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Merge pull request #10090 from hashicorp/b-update-hil 

vendor: update HIL
This commit is contained in:
Mitchell Hashimoto 2016-11-13 10:31:21 -08:00 committed by GitHub
parent 8d993d9edd 15979435d6
commit 0bb8ab9afb
20 changed files with 1267 additions and 1656 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

2
config/loader_test.go
View File

@ -141,7 +141,7 @@ func TestLoadFileEscapedQuotes(t *testing.T) {
t.Fatalf("expected syntax error as escaped quotes are no longer supported")
}
if !strings.Contains(err.Error(), "syntax error") {
if !strings.Contains(err.Error(), "parse error") {
t.Fatalf("expected \"syntax error\", got: %s", err)
}
}

16
vendor/github.com/hashicorp/hil/ast/ast.go generated vendored
View File

@ -19,13 +19,22 @@ type Node interface {
// Pos is the starting position of an AST node
type Pos struct {
Column, Line int // Column/Line number, starting at 1
Column, Line int // Column/Line number, starting at 1
Filename string // Optional source filename, if known
}
func (p Pos) String() string {
return fmt.Sprintf("%d:%d", p.Line, p.Column)
if p.Filename == "" {
return fmt.Sprintf("%d:%d", p.Line, p.Column)
} else {
return fmt.Sprintf("%s:%d:%d", p.Filename, p.Line, p.Column)
}
}
// InitPos is an initiaial position value. This should be used as
// the starting position (presets the column and line to 1).
var InitPos = Pos{Column: 1, Line: 1}
// Visitors are just implementations of this function.
//
// The function must return the Node to replace this node with. "nil" is
@ -49,6 +58,7 @@ type Type uint32
const (
TypeInvalid Type = 0
TypeAny Type = 1 << iota
TypeBool
TypeString
TypeInt
TypeFloat
@ -69,6 +79,8 @@ func (t Type) Printable() string {
return "invalid type"
case TypeAny:
return "any type"
case TypeBool:
return "type bool"
case TypeString:
return "type string"
case TypeInt:

28
vendor/github.com/hashicorp/hil/ast/type_string.go generated vendored
View File

@ -7,21 +7,25 @@ import "fmt"
const (
_Type_name_0 = "TypeInvalid"
_Type_name_1 = "TypeAny"
_Type_name_2 = "TypeString"
_Type_name_3 = "TypeInt"
_Type_name_4 = "TypeFloat"
_Type_name_5 = "TypeList"
_Type_name_6 = "TypeMap"
_Type_name_2 = "TypeBool"
_Type_name_3 = "TypeString"
_Type_name_4 = "TypeInt"
_Type_name_5 = "TypeFloat"
_Type_name_6 = "TypeList"
_Type_name_7 = "TypeMap"
_Type_name_8 = "TypeUnknown"
)
var (
_Type_index_0 = [...]uint8{0, 11}
_Type_index_1 = [...]uint8{0, 7}
_Type_index_2 = [...]uint8{0, 10}
_Type_index_3 = [...]uint8{0, 7}
_Type_index_4 = [...]uint8{0, 9}
_Type_index_5 = [...]uint8{0, 8}
_Type_index_6 = [...]uint8{0, 7}
_Type_index_2 = [...]uint8{0, 8}
_Type_index_3 = [...]uint8{0, 10}
_Type_index_4 = [...]uint8{0, 7}
_Type_index_5 = [...]uint8{0, 9}
_Type_index_6 = [...]uint8{0, 8}
_Type_index_7 = [...]uint8{0, 7}
_Type_index_8 = [...]uint8{0, 11}
)
func (i Type) String() string {
@ -40,6 +44,10 @@ func (i Type) String() string {
return _Type_name_5
case i == 64:
return _Type_name_6
case i == 128:
return _Type_name_7
case i == 256:
return _Type_name_8
default:
return fmt.Sprintf("Type(%d)", i)
}

27
vendor/github.com/hashicorp/hil/builtins.go generated vendored
View File

@ -18,12 +18,14 @@ func registerBuiltins(scope *ast.BasicScope) *ast.BasicScope {
}
// Implicit conversions
scope.FuncMap["__builtin_BoolToString"] = builtinBoolToString()
scope.FuncMap["__builtin_FloatToInt"] = builtinFloatToInt()
scope.FuncMap["__builtin_FloatToString"] = builtinFloatToString()
scope.FuncMap["__builtin_IntToFloat"] = builtinIntToFloat()
scope.FuncMap["__builtin_IntToString"] = builtinIntToString()
scope.FuncMap["__builtin_StringToInt"] = builtinStringToInt()
scope.FuncMap["__builtin_StringToFloat"] = builtinStringToFloat()
scope.FuncMap["__builtin_StringToBool"] = builtinStringToBool()
// Math operations
scope.FuncMap["__builtin_IntMath"] = builtinIntMath()
@ -167,3 +169,28 @@ func builtinStringToFloat() ast.Function {
},
}
}
func builtinBoolToString() ast.Function {
return ast.Function{
ArgTypes: []ast.Type{ast.TypeBool},
ReturnType: ast.TypeString,
Callback: func(args []interface{}) (interface{}, error) {
return strconv.FormatBool(args[0].(bool)), nil
},
}
}
func builtinStringToBool() ast.Function {
return ast.Function{
ArgTypes: []ast.Type{ast.TypeString},
ReturnType: ast.TypeBool,
Callback: func(args []interface{}) (interface{}, error) {
v, err := strconv.ParseBool(args[0].(string))
if err != nil {
return nil, err
}
return v, nil
},
}
}

10
vendor/github.com/hashicorp/hil/eval.go generated vendored
View File

@ -33,6 +33,7 @@ type SemanticChecker func(ast.Node) error
// TypeString: string
// TypeList: []interface{}
// TypeMap: map[string]interface{}
// TypBool: bool
type EvaluationResult struct {
Type EvalType
Value interface{}
@ -77,6 +78,11 @@ func Eval(root ast.Node, config *EvalConfig) (EvaluationResult, error) {
Type: TypeString,
Value: output,
}, nil
case ast.TypeBool:
return EvaluationResult{
Type: TypeBool,
Value: output,
}, nil
case ast.TypeUnknown:
return EvaluationResult{
Type: TypeUnknown,
@ -107,6 +113,10 @@ func internalEval(root ast.Node, config *EvalConfig) (interface{}, ast.Type, err
ast.TypeString: {
ast.TypeInt: "__builtin_StringToInt",
ast.TypeFloat: "__builtin_StringToFloat",
ast.TypeBool: "__builtin_StringToBool",
},
ast.TypeBool: {
ast.TypeString: "__builtin_BoolToString",
},
}

1
vendor/github.com/hashicorp/hil/eval_type.go generated vendored
View File

@ -9,6 +9,7 @@ type EvalType uint32
const (
TypeInvalid EvalType = 0
TypeString EvalType = 1 << iota
TypeBool
TypeList
TypeMap
TypeUnknown

14
vendor/github.com/hashicorp/hil/evaltype_string.go generated vendored
View File

@ -7,15 +7,19 @@ import "fmt"
const (
_EvalType_name_0 = "TypeInvalid"
_EvalType_name_1 = "TypeString"
_EvalType_name_2 = "TypeList"
_EvalType_name_3 = "TypeMap"
_EvalType_name_2 = "TypeBool"
_EvalType_name_3 = "TypeList"
_EvalType_name_4 = "TypeMap"
_EvalType_name_5 = "TypeUnknown"
)
var (
_EvalType_index_0 = [...]uint8{0, 11}
_EvalType_index_1 = [...]uint8{0, 10}
_EvalType_index_2 = [...]uint8{0, 8}
_EvalType_index_3 = [...]uint8{0, 7}
_EvalType_index_3 = [...]uint8{0, 8}
_EvalType_index_4 = [...]uint8{0, 7}
_EvalType_index_5 = [...]uint8{0, 11}
)
func (i EvalType) String() string {
@ -28,6 +32,10 @@ func (i EvalType) String() string {
return _EvalType_name_2
case i == 8:
return _EvalType_name_3
case i == 16:
return _EvalType_name_4
case i == 32:
return _EvalType_name_5
default:
return fmt.Sprintf("EvalType(%d)", i)
}

200
vendor/github.com/hashicorp/hil/lang.y generated vendored
View File

@ -1,200 +0,0 @@
// This is the yacc input for creating the parser for interpolation
// expressions in Go. To build it, just run `go generate` on this
// package, as the lexer has the go generate pragma within it.
%{
package hil
import (
"fmt"
"github.com/hashicorp/hil/ast"
)
%}
%union {
node ast.Node
nodeList []ast.Node
str string
token *parserToken
}
%token <str> PROGRAM_BRACKET_LEFT PROGRAM_BRACKET_RIGHT
%token <str> PROGRAM_STRING_START PROGRAM_STRING_END
%token <str> PAREN_LEFT PAREN_RIGHT COMMA
%token <str> SQUARE_BRACKET_LEFT SQUARE_BRACKET_RIGHT
%token <token> ARITH_OP IDENTIFIER INTEGER FLOAT STRING
%type <node> expr interpolation literal literalModeTop literalModeValue
%type <nodeList> args
%left ARITH_OP
%%
top:
{
parserResult = &ast.LiteralNode{
Value: "",
Typex: ast.TypeString,
Posx: ast.Pos{Column: 1, Line: 1},
}
}
| literalModeTop
{
parserResult = $1
// We want to make sure that the top value is always an Output
// so that the return value is always a string, list of map from an
// interpolation.
//
// The logic for checking for a LiteralNode is a little annoying
// because functionally the AST is the same, but we do that because
// it makes for an easy literal check later (to check if a string
// has any interpolations).
if _, ok := $1.(*ast.Output); !ok {
if n, ok := $1.(*ast.LiteralNode); !ok || n.Typex != ast.TypeString {
parserResult = &ast.Output{
Exprs: []ast.Node{$1},
Posx: $1.Pos(),
}
}
}
}
literalModeTop:
literalModeValue
{
$$ = $1
}
| literalModeTop literalModeValue
{
var result []ast.Node
if c, ok := $1.(*ast.Output); ok {
result = append(c.Exprs, $2)
} else {
result = []ast.Node{$1, $2}
}
$$ = &ast.Output{
Exprs: result,
Posx: result[0].Pos(),
}
}
literalModeValue:
literal
{
$$ = $1
}
| interpolation
{
$$ = $1
}
interpolation:
PROGRAM_BRACKET_LEFT expr PROGRAM_BRACKET_RIGHT
{
$$ = $2
}
expr:
PAREN_LEFT expr PAREN_RIGHT
{
$$ = $2
}
| literalModeTop
{
$$ = $1
}
| INTEGER
{
$$ = &ast.LiteralNode{
Value: $1.Value.(int),
Typex: ast.TypeInt,
Posx: $1.Pos,
}
}
| FLOAT
{
$$ = &ast.LiteralNode{
Value: $1.Value.(float64),
Typex: ast.TypeFloat,
Posx: $1.Pos,
}
}
| ARITH_OP expr
{
// This is REALLY jank. We assume that a singular ARITH_OP
// means 0 ARITH_OP expr, which... is weird. We don't want to
// support *, /, etc., only -. We should fix this later with a pure
// Go scanner/parser.
if $1.Value.(ast.ArithmeticOp) != ast.ArithmeticOpSub {
if parserErr == nil {
parserErr = fmt.Errorf("Invalid unary operation: %v", $1.Value)
}
}
$$ = &ast.Arithmetic{
Op: $1.Value.(ast.ArithmeticOp),
Exprs: []ast.Node{
&ast.LiteralNode{Value: 0, Typex: ast.TypeInt},
$2,
},
Posx: $2.Pos(),
}
}
| expr ARITH_OP expr
{
$$ = &ast.Arithmetic{
Op: $2.Value.(ast.ArithmeticOp),
Exprs: []ast.Node{$1, $3},
Posx: $1.Pos(),
}
}
| IDENTIFIER
{
$$ = &ast.VariableAccess{Name: $1.Value.(string), Posx: $1.Pos}
}
| IDENTIFIER PAREN_LEFT args PAREN_RIGHT
{
$$ = &ast.Call{Func: $1.Value.(string), Args: $3, Posx: $1.Pos}
}
| IDENTIFIER SQUARE_BRACKET_LEFT expr SQUARE_BRACKET_RIGHT
{
$$ = &ast.Index{
Target: &ast.VariableAccess{
Name: $1.Value.(string),
Posx: $1.Pos,
},
Key: $3,
Posx: $1.Pos,
}
}
args:
{
$$ = nil
}
| args COMMA expr
{
$$ = append($1, $3)
}
| expr
{
$$ = append($$, $1)
}
literal:
STRING
{
$$ = &ast.LiteralNode{
Value: $1.Value.(string),
Typex: ast.TypeString,
Posx: $1.Pos,
}
}
%%

407
vendor/github.com/hashicorp/hil/lex.go generated vendored
View File

@ -1,407 +0,0 @@
package hil
import (
"bytes"
"fmt"
"strconv"
"unicode"
"unicode/utf8"
"github.com/hashicorp/hil/ast"
)
//go:generate go tool yacc -p parser lang.y
// The parser expects the lexer to return 0 on EOF.
const lexEOF = 0
// The parser uses the type <prefix>Lex as a lexer. It must provide
// the methods Lex(*<prefix>SymType) int and Error(string).
type parserLex struct {
Err error
Input string
mode parserMode
interpolationDepth int
pos int
width int
col, line int
lastLine int
astPos *ast.Pos
}
// parserToken is the token yielded to the parser. The value can be
// determined within the parser type based on the enum value returned
// from Lex.
type parserToken struct {
Value interface{}
Pos ast.Pos
}
// parserMode keeps track of what mode we're in for the parser. We have
// two modes: literal and interpolation. Literal mode is when strings
// don't have to be quoted, and interpolations are defined as ${foo}.
// Interpolation mode means that strings have to be quoted and unquoted
// things are identifiers, such as foo("bar").
type parserMode uint8
const (
parserModeInvalid parserMode = 0
parserModeLiteral = 1 << iota
parserModeInterpolation
)
// The parser calls this method to get each new token.
func (x *parserLex) Lex(yylval *parserSymType) int {
// We always start in literal mode, since programs don't start
// in an interpolation. ex. "foo ${bar}" vs "bar" (and assuming interp.)
if x.mode == parserModeInvalid {
x.mode = parserModeLiteral
}
// Defer an update to set the proper column/line we read the next token.
defer func() {
if yylval.token != nil && yylval.token.Pos.Column == 0 {
yylval.token.Pos = *x.astPos
}
}()
x.astPos = nil
return x.lex(yylval)
}
func (x *parserLex) lex(yylval *parserSymType) int {
switch x.mode {
case parserModeLiteral:
return x.lexModeLiteral(yylval)
case parserModeInterpolation:
return x.lexModeInterpolation(yylval)
default:
x.Error(fmt.Sprintf("Unknown parse mode: %d", x.mode))
return lexEOF
}
}
func (x *parserLex) lexModeLiteral(yylval *parserSymType) int {
for {
c := x.next()
if c == lexEOF {
return lexEOF
}
// Are we starting an interpolation?
if c == '$' && x.peek() == '{' {
x.next()
x.interpolationDepth++
x.mode = parserModeInterpolation
return PROGRAM_BRACKET_LEFT
}
// We're just a normal string that isn't part of any interpolation yet.
x.backup()
result, terminated := x.lexString(yylval, x.interpolationDepth > 0)
// If the string terminated and we're within an interpolation already
// then that means that we finished a nested string, so pop
// back out to interpolation mode.
if terminated && x.interpolationDepth > 0 {
x.mode = parserModeInterpolation
// If the string is empty, just skip it. We're still in
// an interpolation so we do this to avoid empty nodes.
if yylval.token.Value.(string) == "" {
return x.lex(yylval)
}
}
return result
}
}
func (x *parserLex) lexModeInterpolation(yylval *parserSymType) int {
for {
c := x.next()
if c == lexEOF {
return lexEOF
}
// Ignore all whitespace
if unicode.IsSpace(c) {
continue
}
// If we see a double quote then we're lexing a string since
// we're in interpolation mode.
if c == '"' {
result, terminated := x.lexString(yylval, true)
if !terminated {
// The string didn't end, which means that we're in the
// middle of starting another interpolation.
x.mode = parserModeLiteral
// If the string is empty and we're starting an interpolation,
// then just skip it to avoid empty string AST nodes
if yylval.token.Value.(string) == "" {
return x.lex(yylval)
}
}
return result
}
// If we are seeing a number, it is the start of a number. Lex it.
if c >= '0' && c <= '9' {
x.backup()
return x.lexNumber(yylval)
}
switch c {
case '}':
// '}' means we ended the interpolation. Pop back into
// literal mode and reduce our interpolation depth.
x.interpolationDepth--
x.mode = parserModeLiteral
return PROGRAM_BRACKET_RIGHT
case '(':
return PAREN_LEFT
case ')':
return PAREN_RIGHT
case '[':
return SQUARE_BRACKET_LEFT
case ']':
return SQUARE_BRACKET_RIGHT
case ',':
return COMMA
case '+':
yylval.token = &parserToken{Value: ast.ArithmeticOpAdd}
return ARITH_OP
case '-':
yylval.token = &parserToken{Value: ast.ArithmeticOpSub}
return ARITH_OP
case '*':
yylval.token = &parserToken{Value: ast.ArithmeticOpMul}
return ARITH_OP
case '/':
yylval.token = &parserToken{Value: ast.ArithmeticOpDiv}
return ARITH_OP
case '%':
yylval.token = &parserToken{Value: ast.ArithmeticOpMod}
return ARITH_OP
default:
x.backup()
return x.lexId(yylval)
}
}
}
func (x *parserLex) lexId(yylval *parserSymType) int {
var b bytes.Buffer
var last rune
for {
c := x.next()
if c == lexEOF {
break
}
// We only allow * after a '.' for resource splast: type.name.*.id
// Otherwise, its probably multiplication.
if c == '*' && last != '.' {
x.backup()
break
}
// If this isn't a character we want in an ID, return out.
// One day we should make this a regexp.
if c != '_' &&
c != '-' &&
c != '.' &&
c != '*' &&
!unicode.IsLetter(c) &&
!unicode.IsNumber(c) {
x.backup()
break
}
if _, err := b.WriteRune(c); err != nil {
x.Error(err.Error())
return lexEOF
}
last = c
}
yylval.token = &parserToken{Value: b.String()}
return IDENTIFIER
}
// lexNumber lexes out a number: an integer or a float.
func (x *parserLex) lexNumber(yylval *parserSymType) int {
var b bytes.Buffer
gotPeriod := false
for {
c := x.next()
if c == lexEOF {
break
}
// If we see a period, we might be getting a float..
if c == '.' {
// If we've already seen a period, then ignore it, and
// exit. This will probably result in a syntax error later.
if gotPeriod {
x.backup()
break
}
gotPeriod = true
} else if c < '0' || c > '9' {
// If we're not seeing a number, then also exit.
x.backup()
break
}
if _, err := b.WriteRune(c); err != nil {
x.Error(fmt.Sprintf("internal error: %s", err))
return lexEOF
}
}
// If we didn't see a period, it is an int
if !gotPeriod {
v, err := strconv.ParseInt(b.String(), 0, 0)
if err != nil {
x.Error(fmt.Sprintf("expected number: %s", err))
return lexEOF
}
yylval.token = &parserToken{Value: int(v)}
return INTEGER
}
// If we did see a period, it is a float
f, err := strconv.ParseFloat(b.String(), 64)
if err != nil {
x.Error(fmt.Sprintf("expected float: %s", err))
return lexEOF
}
yylval.token = &parserToken{Value: f}
return FLOAT
}
func (x *parserLex) lexString(yylval *parserSymType, quoted bool) (int, bool) {
var b bytes.Buffer
terminated := false
for {
c := x.next()
if c == lexEOF {
if quoted {
x.Error("unterminated string")
}
break
}
// Behavior is a bit different if we're lexing within a quoted string.
if quoted {
// If its a double quote, we've reached the end of the string
if c == '"' {
terminated = true
break
}
// Let's check to see if we're escaping anything.
if c == '\\' {
switch n := x.next(); n {
case '\\', '"':
c = n
case 'n':
c = '\n'
default:
x.backup()
}
}
}
// If we hit a dollar sign, then check if we're starting
// another interpolation. If so, then we're done.
if c == '$' {
n := x.peek()
// If it is '{', then we're starting another interpolation
if n == '{' {
x.backup()
break
}
// If it is '$', then we're escaping a dollar sign
if n == '$' {
x.next()
}
}
if _, err := b.WriteRune(c); err != nil {
x.Error(err.Error())
return lexEOF, false
}
}
yylval.token = &parserToken{Value: b.String()}
return STRING, terminated
}
// Return the next rune for the lexer.
func (x *parserLex) next() rune {
if int(x.pos) >= len(x.Input) {
x.width = 0
return lexEOF
}
r, w := utf8.DecodeRuneInString(x.Input[x.pos:])
x.width = w
x.pos += x.width
if x.line == 0 {
x.line = 1
x.col = 1
} else {
x.col += 1
}
if r == '\n' {
x.lastLine = x.col
x.line += 1
x.col = 1
}
if x.astPos == nil {
x.astPos = &ast.Pos{Column: x.col, Line: x.line}
}
return r
}
// peek returns but does not consume the next rune in the input
func (x *parserLex) peek() rune {
r := x.next()
x.backup()
return r
}
// backup steps back one rune. Can only be called once per next.
func (x *parserLex) backup() {
x.pos -= x.width
x.col -= 1
// If we are at column 0, we're backing up across a line boundary
// so we need to be careful to get the proper value.
if x.col == 0 {
x.col = x.lastLine
x.line -= 1
}
}
// The parser calls this method on a parse error.
func (x *parserLex) Error(s string) {
x.Err = fmt.Errorf("parse error: %s", s)
}

53
vendor/github.com/hashicorp/hil/parse.go generated vendored
View File

@ -1,42 +1,29 @@
package hil
import (
"sync"
"github.com/hashicorp/hil/ast"
"github.com/hashicorp/hil/parser"
"github.com/hashicorp/hil/scanner"
)
var parserLock sync.Mutex
var parserResult ast.Node
var parserErr error
// Parse parses the given program and returns an executable AST tree.
//
// Syntax errors are returned with error having the dynamic type
// *parser.ParseError, which gives the caller access to the source position
// where the error was found, which allows (for example) combining it with
// a known source filename to add context to the error message.
func Parse(v string) (ast.Node, error) {
// Unfortunately due to the way that goyacc generated parsers are
// formatted, we can only do a single parse at a time without a lot
// of extra work. In the future we can remove this limitation.
parserLock.Lock()
defer parserLock.Unlock()
// Reset our globals
parserErr = nil
parserResult = nil
// Create the lexer
lex := &parserLex{Input: v}
// Parse!
parserParse(lex)
// If we have a lex error, return that
if lex.Err != nil {
return nil, lex.Err
}
// If we have a parser error, return that
if parserErr != nil {
return nil, parserErr
}
return parserResult, nil
return ParseWithPosition(v, ast.Pos{Line: 1, Column: 1})
}
// ParseWithPosition is like Parse except that it overrides the source
// row and column position of the first character in the string, which should
// be 1-based.
//
// This can be used when HIL is embedded in another language and the outer
// parser knows the row and column where the HIL expression started within
// the overall source file.
func ParseWithPosition(v string, pos ast.Pos) (ast.Node, error) {
ch := scanner.Scan(v, pos)
return parser.Parse(ch)
}

38
vendor/github.com/hashicorp/hil/parser/error.go generated vendored Normal file
View File

@ -0,0 +1,38 @@
package parser
import (
"fmt"
"github.com/hashicorp/hil/ast"
"github.com/hashicorp/hil/scanner"
)
type ParseError struct {
Message string
Pos ast.Pos
}
func Errorf(pos ast.Pos, format string, args ...interface{}) error {
return &ParseError{
Message: fmt.Sprintf(format, args...),
Pos: pos,
}
}
// TokenErrorf is a convenient wrapper around Errorf that uses the
// position of the given token.
func TokenErrorf(token *scanner.Token, format string, args ...interface{}) error {
return Errorf(token.Pos, format, args...)
}
func ExpectationError(wanted string, got *scanner.Token) error {
return TokenErrorf(got, "expected %s but found %s", wanted, got)
}
func (e *ParseError) Error() string {
return fmt.Sprintf("parse error at %s: %s", e.Pos, e.Message)
}
func (e *ParseError) String() string {
return e.Error()
}

28
vendor/github.com/hashicorp/hil/parser/fuzz.go generated vendored Normal file
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@ -0,0 +1,28 @@
// +build gofuzz
package parser
import (
"github.com/hashicorp/hil/ast"
"github.com/hashicorp/hil/scanner"
)
// This is a fuzz testing function designed to be used with go-fuzz:
// https://github.com/dvyukov/go-fuzz
//
// It's not included in a normal build due to the gofuzz build tag above.
//
// There are some input files that you can use as a seed corpus for go-fuzz
// in the directory ./fuzz-corpus .
func Fuzz(data []byte) int {
str := string(data)
ch := scanner.Scan(str, ast.Pos{Line: 1, Column: 1})
_, err := Parse(ch)
if err != nil {
return 0
}
return 1
}

463
vendor/github.com/hashicorp/hil/parser/parser.go generated vendored Normal file
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@ -0,0 +1,463 @@
package parser
import (
"strconv"
"strings"
"unicode/utf8"
"github.com/hashicorp/hil/ast"
"github.com/hashicorp/hil/scanner"
)
func Parse(ch <-chan *scanner.Token) (ast.Node, error) {
peeker := scanner.NewPeeker(ch)
parser := &parser{peeker}
output, err := parser.ParseTopLevel()
peeker.Close()
return output, err
}
type parser struct {
peeker *scanner.Peeker
}
func (p *parser) ParseTopLevel() (ast.Node, error) {
return p.parseInterpolationSeq(false)
}
func (p *parser) ParseQuoted() (ast.Node, error) {
return p.parseInterpolationSeq(true)
}
// parseInterpolationSeq parses either the top-level sequence of literals
// and interpolation expressions or a similar sequence within a quoted
// string inside an interpolation expression. The latter case is requested
// by setting 'quoted' to true.
func (p *parser) parseInterpolationSeq(quoted bool) (ast.Node, error) {
literalType := scanner.LITERAL
endType := scanner.EOF
if quoted {
// exceptions for quoted sequences
literalType = scanner.STRING
endType = scanner.CQUOTE
}
startPos := p.peeker.Peek().Pos
if quoted {
tok := p.peeker.Read()
if tok.Type != scanner.OQUOTE {
return nil, ExpectationError("open quote", tok)
}
}
var exprs []ast.Node
for {
tok := p.peeker.Read()
if tok.Type == endType {
break
}
switch tok.Type {
case literalType:
val, err := p.parseStringToken(tok)
if err != nil {
return nil, err
}
exprs = append(exprs, &ast.LiteralNode{
Value: val,
Typex: ast.TypeString,
Posx: tok.Pos,
})
case scanner.BEGIN:
expr, err := p.ParseInterpolation()
if err != nil {
return nil, err
}
exprs = append(exprs, expr)
default:
return nil, ExpectationError(`"${"`, tok)
}
}
if len(exprs) == 0 {
// If we have no parts at all then the input must've
// been an empty string.
exprs = append(exprs, &ast.LiteralNode{
Value: "",
Typex: ast.TypeString,
Posx: startPos,
})
}
// As a special case, if our "Output" contains only one expression
// and it's a literal string then we'll hoist it up to be our
// direct return value, so callers can easily recognize a string
// that has no interpolations at all.
if len(exprs) == 1 {
if lit, ok := exprs[0].(*ast.LiteralNode); ok {
if lit.Typex == ast.TypeString {
return lit, nil
}
}
}
return &ast.Output{
Exprs: exprs,
Posx: startPos,
}, nil
}
// parseStringToken takes a token of either LITERAL or STRING type and
// returns the interpreted string, after processing any relevant
// escape sequences.
func (p *parser) parseStringToken(tok *scanner.Token) (string, error) {
var backslashes bool
switch tok.Type {
case scanner.LITERAL:
backslashes = false
case scanner.STRING:
backslashes = true
default:
panic("unsupported string token type")
}
raw := []byte(tok.Content)
buf := make([]byte, 0, len(raw))
for i := 0; i < len(raw); i++ {
b := raw[i]
more := len(raw) > (i + 1)
if b == '$' {
if more && raw[i+1] == '$' {
// skip over the second dollar sign
i++
}
} else if backslashes && b == '\\' {
if !more {
return "", Errorf(
ast.Pos{
Column: tok.Pos.Column + utf8.RuneCount(raw[:i]),
Line: tok.Pos.Line,
},
`unfinished backslash escape sequence`,
)
}
escapeType := raw[i+1]
switch escapeType {
case '\\':
// skip over the second slash
i++
case 'n':
b = '\n'
i++
default:
return "", Errorf(
ast.Pos{
Column: tok.Pos.Column + utf8.RuneCount(raw[:i]),
Line: tok.Pos.Line,
},
`invalid backslash escape sequence`,
)
}
}
buf = append(buf, b)
}
return string(buf), nil
}
func (p *parser) ParseInterpolation() (ast.Node, error) {
// By the time we're called, we're already "inside" the ${ sequence
// because the caller consumed the ${ token.
expr, err := p.ParseExpression()
if err != nil {
return nil, err
}
err = p.requireTokenType(scanner.END, `"}"`)
if err != nil {
return nil, err
}
return expr, nil
}
func (p *parser) ParseExpression() (ast.Node, error) {
startPos := p.peeker.Peek().Pos
var lhs, rhs ast.Node
operator := ast.ArithmeticOpInvalid
var err error
// parse a term that might be the first operand of a binary
// expression or it might just be a standalone term, but
// we won't know until we've parsed it and can look ahead
// to see if there's an operator token.
lhs, err = p.ParseExpressionTerm()
if err != nil {
return nil, err
}
// We'll keep eating up arithmetic operators until we run
// out, so that binary expressions will combine in a manner
// that is compatible with the old yacc-based parser:
// a+b*c => (a+b)*c, *not* a+(b*c)
//
// (perhaps later we'll implement some more intuitive precendence
// rules here, but for now being compatible with the old parser
// is the goal.)
for {
next := p.peeker.Peek()
newOperator := ast.ArithmeticOpInvalid
switch next.Type {
case scanner.PLUS:
newOperator = ast.ArithmeticOpAdd
case scanner.MINUS:
newOperator = ast.ArithmeticOpSub
case scanner.STAR:
newOperator = ast.ArithmeticOpMul
case scanner.SLASH:
newOperator = ast.ArithmeticOpDiv
case scanner.PERCENT:
newOperator = ast.ArithmeticOpMod
}
if newOperator == ast.ArithmeticOpInvalid {
break
}
// Are we extending an expression started on
// the previous iteration?
if operator != ast.ArithmeticOpInvalid {
lhs = &ast.Arithmetic{
Op: operator,
Exprs: []ast.Node{lhs, rhs},
Posx: startPos,
}
}
operator = newOperator
p.peeker.Read() // eat operator token
rhs, err = p.ParseExpressionTerm()
if err != nil {
return nil, err
}
}
if operator != ast.ArithmeticOpInvalid {
return &ast.Arithmetic{
Op: operator,
Exprs: []ast.Node{lhs, rhs},
Posx: startPos,
}, nil
} else {
return lhs, nil
}
}
func (p *parser) ParseExpressionTerm() (ast.Node, error) {
next := p.peeker.Peek()
switch next.Type {
case scanner.OPAREN:
p.peeker.Read()
expr, err := p.ParseExpression()
if err != nil {
return nil, err
}
err = p.requireTokenType(scanner.CPAREN, `")"`)
return expr, err
case scanner.OQUOTE:
return p.ParseQuoted()
case scanner.INTEGER:
tok := p.peeker.Read()
val, err := strconv.Atoi(tok.Content)
if err != nil {
return nil, TokenErrorf(tok, "invalid integer: %s", err)
}
return &ast.LiteralNode{
Value: val,
Typex: ast.TypeInt,
Posx: tok.Pos,
}, nil
case scanner.FLOAT:
tok := p.peeker.Read()
val, err := strconv.ParseFloat(tok.Content, 64)
if err != nil {
return nil, TokenErrorf(tok, "invalid float: %s", err)
}
return &ast.LiteralNode{
Value: val,
Typex: ast.TypeFloat,
Posx: tok.Pos,
}, nil
case scanner.BOOL:
tok := p.peeker.Read()
// the scanner guarantees that tok.Content is either "true" or "false"
var val bool
if tok.Content[0] == 't' {
val = true
} else {
val = false
}
return &ast.LiteralNode{
Value: val,
Typex: ast.TypeBool,
Posx: tok.Pos,
}, nil
case scanner.MINUS:
opTok := p.peeker.Read()
// important to use ParseExpressionTerm rather than ParseExpression
// here, otherwise we can capture a following binary expression into
// our negation.
// e.g. -46+5 should parse as (0-46)+5, not 0-(46+5)
operand, err := p.ParseExpressionTerm()
if err != nil {
return nil, err
}
// The AST currently represents negative numbers as
// a binary subtraction of the number from zero.
return &ast.Arithmetic{
Op: ast.ArithmeticOpSub,
Exprs: []ast.Node{
&ast.LiteralNode{
Value: 0,
Typex: ast.TypeInt,
Posx: opTok.Pos,
},
operand,
},
Posx: opTok.Pos,
}, nil
case scanner.IDENTIFIER:
return p.ParseScopeInteraction()
default:
return nil, ExpectationError("expression", next)
}
}
// ParseScopeInteraction parses the expression types that interact
// with the evaluation scope: variable access, function calls, and
// indexing.
//
// Indexing should actually be a distinct operator in its own right,
// so that e.g. it can be applied to the result of a function call,
// but for now we're preserving the behavior of the older yacc-based
// parser.
func (p *parser) ParseScopeInteraction() (ast.Node, error) {
first := p.peeker.Read()
startPos := first.Pos
if first.Type != scanner.IDENTIFIER {
return nil, ExpectationError("identifier", first)
}
next := p.peeker.Peek()
if next.Type == scanner.OPAREN {
// function call
funcName := first.Content
p.peeker.Read() // eat paren
var args []ast.Node
for {
if p.peeker.Peek().Type == scanner.CPAREN {
break
}
arg, err := p.ParseExpression()
if err != nil {
return nil, err
}
args = append(args, arg)
if p.peeker.Peek().Type == scanner.COMMA {
p.peeker.Read() // eat comma
continue
} else {
break
}
}
err := p.requireTokenType(scanner.CPAREN, `")"`)
if err != nil {
return nil, err
}
return &ast.Call{
Func: funcName,
Args: args,
Posx: startPos,
}, nil
}
varParts := []string{first.Content}
for p.peeker.Peek().Type == scanner.PERIOD {
p.peeker.Read() // eat period
// Read the next item, since variable access in HIL is composed
// of many things. For example: "var.0.bar" is the entire var access.
partTok := p.peeker.Read()
switch partTok.Type {
case scanner.IDENTIFIER:
case scanner.STAR:
case scanner.INTEGER:
default:
return nil, ExpectationError("identifier", partTok)
}
varParts = append(varParts, partTok.Content)
}
varName := strings.Join(varParts, ".")
varNode := &ast.VariableAccess{
Name: varName,
Posx: startPos,
}
if p.peeker.Peek().Type == scanner.OBRACKET {
// index operator
startPos := p.peeker.Read().Pos // eat bracket
indexExpr, err := p.ParseExpression()
if err != nil {
return nil, err
}
err = p.requireTokenType(scanner.CBRACKET, `"]"`)
if err != nil {
return nil, err
}
return &ast.Index{
Target: varNode,
Key: indexExpr,
Posx: startPos,
}, nil
}
return varNode, nil
}
// requireTokenType consumes the next token an returns an error if its
// type does not match the given type. nil is returned if the type matches.
//
// This is a helper around peeker.Read() for situations where the parser just
// wants to assert that a particular token type must be present.
func (p *parser) requireTokenType(wantType scanner.TokenType, wantName string) error {
token := p.peeker.Read()
if token.Type != wantType {
return ExpectationError(wantName, token)
}
return nil
}

55
vendor/github.com/hashicorp/hil/scanner/peeker.go generated vendored Normal file
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@ -0,0 +1,55 @@
package scanner
// Peeker is a utility that wraps a token channel returned by Scan and
// provides an interface that allows a caller (e.g. the parser) to
// work with the token stream in a mode that allows one token of lookahead,
// and provides utilities for more convenient processing of the stream.
type Peeker struct {
ch <-chan *Token
peeked *Token
}
func NewPeeker(ch <-chan *Token) *Peeker {
return &Peeker{
ch: ch,
}
}
// Peek returns the next token in the stream without consuming it. A
// subsequent call to Read will return the same token.
func (p *Peeker) Peek() *Token {
if p.peeked == nil {
p.peeked = <-p.ch
}
return p.peeked
}
// Read consumes the next token in the stream and returns it.
func (p *Peeker) Read() *Token {
token := p.Peek()
// As a special case, we will produce the EOF token forever once
// it is reached.
if token.Type != EOF {
p.peeked = nil
}
return token
}
// Close ensures that the token stream has been exhausted, to prevent
// the goroutine in the underlying scanner from leaking.
//
// It's not necessary to call this if the caller reads the token stream
// to EOF, since that implicitly closes the scanner.
func (p *Peeker) Close() {
for _ = range p.ch {
// discard
}
// Install a synthetic EOF token in 'peeked' in case someone
// erroneously calls Peek() or Read() after we've closed.
p.peeked = &Token{
Type: EOF,
Content: "",
}
}

442
vendor/github.com/hashicorp/hil/scanner/scanner.go generated vendored Normal file
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@ -0,0 +1,442 @@
package scanner
import (
"unicode"
"unicode/utf8"
"github.com/hashicorp/hil/ast"
)
// Scan returns a channel that recieves Tokens from the given input string.
//
// The scanner's job is just to partition the string into meaningful parts.
// It doesn't do any transformation of the raw input string, so the caller
// must deal with any further interpretation required, such as parsing INTEGER
// tokens into real ints, or dealing with escape sequences in LITERAL or
// STRING tokens.
//
// Strings in the returned tokens are slices from the original string.
//
// startPos should be set to ast.InitPos unless the caller knows that
// this interpolation string is part of a larger file and knows the position
// of the first character in that larger file.
func Scan(s string, startPos ast.Pos) <-chan *Token {
ch := make(chan *Token)
go scan(s, ch, startPos)
return ch
}
func scan(s string, ch chan<- *Token, pos ast.Pos) {
// 'remain' starts off as the whole string but we gradually
// slice of the front of it as we work our way through.
remain := s
// nesting keeps track of how many ${ .. } sequences we are
// inside, so we can recognize the minor differences in syntax
// between outer string literals (LITERAL tokens) and quoted
// string literals (STRING tokens).
nesting := 0
// We're going to flip back and forth between parsing literals/strings
// and parsing interpolation sequences ${ .. } until we reach EOF or
// some INVALID token.
All:
for {
startPos := pos
// Literal string processing first, since the beginning of
// a string is always outside of an interpolation sequence.
literalVal, terminator := scanLiteral(remain, pos, nesting > 0)
if len(literalVal) > 0 {
litType := LITERAL
if nesting > 0 {
litType = STRING
}
ch <- &Token{
Type: litType,
Content: literalVal,
Pos: startPos,
}
remain = remain[len(literalVal):]
}
ch <- terminator
remain = remain[len(terminator.Content):]
pos = terminator.Pos
// Safe to use len() here because none of the terminator tokens
// can contain UTF-8 sequences.
pos.Column = pos.Column + len(terminator.Content)
switch terminator.Type {
case INVALID:
// Synthetic EOF after invalid token, since further scanning
// is likely to just produce more garbage.
ch <- &Token{
Type: EOF,
Content: "",
Pos: pos,
}
break All
case EOF:
// All done!
break All
case BEGIN:
nesting++
case CQUOTE:
// nothing special to do
default:
// Should never happen
panic("invalid string/literal terminator")
}
// Now we do the processing of the insides of ${ .. } sequences.
// This loop terminates when we encounter either a closing } or
// an opening ", which will cause us to return to literal processing.
Interpolation:
for {
token, size, newPos := scanInterpolationToken(remain, pos)
ch <- token
remain = remain[size:]
pos = newPos
switch token.Type {
case INVALID:
// Synthetic EOF after invalid token, since further scanning
// is likely to just produce more garbage.
ch <- &Token{
Type: EOF,
Content: "",
Pos: pos,
}
break All
case EOF:
// All done
// (though a syntax error that we'll catch in the parser)
break All
case END:
nesting--
if nesting < 0 {
// Can happen if there are unbalanced ${ and } sequences
// in the input, which we'll catch in the parser.
nesting = 0
}
break Interpolation
case OQUOTE:
// Beginning of nested quoted string
break Interpolation
}
}
}
close(ch)
}
// Returns the token found at the start of the given string, followed by
// the number of bytes that were consumed from the string and the adjusted
// source position.
//
// Note that the number of bytes consumed can be more than the length of
// the returned token contents if the string begins with whitespace, since
// it will be silently consumed before reading the token.
func scanInterpolationToken(s string, startPos ast.Pos) (*Token, int, ast.Pos) {
pos := startPos
size := 0
// Consume whitespace, if any
for len(s) > 0 && byteIsSpace(s[0]) {
if s[0] == '\n' {
pos.Column = 1
pos.Line++
} else {
pos.Column++
}
size++
s = s[1:]
}
// Unexpected EOF during sequence
if len(s) == 0 {
return &Token{
Type: EOF,
Content: "",
Pos: pos,
}, size, pos
}
next := s[0]
var token *Token
switch next {
case '(', ')', '[', ']', ',', '.', '+', '-', '*', '/', '%':
// Easy punctuation symbols that don't have any special meaning
// during scanning, and that stand for themselves in the
// TokenType enumeration.
token = &Token{
Type: TokenType(next),
Content: s[:1],
Pos: pos,
}
case '}':
token = &Token{
Type: END,
Content: s[:1],
Pos: pos,
}
case '"':
token = &Token{
Type: OQUOTE,
Content: s[:1],
Pos: pos,
}
default:
if next >= '0' && next <= '9' {
num, numType := scanNumber(s)
token = &Token{
Type: numType,
Content: num,
Pos: pos,
}
} else if stringStartsWithIdentifier(s) {
ident, runeLen := scanIdentifier(s)
tokenType := IDENTIFIER
if ident == "true" || ident == "false" {
tokenType = BOOL
}
token = &Token{
Type: tokenType,
Content: ident,
Pos: pos,
}
// Skip usual token handling because it doesn't
// know how to deal with UTF-8 sequences.
pos.Column = pos.Column + runeLen
return token, size + len(ident), pos
} else {
_, byteLen := utf8.DecodeRuneInString(s)
token = &Token{
Type: INVALID,
Content: s[:byteLen],
Pos: pos,
}
// Skip usual token handling because it doesn't
// know how to deal with UTF-8 sequences.
pos.Column = pos.Column + 1
return token, size + byteLen, pos
}
}
// Here we assume that the token content contains no UTF-8 sequences,
// because we dealt with UTF-8 characters as a special case where
// necessary above.
size = size + len(token.Content)
pos.Column = pos.Column + len(token.Content)
return token, size, pos
}
// Returns the (possibly-empty) prefix of the given string that represents
// a literal, followed by the token that marks the end of the literal.
func scanLiteral(s string, startPos ast.Pos, nested bool) (string, *Token) {
litLen := 0
pos := startPos
var terminator *Token
for {
if litLen >= len(s) {
if nested {
// We've ended in the middle of a quoted string,
// which means this token is actually invalid.
return "", &Token{
Type: INVALID,
Content: s,
Pos: startPos,
}
}
terminator = &Token{
Type: EOF,
Content: "",
Pos: pos,
}
break
}
next := s[litLen]
if next == '$' && len(s) > litLen+1 {
follow := s[litLen+1]
if follow == '{' {
terminator = &Token{
Type: BEGIN,
Content: s[litLen : litLen+2],
Pos: pos,
}
pos.Column = pos.Column + 2
break
} else if follow == '$' {
// Double-$ escapes the special processing of $,
// so we will consume both characters here.
pos.Column = pos.Column + 2
litLen = litLen + 2
continue
}
}
// special handling that applies only to quoted strings
if nested {
if next == '"' {
terminator = &Token{
Type: CQUOTE,
Content: s[litLen : litLen+1],
Pos: pos,
}
pos.Column = pos.Column + 1
break
}
// Escaped quote marks do not terminate the string.
//
// All we do here in the scanner is avoid terminating a string
// due to an escaped quote. The parser is responsible for the
// full handling of escape sequences, since it's able to produce
// better error messages than we can produce in here.
if next == '\\' && len(s) > litLen+1 {
follow := s[litLen+1]
if follow == '"' {
// \" escapes the special processing of ",
// so we will consume both characters here.
pos.Column = pos.Column + 2
litLen = litLen + 2
continue
}
}
}
if next == '\n' {
pos.Column = 1
pos.Line++
litLen++
} else {
pos.Column++
// "Column" measures runes, so we need to actually consume
// a valid UTF-8 character here.
_, size := utf8.DecodeRuneInString(s[litLen:])
litLen = litLen + size
}
}
return s[:litLen], terminator
}
// scanNumber returns the extent of the prefix of the string that represents
// a valid number, along with what type of number it represents: INT or FLOAT.
//
// scanNumber does only basic character analysis: numbers consist of digits
// and periods, with at least one period signalling a FLOAT. It's the parser's
// responsibility to validate the form and range of the number, such as ensuring
// that a FLOAT actually contains only one period, etc.
func scanNumber(s string) (string, TokenType) {
period := -1
byteLen := 0
numType := INTEGER
for {
if byteLen >= len(s) {
break
}
next := s[byteLen]
if next != '.' && (next < '0' || next > '9') {
// If our last value was a period, then we're not a float,
// we're just an integer that ends in a period.
if period == byteLen-1 {
byteLen--
numType = INTEGER
}
break
}
if next == '.' {
// If we've already seen a period, break out
if period >= 0 {
break
}
period = byteLen
numType = FLOAT
}
byteLen++
}
return s[:byteLen], numType
}
// scanIdentifier returns the extent of the prefix of the string that
// represents a valid identifier, along with the length of that prefix
// in runes.
//
// Identifiers may contain utf8-encoded non-Latin letters, which will
// cause the returned "rune length" to be shorter than the byte length
// of the returned string.
func scanIdentifier(s string) (string, int) {
byteLen := 0
runeLen := 0
for {
if byteLen >= len(s) {
break
}
nextRune, size := utf8.DecodeRuneInString(s[byteLen:])
if !(nextRune == '_' || unicode.IsNumber(nextRune) || unicode.IsLetter(nextRune) || unicode.IsMark(nextRune)) {
break
}
byteLen = byteLen + size
runeLen = runeLen + 1
}
return s[:byteLen], runeLen
}
// byteIsSpace implements a restrictive interpretation of spaces that includes
// only what's valid inside interpolation sequences: spaces, tabs, newlines.
func byteIsSpace(b byte) bool {
switch b {
case ' ', '\t', '\r', '\n':
return true
default:
return false
}
}
// stringStartsWithIdentifier returns true if the given string begins with
// a character that is a legal start of an identifier: an underscore or
// any character that Unicode considers to be a letter.
func stringStartsWithIdentifier(s string) bool {
if len(s) == 0 {
return false
}
first := s[0]
// Easy ASCII cases first
if (first >= 'a' && first <= 'z') || (first >= 'A' && first <= 'Z') || first == '_' {
return true
}
// If our first byte begins a UTF-8 sequence then the sequence might
// be a unicode letter.
if utf8.RuneStart(first) {
firstRune, _ := utf8.DecodeRuneInString(s)
if unicode.IsLetter(firstRune) {
return true
}
}
return false
}

81
vendor/github.com/hashicorp/hil/scanner/token.go generated vendored Normal file
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@ -0,0 +1,81 @@
package scanner
import (
"fmt"
"github.com/hashicorp/hil/ast"
)
type Token struct {
Type TokenType
Content string
Pos ast.Pos
}
//go:generate stringer -type=TokenType
type TokenType rune
const (
// Raw string data outside of ${ .. } sequences
LITERAL TokenType = 'o'
// STRING is like a LITERAL but it's inside a quoted string
// within a ${ ... } sequence, and so it can contain backslash
// escaping.
STRING TokenType = 'S'
// Other Literals
INTEGER TokenType = 'I'
FLOAT TokenType = 'F'
BOOL TokenType = 'B'
BEGIN TokenType = '$' // actually "${"
END TokenType = '}'
OQUOTE TokenType = '“' // Opening quote of a nested quoted sequence
CQUOTE TokenType = '”' // Closing quote of a nested quoted sequence
OPAREN TokenType = '('
CPAREN TokenType = ')'
OBRACKET TokenType = '['
CBRACKET TokenType = ']'
COMMA TokenType = ','
IDENTIFIER TokenType = 'i'
PERIOD TokenType = '.'
PLUS TokenType = '+'
MINUS TokenType = '-'
STAR TokenType = '*'
SLASH TokenType = '/'
PERCENT TokenType = '%'
EOF TokenType = '␄'
// Produced for sequences that cannot be understood as valid tokens
// e.g. due to use of unrecognized punctuation.
INVALID TokenType = '<27>'
)
func (t *Token) String() string {
switch t.Type {
case EOF:
return "end of string"
case INVALID:
return fmt.Sprintf("invalid sequence %q", t.Content)
case INTEGER:
return fmt.Sprintf("integer %s", t.Content)
case FLOAT:
return fmt.Sprintf("float %s", t.Content)
case STRING:
return fmt.Sprintf("string %q", t.Content)
case LITERAL:
return fmt.Sprintf("literal %q", t.Content)
case OQUOTE:
return fmt.Sprintf("opening quote")
case CQUOTE:
return fmt.Sprintf("closing quote")
default:
// The remaining token types have content that
// speaks for itself.
return fmt.Sprintf("%q", t.Content)
}
}

40
vendor/github.com/hashicorp/hil/scanner/tokentype_string.go generated vendored Normal file
View File

@ -0,0 +1,40 @@
// Code generated by "stringer -type=TokenType"; DO NOT EDIT
package scanner
import "fmt"
const _TokenType_name = "BEGINPERCENTOPARENCPARENSTARPLUSCOMMAMINUSPERIODSLASHBOOLFLOATINTEGERSTRINGOBRACKETCBRACKETIDENTIFIERLITERALENDOQUOTECQUOTEEOFINVALID"
var _TokenType_map = map[TokenType]string{
36: _TokenType_name[0:5],
37: _TokenType_name[5:12],
40: _TokenType_name[12:18],
41: _TokenType_name[18:24],
42: _TokenType_name[24:28],
43: _TokenType_name[28:32],
44: _TokenType_name[32:37],
45: _TokenType_name[37:42],
46: _TokenType_name[42:48],
47: _TokenType_name[48:53],
66: _TokenType_name[53:57],
70: _TokenType_name[57:62],
73: _TokenType_name[62:69],
83: _TokenType_name[69:75],
91: _TokenType_name[75:83],
93: _TokenType_name[83:91],
105: _TokenType_name[91:101],
111: _TokenType_name[101:108],
125: _TokenType_name[108:111],
8220: _TokenType_name[111:117],
8221: _TokenType_name[117:123],
9220: _TokenType_name[123:126],
65533: _TokenType_name[126:133],
}
func (i TokenType) String() string {
if str, ok := _TokenType_map[i]; ok {
return str
}
return fmt.Sprintf("TokenType(%d)", i)
}

666
vendor/github.com/hashicorp/hil/y.go generated vendored
View File

@ -1,666 +0,0 @@
//line lang.y:6
package hil
import __yyfmt__ "fmt"
//line lang.y:6
import (
"fmt"
"github.com/hashicorp/hil/ast"
)
//line lang.y:16
type parserSymType struct {
yys int
node ast.Node
nodeList []ast.Node
str string
token *parserToken
}
const PROGRAM_BRACKET_LEFT = 57346
const PROGRAM_BRACKET_RIGHT = 57347
const PROGRAM_STRING_START = 57348
const PROGRAM_STRING_END = 57349
const PAREN_LEFT = 57350
const PAREN_RIGHT = 57351
const COMMA = 57352
const SQUARE_BRACKET_LEFT = 57353
const SQUARE_BRACKET_RIGHT = 57354
const ARITH_OP = 57355
const IDENTIFIER = 57356
const INTEGER = 57357
const FLOAT = 57358
const STRING = 57359
var parserToknames = [...]string{
"$end",
"error",
"$unk",
"PROGRAM_BRACKET_LEFT",
"PROGRAM_BRACKET_RIGHT",
"PROGRAM_STRING_START",
"PROGRAM_STRING_END",
"PAREN_LEFT",
"PAREN_RIGHT",
"COMMA",
"SQUARE_BRACKET_LEFT",
"SQUARE_BRACKET_RIGHT",
"ARITH_OP",
"IDENTIFIER",
"INTEGER",
"FLOAT",
"STRING",
}
var parserStatenames = [...]string{}
const parserEofCode = 1
const parserErrCode = 2
const parserInitialStackSize = 16
//line lang.y:200
//line yacctab:1
var parserExca = [...]int{
-1, 1,
1, -1,
-2, 0,
}
const parserNprod = 21
const parserPrivate = 57344
var parserTokenNames []string
var parserStates []string
const parserLast = 37
var parserAct = [...]int{
9, 7, 29, 17, 23, 16, 17, 3, 17, 20,
8, 18, 21, 17, 6, 19, 27, 28, 22, 8,
1, 25, 26, 7, 11, 2, 24, 10, 4, 30,
5, 0, 14, 15, 12, 13, 6,
}
var parserPact = [...]int{
-3, -1000, -3, -1000, -1000, -1000, -1000, 19, -1000, 0,
19, -3, -1000, -1000, 19, 1, -1000, 19, -5, -1000,
19, 19, -1000, -1000, 7, -7, -10, -1000, 19, -1000,
-7,
}
var parserPgo = [...]int{
0, 0, 30, 28, 24, 7, 26, 20,
}
var parserR1 = [...]int{
0, 7, 7, 4, 4, 5, 5, 2, 1, 1,
1, 1, 1, 1, 1, 1, 1, 6, 6, 6,
3,
}
var parserR2 = [...]int{
0, 0, 1, 1, 2, 1, 1, 3, 3, 1,
1, 1, 2, 3, 1, 4, 4, 0, 3, 1,
1,
}
var parserChk = [...]int{
-1000, -7, -4, -5, -3, -2, 17, 4, -5, -1,
8, -4, 15, 16, 13, 14, 5, 13, -1, -1,
8, 11, -1, 9, -6, -1, -1, 9, 10, 12,
-1,
}
var parserDef = [...]int{
1, -2, 2, 3, 5, 6, 20, 0, 4, 0,
0, 9, 10, 11, 0, 14, 7, 0, 0, 12,
17, 0, 13, 8, 0, 19, 0, 15, 0, 16,
18,
}
var parserTok1 = [...]int{
1,
}
var parserTok2 = [...]int{
2, 3, 4, 5, 6, 7, 8, 9, 10, 11,
12, 13, 14, 15, 16, 17,
}
var parserTok3 = [...]int{
0,
}
var parserErrorMessages = [...]struct {
state int
token int
msg string
}{}
//line yaccpar:1
/* parser for yacc output */
var (
parserDebug = 0
parserErrorVerbose = false
)
type parserLexer interface {
Lex(lval *parserSymType) int
Error(s string)
}
type parserParser interface {
Parse(parserLexer) int
Lookahead() int
}
type parserParserImpl struct {
lval parserSymType
stack [parserInitialStackSize]parserSymType
char int
}
func (p *parserParserImpl) Lookahead() int {
return p.char
}
func parserNewParser() parserParser {
return &parserParserImpl{}
}
const parserFlag = -1000
func parserTokname(c int) string {
if c >= 1 && c-1 < len(parserToknames) {
if parserToknames[c-1] != "" {
return parserToknames[c-1]
}
}
return __yyfmt__.Sprintf("tok-%v", c)
}
func parserStatname(s int) string {
if s >= 0 && s < len(parserStatenames) {
if parserStatenames[s] != "" {
return parserStatenames[s]
}
}
return __yyfmt__.Sprintf("state-%v", s)
}
func parserErrorMessage(state, lookAhead int) string {
const TOKSTART = 4
if !parserErrorVerbose {
return "syntax error"
}
for _, e := range parserErrorMessages {
if e.state == state && e.token == lookAhead {
return "syntax error: " + e.msg
}
}
res := "syntax error: unexpected " + parserTokname(lookAhead)
// To match Bison, suggest at most four expected tokens.
expected := make([]int, 0, 4)
// Look for shiftable tokens.
base := parserPact[state]
for tok := TOKSTART; tok-1 < len(parserToknames); tok++ {
if n := base + tok; n >= 0 && n < parserLast && parserChk[parserAct[n]] == tok {
if len(expected) == cap(expected) {
return res
}
expected = append(expected, tok)
}
}
if parserDef[state] == -2 {
i := 0
for parserExca[i] != -1 || parserExca[i+1] != state {
i += 2
}
// Look for tokens that we accept or reduce.
for i += 2; parserExca[i] >= 0; i += 2 {
tok := parserExca[i]
if tok < TOKSTART || parserExca[i+1] == 0 {
continue
}
if len(expected) == cap(expected) {
return res
}
expected = append(expected, tok)
}
// If the default action is to accept or reduce, give up.
if parserExca[i+1] != 0 {
return res
}
}
for i, tok := range expected {
if i == 0 {
res += ", expecting "
} else {
res += " or "
}
res += parserTokname(tok)
}
return res
}
func parserlex1(lex parserLexer, lval *parserSymType) (char, token int) {
token = 0
char = lex.Lex(lval)
if char <= 0 {
token = parserTok1[0]
goto out
}
if char < len(parserTok1) {
token = parserTok1[char]
goto out
}
if char >= parserPrivate {
if char < parserPrivate+len(parserTok2) {
token = parserTok2[char-parserPrivate]
goto out
}
}
for i := 0; i < len(parserTok3); i += 2 {
token = parserTok3[i+0]
if token == char {
token = parserTok3[i+1]
goto out
}
}
out:
if token == 0 {
token = parserTok2[1] /* unknown char */
}
if parserDebug >= 3 {
__yyfmt__.Printf("lex %s(%d)\n", parserTokname(token), uint(char))
}
return char, token
}
func parserParse(parserlex parserLexer) int {
return parserNewParser().Parse(parserlex)
}
func (parserrcvr *parserParserImpl) Parse(parserlex parserLexer) int {
var parsern int
var parserVAL parserSymType
var parserDollar []parserSymType
_ = parserDollar // silence set and not used
parserS := parserrcvr.stack[:]
Nerrs := 0 /* number of errors */
Errflag := 0 /* error recovery flag */
parserstate := 0
parserrcvr.char = -1
parsertoken := -1 // parserrcvr.char translated into internal numbering
defer func() {
// Make sure we report no lookahead when not parsing.
parserstate = -1
parserrcvr.char = -1
parsertoken = -1
}()
parserp := -1
goto parserstack
ret0:
return 0
ret1:
return 1
parserstack:
/* put a state and value onto the stack */
if parserDebug >= 4 {
__yyfmt__.Printf("char %v in %v\n", parserTokname(parsertoken), parserStatname(parserstate))
}
parserp++
if parserp >= len(parserS) {
nyys := make([]parserSymType, len(parserS)*2)
copy(nyys, parserS)
parserS = nyys
}
parserS[parserp] = parserVAL
parserS[parserp].yys = parserstate
parsernewstate:
parsern = parserPact[parserstate]
if parsern <= parserFlag {
goto parserdefault /* simple state */
}
if parserrcvr.char < 0 {
parserrcvr.char, parsertoken = parserlex1(parserlex, &parserrcvr.lval)
}
parsern += parsertoken
if parsern < 0 || parsern >= parserLast {
goto parserdefault
}
parsern = parserAct[parsern]
if parserChk[parsern] == parsertoken { /* valid shift */
parserrcvr.char = -1
parsertoken = -1
parserVAL = parserrcvr.lval
parserstate = parsern
if Errflag > 0 {
Errflag--
}
goto parserstack
}
parserdefault:
/* default state action */
parsern = parserDef[parserstate]
if parsern == -2 {
if parserrcvr.char < 0 {
parserrcvr.char, parsertoken = parserlex1(parserlex, &parserrcvr.lval)
}
/* look through exception table */
xi := 0
for {
if parserExca[xi+0] == -1 && parserExca[xi+1] == parserstate {
break
}
xi += 2
}
for xi += 2; ; xi += 2 {
parsern = parserExca[xi+0]
if parsern < 0 || parsern == parsertoken {
break
}
}
parsern = parserExca[xi+1]
if parsern < 0 {
goto ret0
}
}
if parsern == 0 {
/* error ... attempt to resume parsing */
switch Errflag {
case 0: /* brand new error */
parserlex.Error(parserErrorMessage(parserstate, parsertoken))
Nerrs++
if parserDebug >= 1 {
__yyfmt__.Printf("%s", parserStatname(parserstate))
__yyfmt__.Printf(" saw %s\n", parserTokname(parsertoken))
}
fallthrough
case 1, 2: /* incompletely recovered error ... try again */
Errflag = 3
/* find a state where "error" is a legal shift action */
for parserp >= 0 {
parsern = parserPact[parserS[parserp].yys] + parserErrCode
if parsern >= 0 && parsern < parserLast {
parserstate = parserAct[parsern] /* simulate a shift of "error" */
if parserChk[parserstate] == parserErrCode {
goto parserstack
}
}
/* the current p has no shift on "error", pop stack */
if parserDebug >= 2 {
__yyfmt__.Printf("error recovery pops state %d\n", parserS[parserp].yys)
}
parserp--
}
/* there is no state on the stack with an error shift ... abort */
goto ret1
case 3: /* no shift yet; clobber input char */
if parserDebug >= 2 {
__yyfmt__.Printf("error recovery discards %s\n", parserTokname(parsertoken))
}
if parsertoken == parserEofCode {
goto ret1
}
parserrcvr.char = -1
parsertoken = -1
goto parsernewstate /* try again in the same state */
}
}
/* reduction by production parsern */
if parserDebug >= 2 {
__yyfmt__.Printf("reduce %v in:\n\t%v\n", parsern, parserStatname(parserstate))
}
parsernt := parsern
parserpt := parserp
_ = parserpt // guard against "declared and not used"
parserp -= parserR2[parsern]
// parserp is now the index of $0. Perform the default action. Iff the
// reduced production is ε, $1 is possibly out of range.
if parserp+1 >= len(parserS) {
nyys := make([]parserSymType, len(parserS)*2)
copy(nyys, parserS)
parserS = nyys
}
parserVAL = parserS[parserp+1]
/* consult goto table to find next state */
parsern = parserR1[parsern]
parserg := parserPgo[parsern]
parserj := parserg + parserS[parserp].yys + 1
if parserj >= parserLast {
parserstate = parserAct[parserg]
} else {
parserstate = parserAct[parserj]
if parserChk[parserstate] != -parsern {
parserstate = parserAct[parserg]
}
}
// dummy call; replaced with literal code
switch parsernt {
case 1:
parserDollar = parserS[parserpt-0 : parserpt+1]
//line lang.y:38
{
parserResult = &ast.LiteralNode{
Value: "",
Typex: ast.TypeString,
Posx: ast.Pos{Column: 1, Line: 1},
}
}
case 2:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:46
{
parserResult = parserDollar[1].node
// We want to make sure that the top value is always an Output
// so that the return value is always a string, list of map from an
// interpolation.
//
// The logic for checking for a LiteralNode is a little annoying
// because functionally the AST is the same, but we do that because
// it makes for an easy literal check later (to check if a string
// has any interpolations).
if _, ok := parserDollar[1].node.(*ast.Output); !ok {
if n, ok := parserDollar[1].node.(*ast.LiteralNode); !ok || n.Typex != ast.TypeString {
parserResult = &ast.Output{
Exprs: []ast.Node{parserDollar[1].node},
Posx: parserDollar[1].node.Pos(),
}
}
}
}
case 3:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:69
{
parserVAL.node = parserDollar[1].node
}
case 4:
parserDollar = parserS[parserpt-2 : parserpt+1]
//line lang.y:73
{
var result []ast.Node
if c, ok := parserDollar[1].node.(*ast.Output); ok {
result = append(c.Exprs, parserDollar[2].node)
} else {
result = []ast.Node{parserDollar[1].node, parserDollar[2].node}
}
parserVAL.node = &ast.Output{
Exprs: result,
Posx: result[0].Pos(),
}
}
case 5:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:89
{
parserVAL.node = parserDollar[1].node
}
case 6:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:93
{
parserVAL.node = parserDollar[1].node
}
case 7:
parserDollar = parserS[parserpt-3 : parserpt+1]
//line lang.y:99
{
parserVAL.node = parserDollar[2].node
}
case 8:
parserDollar = parserS[parserpt-3 : parserpt+1]
//line lang.y:105
{
parserVAL.node = parserDollar[2].node
}
case 9:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:109
{
parserVAL.node = parserDollar[1].node
}
case 10:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:113
{
parserVAL.node = &ast.LiteralNode{
Value: parserDollar[1].token.Value.(int),
Typex: ast.TypeInt,
Posx: parserDollar[1].token.Pos,
}
}
case 11:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:121
{
parserVAL.node = &ast.LiteralNode{
Value: parserDollar[1].token.Value.(float64),
Typex: ast.TypeFloat,
Posx: parserDollar[1].token.Pos,
}
}
case 12:
parserDollar = parserS[parserpt-2 : parserpt+1]
//line lang.y:129
{
// This is REALLY jank. We assume that a singular ARITH_OP
// means 0 ARITH_OP expr, which... is weird. We don't want to
// support *, /, etc., only -. We should fix this later with a pure
// Go scanner/parser.
if parserDollar[1].token.Value.(ast.ArithmeticOp) != ast.ArithmeticOpSub {
if parserErr == nil {
parserErr = fmt.Errorf("Invalid unary operation: %v", parserDollar[1].token.Value)
}
}
parserVAL.node = &ast.Arithmetic{
Op: parserDollar[1].token.Value.(ast.ArithmeticOp),
Exprs: []ast.Node{
&ast.LiteralNode{Value: 0, Typex: ast.TypeInt},
parserDollar[2].node,
},
Posx: parserDollar[2].node.Pos(),
}
}
case 13:
parserDollar = parserS[parserpt-3 : parserpt+1]
//line lang.y:150
{
parserVAL.node = &ast.Arithmetic{
Op: parserDollar[2].token.Value.(ast.ArithmeticOp),
Exprs: []ast.Node{parserDollar[1].node, parserDollar[3].node},
Posx: parserDollar[1].node.Pos(),
}
}
case 14:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:158
{
parserVAL.node = &ast.VariableAccess{Name: parserDollar[1].token.Value.(string), Posx: parserDollar[1].token.Pos}
}
case 15:
parserDollar = parserS[parserpt-4 : parserpt+1]
//line lang.y:162
{
parserVAL.node = &ast.Call{Func: parserDollar[1].token.Value.(string), Args: parserDollar[3].nodeList, Posx: parserDollar[1].token.Pos}
}
case 16:
parserDollar = parserS[parserpt-4 : parserpt+1]
//line lang.y:166
{
parserVAL.node = &ast.Index{
Target: &ast.VariableAccess{
Name: parserDollar[1].token.Value.(string),
Posx: parserDollar[1].token.Pos,
},
Key: parserDollar[3].node,
Posx: parserDollar[1].token.Pos,
}
}
case 17:
parserDollar = parserS[parserpt-0 : parserpt+1]
//line lang.y:178
{
parserVAL.nodeList = nil
}
case 18:
parserDollar = parserS[parserpt-3 : parserpt+1]
//line lang.y:182
{
parserVAL.nodeList = append(parserDollar[1].nodeList, parserDollar[3].node)
}
case 19:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:186
{
parserVAL.nodeList = append(parserVAL.nodeList, parserDollar[1].node)
}
case 20:
parserDollar = parserS[parserpt-1 : parserpt+1]
//line lang.y:192
{
parserVAL.node = &ast.LiteralNode{
Value: parserDollar[1].token.Value.(string),
Typex: ast.TypeString,
Posx: parserDollar[1].token.Pos,
}
}
}
goto parserstack /* stack new state and value */
}

328
vendor/github.com/hashicorp/hil/y.output generated vendored
View File

@ -1,328 +0,0 @@
state 0
$accept: .top $end
top: . (1)
PROGRAM_BRACKET_LEFT shift 7
STRING shift 6
. reduce 1 (src line 37)
interpolation goto 5
literal goto 4
literalModeTop goto 2
literalModeValue goto 3
top goto 1
state 1
$accept: top.$end
$end accept
. error
state 2
top: literalModeTop. (2)
literalModeTop: literalModeTop.literalModeValue
PROGRAM_BRACKET_LEFT shift 7
STRING shift 6
. reduce 2 (src line 45)
interpolation goto 5
literal goto 4
literalModeValue goto 8
state 3
literalModeTop: literalModeValue. (3)
. reduce 3 (src line 67)
state 4
literalModeValue: literal. (5)
. reduce 5 (src line 87)
state 5
literalModeValue: interpolation. (6)
. reduce 6 (src line 92)
state 6
literal: STRING. (20)
. reduce 20 (src line 190)
state 7
interpolation: PROGRAM_BRACKET_LEFT.expr PROGRAM_BRACKET_RIGHT
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 9
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 8
literalModeTop: literalModeTop literalModeValue. (4)
. reduce 4 (src line 72)
state 9
interpolation: PROGRAM_BRACKET_LEFT expr.PROGRAM_BRACKET_RIGHT
expr: expr.ARITH_OP expr
PROGRAM_BRACKET_RIGHT shift 16
ARITH_OP shift 17
. error
state 10
expr: PAREN_LEFT.expr PAREN_RIGHT
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 18
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 11
literalModeTop: literalModeTop.literalModeValue
expr: literalModeTop. (9)
PROGRAM_BRACKET_LEFT shift 7
STRING shift 6
. reduce 9 (src line 108)
interpolation goto 5
literal goto 4
literalModeValue goto 8
state 12
expr: INTEGER. (10)
. reduce 10 (src line 112)
state 13
expr: FLOAT. (11)
. reduce 11 (src line 120)
state 14
expr: ARITH_OP.expr
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 19
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 15
expr: IDENTIFIER. (14)
expr: IDENTIFIER.PAREN_LEFT args PAREN_RIGHT
expr: IDENTIFIER.SQUARE_BRACKET_LEFT expr SQUARE_BRACKET_RIGHT
PAREN_LEFT shift 20
SQUARE_BRACKET_LEFT shift 21
. reduce 14 (src line 157)
state 16
interpolation: PROGRAM_BRACKET_LEFT expr PROGRAM_BRACKET_RIGHT. (7)
. reduce 7 (src line 97)
state 17
expr: expr ARITH_OP.expr
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 22
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 18
expr: PAREN_LEFT expr.PAREN_RIGHT
expr: expr.ARITH_OP expr
PAREN_RIGHT shift 23
ARITH_OP shift 17
. error
state 19
expr: ARITH_OP expr. (12)
expr: expr.ARITH_OP expr
. reduce 12 (src line 128)
state 20
expr: IDENTIFIER PAREN_LEFT.args PAREN_RIGHT
args: . (17)
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. reduce 17 (src line 177)
expr goto 25
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
args goto 24
state 21
expr: IDENTIFIER SQUARE_BRACKET_LEFT.expr SQUARE_BRACKET_RIGHT
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 26
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 22
expr: expr.ARITH_OP expr
expr: expr ARITH_OP expr. (13)
. reduce 13 (src line 149)
state 23
expr: PAREN_LEFT expr PAREN_RIGHT. (8)
. reduce 8 (src line 103)
state 24
expr: IDENTIFIER PAREN_LEFT args.PAREN_RIGHT
args: args.COMMA expr
PAREN_RIGHT shift 27
COMMA shift 28
. error
state 25
expr: expr.ARITH_OP expr
args: expr. (19)
ARITH_OP shift 17
. reduce 19 (src line 185)
state 26
expr: expr.ARITH_OP expr
expr: IDENTIFIER SQUARE_BRACKET_LEFT expr.SQUARE_BRACKET_RIGHT
SQUARE_BRACKET_RIGHT shift 29
ARITH_OP shift 17
. error
state 27
expr: IDENTIFIER PAREN_LEFT args PAREN_RIGHT. (15)
. reduce 15 (src line 161)
state 28
args: args COMMA.expr
PROGRAM_BRACKET_LEFT shift 7
PAREN_LEFT shift 10
ARITH_OP shift 14
IDENTIFIER shift 15
INTEGER shift 12
FLOAT shift 13
STRING shift 6
. error
expr goto 30
interpolation goto 5
literal goto 4
literalModeTop goto 11
literalModeValue goto 3
state 29
expr: IDENTIFIER SQUARE_BRACKET_LEFT expr SQUARE_BRACKET_RIGHT. (16)
. reduce 16 (src line 165)
state 30
expr: expr.ARITH_OP expr
args: args COMMA expr. (18)
ARITH_OP shift 17
. reduce 18 (src line 181)
17 terminals, 8 nonterminals
21 grammar rules, 31/2000 states
0 shift/reduce, 0 reduce/reduce conflicts reported
57 working sets used
memory: parser 45/30000
26 extra closures
67 shift entries, 1 exceptions
16 goto entries
31 entries saved by goto default
Optimizer space used: output 37/30000
37 table entries, 1 zero
maximum spread: 17, maximum offset: 28

24
vendor/vendor.json vendored
View File

@ -1418,16 +1418,28 @@
"revisionTime": "2016-11-09T22:51:35Z"
},
{
"checksumSHA1": "PjLBj8sicHOz2ZzuaMTPZ09OuFs=",
"checksumSHA1": "/TJCBetWCMVsOpehJzVk3S/xtWM=",
"path": "github.com/hashicorp/hil",
"revision": "a69e0a85dd050184c00f6080fce138f2dadb1a4c",
"revisionTime": "2016-11-11T01:09:07Z"
"revision": "2bf5bc8dced8810f7d012b42e278326dbce17126",
"revisionTime": "2016-11-13T18:21:31Z"
},
{
"checksumSHA1": "FFroNUb6Nn6xUQJMsVDTb4Cqzo4=",
"checksumSHA1": "YPJwewz3dAqEWOGP2qIIWeCufF0=",
"path": "github.com/hashicorp/hil/ast",
"revision": "ce4ab742a9dd2bb6e55050337333b2c56666e5a0",
"revisionTime": "2016-10-27T15:25:34Z"
"revision": "2bf5bc8dced8810f7d012b42e278326dbce17126",
"revisionTime": "2016-11-13T18:21:31Z"
},
{
"checksumSHA1": "BeqAygYXJlCHpU0HVWg4mxuROks=",
"path": "github.com/hashicorp/hil/parser",
"revision": "2bf5bc8dced8810f7d012b42e278326dbce17126",
"revisionTime": "2016-11-13T18:21:31Z"
},
{
"checksumSHA1": "vdufm+iFX0toqWyXrbrn5yZnrE0=",
"path": "github.com/hashicorp/hil/scanner",
"revision": "2bf5bc8dced8810f7d012b42e278326dbce17126",
"revisionTime": "2016-11-13T18:21:31Z"
},
{
"path": "github.com/hashicorp/logutils",