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latest.go
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latest.go
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// This code is available on the terms of the project LICENSE.md file,
// also available online at https://blueoakcouncil.org/license/1.0.0.
package auth
import (
"bytes"
"sort"
"sync"
"decred.org/dcrdex/dex/order"
)
type matchOutcome struct {
// sorting is done by time and match ID
time int64
mid order.MatchID
// match outcome and value
outcome Violation
base, quote uint32 // market
value uint64
}
func lessByTimeThenMID(ti, tj *matchOutcome) bool {
if ti.time == tj.time {
return bytes.Compare(ti.mid[:], tj.mid[:]) < 0 // ascending (smaller ID first)
}
return ti.time < tj.time // ascending (newest last in slice)
}
type latestMatchOutcomes struct {
mtx sync.Mutex
cap int16
outcomes []*matchOutcome
}
func newLatestMatchOutcomes(cap int16) *latestMatchOutcomes {
return &latestMatchOutcomes{
cap: cap,
outcomes: make([]*matchOutcome, 0, cap+1), // cap+1 since an old item is popped *after* a new one is pushed
}
}
func (la *latestMatchOutcomes) add(mo *matchOutcome) {
la.mtx.Lock()
defer la.mtx.Unlock()
// Do a dumb search for the match ID, without regard to time, so we can't
// insert a match twice.
for _, oc := range la.outcomes {
if oc.mid == mo.mid {
log.Warnf("(*latestMatchOutcomes).add: Rejecting duplicate match ID: %v", mo.mid)
return
}
}
// Use sort.Search and insert it at the right spot.
n := len(la.outcomes)
i := sort.Search(n, func(i int) bool {
return lessByTimeThenMID(la.outcomes[n-1-i], mo)
})
if i == int(la.cap) /* i == n && n == int(la.cap) */ {
// The new one is the oldest/smallest, but already at capacity.
return
}
// Insert at proper location.
i = n - i // i-1 is first location that stays
la.outcomes = append(la.outcomes[:i], append([]*matchOutcome{mo}, la.outcomes[i:]...)...)
// Pop one stamped if the slice was at capacity prior to pushing the new one.
if len(la.outcomes) > int(la.cap) {
// pop front, the oldest stamped
la.outcomes[0] = nil // avoid memory leak
la.outcomes = la.outcomes[1:]
}
}
func (la *latestMatchOutcomes) binViolations() map[Violation]int64 {
la.mtx.Lock()
defer la.mtx.Unlock()
bins := make(map[Violation]int64)
for _, mo := range la.outcomes {
bins[mo.outcome]++
}
return bins
}
// SwapAmounts breaks down the quantities of completed swaps in four rough
// categories: successfully swapped (Swapped), failed with counterparty funds
// locked for the long/maker lock time (StuckLong), failed with counterparty
// funds locked for the short/taker lock time (StuckShort), and failed to
// initiate swap following match with no funds locked in contracts (Spoofed).
type SwapAmounts struct {
Swapped int64
StuckLong int64
StuckShort int64
Spoofed int64
}
func (sa *SwapAmounts) addAmt(v Violation, value int64) {
switch v {
case ViolationSwapSuccess:
sa.Swapped += value
case ViolationNoSwapAsTaker:
sa.StuckLong += value
case ViolationNoRedeemAsMaker:
sa.StuckShort += value
case ViolationNoSwapAsMaker, ViolationPreimageMiss: // ! preimage misses are presently in preimageOutcome
sa.Spoofed += value
}
}
// func (la *latestMatchOutcomes) swapAmounts() *SwapAmounts {
// sa := new(SwapAmounts)
// for _, mo := range la.outcomes {
// sa.addAmt(mo.outcome, int64(mo.value)) // must be same units (e.g. lots)!
// }
// return sa
// }
func (la *latestMatchOutcomes) mktSwapAmounts(base, quote uint32) *SwapAmounts {
sa := new(SwapAmounts)
for _, mo := range la.outcomes {
if mo.base == base && mo.quote == quote {
sa.addAmt(mo.outcome, int64(mo.value))
}
}
return sa
}
type preimageOutcome struct {
time int64
oid order.OrderID
miss bool
}
func lessByTimeThenOID(ti, tj *preimageOutcome) bool {
if ti.time == tj.time {
return bytes.Compare(ti.oid[:], tj.oid[:]) < 0 // ascending (smaller ID first)
}
return ti.time < tj.time // ascending (newest last in slice)
}
type latestPreimageOutcomes struct {
mtx sync.Mutex
cap int16
outcomes []*preimageOutcome
}
func newLatestPreimageOutcomes(cap int16) *latestPreimageOutcomes {
return &latestPreimageOutcomes{
cap: cap,
outcomes: make([]*preimageOutcome, 0, cap+1), // cap+1 since an old item is popped *after* a new one is pushed
}
}
func (la *latestPreimageOutcomes) add(po *preimageOutcome) {
la.mtx.Lock()
defer la.mtx.Unlock()
// Do a dumb search for the order ID, without regard to time, so we can't
// insert an order twice.
for _, oc := range la.outcomes {
if oc.oid == po.oid {
log.Warnf("(*latestPreimageOutcomes).add: Rejecting duplicate order ID: %v", po.oid)
return
}
}
// Use sort.Search and insert it at the right spot.
n := len(la.outcomes)
i := sort.Search(n, func(i int) bool {
return lessByTimeThenOID(la.outcomes[n-1-i], po)
})
if i == int(la.cap) /* i == n && n == int(la.cap) */ {
// The new one is the oldest/smallest, but already at capacity.
return
}
// Insert at proper location.
i = n - i // i-1 is first location that stays
la.outcomes = append(la.outcomes[:i], append([]*preimageOutcome{po}, la.outcomes[i:]...)...)
// Pop one stamped if the slice was at capacity prior to pushing the new one.
if len(la.outcomes) > int(la.cap) {
// pop front, the oldest stamped
la.outcomes[0] = nil // avoid memory leak
la.outcomes = la.outcomes[1:]
}
}
func (la *latestPreimageOutcomes) misses() (misses int32) {
la.mtx.Lock()
defer la.mtx.Unlock()
for _, th := range la.outcomes {
if th.miss {
misses++
}
}
return
}