package auditor

import (
	"bytes"
	"sync"
	"time"

	"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/util/rand"
	"git.frostfs.info/TrueCloudLab/frostfs-sdk-go/netmap"
	"git.frostfs.info/TrueCloudLab/frostfs-sdk-go/object"
	oid "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/object/id"
	"git.frostfs.info/TrueCloudLab/tzhash/tz"
	"go.uber.org/zap"
)

func (c *Context) executePDP() {
	c.processPairs()
	c.writePairsResult()
}

func (c *Context) processPairs() {
	wg := new(sync.WaitGroup)

	for i := range c.pairs {
		p := &c.pairs[i]
		wg.Add(1)

		if err := c.pdpWorkerPool.Submit(func() {
			c.processPair(p)
			wg.Done()
		}); err != nil {
			wg.Done()
		}
	}

	wg.Wait()
	c.pdpWorkerPool.Release()
}

func (c *Context) processPair(p *gamePair) {
	c.distributeRanges(p)
	c.collectHashes(p)
	c.analyzeHashes(p)
}

func (c *Context) distributeRanges(p *gamePair) {
	p.rn1 = make([]*object.Range, hashRangeNumber-1)
	p.rn2 = make([]*object.Range, hashRangeNumber-1)

	for i := 0; i < hashRangeNumber-1; i++ {
		p.rn1[i] = object.NewRange()
		p.rn2[i] = object.NewRange()
	}

	notches := c.splitPayload(p.id)

	{ // node 1
		// [0:n2]
		p.rn1[0].SetLength(notches[1])

		// [n2:n3]
		p.rn1[1].SetOffset(notches[1])
		p.rn1[1].SetLength(notches[2] - notches[1])

		// [n3:full]
		p.rn1[2].SetOffset(notches[2])
		p.rn1[2].SetLength(notches[3] - notches[2])
	}

	{ // node 2
		// [0:n1]
		p.rn2[0].SetLength(notches[0])

		// [n1:n2]
		p.rn2[1].SetOffset(notches[0])
		p.rn2[1].SetLength(notches[1] - notches[0])

		// [n2:full]
		p.rn2[2].SetOffset(notches[1])
		p.rn2[2].SetLength(notches[3] - notches[1])
	}
}

func (c *Context) splitPayload(id oid.ID) []uint64 {
	var (
		prev    uint64
		size    = c.objectSize(id)
		notches = make([]uint64, 0, hashRangeNumber)
	)

	for i := uint64(0); i < hashRangeNumber; i++ {
		if i < hashRangeNumber-1 {
			max := size - prev - (hashRangeNumber - i)
			if max == 0 {
				prev++
			} else {
				prev += rand.Uint64()%max + 1
			}
		} else {
			prev = size
		}

		notches = append(notches, prev)
	}

	return notches
}

func (c *Context) collectHashes(p *gamePair) {
	fn := func(n netmap.NodeInfo, rngs []*object.Range) [][]byte {
		// Here we randomize the order a bit: the hypothesis is that this
		// makes it harder for an unscrupulous node to come up with a
		// reliable cheating strategy.
		order := make([]int, len(rngs))
		for i := range order {
			order[i] = i
		}
		rand.Shuffle(len(order), func(i, j int) { order[i], order[j] = order[j], order[i] })

		var getRangeHashPrm GetRangeHashPrm
		getRangeHashPrm.Context = c.task.AuditContext()
		getRangeHashPrm.CID = c.task.ContainerID()
		getRangeHashPrm.OID = p.id
		getRangeHashPrm.Node = n

		res := make([][]byte, len(rngs))
		for _, i := range order {
			var sleepDur time.Duration
			if c.maxPDPSleep > 0 {
				sleepDur = time.Duration(rand.Uint64() % c.maxPDPSleep)
			}

			c.log.Debug("sleep before get range hash",
				zap.Stringer("interval", sleepDur),
			)

			time.Sleep(sleepDur)

			getRangeHashPrm.Range = rngs[i]

			h, err := c.cnrCom.GetRangeHash(getRangeHashPrm)
			if err != nil {
				c.log.Debug("could not get payload range hash",
					zap.Stringer("id", p.id),
					zap.String("node", netmap.StringifyPublicKey(n)),
					zap.String("error", err.Error()),
				)
				return res
			}
			res[i] = h
		}
		return res
	}

	p.hh1 = fn(p.n1, p.rn1)
	p.hh2 = fn(p.n2, p.rn2)
}

func (c *Context) analyzeHashes(p *gamePair) {
	if len(p.hh1) != hashRangeNumber-1 || len(p.hh2) != hashRangeNumber-1 {
		c.failNodesPDP(p.n1, p.n2)
		return
	}

	h1, err := tz.Concat([][]byte{p.hh2[0], p.hh2[1]})
	if err != nil || !bytes.Equal(p.hh1[0], h1) {
		c.failNodesPDP(p.n1, p.n2)
		return
	}

	h2, err := tz.Concat([][]byte{p.hh1[1], p.hh1[2]})
	if err != nil || !bytes.Equal(p.hh2[2], h2) {
		c.failNodesPDP(p.n1, p.n2)
		return
	}

	fh, err := tz.Concat([][]byte{h1, h2})
	if err != nil || !bytes.Equal(fh, c.objectHomoHash(p.id)) {
		c.failNodesPDP(p.n1, p.n2)
		return
	}

	c.passNodesPDP(p.n1, p.n2)
}

func (c *Context) failNodesPDP(ns ...netmap.NodeInfo) {
	c.pairedMtx.Lock()

	for i := range ns {
		c.pairedNodes[ns[i].Hash()].failedPDP = true
	}

	c.pairedMtx.Unlock()
}

func (c *Context) passNodesPDP(ns ...netmap.NodeInfo) {
	c.pairedMtx.Lock()

	for i := range ns {
		c.pairedNodes[ns[i].Hash()].passedPDP = true
	}

	c.pairedMtx.Unlock()
}

func (c *Context) writePairsResult() {
	var failCount, okCount int

	c.iteratePairedNodes(
		func(netmap.NodeInfo) { failCount++ },
		func(netmap.NodeInfo) { okCount++ },
	)

	failedNodes := make([][]byte, 0, failCount)
	passedNodes := make([][]byte, 0, okCount)

	c.iteratePairedNodes(
		func(n netmap.NodeInfo) {
			failedNodes = append(failedNodes, n.PublicKey())
		},
		func(n netmap.NodeInfo) {
			passedNodes = append(passedNodes, n.PublicKey())
		},
	)

	c.report.SetPDPResults(passedNodes, failedNodes)
}

func (c *Context) iteratePairedNodes(onFail, onPass func(netmap.NodeInfo)) {
	for _, pairedNode := range c.pairedNodes {
		if pairedNode.failedPDP {
			onFail(pairedNode.node)
		}

		if pairedNode.passedPDP {
			onPass(pairedNode.node)
		}
	}
}