matterbridge/vendor/github.com/pelletier/go-toml/query/match.go

package query

import (
	"fmt"
	"github.com/pelletier/go-toml"
)

// base match
type matchBase struct {
	next pathFn
}

func (f *matchBase) setNext(next pathFn) {
	f.next = next
}

// terminating functor - gathers results
type terminatingFn struct {
	// empty
}

func newTerminatingFn() *terminatingFn {
	return &terminatingFn{}
}

func (f *terminatingFn) setNext(next pathFn) {
	// do nothing
}

func (f *terminatingFn) call(node interface{}, ctx *queryContext) {
	ctx.result.appendResult(node, ctx.lastPosition)
}

// match single key
type matchKeyFn struct {
	matchBase
	Name string
}

func newMatchKeyFn(name string) *matchKeyFn {
	return &matchKeyFn{Name: name}
}

func (f *matchKeyFn) call(node interface{}, ctx *queryContext) {
	if array, ok := node.([]*toml.Tree); ok {
		for _, tree := range array {
			item := tree.Get(f.Name)
			if item != nil {
				ctx.lastPosition = tree.GetPosition(f.Name)
				f.next.call(item, ctx)
			}
		}
	} else if tree, ok := node.(*toml.Tree); ok {
		item := tree.Get(f.Name)
		if item != nil {
			ctx.lastPosition = tree.GetPosition(f.Name)
			f.next.call(item, ctx)
		}
	}
}

// match single index
type matchIndexFn struct {
	matchBase
	Idx int
}

func newMatchIndexFn(idx int) *matchIndexFn {
	return &matchIndexFn{Idx: idx}
}

func (f *matchIndexFn) call(node interface{}, ctx *queryContext) {
	if arr, ok := node.([]interface{}); ok {
		if f.Idx < len(arr) && f.Idx >= 0 {
			if treesArray, ok := node.([]*toml.Tree); ok {
				if len(treesArray) > 0 {
					ctx.lastPosition = treesArray[0].Position()
				}
			}
			f.next.call(arr[f.Idx], ctx)
		}
	}
}

// filter by slicing
type matchSliceFn struct {
	matchBase
	Start, End, Step int
}

func newMatchSliceFn(start, end, step int) *matchSliceFn {
	return &matchSliceFn{Start: start, End: end, Step: step}
}

func (f *matchSliceFn) call(node interface{}, ctx *queryContext) {
	if arr, ok := node.([]interface{}); ok {
		// adjust indexes for negative values, reverse ordering
		realStart, realEnd := f.Start, f.End
		if realStart < 0 {
			realStart = len(arr) + realStart
		}
		if realEnd < 0 {
			realEnd = len(arr) + realEnd
		}
		if realEnd < realStart {
			realEnd, realStart = realStart, realEnd // swap
		}
		// loop and gather
		for idx := realStart; idx < realEnd; idx += f.Step {
			if treesArray, ok := node.([]*toml.Tree); ok {
				if len(treesArray) > 0 {
					ctx.lastPosition = treesArray[0].Position()
				}
			}
			f.next.call(arr[idx], ctx)
		}
	}
}

// match anything
type matchAnyFn struct {
	matchBase
}

func newMatchAnyFn() *matchAnyFn {
	return &matchAnyFn{}
}

func (f *matchAnyFn) call(node interface{}, ctx *queryContext) {
	if tree, ok := node.(*toml.Tree); ok {
		for _, k := range tree.Keys() {
			v := tree.Get(k)
			ctx.lastPosition = tree.GetPosition(k)
			f.next.call(v, ctx)
		}
	}
}

// filter through union
type matchUnionFn struct {
	Union []pathFn
}

func (f *matchUnionFn) setNext(next pathFn) {
	for _, fn := range f.Union {
		fn.setNext(next)
	}
}

func (f *matchUnionFn) call(node interface{}, ctx *queryContext) {
	for _, fn := range f.Union {
		fn.call(node, ctx)
	}
}

// match every single last node in the tree
type matchRecursiveFn struct {
	matchBase
}

func newMatchRecursiveFn() *matchRecursiveFn {
	return &matchRecursiveFn{}
}

func (f *matchRecursiveFn) call(node interface{}, ctx *queryContext) {
	originalPosition := ctx.lastPosition
	if tree, ok := node.(*toml.Tree); ok {
		var visit func(tree *toml.Tree)
		visit = func(tree *toml.Tree) {
			for _, k := range tree.Keys() {
				v := tree.Get(k)
				ctx.lastPosition = tree.GetPosition(k)
				f.next.call(v, ctx)
				switch node := v.(type) {
				case *toml.Tree:
					visit(node)
				case []*toml.Tree:
					for _, subtree := range node {
						visit(subtree)
					}
				}
			}
		}
		ctx.lastPosition = originalPosition
		f.next.call(tree, ctx)
		visit(tree)
	}
}

// match based on an externally provided functional filter
type matchFilterFn struct {
	matchBase
	Pos  toml.Position
	Name string
}

func newMatchFilterFn(name string, pos toml.Position) *matchFilterFn {
	return &matchFilterFn{Name: name, Pos: pos}
}

func (f *matchFilterFn) call(node interface{}, ctx *queryContext) {
	fn, ok := (*ctx.filters)[f.Name]
	if !ok {
		panic(fmt.Sprintf("%s: query context does not have filter '%s'",
			f.Pos.String(), f.Name))
	}
	switch castNode := node.(type) {
	case *toml.Tree:
		for _, k := range castNode.Keys() {
			v := castNode.Get(k)
			if fn(v) {
				ctx.lastPosition = castNode.GetPosition(k)
				f.next.call(v, ctx)
			}
		}
	case []*toml.Tree:
		for _, v := range castNode {
			if fn(v) {
				if len(castNode) > 0 {
					ctx.lastPosition = castNode[0].Position()
				}
				f.next.call(v, ctx)
			}
		}
	case []interface{}:
		for _, v := range castNode {
			if fn(v) {
				f.next.call(v, ctx)
			}
		}
	}
}
Add vendor files for spf13/viper 2018-03-04 22:46:13 +00:00			`package query`

			`import (`
			`"fmt"`
			`"github.com/pelletier/go-toml"`
			`)`

			`// base match`
			`type matchBase struct {`
			`next pathFn`
			`}`

			`func (f *matchBase) setNext(next pathFn) {`
			`f.next = next`
			`}`

			`// terminating functor - gathers results`
			`type terminatingFn struct {`
			`// empty`
			`}`

			`func newTerminatingFn() *terminatingFn {`
			`return &terminatingFn{}`
			`}`

			`func (f *terminatingFn) setNext(next pathFn) {`
			`// do nothing`
			`}`

			`func (f terminatingFn) call(node interface{}, ctx queryContext) {`
			`ctx.result.appendResult(node, ctx.lastPosition)`
			`}`

			`// match single key`
			`type matchKeyFn struct {`
			`matchBase`
			`Name string`
			`}`

			`func newMatchKeyFn(name string) *matchKeyFn {`
			`return &matchKeyFn{Name: name}`
			`}`

			`func (f matchKeyFn) call(node interface{}, ctx queryContext) {`
			`if array, ok := node.([]*toml.Tree); ok {`
			`for _, tree := range array {`
			`item := tree.Get(f.Name)`
			`if item != nil {`
			`ctx.lastPosition = tree.GetPosition(f.Name)`
			`f.next.call(item, ctx)`
			`}`
			`}`
			`} else if tree, ok := node.(*toml.Tree); ok {`
			`item := tree.Get(f.Name)`
			`if item != nil {`
			`ctx.lastPosition = tree.GetPosition(f.Name)`
			`f.next.call(item, ctx)`
			`}`
			`}`
			`}`

			`// match single index`
			`type matchIndexFn struct {`
			`matchBase`
			`Idx int`
			`}`

			`func newMatchIndexFn(idx int) *matchIndexFn {`
			`return &matchIndexFn{Idx: idx}`
			`}`

			`func (f matchIndexFn) call(node interface{}, ctx queryContext) {`
			`if arr, ok := node.([]interface{}); ok {`
			`if f.Idx < len(arr) && f.Idx >= 0 {`
			`if treesArray, ok := node.([]*toml.Tree); ok {`
			`if len(treesArray) > 0 {`
			`ctx.lastPosition = treesArray[0].Position()`
			`}`
			`}`
			`f.next.call(arr[f.Idx], ctx)`
			`}`
			`}`
			`}`

			`// filter by slicing`
			`type matchSliceFn struct {`
			`matchBase`
			`Start, End, Step int`
			`}`

			`func newMatchSliceFn(start, end, step int) *matchSliceFn {`
			`return &matchSliceFn{Start: start, End: end, Step: step}`
			`}`

			`func (f matchSliceFn) call(node interface{}, ctx queryContext) {`
			`if arr, ok := node.([]interface{}); ok {`
			`// adjust indexes for negative values, reverse ordering`
			`realStart, realEnd := f.Start, f.End`
			`if realStart < 0 {`
			`realStart = len(arr) + realStart`
			`}`
			`if realEnd < 0 {`
			`realEnd = len(arr) + realEnd`
			`}`
			`if realEnd < realStart {`
			`realEnd, realStart = realStart, realEnd // swap`
			`}`
			`// loop and gather`
			`for idx := realStart; idx < realEnd; idx += f.Step {`
			`if treesArray, ok := node.([]*toml.Tree); ok {`
			`if len(treesArray) > 0 {`
			`ctx.lastPosition = treesArray[0].Position()`
			`}`
			`}`
			`f.next.call(arr[idx], ctx)`
			`}`
			`}`
			`}`

			`// match anything`
			`type matchAnyFn struct {`
			`matchBase`
			`}`

			`func newMatchAnyFn() *matchAnyFn {`
			`return &matchAnyFn{}`
			`}`

			`func (f matchAnyFn) call(node interface{}, ctx queryContext) {`
			`if tree, ok := node.(*toml.Tree); ok {`
			`for _, k := range tree.Keys() {`
			`v := tree.Get(k)`
			`ctx.lastPosition = tree.GetPosition(k)`
			`f.next.call(v, ctx)`
			`}`
			`}`
			`}`

			`// filter through union`
			`type matchUnionFn struct {`
			`Union []pathFn`
			`}`

			`func (f *matchUnionFn) setNext(next pathFn) {`
			`for _, fn := range f.Union {`
			`fn.setNext(next)`
			`}`
			`}`

			`func (f matchUnionFn) call(node interface{}, ctx queryContext) {`
			`for _, fn := range f.Union {`
			`fn.call(node, ctx)`
			`}`
			`}`

			`// match every single last node in the tree`
			`type matchRecursiveFn struct {`
			`matchBase`
			`}`

			`func newMatchRecursiveFn() *matchRecursiveFn {`
			`return &matchRecursiveFn{}`
			`}`

			`func (f matchRecursiveFn) call(node interface{}, ctx queryContext) {`
			`originalPosition := ctx.lastPosition`
			`if tree, ok := node.(*toml.Tree); ok {`
			`var visit func(tree *toml.Tree)`
			`visit = func(tree *toml.Tree) {`
			`for _, k := range tree.Keys() {`
			`v := tree.Get(k)`
			`ctx.lastPosition = tree.GetPosition(k)`
			`f.next.call(v, ctx)`
			`switch node := v.(type) {`
			`case *toml.Tree:`
			`visit(node)`
			`case []*toml.Tree:`
			`for _, subtree := range node {`
			`visit(subtree)`
			`}`
			`}`
			`}`
			`}`
			`ctx.lastPosition = originalPosition`
			`f.next.call(tree, ctx)`
			`visit(tree)`
			`}`
			`}`

			`// match based on an externally provided functional filter`
			`type matchFilterFn struct {`
			`matchBase`
			`Pos toml.Position`
			`Name string`
			`}`

			`func newMatchFilterFn(name string, pos toml.Position) *matchFilterFn {`
			`return &matchFilterFn{Name: name, Pos: pos}`
			`}`

			`func (f matchFilterFn) call(node interface{}, ctx queryContext) {`
			`fn, ok := (*ctx.filters)[f.Name]`
			`if !ok {`
			`panic(fmt.Sprintf("%s: query context does not have filter '%s'",`
			`f.Pos.String(), f.Name))`
			`}`
			`switch castNode := node.(type) {`
			`case *toml.Tree:`
			`for _, k := range castNode.Keys() {`
			`v := castNode.Get(k)`
			`if fn(v) {`
			`ctx.lastPosition = castNode.GetPosition(k)`
			`f.next.call(v, ctx)`
			`}`
			`}`
			`case []*toml.Tree:`
			`for _, v := range castNode {`
			`if fn(v) {`
			`if len(castNode) > 0 {`
			`ctx.lastPosition = castNode[0].Position()`
			`}`
			`f.next.call(v, ctx)`
			`}`
			`}`
			`case []interface{}:`
			`for _, v := range castNode {`
			`if fn(v) {`
			`f.next.call(v, ctx)`
			`}`
			`}`
			`}`
			`}`