secretshop/pkg/suse/secretshop-1.0.0/vendor/github.com/hashicorp/hcl/hcl/printer/nodes.go

package printer

import (
	"bytes"
	"fmt"
	"sort"

	"github.com/hashicorp/hcl/hcl/ast"
	"github.com/hashicorp/hcl/hcl/token"
)

const (
	blank    = byte(' ')
	newline  = byte('\n')
	tab      = byte('\t')
	infinity = 1 << 30 // offset or line
)

var (
	unindent = []byte("\uE123") // in the private use space
)

type printer struct {
	cfg  Config
	prev token.Pos

	comments           []*ast.CommentGroup // may be nil, contains all comments
	standaloneComments []*ast.CommentGroup // contains all standalone comments (not assigned to any node)

	enableTrace bool
	indentTrace int
}

type ByPosition []*ast.CommentGroup

func (b ByPosition) Len() int           { return len(b) }
func (b ByPosition) Swap(i, j int)      { b[i], b[j] = b[j], b[i] }
func (b ByPosition) Less(i, j int) bool { return b[i].Pos().Before(b[j].Pos()) }

// collectComments comments all standalone comments which are not lead or line
// comment
func (p *printer) collectComments(node ast.Node) {
	// first collect all comments. This is already stored in
	// ast.File.(comments)
	ast.Walk(node, func(nn ast.Node) (ast.Node, bool) {
		switch t := nn.(type) {
		case *ast.File:
			p.comments = t.Comments
			return nn, false
		}
		return nn, true
	})

	standaloneComments := make(map[token.Pos]*ast.CommentGroup, 0)
	for _, c := range p.comments {
		standaloneComments[c.Pos()] = c
	}

	// next remove all lead and line comments from the overall comment map.
	// This will give us comments which are standalone, comments which are not
	// assigned to any kind of node.
	ast.Walk(node, func(nn ast.Node) (ast.Node, bool) {
		switch t := nn.(type) {
		case *ast.LiteralType:
			if t.LeadComment != nil {
				for _, comment := range t.LeadComment.List {
					if _, ok := standaloneComments[comment.Pos()]; ok {
						delete(standaloneComments, comment.Pos())
					}
				}
			}

			if t.LineComment != nil {
				for _, comment := range t.LineComment.List {
					if _, ok := standaloneComments[comment.Pos()]; ok {
						delete(standaloneComments, comment.Pos())
					}
				}
			}
		case *ast.ObjectItem:
			if t.LeadComment != nil {
				for _, comment := range t.LeadComment.List {
					if _, ok := standaloneComments[comment.Pos()]; ok {
						delete(standaloneComments, comment.Pos())
					}
				}
			}

			if t.LineComment != nil {
				for _, comment := range t.LineComment.List {
					if _, ok := standaloneComments[comment.Pos()]; ok {
						delete(standaloneComments, comment.Pos())
					}
				}
			}
		}

		return nn, true
	})

	for _, c := range standaloneComments {
		p.standaloneComments = append(p.standaloneComments, c)
	}

	sort.Sort(ByPosition(p.standaloneComments))
}

// output prints creates b printable HCL output and returns it.
func (p *printer) output(n interface{}) []byte {
	var buf bytes.Buffer

	switch t := n.(type) {
	case *ast.File:
		// File doesn't trace so we add the tracing here
		defer un(trace(p, "File"))
		return p.output(t.Node)
	case *ast.ObjectList:
		defer un(trace(p, "ObjectList"))

		var index int
		for {
			// Determine the location of the next actual non-comment
			// item. If we're at the end, the next item is at "infinity"
			var nextItem token.Pos
			if index != len(t.Items) {
				nextItem = t.Items[index].Pos()
			} else {
				nextItem = token.Pos{Offset: infinity, Line: infinity}
			}

			// Go through the standalone comments in the file and print out
			// the comments that we should be for this object item.
			for _, c := range p.standaloneComments {
				// Go through all the comments in the group. The group
				// should be printed together, not separated by double newlines.
				printed := false
				newlinePrinted := false
				for _, comment := range c.List {
					// We only care about comments after the previous item
					// we've printed so that comments are printed in the
					// correct locations (between two objects for example).
					// And before the next item.
					if comment.Pos().After(p.prev) && comment.Pos().Before(nextItem) {
						// if we hit the end add newlines so we can print the comment
						// we don't do this if prev is invalid which means the
						// beginning of the file since the first comment should
						// be at the first line.
						if !newlinePrinted && p.prev.IsValid() && index == len(t.Items) {
							buf.Write([]byte{newline, newline})
							newlinePrinted = true
						}

						// Write the actual comment.
						buf.WriteString(comment.Text)
						buf.WriteByte(newline)

						// Set printed to true to note that we printed something
						printed = true
					}
				}

				// If we're not at the last item, write a new line so
				// that there is a newline separating this comment from
				// the next object.
				if printed && index != len(t.Items) {
					buf.WriteByte(newline)
				}
			}

			if index == len(t.Items) {
				break
			}

			buf.Write(p.output(t.Items[index]))
			if index != len(t.Items)-1 {
				// Always write a newline to separate us from the next item
				buf.WriteByte(newline)

				// Need to determine if we're going to separate the next item
				// with a blank line. The logic here is simple, though there
				// are a few conditions:
				//
				//   1. The next object is more than one line away anyways,
				//      so we need an empty line.
				//
				//   2. The next object is not a "single line" object, so
				//      we need an empty line.
				//
				//   3. This current object is not a single line object,
				//      so we need an empty line.
				current := t.Items[index]
				next := t.Items[index+1]
				if next.Pos().Line != t.Items[index].Pos().Line+1 ||
					!p.isSingleLineObject(next) ||
					!p.isSingleLineObject(current) {
					buf.WriteByte(newline)
				}
			}
			index++
		}
	case *ast.ObjectKey:
		buf.WriteString(t.Token.Text)
	case *ast.ObjectItem:
		p.prev = t.Pos()
		buf.Write(p.objectItem(t))
	case *ast.LiteralType:
		buf.Write(p.literalType(t))
	case *ast.ListType:
		buf.Write(p.list(t))
	case *ast.ObjectType:
		buf.Write(p.objectType(t))
	default:
		fmt.Printf(" unknown type: %T\n", n)
	}

	return buf.Bytes()
}

func (p *printer) literalType(lit *ast.LiteralType) []byte {
	result := []byte(lit.Token.Text)
	switch lit.Token.Type {
	case token.HEREDOC:
		// Clear the trailing newline from heredocs
		if result[len(result)-1] == '\n' {
			result = result[:len(result)-1]
		}

		// Poison lines 2+ so that we don't indent them
		result = p.heredocIndent(result)
	case token.STRING:
		// If this is a multiline string, poison lines 2+ so we don't
		// indent them.
		if bytes.IndexRune(result, '\n') >= 0 {
			result = p.heredocIndent(result)
		}
	}

	return result
}

// objectItem returns the printable HCL form of an object item. An object type
// starts with one/multiple keys and has a value. The value might be of any
// type.
func (p *printer) objectItem(o *ast.ObjectItem) []byte {
	defer un(trace(p, fmt.Sprintf("ObjectItem: %s", o.Keys[0].Token.Text)))
	var buf bytes.Buffer

	if o.LeadComment != nil {
		for _, comment := range o.LeadComment.List {
			buf.WriteString(comment.Text)
			buf.WriteByte(newline)
		}
	}

	// If key and val are on different lines, treat line comments like lead comments.
	if o.LineComment != nil && o.Val.Pos().Line != o.Keys[0].Pos().Line {
		for _, comment := range o.LineComment.List {
			buf.WriteString(comment.Text)
			buf.WriteByte(newline)
		}
	}

	for i, k := range o.Keys {
		buf.WriteString(k.Token.Text)
		buf.WriteByte(blank)

		// reach end of key
		if o.Assign.IsValid() && i == len(o.Keys)-1 && len(o.Keys) == 1 {
			buf.WriteString("=")
			buf.WriteByte(blank)
		}
	}

	buf.Write(p.output(o.Val))

	if o.LineComment != nil && o.Val.Pos().Line == o.Keys[0].Pos().Line {
		buf.WriteByte(blank)
		for _, comment := range o.LineComment.List {
			buf.WriteString(comment.Text)
		}
	}

	return buf.Bytes()
}

// objectType returns the printable HCL form of an object type. An object type
// begins with a brace and ends with a brace.
func (p *printer) objectType(o *ast.ObjectType) []byte {
	defer un(trace(p, "ObjectType"))
	var buf bytes.Buffer
	buf.WriteString("{")

	var index int
	var nextItem token.Pos
	var commented, newlinePrinted bool
	for {
		// Determine the location of the next actual non-comment
		// item. If we're at the end, the next item is the closing brace
		if index != len(o.List.Items) {
			nextItem = o.List.Items[index].Pos()
		} else {
			nextItem = o.Rbrace
		}

		// Go through the standalone comments in the file and print out
		// the comments that we should be for this object item.
		for _, c := range p.standaloneComments {
			printed := false
			var lastCommentPos token.Pos
			for _, comment := range c.List {
				// We only care about comments after the previous item
				// we've printed so that comments are printed in the
				// correct locations (between two objects for example).
				// And before the next item.
				if comment.Pos().After(p.prev) && comment.Pos().Before(nextItem) {
					// If there are standalone comments and the initial newline has not
					// been printed yet, do it now.
					if !newlinePrinted {
						newlinePrinted = true
						buf.WriteByte(newline)
					}

					// add newline if it's between other printed nodes
					if index > 0 {
						commented = true
						buf.WriteByte(newline)
					}

					// Store this position
					lastCommentPos = comment.Pos()

					// output the comment itself
					buf.Write(p.indent(p.heredocIndent([]byte(comment.Text))))

					// Set printed to true to note that we printed something
					printed = true

					/*
						if index != len(o.List.Items) {
							buf.WriteByte(newline) // do not print on the end
						}
					*/
				}
			}

			// Stuff to do if we had comments
			if printed {
				// Always write a newline
				buf.WriteByte(newline)

				// If there is another item in the object and our comment
				// didn't hug it directly, then make sure there is a blank
				// line separating them.
				if nextItem != o.Rbrace && nextItem.Line != lastCommentPos.Line+1 {
					buf.WriteByte(newline)
				}
			}
		}

		if index == len(o.List.Items) {
			p.prev = o.Rbrace
			break
		}

		// At this point we are sure that it's not a totally empty block: print
		// the initial newline if it hasn't been printed yet by the previous
		// block about standalone comments.
		if !newlinePrinted {
			buf.WriteByte(newline)
			newlinePrinted = true
		}

		// check if we have adjacent one liner items. If yes we'll going to align
		// the comments.
		var aligned []*ast.ObjectItem
		for _, item := range o.List.Items[index:] {
			// we don't group one line lists
			if len(o.List.Items) == 1 {
				break
			}

			// one means a oneliner with out any lead comment
			// two means a oneliner with lead comment
			// anything else might be something else
			cur := lines(string(p.objectItem(item)))
			if cur > 2 {
				break
			}

			curPos := item.Pos()

			nextPos := token.Pos{}
			if index != len(o.List.Items)-1 {
				nextPos = o.List.Items[index+1].Pos()
			}

			prevPos := token.Pos{}
			if index != 0 {
				prevPos = o.List.Items[index-1].Pos()
			}

			// fmt.Println("DEBUG ----------------")
			// fmt.Printf("prev = %+v prevPos: %s\n", prev, prevPos)
			// fmt.Printf("cur = %+v curPos: %s\n", cur, curPos)
			// fmt.Printf("next = %+v nextPos: %s\n", next, nextPos)

			if curPos.Line+1 == nextPos.Line {
				aligned = append(aligned, item)
				index++
				continue
			}

			if curPos.Line-1 == prevPos.Line {
				aligned = append(aligned, item)
				index++

				// finish if we have a new line or comment next. This happens
				// if the next item is not adjacent
				if curPos.Line+1 != nextPos.Line {
					break
				}
				continue
			}

			break
		}

		// put newlines if the items are between other non aligned items.
		// newlines are also added if there is a standalone comment already, so
		// check it too
		if !commented && index != len(aligned) {
			buf.WriteByte(newline)
		}

		if len(aligned) >= 1 {
			p.prev = aligned[len(aligned)-1].Pos()

			items := p.alignedItems(aligned)
			buf.Write(p.indent(items))
		} else {
			p.prev = o.List.Items[index].Pos()

			buf.Write(p.indent(p.objectItem(o.List.Items[index])))
			index++
		}

		buf.WriteByte(newline)
	}

	buf.WriteString("}")
	return buf.Bytes()
}

func (p *printer) alignedItems(items []*ast.ObjectItem) []byte {
	var buf bytes.Buffer

	// find the longest key and value length, needed for alignment
	var longestKeyLen int // longest key length
	var longestValLen int // longest value length
	for _, item := range items {
		key := len(item.Keys[0].Token.Text)
		val := len(p.output(item.Val))

		if key > longestKeyLen {
			longestKeyLen = key
		}

		if val > longestValLen {
			longestValLen = val
		}
	}

	for i, item := range items {
		if item.LeadComment != nil {
			for _, comment := range item.LeadComment.List {
				buf.WriteString(comment.Text)
				buf.WriteByte(newline)
			}
		}

		for i, k := range item.Keys {
			keyLen := len(k.Token.Text)
			buf.WriteString(k.Token.Text)
			for i := 0; i < longestKeyLen-keyLen+1; i++ {
				buf.WriteByte(blank)
			}

			// reach end of key
			if i == len(item.Keys)-1 && len(item.Keys) == 1 {
				buf.WriteString("=")
				buf.WriteByte(blank)
			}
		}

		val := p.output(item.Val)
		valLen := len(val)
		buf.Write(val)

		if item.Val.Pos().Line == item.Keys[0].Pos().Line && item.LineComment != nil {
			for i := 0; i < longestValLen-valLen+1; i++ {
				buf.WriteByte(blank)
			}

			for _, comment := range item.LineComment.List {
				buf.WriteString(comment.Text)
			}
		}

		// do not print for the last item
		if i != len(items)-1 {
			buf.WriteByte(newline)
		}
	}

	return buf.Bytes()
}

// list returns the printable HCL form of an list type.
func (p *printer) list(l *ast.ListType) []byte {
	if p.isSingleLineList(l) {
		return p.singleLineList(l)
	}

	var buf bytes.Buffer
	buf.WriteString("[")
	buf.WriteByte(newline)

	var longestLine int
	for _, item := range l.List {
		// for now we assume that the list only contains literal types
		if lit, ok := item.(*ast.LiteralType); ok {
			lineLen := len(lit.Token.Text)
			if lineLen > longestLine {
				longestLine = lineLen
			}
		}
	}

	haveEmptyLine := false
	for i, item := range l.List {
		// If we have a lead comment, then we want to write that first
		leadComment := false
		if lit, ok := item.(*ast.LiteralType); ok && lit.LeadComment != nil {
			leadComment = true

			// Ensure an empty line before every element with a
			// lead comment (except the first item in a list).
			if !haveEmptyLine && i != 0 {
				buf.WriteByte(newline)
			}

			for _, comment := range lit.LeadComment.List {
				buf.Write(p.indent([]byte(comment.Text)))
				buf.WriteByte(newline)
			}
		}

		// also indent each line
		val := p.output(item)
		curLen := len(val)
		buf.Write(p.indent(val))

		// if this item is a heredoc, then we output the comma on
		// the next line. This is the only case this happens.
		comma := []byte{','}
		if lit, ok := item.(*ast.LiteralType); ok && lit.Token.Type == token.HEREDOC {
			buf.WriteByte(newline)
			comma = p.indent(comma)
		}

		buf.Write(comma)

		if lit, ok := item.(*ast.LiteralType); ok && lit.LineComment != nil {
			// if the next item doesn't have any comments, do not align
			buf.WriteByte(blank) // align one space
			for i := 0; i < longestLine-curLen; i++ {
				buf.WriteByte(blank)
			}

			for _, comment := range lit.LineComment.List {
				buf.WriteString(comment.Text)
			}
		}

		buf.WriteByte(newline)

		// Ensure an empty line after every element with a
		// lead comment (except the first item in a list).
		haveEmptyLine = leadComment && i != len(l.List)-1
		if haveEmptyLine {
			buf.WriteByte(newline)
		}
	}

	buf.WriteString("]")
	return buf.Bytes()
}

// isSingleLineList returns true if:
// * they were previously formatted entirely on one line
// * they consist entirely of literals
// * there are either no heredoc strings or the list has exactly one element
// * there are no line comments
func (printer) isSingleLineList(l *ast.ListType) bool {
	for _, item := range l.List {
		if item.Pos().Line != l.Lbrack.Line {
			return false
		}

		lit, ok := item.(*ast.LiteralType)
		if !ok {
			return false
		}

		if lit.Token.Type == token.HEREDOC && len(l.List) != 1 {
			return false
		}

		if lit.LineComment != nil {
			return false
		}
	}

	return true
}

// singleLineList prints a simple single line list.
// For a definition of "simple", see isSingleLineList above.
func (p *printer) singleLineList(l *ast.ListType) []byte {
	buf := &bytes.Buffer{}

	buf.WriteString("[")
	for i, item := range l.List {
		if i != 0 {
			buf.WriteString(", ")
		}

		// Output the item itself
		buf.Write(p.output(item))

		// The heredoc marker needs to be at the end of line.
		if lit, ok := item.(*ast.LiteralType); ok && lit.Token.Type == token.HEREDOC {
			buf.WriteByte(newline)
		}
	}

	buf.WriteString("]")
	return buf.Bytes()
}

// indent indents the lines of the given buffer for each non-empty line
func (p *printer) indent(buf []byte) []byte {
	var prefix []byte
	if p.cfg.SpacesWidth != 0 {
		for i := 0; i < p.cfg.SpacesWidth; i++ {
			prefix = append(prefix, blank)
		}
	} else {
		prefix = []byte{tab}
	}

	var res []byte
	bol := true
	for _, c := range buf {
		if bol && c != '\n' {
			res = append(res, prefix...)
		}

		res = append(res, c)
		bol = c == '\n'
	}
	return res
}

// unindent removes all the indentation from the tombstoned lines
func (p *printer) unindent(buf []byte) []byte {
	var res []byte
	for i := 0; i < len(buf); i++ {
		skip := len(buf)-i <= len(unindent)
		if !skip {
			skip = !bytes.Equal(unindent, buf[i:i+len(unindent)])
		}
		if skip {
			res = append(res, buf[i])
			continue
		}

		// We have a marker. we have to backtrace here and clean out
		// any whitespace ahead of our tombstone up to a \n
		for j := len(res) - 1; j >= 0; j-- {
			if res[j] == '\n' {
				break
			}

			res = res[:j]
		}

		// Skip the entire unindent marker
		i += len(unindent) - 1
	}

	return res
}

// heredocIndent marks all the 2nd and further lines as unindentable
func (p *printer) heredocIndent(buf []byte) []byte {
	var res []byte
	bol := false
	for _, c := range buf {
		if bol && c != '\n' {
			res = append(res, unindent...)
		}
		res = append(res, c)
		bol = c == '\n'
	}
	return res
}

// isSingleLineObject tells whether the given object item is a single
// line object such as "obj {}".
//
// A single line object:
//
//   * has no lead comments (hence multi-line)
//   * has no assignment
//   * has no values in the stanza (within {})
//
func (p *printer) isSingleLineObject(val *ast.ObjectItem) bool {
	// If there is a lead comment, can't be one line
	if val.LeadComment != nil {
		return false
	}

	// If there is assignment, we always break by line
	if val.Assign.IsValid() {
		return false
	}

	// If it isn't an object type, then its not a single line object
	ot, ok := val.Val.(*ast.ObjectType)
	if !ok {
		return false
	}

	// If the object has no items, it is single line!
	return len(ot.List.Items) == 0
}

func lines(txt string) int {
	endline := 1
	for i := 0; i < len(txt); i++ {
		if txt[i] == '\n' {
			endline++
		}
	}
	return endline
}

// ----------------------------------------------------------------------------
// Tracing support

func (p *printer) printTrace(a ...interface{}) {
	if !p.enableTrace {
		return
	}

	const dots = ". . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "
	const n = len(dots)
	i := 2 * p.indentTrace
	for i > n {
		fmt.Print(dots)
		i -= n
	}
	// i <= n
	fmt.Print(dots[0:i])
	fmt.Println(a...)
}

func trace(p *printer, msg string) *printer {
	p.printTrace(msg, "(")
	p.indentTrace++
	return p
}

// Usage pattern: defer un(trace(p, "..."))
func un(p *printer) {
	p.indentTrace--
	p.printTrace(")")
}