nim-codex/tests/dagger/bitswap/testnetwork.nim

241 lines
6.4 KiB
Nim

import std/sequtils
import std/tables
import pkg/asynctest
import pkg/chronos
import pkg/libp2p
import pkg/libp2p/errors
import pkg/protobuf_serialization
import pkg/dagger/stores/memorystore
import pkg/dagger/bitswap/network
import pkg/dagger/bitswap/protobuf/payments
import pkg/dagger/p2p/rng
import pkg/dagger/chunker
import pkg/dagger/blocktype as bt
import ../helpers
import ../examples
suite "Bitswap network":
let
rng = Rng.instance()
seckey = PrivateKey.random(rng[]).tryGet()
peerId = PeerID.init(seckey.getKey().tryGet()).tryGet()
chunker = newRandomChunker(Rng.instance(), size = 1024, chunkSize = 256)
blocks = chunker.mapIt( bt.Block.new(it) )
var
network: BitswapNetwork
networkPeer: NetworkPeer
buffer: BufferStream
done: Future[void]
proc getConn(): Future[Connection] {.async.} =
return Connection(buffer)
setup:
done = newFuture[void]()
buffer = newBufferStream()
network = BitswapNetwork.new(
switch = newStandardSwitch(),
wallet = Wallet.init(EthPrivateKey.random()),
connProvider = getConn)
network.setupPeer(peerId)
networkPeer = network.peers[peerId]
discard await networkPeer.connect()
test "Want List handler":
proc wantListHandler(peer: PeerID, wantList: WantList) {.gcsafe.} =
# check that we got the correct amount of entries
check wantList.entries.len == 4
for b in blocks:
check b.cid in wantList.entries
let entry = wantList.entries[wantList.entries.find(b.cid)]
check entry.wantType == WantType.wantHave
check entry.priority == 1
check entry.cancel == true
check entry.sendDontHave == true
done.complete()
network.handlers.onWantList = wantListHandler
let wantList = makeWantList(
blocks.mapIt( it.cid ),
1, true, WantType.wantHave,
true, true)
let msg = Message(wantlist: wantList)
await buffer.pushData(lenPrefix(Protobuf.encode(msg)))
await done.wait(500.millis)
test "Blocks Handler":
proc blocksHandler(peer: PeerID, blks: seq[bt.Block]) {.gcsafe.} =
check blks == blocks
done.complete()
network.handlers.onBlocks = blocksHandler
let msg = Message(payload: makeBlocks(blocks))
await buffer.pushData(lenPrefix(Protobuf.encode(msg)))
await done.wait(500.millis)
test "Presence Handler":
proc presenceHandler(peer: PeerID, precense: seq[BlockPresence]) {.gcsafe.} =
for b in blocks:
check:
b.cid in precense
done.complete()
network.handlers.onPresence = presenceHandler
let msg = Message(
blockPresences: blocks.mapIt(
BlockPresence(
cid: it.cid.data.buffer,
type: BlockPresenceType.presenceHave
)))
await buffer.pushData(lenPrefix(Protobuf.encode(msg)))
await done.wait(500.millis)
test "handles pricing messages":
let pricing = Pricing.example
proc handlePricing(peer: PeerID, received: Pricing) =
check received == pricing
done.complete()
network.handlers.onPricing = handlePricing
let message = Message(pricing: PricingMessage.init(pricing))
await buffer.pushData(lenPrefix(Protobuf.encode(message)))
await done.wait(100.millis)
test "handles payment messages":
let payment = SignedState.example
proc handlePayment(peer: PeerID, received: SignedState) =
check received == payment
done.complete()
network.handlers.onPayment = handlePayment
let message = Message(payment: StateChannelUpdate.init(payment))
await buffer.pushData(lenPrefix(Protobuf.encode(message)))
await done.wait(100.millis)
suite "Bitswap Network - e2e":
let
chunker = newRandomChunker(Rng.instance(), size = 1024, chunkSize = 256)
blocks = chunker.mapIt( bt.Block.new(it) )
var
switch1, switch2: Switch
wallet1, wallet2: Wallet
network1, network2: BitswapNetwork
awaiters: seq[Future[void]]
done: Future[void]
setup:
done = newFuture[void]()
switch1 = newStandardSwitch()
switch2 = newStandardSwitch()
wallet1 = Wallet.init(EthPrivateKey.random())
wallet2 = Wallet.init(EthPrivateKey.random())
awaiters.add(await switch1.start())
awaiters.add(await switch2.start())
network1 = BitswapNetwork.new(switch1, wallet1)
switch1.mount(network1)
network2 = BitswapNetwork.new(switch2, wallet2)
switch2.mount(network2)
await switch1.connect(
switch2.peerInfo.peerId,
switch2.peerInfo.addrs)
teardown:
await allFuturesThrowing(
switch1.stop(),
switch2.stop())
await allFuturesThrowing(awaiters)
test "broadcast want list":
proc wantListHandler(peer: PeerID, wantList: WantList) {.gcsafe.} =
# check that we got the correct amount of entries
check wantList.entries.len == 4
for b in blocks:
check b.cid in wantList.entries
let entry = wantList.entries[wantList.entries.find(b.cid)]
check entry.wantType == WantType.wantHave
check entry.priority == 1
check entry.cancel == true
check entry.sendDontHave == true
done.complete()
network2.handlers.onWantList = wantListHandler
network1.broadcastWantList(
switch2.peerInfo.peerId,
blocks.mapIt( it.cid ),
1, true, WantType.wantHave,
true, true)
await done.wait(500.millis)
test "broadcast blocks":
proc blocksHandler(peer: PeerID, blks: seq[bt.Block]) {.gcsafe.} =
check blks == blocks
done.complete()
network2.handlers.onBlocks = blocksHandler
network1.broadcastBlocks(
switch2.peerInfo.peerId,
blocks)
await done.wait(500.millis)
test "broadcast precense":
proc presenceHandler(peer: PeerID, precense: seq[BlockPresence]) {.gcsafe.} =
for b in blocks:
check:
b.cid in precense
done.complete()
network2.handlers.onPresence = presenceHandler
network1.broadcastBlockPresence(
switch2.peerInfo.peerId,
blocks.mapIt(
BlockPresence(
cid: it.cid.data.buffer,
type: BlockPresenceType.presenceHave
)))
await done.wait(500.millis)
test "broadcasts pricing":
let pricing = Pricing.example
proc handlePricing(peer: PeerID, received: Pricing) =
check received == pricing
done.complete()
network2.handlers.onPricing = handlePricing
network1.broadcastPricing(switch2.peerInfo.peerId, pricing)
await done.wait(100.millis)