf191a583e53062de2d02c008141c4", false, }, { // We accept empty string too `${md5("")}`, "d41d8cd98f00b204e9800998ecf8427e", false, }, }, }) } func TestInterpolateFuncUUID(t *testing.T) { results := make(map[string]bool) for i := 0; i < 100; i++ { ast, err := hil.Parse("${uuid()}") if err != nil { t.Fatalf("err: %s", err) } out, _, err := hil.Eval(ast, langEvalConfig(nil)) if err != nil { t.Fatalf("err: %s", err) } if results[out.(string)] { t.Fatalf("Got unexpected duplicate uuid: %s", out) } results[out.(string)] = true } } type testFunctionConfig struct { Cases []testFunctionCase Vars map[string]ast.Variable } type testFunctionCase struct { Input string Result interface{} Error bool } func testFunction(t *testing.T, config testFunctionConfig) { for i, tc := range config.Cases { ast, err := hil.Parse(tc.Input) if err != nil { t.Fatalf("Case #%d: input: %#v\nerr: %s", i, tc.Input, err) } out, _, err := hil.Eval(ast, langEvalConfig(config.Vars)) if err != nil != tc.Error { t.Fatalf("Case #%d:\ninput: %#v\nerr: %s", i, tc.Input, err) } if !reflect.DeepEqual(out, tc.Result) { t.Fatalf( "%d: bad output for input: %s\n\nOutput: %#v\nExpected: %#v", i, tc.Input, out, tc.Result) } } }