2ce00adb55
* focus on performance improvement in many aspects. 1. Do BlockBody verification concurrently; 2. Do calculation of intermediate root concurrently; 3. Preload accounts before processing blocks; 4. Make the snapshot layers configurable. 5. Reuse some object to reduce GC. add * rlp: improve decoder stream implementation (#22858) This commit makes various cleanup changes to rlp.Stream. * rlp: shrink Stream struct This removes a lot of unused padding space in Stream by reordering the fields. The size of Stream changes from 120 bytes to 88 bytes. Stream instances are internally cached and reused using sync.Pool, so this does not improve performance. * rlp: simplify list stack The list stack kept track of the size of the current list context as well as the current offset into it. The size had to be stored in the stack in order to subtract it from the remaining bytes of any enclosing list in ListEnd. It seems that this can be implemented in a simpler way: just subtract the size from the enclosing list context in List instead. * rlp: use atomic.Value for type cache (#22902) All encoding/decoding operations read the type cache to find the writer/decoder function responsible for a type. When analyzing CPU profiles of geth during sync, I found that the use of sync.RWMutex in cache lookups appears in the profiles. It seems we are running into CPU cache contention problems when package rlp is heavily used on all CPU cores during sync. This change makes it use atomic.Value + a writer lock instead of sync.RWMutex. In the common case where the typeinfo entry is present in the cache, we simply fetch the map and lookup the type. * rlp: optimize byte array handling (#22924) This change improves the performance of encoding/decoding [N]byte. name old time/op new time/op delta DecodeByteArrayStruct-8 336ns ± 0% 246ns ± 0% -26.98% (p=0.000 n=9+10) EncodeByteArrayStruct-8 225ns ± 1% 148ns ± 1% -34.12% (p=0.000 n=10+10) name old alloc/op new alloc/op delta DecodeByteArrayStruct-8 120B ± 0% 48B ± 0% -60.00% (p=0.000 n=10+10) EncodeByteArrayStruct-8 0.00B 0.00B ~ (all equal) * rlp: optimize big.Int decoding for size <= 32 bytes (#22927) This change grows the static integer buffer in Stream to 32 bytes, making it possible to decode 256bit integers without allocating a temporary buffer. In the recent commit 088da24, Stream struct size decreased from 120 bytes down to 88 bytes. This commit grows the struct to 112 bytes again, but the size change will not degrade performance because Stream instances are internally cached in sync.Pool. name old time/op new time/op delta DecodeBigInts-8 12.2µs ± 0% 8.6µs ± 4% -29.58% (p=0.000 n=9+10) name old speed new speed delta DecodeBigInts-8 230MB/s ± 0% 326MB/s ± 4% +42.04% (p=0.000 n=9+10) * eth/protocols/eth, les: avoid Raw() when decoding HashOrNumber (#22841) Getting the raw value is not necessary to decode this type, and decoding it directly from the stream is faster. * fix testcase * debug no lazy * fix can not repair * address comments Co-authored-by: Felix Lange <fjl@twurst.com> |
||
|---|---|---|
| .. | ||
| adapters | ||
| examples | ||
| pipes | ||
| connect_test.go | ||
| connect.go | ||
| events.go | ||
| http_test.go | ||
| http.go | ||
| mocker_test.go | ||
| mocker.go | ||
| network_test.go | ||
| network.go | ||
| README.md | ||
| simulation.go | ||
| test.go | ||
devp2p Simulations
The p2p/simulations package implements a simulation framework which supports
creating a collection of devp2p nodes, connecting them together to form a
simulation network, performing simulation actions in that network and then
extracting useful information.
Nodes
Each node in a simulation network runs multiple services by wrapping a collection
of objects which implement the node.Service interface meaning they:
- can be started and stopped
- run p2p protocols
- expose RPC APIs
This means that any object which implements the node.Service interface can be
used to run a node in the simulation.
Services
Before running a simulation, a set of service initializers must be registered which can then be used to run nodes in the network.
A service initializer is a function with the following signature:
func(ctx *adapters.ServiceContext) (node.Service, error)
These initializers should be registered by calling the adapters.RegisterServices
function in an init() hook:
func init() {
adapters.RegisterServices(adapters.Services{
"service1": initService1,
"service2": initService2,
})
}
Node Adapters
The simulation framework includes multiple "node adapters" which are responsible for creating an environment in which a node runs.
SimAdapter
The SimAdapter runs nodes in-memory, connecting them using an in-memory,
synchronous net.Pipe and connecting to their RPC server using an in-memory
rpc.Client.
ExecAdapter
The ExecAdapter runs nodes as child processes of the running simulation.
It does this by executing the binary which is running the simulation but
setting argv[0] (i.e. the program name) to p2p-node which is then
detected by an init hook in the child process which runs the node.Service
using the devp2p node stack rather than executing main().
The nodes listen for devp2p connections and WebSocket RPC clients on random localhost ports.
Network
A simulation network is created with an ID and default service (which is used if a node is created without an explicit service), exposes methods for creating, starting, stopping, connecting and disconnecting nodes, and emits events when certain actions occur.
Events
A simulation network emits the following events:
- node event - when nodes are created / started / stopped
- connection event - when nodes are connected / disconnected
- message event - when a protocol message is sent between two nodes
The events have a "control" flag which when set indicates that the event is the outcome of a controlled simulation action (e.g. creating a node or explicitly connecting two nodes together).
This is in contrast to a non-control event, otherwise called a "live" event, which is the outcome of something happening in the network as a result of a control event (e.g. a node actually started up or a connection was actually established between two nodes).
Live events are detected by the simulation network by subscribing to node peer events via RPC when the nodes start up.
Testing Framework
The Simulation type can be used in tests to perform actions in a simulation
network and then wait for expectations to be met.
With a running simulation network, the Simulation.Run method can be called
with a Step which has the following fields:
-
Action- a function which performs some action in the network -
Expect- an expectation function which returns whether or not a given node meets the expectation -
Trigger- a channel which receives node IDs which then trigger a check of the expectation function to be performed against that node
As a concrete example, consider a simulated network of Ethereum nodes. An
Action could be the sending of a transaction, Expect it being included in
a block, and Trigger a check for every block that is mined.
On return, the Simulation.Run method returns a StepResult which can be used
to determine if all nodes met the expectation, how long it took them to meet
the expectation and what network events were emitted during the step run.
HTTP API
The simulation framework includes a HTTP API which can be used to control the simulation.
The API is initialised with a particular node adapter and has the following endpoints:
GET / Get network information
POST /start Start all nodes in the network
POST /stop Stop all nodes in the network
GET /events Stream network events
GET /snapshot Take a network snapshot
POST /snapshot Load a network snapshot
POST /nodes Create a node
GET /nodes Get all nodes in the network
GET /nodes/:nodeid Get node information
POST /nodes/:nodeid/start Start a node
POST /nodes/:nodeid/stop Stop a node
POST /nodes/:nodeid/conn/:peerid Connect two nodes
DELETE /nodes/:nodeid/conn/:peerid Disconnect two nodes
GET /nodes/:nodeid/rpc Make RPC requests to a node via WebSocket
For convenience, nodeid in the URL can be the name of a node rather than its
ID.
Command line client
p2psim is a command line client for the HTTP API, located in
cmd/p2psim.
It provides the following commands:
p2psim show
p2psim events [--current] [--filter=FILTER]
p2psim snapshot
p2psim load
p2psim node create [--name=NAME] [--services=SERVICES] [--key=KEY]
p2psim node list
p2psim node show <node>
p2psim node start <node>
p2psim node stop <node>
p2psim node connect <node> <peer>
p2psim node disconnect <node> <peer>
p2psim node rpc <node> <method> [<args>] [--subscribe]