neoneo-go/pkg/core/mpt/batch.go

package mpt

import (
	"bytes"
	"sort"
)

// Batch is batch of storage changes.
// It stores key-value pairs in a sorted state.
type Batch struct {
	kv []keyValue
}

type keyValue struct {
	key   []byte
	value []byte
}

// Add adds key-value pair to batch.
// If there is an item with the specified key, it is replaced.
func (b *Batch) Add(key []byte, value []byte) {
	path := toNibbles(key)
	i := sort.Search(len(b.kv), func(i int) bool {
		return bytes.Compare(path, b.kv[i].key) <= 0
	})
	if i == len(b.kv) {
		b.kv = append(b.kv, keyValue{path, value})
	} else if bytes.Equal(b.kv[i].key, path) {
		b.kv[i].value = value
	} else {
		b.kv = append(b.kv, keyValue{})
		copy(b.kv[i+1:], b.kv[i:])
		b.kv[i].key = path
		b.kv[i].value = value
	}
}

// PutBatch puts batch to trie.
// It is not atomic (and probably cannot be without substantial slow-down)
// and returns number of elements processed.
// However each element is being put atomically, so Trie is always in a valid state.
// It is used mostly after the block processing to update MPT and error is not expected.
func (t *Trie) PutBatch(b Batch) (int, error) {
	r, n, err := t.putBatch(b.kv)
	t.root = r
	return n, err
}

func (t *Trie) putBatch(kv []keyValue) (Node, int, error) {
	return t.putBatchIntoNode(t.root, kv)
}

func (t *Trie) putBatchIntoNode(curr Node, kv []keyValue) (Node, int, error) {
	switch n := curr.(type) {
	case *LeafNode:
		return t.putBatchIntoLeaf(n, kv)
	case *BranchNode:
		return t.putBatchIntoBranch(n, kv)
	case *ExtensionNode:
		return t.putBatchIntoExtension(n, kv)
	case *HashNode:
		return t.putBatchIntoHash(n, kv)
	default:
		panic("invalid MPT node type")
	}
}

func (t *Trie) putBatchIntoLeaf(curr *LeafNode, kv []keyValue) (Node, int, error) {
	t.removeRef(curr.Hash(), curr.Bytes())
	return t.newSubTrieMany(nil, kv, curr.value)
}

func (t *Trie) putBatchIntoBranch(curr *BranchNode, kv []keyValue) (Node, int, error) {
	return t.addToBranch(curr, kv, true)
}

func (t *Trie) mergeExtension(prefix []byte, sub Node) Node {
	switch sn := sub.(type) {
	case *ExtensionNode:
		t.removeRef(sn.Hash(), sn.bytes)
		sn.key = append(prefix, sn.key...)
		sn.invalidateCache()
		t.addRef(sn.Hash(), sn.bytes)
		return sn
	case *HashNode:
		return sn
	default:
		if len(prefix) != 0 {
			e := NewExtensionNode(prefix, sub)
			t.addRef(e.Hash(), e.bytes)
			return e
		}
		return sub
	}
}

func (t *Trie) putBatchIntoExtension(curr *ExtensionNode, kv []keyValue) (Node, int, error) {
	t.removeRef(curr.Hash(), curr.bytes)

	common := lcpMany(kv)
	pref := lcp(common, curr.key)
	if len(pref) == len(curr.key) {
		// Extension must be split into new nodes.
		stripPrefix(len(curr.key), kv)
		sub, n, err := t.putBatchIntoNode(curr.next, kv)
		return t.mergeExtension(pref, sub), n, err
	}

	if len(pref) != 0 {
		stripPrefix(len(pref), kv)
		sub, n, err := t.putBatchIntoExtensionNoPrefix(curr.key[len(pref):], curr.next, kv)
		return t.mergeExtension(pref, sub), n, err
	}
	return t.putBatchIntoExtensionNoPrefix(curr.key, curr.next, kv)
}

func (t *Trie) putBatchIntoExtensionNoPrefix(key []byte, next Node, kv []keyValue) (Node, int, error) {
	b := NewBranchNode()
	if len(key) > 1 {
		b.Children[key[0]] = t.newSubTrie(key[1:], next, false)
	} else {
		b.Children[key[0]] = next
	}
	return t.addToBranch(b, kv, false)
}

func isEmpty(n Node) bool {
	hn, ok := n.(*HashNode)
	return ok && hn.IsEmpty()
}

// addToBranch puts items into the branch node assuming b is not yet in trie.
func (t *Trie) addToBranch(b *BranchNode, kv []keyValue, inTrie bool) (Node, int, error) {
	if inTrie {
		t.removeRef(b.Hash(), b.bytes)
	}
	n, err := t.iterateBatch(kv, func(c byte, kv []keyValue) (int, error) {
		child, n, err := t.putBatchIntoNode(b.Children[c], kv)
		b.Children[c] = child
		return n, err
	})
	if inTrie && n != 0 {
		b.invalidateCache()
	}
	return t.stripBranch(b), n, err
}

// stripsBranch strips branch node after incomplete batch put.
// It assumes there is no reference to b in trie.
func (t *Trie) stripBranch(b *BranchNode) Node {
	var n int
	var lastIndex byte
	for i := range b.Children {
		if !isEmpty(b.Children[i]) {
			n++
			lastIndex = byte(i)
		}
	}
	switch {
	case n == 0:
		return new(HashNode)
	case n == 1:
		return t.mergeExtension([]byte{lastIndex}, b.Children[lastIndex])
	default:
		t.addRef(b.Hash(), b.bytes)
		return b
	}
}

func (t *Trie) iterateBatch(kv []keyValue, f func(c byte, kv []keyValue) (int, error)) (int, error) {
	var n int
	for len(kv) != 0 {
		c, i := getLastIndex(kv)
		if c != lastChild {
			stripPrefix(1, kv[:i])
		}
		sub, err := f(c, kv[:i])
		n += sub
		if err != nil {
			return n, err
		}
		kv = kv[i:]
	}
	return n, nil
}

func (t *Trie) putBatchIntoHash(curr *HashNode, kv []keyValue) (Node, int, error) {
	if curr.IsEmpty() {
		common := lcpMany(kv)
		stripPrefix(len(common), kv)
		return t.newSubTrieMany(common, kv, nil)
	}
	result, err := t.getFromStore(curr.hash)
	if err != nil {
		return curr, 0, err
	}
	return t.putBatchIntoNode(result, kv)
}

// Creates new subtrie from provided key-value pairs.
// Items in kv must have no common prefix.
// If there are any deletions in kv, return error.
// kv is not empty.
// kv is sorted by key.
// value is current value stored by prefix.
func (t *Trie) newSubTrieMany(prefix []byte, kv []keyValue, value []byte) (Node, int, error) {
	if len(kv[0].key) == 0 {
		if len(kv[0].value) == 0 {
			if len(kv) == 1 {
				return new(HashNode), 1, nil
			}
			node, n, err := t.newSubTrieMany(prefix, kv[1:], nil)
			return node, n + 1, err
		}
		if len(kv) == 1 {
			return t.newSubTrie(prefix, NewLeafNode(kv[0].value), true), 1, nil
		}
		value = kv[0].value
	}

	// Prefix is empty and we have at least 2 children.
	b := NewBranchNode()
	if len(value) != 0 {
		// Empty key is always first.
		leaf := NewLeafNode(value)
		t.addRef(leaf.Hash(), leaf.bytes)
		b.Children[lastChild] = leaf
	}
	nd, n, err := t.addToBranch(b, kv, false)
	return t.mergeExtension(prefix, nd), n, err
}

func stripPrefix(n int, kv []keyValue) {
	for i := range kv {
		kv[i].key = kv[i].key[n:]
	}
}

func getLastIndex(kv []keyValue) (byte, int) {
	if len(kv[0].key) == 0 {
		return lastChild, 1
	}
	c := kv[0].key[0]
	for i := range kv[1:] {
		if kv[i+1].key[0] != c {
			return c, i + 1
		}
	}
	return c, len(kv)
}
mpt: support put in batches 2020-12-26 10:27:59 +00:00			`package mpt`

			`import (`
			`"bytes"`
			`"sort"`
			`)`

			`// Batch is batch of storage changes.`
			`// It stores key-value pairs in a sorted state.`
			`type Batch struct {`
			`kv []keyValue`
			`}`

			`type keyValue struct {`
			`key []byte`
			`value []byte`
			`}`

			`// Add adds key-value pair to batch.`
			`// If there is an item with the specified key, it is replaced.`
			`func (b *Batch) Add(key []byte, value []byte) {`
			`path := toNibbles(key)`
			`i := sort.Search(len(b.kv), func(i int) bool {`
			`return bytes.Compare(path, b.kv[i].key) <= 0`
			`})`
			`if i == len(b.kv) {`
			`b.kv = append(b.kv, keyValue{path, value})`
			`} else if bytes.Equal(b.kv[i].key, path) {`
			`b.kv[i].value = value`
			`} else {`
			`b.kv = append(b.kv, keyValue{})`
			`copy(b.kv[i+1:], b.kv[i:])`
			`b.kv[i].key = path`
			`b.kv[i].value = value`
			`}`
			`}`

			`// PutBatch puts batch to trie.`
			`// It is not atomic (and probably cannot be without substantial slow-down)`
			`// and returns number of elements processed.`
			`// However each element is being put atomically, so Trie is always in a valid state.`
			`// It is used mostly after the block processing to update MPT and error is not expected.`
			`func (t *Trie) PutBatch(b Batch) (int, error) {`
			`r, n, err := t.putBatch(b.kv)`
			`t.root = r`
			`return n, err`
			`}`

			`func (t *Trie) putBatch(kv []keyValue) (Node, int, error) {`
			`return t.putBatchIntoNode(t.root, kv)`
			`}`

			`func (t *Trie) putBatchIntoNode(curr Node, kv []keyValue) (Node, int, error) {`
			`switch n := curr.(type) {`
			`case *LeafNode:`
			`return t.putBatchIntoLeaf(n, kv)`
			`case *BranchNode:`
			`return t.putBatchIntoBranch(n, kv)`
			`case *ExtensionNode:`
			`return t.putBatchIntoExtension(n, kv)`
			`case *HashNode:`
			`return t.putBatchIntoHash(n, kv)`
			`default:`
			`panic("invalid MPT node type")`
			`}`
			`}`

			`func (t Trie) putBatchIntoLeaf(curr LeafNode, kv []keyValue) (Node, int, error) {`
			`t.removeRef(curr.Hash(), curr.Bytes())`
			`return t.newSubTrieMany(nil, kv, curr.value)`
			`}`

			`func (t Trie) putBatchIntoBranch(curr BranchNode, kv []keyValue) (Node, int, error) {`
			`return t.addToBranch(curr, kv, true)`
			`}`

			`func (t *Trie) mergeExtension(prefix []byte, sub Node) Node {`
			`switch sn := sub.(type) {`
			`case *ExtensionNode:`
			`t.removeRef(sn.Hash(), sn.bytes)`
			`sn.key = append(prefix, sn.key...)`
			`sn.invalidateCache()`
			`t.addRef(sn.Hash(), sn.bytes)`
			`return sn`
			`case *HashNode:`
			`return sn`
			`default:`
			`if len(prefix) != 0 {`
			`e := NewExtensionNode(prefix, sub)`
			`t.addRef(e.Hash(), e.bytes)`
			`return e`
			`}`
			`return sub`
			`}`
			`}`

			`func (t Trie) putBatchIntoExtension(curr ExtensionNode, kv []keyValue) (Node, int, error) {`
			`t.removeRef(curr.Hash(), curr.bytes)`

			`common := lcpMany(kv)`
			`pref := lcp(common, curr.key)`
			`if len(pref) == len(curr.key) {`
			`// Extension must be split into new nodes.`
			`stripPrefix(len(curr.key), kv)`
			`sub, n, err := t.putBatchIntoNode(curr.next, kv)`
			`return t.mergeExtension(pref, sub), n, err`
			`}`

			`if len(pref) != 0 {`
			`stripPrefix(len(pref), kv)`
			`sub, n, err := t.putBatchIntoExtensionNoPrefix(curr.key[len(pref):], curr.next, kv)`
			`return t.mergeExtension(pref, sub), n, err`
			`}`
			`return t.putBatchIntoExtensionNoPrefix(curr.key, curr.next, kv)`
			`}`

			`func (t *Trie) putBatchIntoExtensionNoPrefix(key []byte, next Node, kv []keyValue) (Node, int, error) {`
			`b := NewBranchNode()`
			`if len(key) > 1 {`
			`b.Children[key[0]] = t.newSubTrie(key[1:], next, false)`
			`} else {`
			`b.Children[key[0]] = next`
			`}`
			`return t.addToBranch(b, kv, false)`
			`}`

			`func isEmpty(n Node) bool {`
			`hn, ok := n.(*HashNode)`
			`return ok && hn.IsEmpty()`
			`}`

			`// addToBranch puts items into the branch node assuming b is not yet in trie.`
			`func (t Trie) addToBranch(b BranchNode, kv []keyValue, inTrie bool) (Node, int, error) {`
			`if inTrie {`
			`t.removeRef(b.Hash(), b.bytes)`
			`}`
			`n, err := t.iterateBatch(kv, func(c byte, kv []keyValue) (int, error) {`
			`child, n, err := t.putBatchIntoNode(b.Children[c], kv)`
			`b.Children[c] = child`
			`return n, err`
			`})`
			`if inTrie && n != 0 {`
			`b.invalidateCache()`
			`}`
			`return t.stripBranch(b), n, err`
			`}`

			`// stripsBranch strips branch node after incomplete batch put.`
			`// It assumes there is no reference to b in trie.`
			`func (t Trie) stripBranch(b BranchNode) Node {`
			`var n int`
			`var lastIndex byte`
			`for i := range b.Children {`
			`if !isEmpty(b.Children[i]) {`
			`n++`
			`lastIndex = byte(i)`
			`}`
			`}`
			`switch {`
			`case n == 0:`
			`return new(HashNode)`
			`case n == 1:`
			`return t.mergeExtension([]byte{lastIndex}, b.Children[lastIndex])`
			`default:`
			`t.addRef(b.Hash(), b.bytes)`
			`return b`
			`}`
			`}`

			`func (t *Trie) iterateBatch(kv []keyValue, f func(c byte, kv []keyValue) (int, error)) (int, error) {`
			`var n int`
			`for len(kv) != 0 {`
			`c, i := getLastIndex(kv)`
			`if c != lastChild {`
			`stripPrefix(1, kv[:i])`
			`}`
			`sub, err := f(c, kv[:i])`
			`n += sub`
			`if err != nil {`
			`return n, err`
			`}`
			`kv = kv[i:]`
			`}`
			`return n, nil`
			`}`

			`func (t Trie) putBatchIntoHash(curr HashNode, kv []keyValue) (Node, int, error) {`
			`if curr.IsEmpty() {`
			`common := lcpMany(kv)`
			`stripPrefix(len(common), kv)`
			`return t.newSubTrieMany(common, kv, nil)`
			`}`
			`result, err := t.getFromStore(curr.hash)`
			`if err != nil {`
			`return curr, 0, err`
			`}`
			`return t.putBatchIntoNode(result, kv)`
			`}`

			`// Creates new subtrie from provided key-value pairs.`
			`// Items in kv must have no common prefix.`
			`// If there are any deletions in kv, return error.`
			`// kv is not empty.`
			`// kv is sorted by key.`
			`// value is current value stored by prefix.`
			`func (t *Trie) newSubTrieMany(prefix []byte, kv []keyValue, value []byte) (Node, int, error) {`
			`if len(kv[0].key) == 0 {`
			`if len(kv[0].value) == 0 {`
			`if len(kv) == 1 {`
mpt: allow to remove non-existent keys in batch This bug was here before batch were intoduced. `Delete` is allowed to be called on missing keys with HALT result, MPT needs to take this into account. 2021-02-17 09:26:32 +00:00			`return new(HashNode), 1, nil`
mpt: support put in batches 2020-12-26 10:27:59 +00:00			`}`
			`node, n, err := t.newSubTrieMany(prefix, kv[1:], nil)`
			`return node, n + 1, err`
			`}`
			`if len(kv) == 1 {`
			`return t.newSubTrie(prefix, NewLeafNode(kv[0].value), true), 1, nil`
			`}`
			`value = kv[0].value`
			`}`

			`// Prefix is empty and we have at least 2 children.`
			`b := NewBranchNode()`
			`if len(value) != 0 {`
			`// Empty key is always first.`
			`leaf := NewLeafNode(value)`
			`t.addRef(leaf.Hash(), leaf.bytes)`
			`b.Children[lastChild] = leaf`
			`}`
			`nd, n, err := t.addToBranch(b, kv, false)`
			`return t.mergeExtension(prefix, nd), n, err`
			`}`

			`func stripPrefix(n int, kv []keyValue) {`
			`for i := range kv {`
			`kv[i].key = kv[i].key[n:]`
			`}`
			`}`

			`func getLastIndex(kv []keyValue) (byte, int) {`
			`if len(kv[0].key) == 0 {`
			`return lastChild, 1`
			`}`
			`c := kv[0].key[0]`
			`for i := range kv[1:] {`
			`if kv[i+1].key[0] != c {`
			`return c, i + 1`
			`}`
			`}`
			`return c, len(kv)`
			`}`