openethereum/ethcore/light/src/net/request_credits.rs

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// Copyright 2015-2019 Parity Technologies (UK) Ltd.
// This file is part of Parity Ethereum.
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// Parity Ethereum is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity Ethereum is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity Ethereum. If not, see <http://www.gnu.org/licenses/>.
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//! Request credit management.
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//!
//! Every request in the light protocol leads to a reduction
//! of the requester's amount of credits as a rate-limiting mechanism.
//! The amount of credits will recharge at a set rate.
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//!
//! This module provides an interface for configuration of
//! costs and recharge rates of request credits.
//!
//! Current default costs are picked completely arbitrarily, not based
//! on any empirical timings or mathematical models.
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use request::{self, Request};
use super::error::Error;
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use rlp::{Rlp, RlpStream, Decodable, Encodable, DecoderError};
use ethereum_types::U256;
use std::time::{Duration, Instant};
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/// Credits value.
///
/// Produced and recharged using `FlowParams`.
/// Definitive updates can be made as well -- these will reset the recharge
/// point to the time of the update.
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct Credits {
estimate: U256,
recharge_point: Instant,
}
impl Credits {
/// Get the current amount of credits..
pub fn current(&self) -> U256 { self.estimate }
/// Make a definitive update.
/// This will be the value obtained after receiving
/// a response to a request.
pub fn update_to(&mut self, value: U256) {
self.estimate = value;
self.recharge_point = Instant::now();
}
/// Maintain ratio to current limit against an old limit.
pub fn maintain_ratio(&mut self, old_limit: U256, new_limit: U256) {
self.estimate = (new_limit * self.estimate) / old_limit;
}
/// Attempt to apply the given cost to the amount of credits.
///
/// If successful, the cost will be deducted successfully.
///
/// If unsuccessful, the structure will be unaltered an an
/// error will be produced.
pub fn deduct_cost(&mut self, cost: U256) -> Result<(), Error> {
if cost > self.estimate {
Err(Error::NoCredits)
} else {
self.estimate = self.estimate - cost;
Ok(())
}
}
}
/// A cost table, mapping requests to base and per-request costs.
/// Costs themselves may be missing.
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct CostTable {
base: U256, // cost per packet.
headers: Option<U256>, // cost per header
transaction_index: Option<U256>,
body: Option<U256>,
receipts: Option<U256>,
account: Option<U256>,
storage: Option<U256>,
code: Option<U256>,
header_proof: Option<U256>,
transaction_proof: Option<U256>, // cost per gas.
epoch_signal: Option<U256>,
}
impl CostTable {
fn costs_set(&self) -> usize {
let mut num_set = 0;
{
let mut incr_if_set = |cost: &Option<_>| if cost.is_some() { num_set += 1 };
incr_if_set(&self.headers);
incr_if_set(&self.transaction_index);
incr_if_set(&self.body);
incr_if_set(&self.receipts);
incr_if_set(&self.account);
incr_if_set(&self.storage);
incr_if_set(&self.code);
incr_if_set(&self.header_proof);
incr_if_set(&self.transaction_proof);
incr_if_set(&self.epoch_signal);
}
num_set
}
}
impl Default for CostTable {
fn default() -> Self {
// arbitrarily chosen constants.
CostTable {
base: 100_000.into(),
headers: Some(10000.into()),
transaction_index: Some(10000.into()),
body: Some(15000.into()),
receipts: Some(5000.into()),
account: Some(25000.into()),
storage: Some(25000.into()),
code: Some(20000.into()),
header_proof: Some(15000.into()),
transaction_proof: Some(2.into()),
epoch_signal: Some(10000.into()),
}
}
}
impl Encodable for CostTable {
fn rlp_append(&self, s: &mut RlpStream) {
fn append_cost(s: &mut RlpStream, cost: &Option<U256>, kind: request::Kind) {
if let Some(ref cost) = *cost {
s.begin_list(2);
// hack around https://github.com/paritytech/parity-ethereum/issues/4356
Encodable::rlp_append(&kind, s);
s.append(cost);
}
}
s.begin_list(1 + self.costs_set()).append(&self.base);
append_cost(s, &self.headers, request::Kind::Headers);
append_cost(s, &self.transaction_index, request::Kind::TransactionIndex);
append_cost(s, &self.body, request::Kind::Body);
append_cost(s, &self.receipts, request::Kind::Receipts);
append_cost(s, &self.account, request::Kind::Account);
append_cost(s, &self.storage, request::Kind::Storage);
append_cost(s, &self.code, request::Kind::Code);
append_cost(s, &self.header_proof, request::Kind::HeaderProof);
append_cost(s, &self.transaction_proof, request::Kind::Execution);
append_cost(s, &self.epoch_signal, request::Kind::Signal);
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}
}
impl Decodable for CostTable {
fn decode(rlp: &Rlp) -> Result<Self, DecoderError> {
let base = rlp.val_at(0)?;
let mut headers = None;
let mut transaction_index = None;
let mut body = None;
let mut receipts = None;
let mut account = None;
let mut storage = None;
let mut code = None;
let mut header_proof = None;
let mut transaction_proof = None;
let mut epoch_signal = None;
for cost_list in rlp.iter().skip(1) {
let cost = cost_list.val_at(1)?;
match cost_list.val_at(0)? {
request::Kind::Headers => headers = Some(cost),
request::Kind::TransactionIndex => transaction_index = Some(cost),
request::Kind::Body => body = Some(cost),
request::Kind::Receipts => receipts = Some(cost),
request::Kind::Account => account = Some(cost),
request::Kind::Storage => storage = Some(cost),
request::Kind::Code => code = Some(cost),
request::Kind::HeaderProof => header_proof = Some(cost),
request::Kind::Execution => transaction_proof = Some(cost),
request::Kind::Signal => epoch_signal = Some(cost),
}
}
let table = CostTable {
base,
headers,
transaction_index,
body,
receipts,
account,
storage,
code,
header_proof,
transaction_proof,
epoch_signal,
};
if table.costs_set() == 0 {
Err(DecoderError::Custom("no cost types set."))
} else {
Ok(table)
}
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}
}
/// Handles costs, recharge, limits of request credits.
#[derive(Debug, Clone, PartialEq)]
pub struct FlowParams {
costs: CostTable,
limit: U256,
recharge: U256,
}
impl FlowParams {
/// Create new flow parameters from a request cost table,
/// credit limit, and (minimum) rate of recharge.
pub fn new(limit: U256, costs: CostTable, recharge: U256) -> Self {
FlowParams {
costs,
limit,
recharge,
}
}
/// Create new flow parameters from ,
/// proportion of total capacity which should be given to a peer,
/// and stored capacity a peer can accumulate.
pub fn from_request_times<F: Fn(::request::Kind) -> Duration>(
request_time: F,
load_share: f64,
max_stored: Duration
) -> Self {
use request::Kind;
let load_share = load_share.abs();
let recharge: u64 = 100_000_000;
let max = {
let sec = max_stored.as_secs().saturating_mul(recharge);
let nanos = (max_stored.subsec_nanos() as u64).saturating_mul(recharge) / 1_000_000_000;
sec + nanos
};
let cost_for_kind = |kind| {
// how many requests we can handle per second
let rq_dur = request_time(kind);
let second_duration = {
let as_ns = rq_dur.as_secs() as f64 * 1_000_000_000f64 + rq_dur.subsec_nanos() as f64;
1_000_000_000f64 / as_ns
};
// scale by share of the load given to this peer.
let serve_per_second = second_duration * load_share;
let serve_per_second = serve_per_second.max(1.0 / 10_000.0);
// as a percentage of the recharge per second.
Some(U256::from((recharge as f64 / serve_per_second) as u64))
};
let costs = CostTable {
base: 0.into(),
headers: cost_for_kind(Kind::Headers),
transaction_index: cost_for_kind(Kind::TransactionIndex),
body: cost_for_kind(Kind::Body),
receipts: cost_for_kind(Kind::Receipts),
account: cost_for_kind(Kind::Account),
storage: cost_for_kind(Kind::Storage),
code: cost_for_kind(Kind::Code),
header_proof: cost_for_kind(Kind::HeaderProof),
transaction_proof: cost_for_kind(Kind::Execution),
epoch_signal: cost_for_kind(Kind::Signal),
};
FlowParams {
costs,
limit: max.into(),
recharge: recharge.into(),
}
}
/// Create effectively infinite flow params.
pub fn free() -> Self {
let free_cost: Option<U256> = Some(0.into());
FlowParams {
limit: (!0_u64).into(),
recharge: 1.into(),
costs: CostTable {
base: 0.into(),
headers: free_cost,
transaction_index: free_cost,
body: free_cost,
receipts: free_cost,
account: free_cost,
storage: free_cost,
code: free_cost,
header_proof: free_cost,
transaction_proof: free_cost,
epoch_signal: free_cost,
}
}
}
/// Get a reference to the credit limit.
pub fn limit(&self) -> &U256 { &self.limit }
/// Get a reference to the cost table.
pub fn cost_table(&self) -> &CostTable { &self.costs }
/// Get the base cost of a request.
pub fn base_cost(&self) -> U256 { self.costs.base }
/// Get a reference to the recharge rate.
pub fn recharge_rate(&self) -> &U256 { &self.recharge }
/// Compute the actual cost of a request, given the kind of request
/// and number of requests made.
pub fn compute_cost(&self, request: &Request) -> Option<U256> {
match *request {
Request::Headers(ref req) => self.costs.headers.map(|c| c * U256::from(req.max)),
Request::HeaderProof(_) => self.costs.header_proof,
Request::TransactionIndex(_) => self.costs.transaction_index,
Request::Body(_) => self.costs.body,
Request::Receipts(_) => self.costs.receipts,
Request::Account(_) => self.costs.account,
Request::Storage(_) => self.costs.storage,
Request::Code(_) => self.costs.code,
Request::Execution(ref req) => self.costs.transaction_proof.map(|c| c * req.gas),
Request::Signal(_) => self.costs.epoch_signal,
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}
}
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/// Compute the cost of a set of requests.
/// This is the base cost plus the cost of each individual request.
pub fn compute_cost_multi(&self, requests: &[Request]) -> Option<U256> {
let mut cost = self.costs.base;
for request in requests {
match self.compute_cost(request) {
Some(c) => cost = cost + c,
None => return None,
}
}
Some(cost)
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}
/// Create initial credits.
pub fn create_credits(&self) -> Credits {
Credits {
estimate: self.limit,
recharge_point: Instant::now(),
}
}
/// Recharge the given credits based on time passed since last
/// update.
pub fn recharge(&self, credits: &mut Credits) {
let now = Instant::now();
// recompute and update only in terms of full seconds elapsed
// in order to keep the estimate as an underestimate.
let elapsed = (now - credits.recharge_point).as_secs();
credits.recharge_point += Duration::from_secs(elapsed);
let elapsed: U256 = elapsed.into();
credits.estimate = ::std::cmp::min(self.limit, credits.estimate + (elapsed * self.recharge));
}
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/// Refund some credits which were previously deducted.
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/// Does not update the recharge timestamp.
pub fn refund(&self, credits: &mut Credits, refund_amount: U256) {
credits.estimate = credits.estimate + refund_amount;
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if credits.estimate > self.limit {
credits.estimate = self.limit
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}
}
}
impl Default for FlowParams {
fn default() -> Self {
FlowParams {
limit: 50_000_000.into(),
costs: CostTable::default(),
recharge: 100_000.into(),
}
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn should_serialize_cost_table() {
let costs = CostTable::default();
let serialized = ::rlp::encode(&costs);
let new_costs: CostTable = ::rlp::decode(&*serialized).unwrap();
assert_eq!(costs, new_costs);
}
#[test]
fn credits_mechanism() {
use std::thread;
use std::time::Duration;
let flow_params = FlowParams::new(100.into(), Default::default(), 20.into());
let mut credits = flow_params.create_credits();
assert!(credits.deduct_cost(101.into()).is_err());
assert!(credits.deduct_cost(10.into()).is_ok());
thread::sleep(Duration::from_secs(1));
flow_params.recharge(&mut credits);
assert_eq!(credits.estimate, 100.into());
}
#[test]
fn scale_by_load_share_and_time() {
let flow_params = FlowParams::from_request_times(
|_| Duration::new(0, 10_000),
0.05,
Duration::from_secs(60),
);
let flow_params2 = FlowParams::from_request_times(
|_| Duration::new(0, 10_000),
0.1,
Duration::from_secs(60),
);
let flow_params3 = FlowParams::from_request_times(
|_| Duration::new(0, 5_000),
0.05,
Duration::from_secs(60),
);
assert_eq!(flow_params2.costs, flow_params3.costs);
assert_eq!(flow_params.costs.headers.unwrap(), flow_params2.costs.headers.unwrap() * 2u32);
}
}