//  Copyright (c) 2017 Couchbase, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// 		http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

package vellum

import (
	"bytes"
	"io"
)

var defaultBuilderOpts = &BuilderOpts{
	Encoder:           1,
	RegistryTableSize: 10000,
	RegistryMRUSize:   2,
}

// A Builder is used to build a new FST.  When possible data is
// streamed out to the underlying Writer as soon as possible.
type Builder struct {
	unfinished *unfinishedNodes
	registry   *registry
	last       []byte
	len        int

	lastAddr int

	encoder encoder
	opts    *BuilderOpts

	builderNodePool builderNodePool
	transitionPool  transitionPool
}

const noneAddr = 1
const emptyAddr = 0

// NewBuilder returns a new Builder which will stream out the
// underlying representation to the provided Writer as the set is built.
func newBuilder(w io.Writer, opts *BuilderOpts) (*Builder, error) {
	if opts == nil {
		opts = defaultBuilderOpts
	}
	rv := &Builder{
		registry: newRegistry(opts.RegistryTableSize, opts.RegistryMRUSize),
		opts:     opts,
		lastAddr: noneAddr,
	}
	rv.unfinished = newUnfinishedNodes(&rv.builderNodePool)

	var err error
	rv.encoder, err = loadEncoder(opts.Encoder, w)
	if err != nil {
		return nil, err
	}
	err = rv.encoder.start()
	if err != nil {
		return nil, err
	}
	return rv, nil
}

func (b *Builder) Reset(w io.Writer) error {
	b.transitionPool.reset()
	b.builderNodePool.reset()
	b.unfinished.Reset(&b.builderNodePool)
	b.registry.Reset()
	b.lastAddr = noneAddr
	b.encoder.reset(w)
	b.last = nil
	b.len = 0

	err := b.encoder.start()
	if err != nil {
		return err
	}
	return nil
}

// Insert the provided value to the set being built.
// NOTE: values must be inserted in lexicographical order.
func (b *Builder) Insert(key []byte, val uint64) error {
	// ensure items are added in lexicographic order
	if bytes.Compare(key, b.last) < 0 {
		return ErrOutOfOrder
	}
	if len(key) == 0 {
		b.len = 1
		b.unfinished.setRootOutput(val)
		return nil
	}

	prefixLen, out := b.unfinished.findCommonPrefixAndSetOutput(key, val)
	b.len++
	err := b.compileFrom(prefixLen)
	if err != nil {
		return err
	}
	b.copyLastKey(key)
	b.unfinished.addSuffix(key[prefixLen:], out, &b.builderNodePool)

	return nil
}

func (b *Builder) copyLastKey(key []byte) {
	if b.last == nil {
		b.last = make([]byte, 0, 64)
	} else {
		b.last = b.last[:0]
	}
	b.last = append(b.last, key...)
}

// Close MUST be called after inserting all values.
func (b *Builder) Close() error {
	err := b.compileFrom(0)
	if err != nil {
		return err
	}
	root := b.unfinished.popRoot()
	rootAddr, err := b.compile(root)
	if err != nil {
		return err
	}
	return b.encoder.finish(b.len, rootAddr)
}

func (b *Builder) compileFrom(iState int) error {
	addr := noneAddr
	for iState+1 < len(b.unfinished.stack) {
		var node *builderNode
		if addr == noneAddr {
			node = b.unfinished.popEmpty()
		} else {
			node = b.unfinished.popFreeze(addr, &b.transitionPool)
		}
		var err error
		addr, err = b.compile(node)
		if err != nil {
			return nil
		}
	}
	b.unfinished.topLastFreeze(addr, &b.transitionPool)
	return nil
}

func (b *Builder) compile(node *builderNode) (int, error) {
	if node.final && len(node.trans) == 0 &&
		node.finalOutput == 0 {
		return 0, nil
	}
	found, addr, entry := b.registry.entry(node)
	if found {
		return addr, nil
	}
	addr, err := b.encoder.encodeState(node, b.lastAddr)
	if err != nil {
		return 0, err
	}

	b.lastAddr = addr
	entry.addr = addr
	return addr, nil
}

type unfinishedNodes struct {
	stack []*builderNodeUnfinished

	// cache allocates a reasonable number of builderNodeUnfinished
	// objects up front and tries to keep reusing them
	// because the main data structure is a stack, we assume the
	// same access pattern, and don't track items separately
	// this means calls get() and pushXYZ() must be paired,
	// as well as calls put() and popXYZ()
	cache []builderNodeUnfinished
}

func (u *unfinishedNodes) Reset(p *builderNodePool) {
	u.stack = u.stack[:0]
	for i := 0; i < len(u.cache); i++ {
		u.cache[i] = builderNodeUnfinished{}
	}
	u.pushEmpty(false, p)
}

func newUnfinishedNodes(p *builderNodePool) *unfinishedNodes {
	rv := &unfinishedNodes{
		stack: make([]*builderNodeUnfinished, 0, 64),
		cache: make([]builderNodeUnfinished, 64),
	}
	rv.pushEmpty(false, p)
	return rv
}

// get new builderNodeUnfinished, reusing cache if possible
func (u *unfinishedNodes) get() *builderNodeUnfinished {
	if len(u.stack) < len(u.cache) {
		return &u.cache[len(u.stack)]
	}
	// full now allocate a new one
	return &builderNodeUnfinished{}
}

// return builderNodeUnfinished, clearing it for reuse
func (u *unfinishedNodes) put() {
	if len(u.stack) >= len(u.cache) {
		return
		// do nothing, not part of cache
	}
	u.cache[len(u.stack)] = builderNodeUnfinished{}
}

func (u *unfinishedNodes) findCommonPrefixAndSetOutput(key []byte,
	out uint64) (int, uint64) {
	var i int
	for i < len(key) {
		if i >= len(u.stack) {
			break
		}
		var addPrefix uint64
		if !u.stack[i].hasLastT {
			break
		}
		if u.stack[i].lastIn == key[i] {
			commonPre := outputPrefix(u.stack[i].lastOut, out)
			addPrefix = outputSub(u.stack[i].lastOut, commonPre)
			out = outputSub(out, commonPre)
			u.stack[i].lastOut = commonPre
			i++
		} else {
			break
		}

		if addPrefix != 0 {
			u.stack[i].addOutputPrefix(addPrefix)
		}
	}

	return i, out
}

func (u *unfinishedNodes) pushEmpty(final bool, p *builderNodePool) {
	next := u.get()
	next.node = p.alloc()
	next.node.final = final
	u.stack = append(u.stack, next)
}

func (u *unfinishedNodes) popRoot() *builderNode {
	l := len(u.stack)
	var unfinished *builderNodeUnfinished
	u.stack, unfinished = u.stack[:l-1], u.stack[l-1]
	rv := unfinished.node
	u.put()
	return rv
}

func (u *unfinishedNodes) popFreeze(addr int, tp *transitionPool) *builderNode {
	l := len(u.stack)
	var unfinished *builderNodeUnfinished
	u.stack, unfinished = u.stack[:l-1], u.stack[l-1]
	unfinished.lastCompiled(addr, tp)
	rv := unfinished.node
	u.put()
	return rv
}

func (u *unfinishedNodes) popEmpty() *builderNode {
	l := len(u.stack)
	var unfinished *builderNodeUnfinished
	u.stack, unfinished = u.stack[:l-1], u.stack[l-1]
	rv := unfinished.node
	u.put()
	return rv
}

func (u *unfinishedNodes) setRootOutput(out uint64) {
	u.stack[0].node.final = true
	u.stack[0].node.finalOutput = out
}

func (u *unfinishedNodes) topLastFreeze(addr int, tp *transitionPool) {
	last := len(u.stack) - 1
	u.stack[last].lastCompiled(addr, tp)
}

func (u *unfinishedNodes) addSuffix(bs []byte, out uint64, p *builderNodePool) {
	if len(bs) == 0 {
		return
	}
	last := len(u.stack) - 1
	u.stack[last].hasLastT = true
	u.stack[last].lastIn = bs[0]
	u.stack[last].lastOut = out
	for _, b := range bs[1:] {
		next := u.get()
		next.node = p.alloc()
		next.hasLastT = true
		next.lastIn = b
		next.lastOut = 0
		u.stack = append(u.stack, next)
	}
	u.pushEmpty(true, p)
}

type builderNodeUnfinished struct {
	node     *builderNode
	lastOut  uint64
	lastIn   byte
	hasLastT bool
}

func (b *builderNodeUnfinished) lastCompiled(addr int, tp *transitionPool) {
	if b.hasLastT {
		transIn := b.lastIn
		transOut := b.lastOut
		b.hasLastT = false
		b.lastOut = 0
		trans := tp.alloc()
		trans.in = transIn
		trans.out = transOut
		trans.addr = addr
		b.node.trans = append(b.node.trans, trans)
	}
}

func (b *builderNodeUnfinished) addOutputPrefix(prefix uint64) {
	if b.node.final {
		b.node.finalOutput = outputCat(prefix, b.node.finalOutput)
	}
	for _, t := range b.node.trans {
		t.out = outputCat(prefix, t.out)
	}
	if b.hasLastT {
		b.lastOut = outputCat(prefix, b.lastOut)
	}
}

type builderNode struct {
	finalOutput uint64
	trans       []*transition
	final       bool
}

func (n *builderNode) equiv(o *builderNode) bool {
	if n.final != o.final {
		return false
	}
	if n.finalOutput != o.finalOutput {
		return false
	}
	if len(n.trans) != len(o.trans) {
		return false
	}
	for i, ntrans := range n.trans {
		otrans := o.trans[i]
		if ntrans.in != otrans.in {
			return false
		}
		if ntrans.addr != otrans.addr {
			return false
		}
		if ntrans.out != otrans.out {
			return false
		}
	}
	return true
}

type transition struct {
	out  uint64
	addr int
	in   byte
}

func outputPrefix(l, r uint64) uint64 {
	if l < r {
		return l
	}
	return r
}

func outputSub(l, r uint64) uint64 {
	return l - r
}

func outputCat(l, r uint64) uint64 {
	return l + r
}

// the next builderNode to alloc() will be all[nextOuter][nextInner]
type builderNodePool struct {
	all       [][]builderNode
	nextOuter int
	nextInner int
}

func (p *builderNodePool) reset() {
	p.nextOuter = 0
	p.nextInner = 0
}

func (p *builderNodePool) alloc() *builderNode {
	if p.nextOuter >= len(p.all) {
		p.all = append(p.all, make([]builderNode, 256))
	}
	rv := &p.all[p.nextOuter][p.nextInner]
	p.nextInner += 1
	if p.nextInner >= len(p.all[p.nextOuter]) {
		p.nextOuter += 1
		p.nextInner = 0
	}
	rv.finalOutput = 0
	rv.trans = rv.trans[:0]
	rv.final = false
	return rv
}

// the next transition to alloc() will be all[nextOuter][nextInner]
type transitionPool struct {
	all       [][]transition
	nextOuter int
	nextInner int
}

func (p *transitionPool) reset() {
	p.nextOuter = 0
	p.nextInner = 0
}

func (p *transitionPool) alloc() *transition {
	if p.nextOuter >= len(p.all) {
		p.all = append(p.all, make([]transition, 256))
	}
	rv := &p.all[p.nextOuter][p.nextInner]
	p.nextInner += 1
	if p.nextInner >= len(p.all[p.nextOuter]) {
		p.nextOuter += 1
		p.nextInner = 0
	}
	*rv = transition{}
	return rv
}