mirror of https://github.com/ethereum/go-ethereum
parent
97c37356fd
commit
4800c94392
44
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/example_test.go
generated
vendored
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Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/example_test.go
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// CookieJar - A contestant's algorithm toolbox
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// Copyright (c) 2013 Peter Szilagyi. All rights reserved.
|
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//
|
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// CookieJar is dual licensed: you can redistribute it and/or modify it under
|
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// the terms of the GNU General Public License as published by the Free Software
|
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// Foundation, either version 3 of the License, or (at your option) any later
|
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// version.
|
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//
|
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// The toolbox is distributed in the hope that it will be useful, but WITHOUT
|
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// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
|
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// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
|
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// more details.
|
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//
|
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// Alternatively, the CookieJar toolbox may be used in accordance with the terms
|
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// and conditions contained in a signed written agreement between you and the
|
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// author(s).
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package prque_test |
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import ( |
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"fmt" |
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"gopkg.in/karalabe/cookiejar.v2/collections/prque" |
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) |
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// Insert some data into a priority queue and pop them out in prioritized order.
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func Example_usage() { |
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// Define some data to push into the priority queue
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prio := []float32{77.7, 22.2, 44.4, 55.5, 11.1, 88.8, 33.3, 99.9, 0.0, 66.6} |
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data := []string{"zero", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine"} |
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// Create the priority queue and insert the prioritized data
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pq := prque.New() |
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for i := 0; i < len(data); i++ { |
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pq.Push(data[i], prio[i]) |
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} |
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// Pop out the data and print them
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for !pq.Empty() { |
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val, prio := pq.Pop() |
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fmt.Printf("%.1f:%s ", prio, val) |
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} |
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// Output:
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// 99.9:seven 88.8:five 77.7:zero 66.6:nine 55.5:three 44.4:two 33.3:six 22.2:one 11.1:four 0.0:eight
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} |
75
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/prque.go
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75
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/prque.go
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// CookieJar - A contestant's algorithm toolbox
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// Copyright (c) 2013 Peter Szilagyi. All rights reserved.
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//
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// CookieJar is dual licensed: you can redistribute it and/or modify it under
|
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// the terms of the GNU General Public License as published by the Free Software
|
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// Foundation, either version 3 of the License, or (at your option) any later
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// version.
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//
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// The toolbox is distributed in the hope that it will be useful, but WITHOUT
|
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// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
|
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// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
|
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// more details.
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//
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// Alternatively, the CookieJar toolbox may be used in accordance with the terms
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// and conditions contained in a signed written agreement between you and the
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// author(s).
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// Package prque implements a priority queue data structure supporting arbitrary
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// value types and float priorities.
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//
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// The reasoning behind using floats for the priorities vs. ints or interfaces
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// was larger flexibility without sacrificing too much performance or code
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// complexity.
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//
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// If you would like to use a min-priority queue, simply negate the priorities.
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//
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// Internally the queue is based on the standard heap package working on a
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// sortable version of the block based stack.
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package prque |
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import ( |
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"container/heap" |
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) |
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// Priority queue data structure.
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type Prque struct { |
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cont *sstack |
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} |
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// Creates a new priority queue.
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func New() *Prque { |
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return &Prque{newSstack()} |
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} |
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// Pushes a value with a given priority into the queue, expanding if necessary.
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func (p *Prque) Push(data interface{}, priority float32) { |
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heap.Push(p.cont, &item{data, priority}) |
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} |
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// Pops the value with the greates priority off the stack and returns it.
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// Currently no shrinking is done.
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func (p *Prque) Pop() (interface{}, float32) { |
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item := heap.Pop(p.cont).(*item) |
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return item.value, item.priority |
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} |
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// Pops only the item from the queue, dropping the associated priority value.
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func (p *Prque) PopItem() interface{} { |
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return heap.Pop(p.cont).(*item).value |
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} |
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// Checks whether the priority queue is empty.
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func (p *Prque) Empty() bool { |
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return p.cont.Len() == 0 |
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} |
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// Returns the number of element in the priority queue.
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func (p *Prque) Size() int { |
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return p.cont.Len() |
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} |
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// Clears the contents of the priority queue.
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func (p *Prque) Reset() { |
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p.cont.Reset() |
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} |
110
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/prque_test.go
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110
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/prque_test.go
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// CookieJar - A contestant's algorithm toolbox
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// Copyright (c) 2013 Peter Szilagyi. All rights reserved.
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//
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// CookieJar is dual licensed: you can redistribute it and/or modify it under
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// the terms of the GNU General Public License as published by the Free Software
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// Foundation, either version 3 of the License, or (at your option) any later
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// version.
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//
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// The toolbox is distributed in the hope that it will be useful, but WITHOUT
|
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// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
|
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// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
|
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// more details.
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//
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// Alternatively, the CookieJar toolbox may be used in accordance with the terms
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// and conditions contained in a signed written agreement between you and the
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// author(s).
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package prque |
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import ( |
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"math/rand" |
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"testing" |
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) |
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func TestPrque(t *testing.T) { |
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// Generate a batch of random data and a specific priority order
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size := 16 * blockSize |
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prio := rand.Perm(size) |
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data := make([]int, size) |
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for i := 0; i < size; i++ { |
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data[i] = rand.Int() |
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} |
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queue := New() |
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for rep := 0; rep < 2; rep++ { |
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// Fill a priority queue with the above data
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for i := 0; i < size; i++ { |
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queue.Push(data[i], float32(prio[i])) |
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if queue.Size() != i+1 { |
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t.Errorf("queue size mismatch: have %v, want %v.", queue.Size(), i+1) |
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} |
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} |
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// Create a map the values to the priorities for easier verification
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dict := make(map[float32]int) |
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for i := 0; i < size; i++ { |
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dict[float32(prio[i])] = data[i] |
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} |
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// Pop out the elements in priority order and verify them
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prevPrio := float32(size + 1) |
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for !queue.Empty() { |
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val, prio := queue.Pop() |
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if prio > prevPrio { |
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t.Errorf("invalid priority order: %v after %v.", prio, prevPrio) |
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} |
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prevPrio = prio |
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if val != dict[prio] { |
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t.Errorf("push/pop mismatch: have %v, want %v.", val, dict[prio]) |
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} |
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delete(dict, prio) |
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} |
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} |
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} |
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func TestReset(t *testing.T) { |
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// Fill the queue with some random data
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size := 16 * blockSize |
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queue := New() |
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for i := 0; i < size; i++ { |
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queue.Push(rand.Int(), rand.Float32()) |
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} |
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// Reset and ensure it's empty
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queue.Reset() |
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if !queue.Empty() { |
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t.Errorf("priority queue not empty after reset: %v", queue) |
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} |
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} |
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func BenchmarkPush(b *testing.B) { |
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// Create some initial data
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data := make([]int, b.N) |
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prio := make([]float32, b.N) |
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for i := 0; i < len(data); i++ { |
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data[i] = rand.Int() |
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prio[i] = rand.Float32() |
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} |
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// Execute the benchmark
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b.ResetTimer() |
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queue := New() |
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for i := 0; i < len(data); i++ { |
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queue.Push(data[i], prio[i]) |
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} |
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} |
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func BenchmarkPop(b *testing.B) { |
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// Create some initial data
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data := make([]int, b.N) |
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prio := make([]float32, b.N) |
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for i := 0; i < len(data); i++ { |
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data[i] = rand.Int() |
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prio[i] = rand.Float32() |
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} |
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queue := New() |
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for i := 0; i < len(data); i++ { |
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queue.Push(data[i], prio[i]) |
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} |
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// Execute the benchmark
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b.ResetTimer() |
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for !queue.Empty() { |
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queue.Pop() |
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} |
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} |
103
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/sstack.go
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103
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/sstack.go
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// CookieJar - A contestant's algorithm toolbox
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// Copyright (c) 2013 Peter Szilagyi. All rights reserved.
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//
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// CookieJar is dual licensed: you can redistribute it and/or modify it under
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// the terms of the GNU General Public License as published by the Free Software
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// Foundation, either version 3 of the License, or (at your option) any later
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// version.
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//
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// The toolbox is distributed in the hope that it will be useful, but WITHOUT
|
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// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
|
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// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
|
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// more details.
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//
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// Alternatively, the CookieJar toolbox may be used in accordance with the terms
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// and conditions contained in a signed written agreement between you and the
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// author(s).
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package prque |
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// The size of a block of data
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const blockSize = 4096 |
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// A prioritized item in the sorted stack.
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type item struct { |
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value interface{} |
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priority float32 |
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} |
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// Internal sortable stack data structure. Implements the Push and Pop ops for
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// the stack (heap) functionality and the Len, Less and Swap methods for the
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// sortability requirements of the heaps.
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type sstack struct { |
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size int |
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capacity int |
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offset int |
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blocks [][]*item |
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active []*item |
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} |
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// Creates a new, empty stack.
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func newSstack() *sstack { |
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result := new(sstack) |
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result.active = make([]*item, blockSize) |
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result.blocks = [][]*item{result.active} |
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result.capacity = blockSize |
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return result |
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} |
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// Pushes a value onto the stack, expanding it if necessary. Required by
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// heap.Interface.
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func (s *sstack) Push(data interface{}) { |
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if s.size == s.capacity { |
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s.active = make([]*item, blockSize) |
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s.blocks = append(s.blocks, s.active) |
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s.capacity += blockSize |
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s.offset = 0 |
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} else if s.offset == blockSize { |
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s.active = s.blocks[s.size/blockSize] |
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s.offset = 0 |
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} |
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s.active[s.offset] = data.(*item) |
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s.offset++ |
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s.size++ |
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} |
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// Pops a value off the stack and returns it. Currently no shrinking is done.
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// Required by heap.Interface.
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func (s *sstack) Pop() (res interface{}) { |
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s.size-- |
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s.offset-- |
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if s.offset < 0 { |
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s.offset = blockSize - 1 |
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s.active = s.blocks[s.size/blockSize] |
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} |
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res, s.active[s.offset] = s.active[s.offset], nil |
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return |
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} |
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// Returns the length of the stack. Required by sort.Interface.
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func (s *sstack) Len() int { |
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return s.size |
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} |
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|
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// Compares the priority of two elements of the stack (higher is first).
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// Required by sort.Interface.
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func (s *sstack) Less(i, j int) bool { |
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return s.blocks[i/blockSize][i%blockSize].priority > s.blocks[j/blockSize][j%blockSize].priority |
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} |
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// Swapts two elements in the stack. Required by sort.Interface.
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func (s *sstack) Swap(i, j int) { |
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ib, io, jb, jo := i/blockSize, i%blockSize, j/blockSize, j%blockSize |
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s.blocks[ib][io], s.blocks[jb][jo] = s.blocks[jb][jo], s.blocks[ib][io] |
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} |
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// Resets the stack, effectively clearing its contents.
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func (s *sstack) Reset() { |
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s.size = 0 |
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s.offset = 0 |
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s.active = s.blocks[0] |
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s.capacity = blockSize |
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} |
93
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/sstack_test.go
generated
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93
Godeps/_workspace/src/gopkg.in/karalabe/cookiejar.v2/collections/prque/sstack_test.go
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@ -0,0 +1,93 @@ |
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// CookieJar - A contestant's algorithm toolbox
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// Copyright (c) 2013 Peter Szilagyi. All rights reserved.
|
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//
|
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// CookieJar is dual licensed: you can redistribute it and/or modify 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.
|
||||
//
|
||||
// The toolbox is distributed in the hope that it will be useful, 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.
|
||||
//
|
||||
// Alternatively, the CookieJar toolbox may be used in accordance with the terms
|
||||
// and conditions contained in a signed written agreement between you and the
|
||||
// author(s).
|
||||
|
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package prque |
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|
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import ( |
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"math/rand" |
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"sort" |
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"testing" |
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) |
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|
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func TestSstack(t *testing.T) { |
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// Create some initial data
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size := 16 * blockSize |
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data := make([]*item, size) |
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for i := 0; i < size; i++ { |
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data[i] = &item{rand.Int(), rand.Float32()} |
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} |
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stack := newSstack() |
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for rep := 0; rep < 2; rep++ { |
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// Push all the data into the stack, pop out every second
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secs := []*item{} |
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for i := 0; i < size; i++ { |
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stack.Push(data[i]) |
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if i%2 == 0 { |
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secs = append(secs, stack.Pop().(*item)) |
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} |
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} |
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rest := []*item{} |
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for stack.Len() > 0 { |
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rest = append(rest, stack.Pop().(*item)) |
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} |
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// Make sure the contents of the resulting slices are ok
|
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for i := 0; i < size; i++ { |
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if i%2 == 0 && data[i] != secs[i/2] { |
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t.Errorf("push/pop mismatch: have %v, want %v.", secs[i/2], data[i]) |
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} |
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if i%2 == 1 && data[i] != rest[len(rest)-i/2-1] { |
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t.Errorf("push/pop mismatch: have %v, want %v.", rest[len(rest)-i/2-1], data[i]) |
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} |
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} |
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} |
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} |
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|
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func TestSstackSort(t *testing.T) { |
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// Create some initial data
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size := 16 * blockSize |
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data := make([]*item, size) |
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for i := 0; i < size; i++ { |
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data[i] = &item{rand.Int(), float32(i)} |
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} |
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// Push all the data into the stack
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stack := newSstack() |
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for _, val := range data { |
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stack.Push(val) |
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} |
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// Sort and pop the stack contents (should reverse the order)
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sort.Sort(stack) |
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for _, val := range data { |
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out := stack.Pop() |
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if out != val { |
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t.Errorf("push/pop mismatch after sort: have %v, want %v.", out, val) |
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} |
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} |
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} |
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|
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func TestSstackReset(t *testing.T) { |
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// Push some stuff onto the stack
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size := 16 * blockSize |
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stack := newSstack() |
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for i := 0; i < size; i++ { |
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stack.Push(&item{i, float32(i)}) |
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} |
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// Clear and verify
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||||
stack.Reset() |
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if stack.Len() != 0 { |
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t.Errorf("stack not empty after reset: %v", stack) |
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} |
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} |
@ -1,201 +1,349 @@ |
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package downloader |
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|
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import ( |
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"errors" |
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"fmt" |
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"math" |
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"sync" |
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"time" |
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|
||||
"github.com/ethereum/go-ethereum/common" |
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"github.com/ethereum/go-ethereum/core/types" |
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"gopkg.in/fatih/set.v0" |
||||
"gopkg.in/karalabe/cookiejar.v2/collections/prque" |
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) |
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|
||||
const ( |
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blockCacheLimit = 4096 // Maximum number of blocks to cache before throttling the download
|
||||
) |
||||
|
||||
// fetchRequest is a currently running block retrieval operation.
|
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type fetchRequest struct { |
||||
Peer *peer // Peer to which the request was sent
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Hashes map[common.Hash]int // Requested hashes with their insertion index (priority)
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Time time.Time // Time when the request was made
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} |
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|
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// queue represents hashes that are either need fetching or are being fetched
|
||||
type queue struct { |
||||
hashPool *set.Set |
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fetchPool *set.Set |
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blockHashes *set.Set |
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hashPool map[common.Hash]int // Pending hashes, mapping to their insertion index (priority)
|
||||
hashQueue *prque.Prque // Priority queue of the block hashes to fetch
|
||||
hashCounter int // Counter indexing the added hashes to ensure retrieval order
|
||||
|
||||
pendPool map[string]*fetchRequest // Currently pending block retrieval operations
|
||||
pendCount int // Number of pending block fetches (to throttle the download)
|
||||
|
||||
mu sync.Mutex |
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fetching map[string]*chunk |
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blockPool map[common.Hash]int // Hash-set of the downloaded data blocks, mapping to cache indexes
|
||||
blockCache []*types.Block // Downloaded but not yet delivered blocks
|
||||
blockOffset int // Offset of the first cached block in the block-chain
|
||||
|
||||
blockOffset int |
||||
blocks []*types.Block |
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lock sync.RWMutex |
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} |
||||
|
||||
func newqueue() *queue { |
||||
// newQueue creates a new download queue for scheduling block retrieval.
|
||||
func newQueue() *queue { |
||||
return &queue{ |
||||
hashPool: set.New(), |
||||
fetchPool: set.New(), |
||||
blockHashes: set.New(), |
||||
fetching: make(map[string]*chunk), |
||||
hashPool: make(map[common.Hash]int), |
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hashQueue: prque.New(), |
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pendPool: make(map[string]*fetchRequest), |
||||
blockPool: make(map[common.Hash]int), |
||||
} |
||||
} |
||||
|
||||
func (c *queue) reset() { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// Reset clears out the queue contents.
|
||||
func (q *queue) Reset() { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
c.resetNoTS() |
||||
q.hashPool = make(map[common.Hash]int) |
||||
q.hashQueue.Reset() |
||||
q.hashCounter = 0 |
||||
|
||||
q.pendPool = make(map[string]*fetchRequest) |
||||
q.pendCount = 0 |
||||
|
||||
q.blockPool = make(map[common.Hash]int) |
||||
q.blockOffset = 0 |
||||
q.blockCache = nil |
||||
} |
||||
func (c *queue) resetNoTS() { |
||||
c.blockOffset = 0 |
||||
c.hashPool.Clear() |
||||
c.fetchPool.Clear() |
||||
c.blockHashes.Clear() |
||||
c.blocks = nil |
||||
c.fetching = make(map[string]*chunk) |
||||
|
||||
// Done checks if all the downloads have been retrieved, wiping the queue.
|
||||
func (q *queue) Done() { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
if len(q.blockCache) == 0 { |
||||
q.Reset() |
||||
} |
||||
} |
||||
|
||||
func (c *queue) size() int { |
||||
return c.hashPool.Size() + c.blockHashes.Size() + c.fetchPool.Size() |
||||
// Size retrieves the number of hashes in the queue, returning separately for
|
||||
// pending and already downloaded.
|
||||
func (q *queue) Size() (int, int) { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
return len(q.hashPool), len(q.blockPool) |
||||
} |
||||
|
||||
// reserve a `max` set of hashes for `p` peer.
|
||||
func (c *queue) get(p *peer, max int) *chunk { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// Pending retrieves the number of hashes pending for retrieval.
|
||||
func (q *queue) Pending() int { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
// return nothing if the pool has been depleted
|
||||
if c.hashPool.Size() == 0 { |
||||
return nil |
||||
} |
||||
return q.hashQueue.Size() |
||||
} |
||||
|
||||
limit := int(math.Min(float64(max), float64(c.hashPool.Size()))) |
||||
// Create a new set of hashes
|
||||
hashes, i := set.New(), 0 |
||||
c.hashPool.Each(func(v interface{}) bool { |
||||
// break on limit
|
||||
if i == limit { |
||||
return false |
||||
} |
||||
// skip any hashes that have previously been requested from the peer
|
||||
if p.ignored.Has(v) { |
||||
return true |
||||
} |
||||
// InFlight retrieves the number of fetch requests currently in flight.
|
||||
func (q *queue) InFlight() int { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
hashes.Add(v) |
||||
i++ |
||||
return len(q.pendPool) |
||||
} |
||||
|
||||
return true |
||||
}) |
||||
// if no hashes can be requested return a nil chunk
|
||||
if hashes.Size() == 0 { |
||||
return nil |
||||
} |
||||
// Throttle checks if the download should be throttled (active block fetches
|
||||
// exceed block cache).
|
||||
func (q *queue) Throttle() bool { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
// remove the fetchable hashes from hash pool
|
||||
c.hashPool.Separate(hashes) |
||||
c.fetchPool.Merge(hashes) |
||||
return q.pendCount >= len(q.blockCache)-len(q.blockPool) |
||||
} |
||||
|
||||
// Create a new chunk for the seperated hashes. The time is being used
|
||||
// to reset the chunk (timeout)
|
||||
chunk := &chunk{p, hashes, time.Now()} |
||||
// register as 'fetching' state
|
||||
c.fetching[p.id] = chunk |
||||
// Has checks if a hash is within the download queue or not.
|
||||
func (q *queue) Has(hash common.Hash) bool { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
// create new chunk for peer
|
||||
return chunk |
||||
if _, ok := q.hashPool[hash]; ok { |
||||
return true |
||||
} |
||||
if _, ok := q.blockPool[hash]; ok { |
||||
return true |
||||
} |
||||
return false |
||||
} |
||||
|
||||
func (c *queue) has(hash common.Hash) bool { |
||||
return c.hashPool.Has(hash) || c.fetchPool.Has(hash) || c.blockHashes.Has(hash) |
||||
// Insert adds a set of hashes for the download queue for scheduling.
|
||||
func (q *queue) Insert(hashes []common.Hash) { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
// Insert all the hashes prioritized in the arrival order
|
||||
for i, hash := range hashes { |
||||
index := q.hashCounter + i |
||||
|
||||
q.hashPool[hash] = index |
||||
q.hashQueue.Push(hash, float32(index)) // Highest gets schedules first
|
||||
} |
||||
// Update the hash counter for the next batch of inserts
|
||||
q.hashCounter += len(hashes) |
||||
} |
||||
|
||||
func (c *queue) getBlock(hash common.Hash) *types.Block { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// GetHeadBlock retrieves the first block from the cache, or nil if it hasn't
|
||||
// been downloaded yet (or simply non existent).
|
||||
func (q *queue) GetHeadBlock() *types.Block { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
if !c.blockHashes.Has(hash) { |
||||
if len(q.blockCache) == 0 { |
||||
return nil |
||||
} |
||||
return q.blockCache[0] |
||||
} |
||||
|
||||
for _, block := range c.blocks { |
||||
if block.Hash() == hash { |
||||
return block |
||||
// GetBlock retrieves a downloaded block, or nil if non-existent.
|
||||
func (q *queue) GetBlock(hash common.Hash) *types.Block { |
||||
q.lock.RLock() |
||||
defer q.lock.RUnlock() |
||||
|
||||
// Short circuit if the block hasn't been downloaded yet
|
||||
index, ok := q.blockPool[hash] |
||||
if !ok { |
||||
return nil |
||||
} |
||||
// Return the block if it's still available in the cache
|
||||
if q.blockOffset <= index && index < q.blockOffset+len(q.blockCache) { |
||||
return q.blockCache[index-q.blockOffset] |
||||
} |
||||
return nil |
||||
} |
||||
|
||||
// deliver delivers a chunk to the queue that was requested of the peer
|
||||
func (c *queue) deliver(id string, blocks []*types.Block) (err error) { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// TakeBlocks retrieves and permanently removes a batch of blocks from the cache.
|
||||
// The head parameter is required to prevent a race condition where concurrent
|
||||
// takes may fail parent verifications.
|
||||
func (q *queue) TakeBlocks(head *types.Block) types.Blocks { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
chunk := c.fetching[id] |
||||
// If the chunk was never requested simply ignore it
|
||||
if chunk != nil { |
||||
delete(c.fetching, id) |
||||
// check the length of the returned blocks. If the length of blocks is 0
|
||||
// we'll assume the peer doesn't know about the chain.
|
||||
if len(blocks) == 0 { |
||||
// So we can ignore the blocks we didn't know about
|
||||
chunk.peer.ignored.Merge(chunk.hashes) |
||||
} |
||||
|
||||
// Add the blocks
|
||||
for i, block := range blocks { |
||||
// See (1) for future limitation
|
||||
n := int(block.NumberU64()) - c.blockOffset |
||||
if n > len(c.blocks) || n < 0 { |
||||
// set the error and set the blocks which could be processed
|
||||
// abort the rest of the blocks (FIXME this could be improved)
|
||||
err = fmt.Errorf("received block which overflow (N=%v O=%v)", block.Number(), c.blockOffset) |
||||
blocks = blocks[:i] |
||||
// Short circuit if the head block's different
|
||||
if len(q.blockCache) == 0 || q.blockCache[0] != head { |
||||
return nil |
||||
} |
||||
// Otherwise accumulate all available blocks
|
||||
var blocks types.Blocks |
||||
for _, block := range q.blockCache { |
||||
if block == nil { |
||||
break |
||||
} |
||||
c.blocks[n] = block |
||||
blocks = append(blocks, block) |
||||
delete(q.blockPool, block.Hash()) |
||||
} |
||||
// seperate the blocks and the hashes
|
||||
blockHashes := chunk.fetchedHashes(blocks) |
||||
// merge block hashes
|
||||
c.blockHashes.Merge(blockHashes) |
||||
// Add back whatever couldn't be delivered
|
||||
c.hashPool.Merge(chunk.hashes) |
||||
// Remove the hashes from the fetch pool
|
||||
c.fetchPool.Separate(chunk.hashes) |
||||
// Delete the blocks from the slice and let them be garbage collected
|
||||
// without this slice trick the blocks would stay in memory until nil
|
||||
// would be assigned to q.blocks
|
||||
copy(q.blockCache, q.blockCache[len(blocks):]) |
||||
for k, n := len(q.blockCache)-len(blocks), len(q.blockCache); k < n; k++ { |
||||
q.blockCache[k] = nil |
||||
} |
||||
q.blockOffset += len(blocks) |
||||
|
||||
return |
||||
return blocks |
||||
} |
||||
|
||||
func (c *queue) alloc(offset, size int) { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// Reserve reserves a set of hashes for the given peer, skipping any previously
|
||||
// failed download.
|
||||
func (q *queue) Reserve(p *peer, max int) *fetchRequest { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
if c.blockOffset < offset { |
||||
c.blockOffset = offset |
||||
// Short circuit if the pool has been depleted
|
||||
if q.hashQueue.Empty() { |
||||
return nil |
||||
} |
||||
|
||||
// (1) XXX at some point we could limit allocation to memory and use the disk
|
||||
// to store future blocks.
|
||||
if len(c.blocks) < size { |
||||
c.blocks = append(c.blocks, make([]*types.Block, size)...) |
||||
// Retrieve a batch of hashes, skipping previously failed ones
|
||||
send := make(map[common.Hash]int) |
||||
skip := make(map[common.Hash]int) |
||||
|
||||
for len(send) < max && !q.hashQueue.Empty() { |
||||
hash, priority := q.hashQueue.Pop() |
||||
if p.ignored.Has(hash) { |
||||
skip[hash.(common.Hash)] = int(priority) |
||||
} else { |
||||
send[hash.(common.Hash)] = int(priority) |
||||
} |
||||
} |
||||
// Merge all the skipped hashes back
|
||||
for hash, index := range skip { |
||||
q.hashQueue.Push(hash, float32(index)) |
||||
} |
||||
// Assemble and return the block download request
|
||||
if len(send) == 0 { |
||||
return nil |
||||
} |
||||
request := &fetchRequest{ |
||||
Peer: p, |
||||
Hashes: send, |
||||
Time: time.Now(), |
||||
} |
||||
q.pendPool[p.id] = request |
||||
q.pendCount += len(request.Hashes) |
||||
|
||||
return request |
||||
} |
||||
|
||||
// puts puts sets of hashes on to the queue for fetching
|
||||
func (c *queue) put(hashes *set.Set) { |
||||
c.mu.Lock() |
||||
defer c.mu.Unlock() |
||||
// Cancel aborts a fetch request, returning all pending hashes to the queue.
|
||||
func (q *queue) Cancel(request *fetchRequest) { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
c.hashPool.Merge(hashes) |
||||
for hash, index := range request.Hashes { |
||||
q.hashQueue.Push(hash, float32(index)) |
||||
} |
||||
delete(q.pendPool, request.Peer.id) |
||||
q.pendCount -= len(request.Hashes) |
||||
} |
||||
|
||||
type chunk struct { |
||||
peer *peer |
||||
hashes *set.Set |
||||
itime time.Time |
||||
// Expire checks for in flight requests that exceeded a timeout allowance,
|
||||
// canceling them and returning the responsible peers for penalization.
|
||||
func (q *queue) Expire(timeout time.Duration) []string { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
// Iterate over the expired requests and return each to the queue
|
||||
peers := []string{} |
||||
for id, request := range q.pendPool { |
||||
if time.Since(request.Time) > timeout { |
||||
for hash, index := range request.Hashes { |
||||
q.hashQueue.Push(hash, float32(index)) |
||||
} |
||||
q.pendCount -= len(request.Hashes) |
||||
peers = append(peers, id) |
||||
} |
||||
} |
||||
// Remove the expired requests from the pending pool
|
||||
for _, id := range peers { |
||||
delete(q.pendPool, id) |
||||
} |
||||
return peers |
||||
} |
||||
|
||||
func (ch *chunk) fetchedHashes(blocks []*types.Block) *set.Set { |
||||
fhashes := set.New() |
||||
// Deliver injects a block retrieval response into the download queue.
|
||||
func (q *queue) Deliver(id string, blocks []*types.Block) (err error) { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
// Short circuit if the blocks were never requested
|
||||
request := q.pendPool[id] |
||||
if request == nil { |
||||
return errors.New("no fetches pending") |
||||
} |
||||
delete(q.pendPool, id) |
||||
|
||||
// Mark all the hashes in the request as non-pending
|
||||
q.pendCount -= len(request.Hashes) |
||||
|
||||
// If no blocks were retrieved, mark them as unavailable for the origin peer
|
||||
if len(blocks) == 0 { |
||||
for hash, _ := range request.Hashes { |
||||
request.Peer.ignored.Add(hash) |
||||
} |
||||
} |
||||
// Iterate over the downloaded blocks and add each of them
|
||||
errs := make([]error, 0) |
||||
for _, block := range blocks { |
||||
fhashes.Add(block.Hash()) |
||||
// Skip any blocks that fall outside the cache range
|
||||
index := int(block.NumberU64()) - q.blockOffset |
||||
if index >= len(q.blockCache) || index < 0 { |
||||
//fmt.Printf("block cache overflown (N=%v O=%v, C=%v)", block.Number(), q.blockOffset, len(q.blockCache))
|
||||
continue |
||||
} |
||||
// Skip any blocks that were not requested
|
||||
hash := block.Hash() |
||||
if _, ok := request.Hashes[hash]; !ok { |
||||
errs = append(errs, fmt.Errorf("non-requested block %v", hash)) |
||||
continue |
||||
} |
||||
ch.hashes.Separate(fhashes) |
||||
// Otherwise merge the block and mark the hash block
|
||||
q.blockCache[index] = block |
||||
|
||||
return fhashes |
||||
delete(request.Hashes, hash) |
||||
delete(q.hashPool, hash) |
||||
q.blockPool[hash] = int(block.NumberU64()) |
||||
} |
||||
// Return all failed fetches to the queue
|
||||
for hash, index := range request.Hashes { |
||||
q.hashQueue.Push(hash, float32(index)) |
||||
} |
||||
if len(errs) != 0 { |
||||
return fmt.Errorf("multiple failures: %v", errs) |
||||
} |
||||
return nil |
||||
} |
||||
|
||||
// Alloc ensures that the block cache is the correct size, given a starting
|
||||
// offset, and a memory cap.
|
||||
func (q *queue) Alloc(offset int) { |
||||
q.lock.Lock() |
||||
defer q.lock.Unlock() |
||||
|
||||
if q.blockOffset < offset { |
||||
q.blockOffset = offset |
||||
} |
||||
size := len(q.hashPool) |
||||
if size > blockCacheLimit { |
||||
size = blockCacheLimit |
||||
} |
||||
if len(q.blockCache) < size { |
||||
q.blockCache = append(q.blockCache, make([]*types.Block, size-len(q.blockCache))...) |
||||
} |
||||
} |
||||
|
Loading…
Reference in new issue