lnd.xprv/channeldb/paginate.go

package channeldb

import "github.com/lightningnetwork/lnd/channeldb/kvdb"

type paginator struct {
	// cursor is the cursor which we are using to iterate through a bucket.
	cursor kvdb.RCursor

	// reversed indicates whether we are paginating forwards or backwards.
	reversed bool

	// indexOffset is the index from which we will begin querying.
	indexOffset uint64

	// totalItems is the total number of items we allow in our response.
	totalItems uint64
}

// newPaginator returns a struct which can be used to query an indexed bucket
// in pages.
func newPaginator(c kvdb.RCursor, reversed bool,
	indexOffset, totalItems uint64) paginator {

	return paginator{
		cursor:      c,
		reversed:    reversed,
		indexOffset: indexOffset,
		totalItems:  totalItems,
	}
}

// keyValueForIndex seeks our cursor to a given index and returns the key and
// value at that position.
func (p paginator) keyValueForIndex(index uint64) ([]byte, []byte) {
	var keyIndex [8]byte
	byteOrder.PutUint64(keyIndex[:], index)
	return p.cursor.Seek(keyIndex[:])
}

// lastIndex returns the last value in our index, if our index is empty it
// returns 0.
func (p paginator) lastIndex() uint64 {
	keyIndex, _ := p.cursor.Last()
	if keyIndex == nil {
		return 0
	}

	return byteOrder.Uint64(keyIndex)
}

// nextKey is a helper closure to determine what key we should use next when
// we are iterating, depending on whether we are iterating forwards or in
// reverse.
func (p paginator) nextKey() ([]byte, []byte) {
	if p.reversed {
		return p.cursor.Prev()
	}
	return p.cursor.Next()
}

// cursorStart gets the index key and value for the first item we are looking
// up, taking into account that we may be paginating in reverse. The index
// offset provided is *excusive* so we will start with the item after the offset
// for forwards queries, and the item before the index for backwards queries.
func (p paginator) cursorStart() ([]byte, []byte) {
	indexKey, indexValue := p.keyValueForIndex(p.indexOffset + 1)

	// If the query is specifying reverse iteration, then we must
	// handle a few offset cases.
	if p.reversed {
		switch {

		// This indicates the default case, where no offset was
		// specified. In that case we just start from the last
		// entry.
		case p.indexOffset == 0:
			indexKey, indexValue = p.cursor.Last()

		// This indicates the offset being set to the very
		// first entry. Since there are no entries before
		// this offset, and the direction is reversed, we can
		// return without adding any invoices to the response.
		case p.indexOffset == 1:
			return nil, nil

		// If we have been given an index offset that is beyond our last
		// index value, we just return the last indexed value in our set
		// since we are querying in reverse. We do not cover the case
		// where our index offset equals our last index value, because
		// index offset is exclusive, so we would want to start at the
		// value before our last index.
		case p.indexOffset > p.lastIndex():
			return p.cursor.Last()

		// Otherwise we have an index offset which is within our set of
		// indexed keys, and we want to start at the item before our
		// offset. We seek to our index offset, then return the element
		// before it. We do this rather than p.indexOffset-1 to account
		// for indexes that have gaps.
		default:
			p.keyValueForIndex(p.indexOffset)
			indexKey, indexValue = p.cursor.Prev()
		}
	}

	return indexKey, indexValue
}

// query gets the start point for our index offset and iterates through keys
// in our index until we reach the total number of items required for the query
// or we run out of cursor values. This function takes a fetchAndAppend function
// which is responsible for looking up the entry at that index, adding the entry
// to its set of return items (if desired) and return a boolean which indicates
// whether the item was added. This is required to allow the paginator to
// determine when the response has the maximum number of required items.
func (p paginator) query(fetchAndAppend func(k, v []byte) (bool, error)) error {
	indexKey, indexValue := p.cursorStart()

	var totalItems int
	for ; indexKey != nil; indexKey, indexValue = p.nextKey() {
		// If our current return payload exceeds the max number
		// of invoices, then we'll exit now.
		if uint64(totalItems) >= p.totalItems {
			break
		}

		added, err := fetchAndAppend(indexKey, indexValue)
		if err != nil {
			return err
		}

		// If we added an item to our set in the latest fetch and append
		// we increment our total count.
		if added {
			totalItems++
		}
	}

	return nil
}
channeldb: add a paginator struct to process generic pagination We now use the same method of pagination for invoices and payments. Rather than duplicate logic across calls, we add a pagnator struct which can have query specific logic plugged into it. This commit also addresses an existing issue where a reverse query for invoices with an offset larger than our last offset would not return any invoices. We update this behaviour to act more like c.Seek and just start from the last entry. This behaviour change is covered by a unit test that previously checked for the lack of invoices. 2020-06-10 13:34:27 +03:00			`package channeldb`

			`import "github.com/lightningnetwork/lnd/channeldb/kvdb"`

			`type paginator struct {`
			`// cursor is the cursor which we are using to iterate through a bucket.`
			`cursor kvdb.RCursor`

			`// reversed indicates whether we are paginating forwards or backwards.`
			`reversed bool`

			`// indexOffset is the index from which we will begin querying.`
			`indexOffset uint64`

			`// totalItems is the total number of items we allow in our response.`
			`totalItems uint64`
			`}`

			`// newPaginator returns a struct which can be used to query an indexed bucket`
			`// in pages.`
			`func newPaginator(c kvdb.RCursor, reversed bool,`
			`indexOffset, totalItems uint64) paginator {`

			`return paginator{`
			`cursor: c,`
			`reversed: reversed,`
			`indexOffset: indexOffset,`
			`totalItems: totalItems,`
			`}`
			`}`

			`// keyValueForIndex seeks our cursor to a given index and returns the key and`
			`// value at that position.`
			`func (p paginator) keyValueForIndex(index uint64) ([]byte, []byte) {`
			`var keyIndex [8]byte`
			`byteOrder.PutUint64(keyIndex[:], index)`
			`return p.cursor.Seek(keyIndex[:])`
			`}`

			`// lastIndex returns the last value in our index, if our index is empty it`
			`// returns 0.`
			`func (p paginator) lastIndex() uint64 {`
			`keyIndex, _ := p.cursor.Last()`
			`if keyIndex == nil {`
			`return 0`
			`}`

			`return byteOrder.Uint64(keyIndex)`
			`}`

			`// nextKey is a helper closure to determine what key we should use next when`
			`// we are iterating, depending on whether we are iterating forwards or in`
			`// reverse.`
			`func (p paginator) nextKey() ([]byte, []byte) {`
			`if p.reversed {`
			`return p.cursor.Prev()`
			`}`
			`return p.cursor.Next()`
			`}`

			`// cursorStart gets the index key and value for the first item we are looking`
			`// up, taking into account that we may be paginating in reverse. The index`
			`// offset provided is excusive so we will start with the item after the offset`
			`// for forwards queries, and the item before the index for backwards queries.`
			`func (p paginator) cursorStart() ([]byte, []byte) {`
			`indexKey, indexValue := p.keyValueForIndex(p.indexOffset + 1)`

			`// If the query is specifying reverse iteration, then we must`
			`// handle a few offset cases.`
			`if p.reversed {`
			`switch {`

			`// This indicates the default case, where no offset was`
			`// specified. In that case we just start from the last`
			`// entry.`
			`case p.indexOffset == 0:`
			`indexKey, indexValue = p.cursor.Last()`

			`// This indicates the offset being set to the very`
			`// first entry. Since there are no entries before`
			`// this offset, and the direction is reversed, we can`
			`// return without adding any invoices to the response.`
			`case p.indexOffset == 1:`
			`return nil, nil`

			`// If we have been given an index offset that is beyond our last`
			`// index value, we just return the last indexed value in our set`
			`// since we are querying in reverse. We do not cover the case`
			`// where our index offset equals our last index value, because`
			`// index offset is exclusive, so we would want to start at the`
			`// value before our last index.`
			`case p.indexOffset > p.lastIndex():`
			`return p.cursor.Last()`

			`// Otherwise we have an index offset which is within our set of`
			`// indexed keys, and we want to start at the item before our`
			`// offset. We seek to our index offset, then return the element`
			`// before it. We do this rather than p.indexOffset-1 to account`
			`// for indexes that have gaps.`
			`default:`
			`p.keyValueForIndex(p.indexOffset)`
			`indexKey, indexValue = p.cursor.Prev()`
			`}`
			`}`

			`return indexKey, indexValue`
			`}`

			`// query gets the start point for our index offset and iterates through keys`
			`// in our index until we reach the total number of items required for the query`
			`// or we run out of cursor values. This function takes a fetchAndAppend function`
			`// which is responsible for looking up the entry at that index, adding the entry`
			`// to its set of return items (if desired) and return a boolean which indicates`
			`// whether the item was added. This is required to allow the paginator to`
			`// determine when the response has the maximum number of required items.`
			`func (p paginator) query(fetchAndAppend func(k, v []byte) (bool, error)) error {`
			`indexKey, indexValue := p.cursorStart()`

			`var totalItems int`
			`for ; indexKey != nil; indexKey, indexValue = p.nextKey() {`
			`// If our current return payload exceeds the max number`
			`// of invoices, then we'll exit now.`
			`if uint64(totalItems) >= p.totalItems {`
			`break`
			`}`

			`added, err := fetchAndAppend(indexKey, indexValue)`
			`if err != nil {`
			`return err`
			`}`

			`// If we added an item to our set in the latest fetch and append`
			`// we increment our total count.`
			`if added {`
			`totalItems++`
			`}`
			`}`

			`return nil`
			`}`