github.com/annchain/OG@v0.0.9/metrics/sample.go (about) 1 package metrics 2 3 import ( 4 "math" 5 "math/rand" 6 "sort" 7 "sync" 8 "time" 9 ) 10 11 const rescaleThreshold = time.Hour 12 13 // Samples maintain a statistically-significant selection of values from 14 // a stream. 15 type Sample interface { 16 Clear() 17 Count() int64 18 Max() int64 19 Mean() float64 20 Min() int64 21 Percentile(float64) float64 22 Percentiles([]float64) []float64 23 Size() int 24 Snapshot() Sample 25 StdDev() float64 26 Sum() int64 27 Update(int64) 28 Values() []int64 29 Variance() float64 30 } 31 32 // ExpDecaySample is an exponentially-decaying sample using a forward-decaying 33 // priority reservoir. See Cormode et al's "Forward Decay: A Practical Time 34 // Decay Model for Streaming Systems". 35 // 36 // <http://dimacs.rutgers.edu/~graham/pubs/papers/fwddecay.pdf> 37 type ExpDecaySample struct { 38 alpha float64 39 count int64 40 mutex sync.Mutex 41 reservoirSize int 42 t0, t1 time.Time 43 values *expDecaySampleHeap 44 } 45 46 // NewExpDecaySample constructs a new exponentially-decaying sample with the 47 // given reservoir size and alpha. 48 func NewExpDecaySample(reservoirSize int, alpha float64) Sample { 49 if !Enabled { 50 return NilSample{} 51 } 52 s := &ExpDecaySample{ 53 alpha: alpha, 54 reservoirSize: reservoirSize, 55 t0: time.Now(), 56 values: newExpDecaySampleHeap(reservoirSize), 57 } 58 s.t1 = s.t0.Add(rescaleThreshold) 59 return s 60 } 61 62 // Clear clears all samples. 63 func (s *ExpDecaySample) Clear() { 64 s.mutex.Lock() 65 defer s.mutex.Unlock() 66 s.count = 0 67 s.t0 = time.Now() 68 s.t1 = s.t0.Add(rescaleThreshold) 69 s.values.Clear() 70 } 71 72 // Count returns the number of samples recorded, which may exceed the 73 // reservoir size. 74 func (s *ExpDecaySample) Count() int64 { 75 s.mutex.Lock() 76 defer s.mutex.Unlock() 77 return s.count 78 } 79 80 // Max returns the maximum value in the sample, which may not be the maximum 81 // value ever to be part of the sample. 82 func (s *ExpDecaySample) Max() int64 { 83 return SampleMax(s.Values()) 84 } 85 86 // Mean returns the mean of the values in the sample. 87 func (s *ExpDecaySample) Mean() float64 { 88 return SampleMean(s.Values()) 89 } 90 91 // Min returns the minimum value in the sample, which may not be the minimum 92 // value ever to be part of the sample. 93 func (s *ExpDecaySample) Min() int64 { 94 return SampleMin(s.Values()) 95 } 96 97 // Percentile returns an arbitrary percentile of values in the sample. 98 func (s *ExpDecaySample) Percentile(p float64) float64 { 99 return SamplePercentile(s.Values(), p) 100 } 101 102 // Percentiles returns a slice of arbitrary percentiles of values in the 103 // sample. 104 func (s *ExpDecaySample) Percentiles(ps []float64) []float64 { 105 return SamplePercentiles(s.Values(), ps) 106 } 107 108 // Size returns the size of the sample, which is at most the reservoir size. 109 func (s *ExpDecaySample) Size() int { 110 s.mutex.Lock() 111 defer s.mutex.Unlock() 112 return s.values.Size() 113 } 114 115 // Snapshot returns a read-only copy of the sample. 116 func (s *ExpDecaySample) Snapshot() Sample { 117 s.mutex.Lock() 118 defer s.mutex.Unlock() 119 vals := s.values.Values() 120 values := make([]int64, len(vals)) 121 for i, v := range vals { 122 values[i] = v.v 123 } 124 return &SampleSnapshot{ 125 count: s.count, 126 values: values, 127 } 128 } 129 130 // StdDev returns the standard deviation of the values in the sample. 131 func (s *ExpDecaySample) StdDev() float64 { 132 return SampleStdDev(s.Values()) 133 } 134 135 // Sum returns the sum of the values in the sample. 136 func (s *ExpDecaySample) Sum() int64 { 137 return SampleSum(s.Values()) 138 } 139 140 // Update samples a new value. 141 func (s *ExpDecaySample) Update(v int64) { 142 s.update(time.Now(), v) 143 } 144 145 // Values returns a copy of the values in the sample. 146 func (s *ExpDecaySample) Values() []int64 { 147 s.mutex.Lock() 148 defer s.mutex.Unlock() 149 vals := s.values.Values() 150 values := make([]int64, len(vals)) 151 for i, v := range vals { 152 values[i] = v.v 153 } 154 return values 155 } 156 157 // Variance returns the variance of the values in the sample. 158 func (s *ExpDecaySample) Variance() float64 { 159 return SampleVariance(s.Values()) 160 } 161 162 // update samples a new value at a particular timestamp. This is a method all 163 // its own to facilitate testing. 164 func (s *ExpDecaySample) update(t time.Time, v int64) { 165 s.mutex.Lock() 166 defer s.mutex.Unlock() 167 s.count++ 168 if s.values.Size() == s.reservoirSize { 169 s.values.Pop() 170 } 171 s.values.Push(expDecaySample{ 172 k: math.Exp(t.Sub(s.t0).Seconds()*s.alpha) / rand.Float64(), 173 v: v, 174 }) 175 if t.After(s.t1) { 176 values := s.values.Values() 177 t0 := s.t0 178 s.values.Clear() 179 s.t0 = t 180 s.t1 = s.t0.Add(rescaleThreshold) 181 for _, v := range values { 182 v.k = v.k * math.Exp(-s.alpha*s.t0.Sub(t0).Seconds()) 183 s.values.Push(v) 184 } 185 } 186 } 187 188 // NilSample is a no-op Sample. 189 type NilSample struct{} 190 191 // Clear is a no-op. 192 func (NilSample) Clear() {} 193 194 // Count is a no-op. 195 func (NilSample) Count() int64 { return 0 } 196 197 // Max is a no-op. 198 func (NilSample) Max() int64 { return 0 } 199 200 // Mean is a no-op. 201 func (NilSample) Mean() float64 { return 0.0 } 202 203 // Min is a no-op. 204 func (NilSample) Min() int64 { return 0 } 205 206 // Percentile is a no-op. 207 func (NilSample) Percentile(p float64) float64 { return 0.0 } 208 209 // Percentiles is a no-op. 210 func (NilSample) Percentiles(ps []float64) []float64 { 211 return make([]float64, len(ps)) 212 } 213 214 // Size is a no-op. 215 func (NilSample) Size() int { return 0 } 216 217 // Sample is a no-op. 218 func (NilSample) Snapshot() Sample { return NilSample{} } 219 220 // StdDev is a no-op. 221 func (NilSample) StdDev() float64 { return 0.0 } 222 223 // Sum is a no-op. 224 func (NilSample) Sum() int64 { return 0 } 225 226 // Update is a no-op. 227 func (NilSample) Update(v int64) {} 228 229 // Values is a no-op. 230 func (NilSample) Values() []int64 { return []int64{} } 231 232 // Variance is a no-op. 233 func (NilSample) Variance() float64 { return 0.0 } 234 235 // SampleMax returns the maximum value of the slice of int64. 236 func SampleMax(values []int64) int64 { 237 if 0 == len(values) { 238 return 0 239 } 240 var max int64 = math.MinInt64 241 for _, v := range values { 242 if max < v { 243 max = v 244 } 245 } 246 return max 247 } 248 249 // SampleMean returns the mean value of the slice of int64. 250 func SampleMean(values []int64) float64 { 251 if 0 == len(values) { 252 return 0.0 253 } 254 return float64(SampleSum(values)) / float64(len(values)) 255 } 256 257 // SampleMin returns the minimum value of the slice of int64. 258 func SampleMin(values []int64) int64 { 259 if 0 == len(values) { 260 return 0 261 } 262 var min int64 = math.MaxInt64 263 for _, v := range values { 264 if min > v { 265 min = v 266 } 267 } 268 return min 269 } 270 271 // SamplePercentiles returns an arbitrary percentile of the slice of int64. 272 func SamplePercentile(values int64Slice, p float64) float64 { 273 return SamplePercentiles(values, []float64{p})[0] 274 } 275 276 // SamplePercentiles returns a slice of arbitrary percentiles of the slice of 277 // int64. 278 func SamplePercentiles(values int64Slice, ps []float64) []float64 { 279 scores := make([]float64, len(ps)) 280 size := len(values) 281 if size > 0 { 282 sort.Sort(values) 283 for i, p := range ps { 284 pos := p * float64(size+1) 285 if pos < 1.0 { 286 scores[i] = float64(values[0]) 287 } else if pos >= float64(size) { 288 scores[i] = float64(values[size-1]) 289 } else { 290 lower := float64(values[int(pos)-1]) 291 upper := float64(values[int(pos)]) 292 scores[i] = lower + (pos-math.Floor(pos))*(upper-lower) 293 } 294 } 295 } 296 return scores 297 } 298 299 // SampleSnapshot is a read-only copy of another Sample. 300 type SampleSnapshot struct { 301 count int64 302 values []int64 303 } 304 305 func NewSampleSnapshot(count int64, values []int64) *SampleSnapshot { 306 return &SampleSnapshot{ 307 count: count, 308 values: values, 309 } 310 } 311 312 // Clear panics. 313 func (*SampleSnapshot) Clear() { 314 panic("Clear called on a SampleSnapshot") 315 } 316 317 // Count returns the count of inputs at the time the snapshot was taken. 318 func (s *SampleSnapshot) Count() int64 { return s.count } 319 320 // Max returns the maximal value at the time the snapshot was taken. 321 func (s *SampleSnapshot) Max() int64 { return SampleMax(s.values) } 322 323 // Mean returns the mean value at the time the snapshot was taken. 324 func (s *SampleSnapshot) Mean() float64 { return SampleMean(s.values) } 325 326 // Min returns the minimal value at the time the snapshot was taken. 327 func (s *SampleSnapshot) Min() int64 { return SampleMin(s.values) } 328 329 // Percentile returns an arbitrary percentile of values at the time the 330 // snapshot was taken. 331 func (s *SampleSnapshot) Percentile(p float64) float64 { 332 return SamplePercentile(s.values, p) 333 } 334 335 // Percentiles returns a slice of arbitrary percentiles of values at the time 336 // the snapshot was taken. 337 func (s *SampleSnapshot) Percentiles(ps []float64) []float64 { 338 return SamplePercentiles(s.values, ps) 339 } 340 341 // Size returns the size of the sample at the time the snapshot was taken. 342 func (s *SampleSnapshot) Size() int { return len(s.values) } 343 344 // Snapshot returns the snapshot. 345 func (s *SampleSnapshot) Snapshot() Sample { return s } 346 347 // StdDev returns the standard deviation of values at the time the snapshot was 348 // taken. 349 func (s *SampleSnapshot) StdDev() float64 { return SampleStdDev(s.values) } 350 351 // Sum returns the sum of values at the time the snapshot was taken. 352 func (s *SampleSnapshot) Sum() int64 { return SampleSum(s.values) } 353 354 // Update panics. 355 func (*SampleSnapshot) Update(int64) { 356 panic("Update called on a SampleSnapshot") 357 } 358 359 // Values returns a copy of the values in the sample. 360 func (s *SampleSnapshot) Values() []int64 { 361 values := make([]int64, len(s.values)) 362 copy(values, s.values) 363 return values 364 } 365 366 // Variance returns the variance of values at the time the snapshot was taken. 367 func (s *SampleSnapshot) Variance() float64 { return SampleVariance(s.values) } 368 369 // SampleStdDev returns the standard deviation of the slice of int64. 370 func SampleStdDev(values []int64) float64 { 371 return math.Sqrt(SampleVariance(values)) 372 } 373 374 // SampleSum returns the sum of the slice of int64. 375 func SampleSum(values []int64) int64 { 376 var sum int64 377 for _, v := range values { 378 sum += v 379 } 380 return sum 381 } 382 383 // SampleVariance returns the variance of the slice of int64. 384 func SampleVariance(values []int64) float64 { 385 if 0 == len(values) { 386 return 0.0 387 } 388 m := SampleMean(values) 389 var sum float64 390 for _, v := range values { 391 d := float64(v) - m 392 sum += d * d 393 } 394 return sum / float64(len(values)) 395 } 396 397 // A uniform sample using Vitter's Algorithm R. 398 // 399 // <http://www.cs.umd.edu/~samir/498/vitter.pdf> 400 type UniformSample struct { 401 count int64 402 mutex sync.Mutex 403 reservoirSize int 404 values []int64 405 } 406 407 // NewUniformSample constructs a new uniform sample with the given reservoir 408 // size. 409 func NewUniformSample(reservoirSize int) Sample { 410 if !Enabled { 411 return NilSample{} 412 } 413 return &UniformSample{ 414 reservoirSize: reservoirSize, 415 values: make([]int64, 0, reservoirSize), 416 } 417 } 418 419 // Clear clears all samples. 420 func (s *UniformSample) Clear() { 421 s.mutex.Lock() 422 defer s.mutex.Unlock() 423 s.count = 0 424 s.values = make([]int64, 0, s.reservoirSize) 425 } 426 427 // Count returns the number of samples recorded, which may exceed the 428 // reservoir size. 429 func (s *UniformSample) Count() int64 { 430 s.mutex.Lock() 431 defer s.mutex.Unlock() 432 return s.count 433 } 434 435 // Max returns the maximum value in the sample, which may not be the maximum 436 // value ever to be part of the sample. 437 func (s *UniformSample) Max() int64 { 438 s.mutex.Lock() 439 defer s.mutex.Unlock() 440 return SampleMax(s.values) 441 } 442 443 // Mean returns the mean of the values in the sample. 444 func (s *UniformSample) Mean() float64 { 445 s.mutex.Lock() 446 defer s.mutex.Unlock() 447 return SampleMean(s.values) 448 } 449 450 // Min returns the minimum value in the sample, which may not be the minimum 451 // value ever to be part of the sample. 452 func (s *UniformSample) Min() int64 { 453 s.mutex.Lock() 454 defer s.mutex.Unlock() 455 return SampleMin(s.values) 456 } 457 458 // Percentile returns an arbitrary percentile of values in the sample. 459 func (s *UniformSample) Percentile(p float64) float64 { 460 s.mutex.Lock() 461 defer s.mutex.Unlock() 462 return SamplePercentile(s.values, p) 463 } 464 465 // Percentiles returns a slice of arbitrary percentiles of values in the 466 // sample. 467 func (s *UniformSample) Percentiles(ps []float64) []float64 { 468 s.mutex.Lock() 469 defer s.mutex.Unlock() 470 return SamplePercentiles(s.values, ps) 471 } 472 473 // Size returns the size of the sample, which is at most the reservoir size. 474 func (s *UniformSample) Size() int { 475 s.mutex.Lock() 476 defer s.mutex.Unlock() 477 return len(s.values) 478 } 479 480 // Snapshot returns a read-only copy of the sample. 481 func (s *UniformSample) Snapshot() Sample { 482 s.mutex.Lock() 483 defer s.mutex.Unlock() 484 values := make([]int64, len(s.values)) 485 copy(values, s.values) 486 return &SampleSnapshot{ 487 count: s.count, 488 values: values, 489 } 490 } 491 492 // StdDev returns the standard deviation of the values in the sample. 493 func (s *UniformSample) StdDev() float64 { 494 s.mutex.Lock() 495 defer s.mutex.Unlock() 496 return SampleStdDev(s.values) 497 } 498 499 // Sum returns the sum of the values in the sample. 500 func (s *UniformSample) Sum() int64 { 501 s.mutex.Lock() 502 defer s.mutex.Unlock() 503 return SampleSum(s.values) 504 } 505 506 // Update samples a new value. 507 func (s *UniformSample) Update(v int64) { 508 s.mutex.Lock() 509 defer s.mutex.Unlock() 510 s.count++ 511 if len(s.values) < s.reservoirSize { 512 s.values = append(s.values, v) 513 } else { 514 r := rand.Int63n(s.count) 515 if r < int64(len(s.values)) { 516 s.values[int(r)] = v 517 } 518 } 519 } 520 521 // Values returns a copy of the values in the sample. 522 func (s *UniformSample) Values() []int64 { 523 s.mutex.Lock() 524 defer s.mutex.Unlock() 525 values := make([]int64, len(s.values)) 526 copy(values, s.values) 527 return values 528 } 529 530 // Variance returns the variance of the values in the sample. 531 func (s *UniformSample) Variance() float64 { 532 s.mutex.Lock() 533 defer s.mutex.Unlock() 534 return SampleVariance(s.values) 535 } 536 537 // expDecaySample represents an individual sample in a heap. 538 type expDecaySample struct { 539 k float64 540 v int64 541 } 542 543 func newExpDecaySampleHeap(reservoirSize int) *expDecaySampleHeap { 544 return &expDecaySampleHeap{make([]expDecaySample, 0, reservoirSize)} 545 } 546 547 // expDecaySampleHeap is a min-heap of expDecaySamples. 548 // The internal implementation is copied from the standard library's container/heap 549 type expDecaySampleHeap struct { 550 s []expDecaySample 551 } 552 553 func (h *expDecaySampleHeap) Clear() { 554 h.s = h.s[:0] 555 } 556 557 func (h *expDecaySampleHeap) Push(s expDecaySample) { 558 n := len(h.s) 559 h.s = h.s[0 : n+1] 560 h.s[n] = s 561 h.up(n) 562 } 563 564 func (h *expDecaySampleHeap) Pop() expDecaySample { 565 n := len(h.s) - 1 566 h.s[0], h.s[n] = h.s[n], h.s[0] 567 h.down(0, n) 568 569 n = len(h.s) 570 s := h.s[n-1] 571 h.s = h.s[0 : n-1] 572 return s 573 } 574 575 func (h *expDecaySampleHeap) Size() int { 576 return len(h.s) 577 } 578 579 func (h *expDecaySampleHeap) Values() []expDecaySample { 580 return h.s 581 } 582 583 func (h *expDecaySampleHeap) up(j int) { 584 for { 585 i := (j - 1) / 2 // parent 586 if i == j || !(h.s[j].k < h.s[i].k) { 587 break 588 } 589 h.s[i], h.s[j] = h.s[j], h.s[i] 590 j = i 591 } 592 } 593 594 func (h *expDecaySampleHeap) down(i, n int) { 595 for { 596 j1 := 2*i + 1 597 if j1 >= n || j1 < 0 { // j1 < 0 after int overflow 598 break 599 } 600 j := j1 // left child 601 if j2 := j1 + 1; j2 < n && !(h.s[j1].k < h.s[j2].k) { 602 j = j2 // = 2*i + 2 // right child 603 } 604 if !(h.s[j].k < h.s[i].k) { 605 break 606 } 607 h.s[i], h.s[j] = h.s[j], h.s[i] 608 i = j 609 } 610 } 611 612 type int64Slice []int64 613 614 func (p int64Slice) Len() int { return len(p) } 615 func (p int64Slice) Less(i, j int) bool { return p[i] < p[j] } 616 func (p int64Slice) Swap(i, j int) { p[i], p[j] = p[j], p[i] }