trace/batchcursor.go - exp - Git at Google

 // Copyright 2023 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Code generated by "gen.bash" from internal/trace/v2; DO NOT EDIT.

 //go:build go1.21

 package trace

 import (
 	"cmp"
 	"encoding/binary"
 	"fmt"

 	"golang.org/x/exp/trace/internal/event"
 	"golang.org/x/exp/trace/internal/event/go122"
 )

 type batchCursor struct {
 	m       ThreadID
 	lastTs  Time
 	idx     int       // next index into []batch
 	dataOff int       // next index into batch.data
 	ev      baseEvent // last read event
 }

 func (b *batchCursor) nextEvent(batches []batch, freq frequency) (ok bool, err error) {
 	// Batches should generally always have at least one event,
 	// but let's be defensive about that and accept empty batches.
 	for b.idx < len(batches) && len(batches[b.idx].data) == b.dataOff {
 		b.idx++
 		b.dataOff = 0
 		b.lastTs = 0
 	}
 	// Have we reached the end of the batches?
 	if b.idx == len(batches) {
 		return false, nil
 	}
 	// Initialize lastTs if it hasn't been yet.
 	if b.lastTs == 0 {
 		b.lastTs = freq.mul(batches[b.idx].time)
 	}
 	// Read an event out.
 	n, tsdiff, err := readTimedBaseEvent(batches[b.idx].data[b.dataOff:], &b.ev)
 	if err != nil {
 		return false, err
 	}
 	// Complete the timestamp from the cursor's last timestamp.
 	b.ev.time = freq.mul(tsdiff) + b.lastTs

 	// Move the cursor's timestamp forward.
 	b.lastTs = b.ev.time

 	// Move the cursor forward.
 	b.dataOff += n
 	return true, nil
 }

 func (b *batchCursor) compare(a *batchCursor) int {
 	return cmp.Compare(b.ev.time, a.ev.time)
 }

 // readTimedBaseEvent reads out the raw event data from b
 // into e. It does not try to interpret the arguments
 // but it does validate that the event is a regular
 // event with a timestamp (vs. a structural event).
 //
 // It requires that the event its reading be timed, which must
 // be the case for every event in a plain EventBatch.
 func readTimedBaseEvent(b []byte, e *baseEvent) (int, timestamp, error) {
 	// Get the event type.
 	typ := event.Type(b[0])
 	specs := go122.Specs()
 	if int(typ) > len(specs) {
 		return 0, 0, fmt.Errorf("found invalid event type: %v", typ)
 	}
 	e.typ = typ

 	// Get spec.
 	spec := &specs[typ]
 	if len(spec.Args) == 0 || !spec.IsTimedEvent {
 		return 0, 0, fmt.Errorf("found event without a timestamp: type=%v", typ)
 	}
 	n := 1

 	// Read timestamp diff.
 	ts, nb := binary.Uvarint(b[n:])
 	n += nb

 	// Read the rest of the arguments.
 	for i := 0; i < len(spec.Args)-1; i++ {
 		arg, nb := binary.Uvarint(b[n:])
 		e.args[i] = arg
 		n += nb
 	}
 	return n, timestamp(ts), nil
 }

 func heapInsert(heap []*batchCursor, bc *batchCursor) []*batchCursor {
 	// Add the cursor to the end of the heap.
 	heap = append(heap, bc)

 	// Sift the new entry up to the right place.
 	heapSiftUp(heap, len(heap)-1)
 	return heap
 }

 func heapUpdate(heap []*batchCursor, i int) {
 	// Try to sift up.
 	if heapSiftUp(heap, i) != i {
 		return
 	}
 	// Try to sift down, if sifting up failed.
 	heapSiftDown(heap, i)
 }

 func heapRemove(heap []*batchCursor, i int) []*batchCursor {
 	// Sift index i up to the root, ignoring actual values.
 	for i > 0 {
 		heap[(i-1)/2], heap[i] = heap[i], heap[(i-1)/2]
 		i = (i - 1) / 2
 	}
 	// Swap the root with the last element, then remove it.
 	heap[0], heap[len(heap)-1] = heap[len(heap)-1], heap[0]
 	heap = heap[:len(heap)-1]
 	// Sift the root down.
 	heapSiftDown(heap, 0)
 	return heap
 }

 func heapSiftUp(heap []*batchCursor, i int) int {
 	for i > 0 && heap[(i-1)/2].ev.time > heap[i].ev.time {
 		heap[(i-1)/2], heap[i] = heap[i], heap[(i-1)/2]
 		i = (i - 1) / 2
 	}
 	return i
 }

 func heapSiftDown(heap []*batchCursor, i int) int {
 	for {
 		m := min3(heap, i, 2*i+1, 2*i+2)
 		if m == i {
 			// Heap invariant already applies.
 			break
 		}
 		heap[i], heap[m] = heap[m], heap[i]
 		i = m
 	}
 	return i
 }

 func min3(b []*batchCursor, i0, i1, i2 int) int {
 	minIdx := i0
 	minT := maxTime
 	if i0 < len(b) {
 		minT = b[i0].ev.time
 	}
 	if i1 < len(b) {
 		if t := b[i1].ev.time; t < minT {
 			minT = t
 			minIdx = i1
 		}
 	}
 	if i2 < len(b) {
 		if t := b[i2].ev.time; t < minT {
 			minT = t
 			minIdx = i2
 		}
 	}
 	return minIdx
 }
	// Copyright 2023 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Code generated by "gen.bash" from internal/trace/v2; DO NOT EDIT.

	//go:build go1.21

	package trace

	import (
	"cmp"
	"encoding/binary"
	"fmt"

	"golang.org/x/exp/trace/internal/event"
	"golang.org/x/exp/trace/internal/event/go122"
	)

	type batchCursor struct {
	m ThreadID
	lastTs Time
	idx int // next index into []batch
	dataOff int // next index into batch.data
	ev baseEvent // last read event
	}

	func (b *batchCursor) nextEvent(batches []batch, freq frequency) (ok bool, err error) {
	// Batches should generally always have at least one event,
	// but let's be defensive about that and accept empty batches.
	for b.idx < len(batches) && len(batches[b.idx].data) == b.dataOff {
	b.idx++
	b.dataOff = 0
	b.lastTs = 0
	}
	// Have we reached the end of the batches?
	if b.idx == len(batches) {
	return false, nil
	}
	// Initialize lastTs if it hasn't been yet.
	if b.lastTs == 0 {
	b.lastTs = freq.mul(batches[b.idx].time)
	}
	// Read an event out.
	n, tsdiff, err := readTimedBaseEvent(batches[b.idx].data[b.dataOff:], &b.ev)
	if err != nil {
	return false, err
	}
	// Complete the timestamp from the cursor's last timestamp.
	b.ev.time = freq.mul(tsdiff) + b.lastTs

	// Move the cursor's timestamp forward.
	b.lastTs = b.ev.time

	// Move the cursor forward.
	b.dataOff += n
	return true, nil
	}

	func (b batchCursor) compare(a batchCursor) int {
	return cmp.Compare(b.ev.time, a.ev.time)
	}

	// readTimedBaseEvent reads out the raw event data from b
	// into e. It does not try to interpret the arguments
	// but it does validate that the event is a regular
	// event with a timestamp (vs. a structural event).
	//
	// It requires that the event its reading be timed, which must
	// be the case for every event in a plain EventBatch.
	func readTimedBaseEvent(b []byte, e *baseEvent) (int, timestamp, error) {
	// Get the event type.
	typ := event.Type(b[0])
	specs := go122.Specs()
	if int(typ) > len(specs) {
	return 0, 0, fmt.Errorf("found invalid event type: %v", typ)
	}
	e.typ = typ

	// Get spec.
	spec := &specs[typ]
	if len(spec.Args) == 0 \|\| !spec.IsTimedEvent {
	return 0, 0, fmt.Errorf("found event without a timestamp: type=%v", typ)
	}
	n := 1

	// Read timestamp diff.
	ts, nb := binary.Uvarint(b[n:])
	n += nb

	// Read the rest of the arguments.
	for i := 0; i < len(spec.Args)-1; i++ {
	arg, nb := binary.Uvarint(b[n:])
	e.args[i] = arg
	n += nb
	}
	return n, timestamp(ts), nil
	}

	func heapInsert(heap []batchCursor, bc batchCursor) []*batchCursor {
	// Add the cursor to the end of the heap.
	heap = append(heap, bc)

	// Sift the new entry up to the right place.
	heapSiftUp(heap, len(heap)-1)
	return heap
	}

	func heapUpdate(heap []*batchCursor, i int) {
	// Try to sift up.
	if heapSiftUp(heap, i) != i {
	return
	}
	// Try to sift down, if sifting up failed.
	heapSiftDown(heap, i)
	}

	func heapRemove(heap []batchCursor, i int) []batchCursor {
	// Sift index i up to the root, ignoring actual values.
	for i > 0 {
	heap[(i-1)/2], heap[i] = heap[i], heap[(i-1)/2]
	i = (i - 1) / 2
	}
	// Swap the root with the last element, then remove it.
	heap[0], heap[len(heap)-1] = heap[len(heap)-1], heap[0]
	heap = heap[:len(heap)-1]
	// Sift the root down.
	heapSiftDown(heap, 0)
	return heap
	}

	func heapSiftUp(heap []*batchCursor, i int) int {
	for i > 0 && heap[(i-1)/2].ev.time > heap[i].ev.time {
	heap[(i-1)/2], heap[i] = heap[i], heap[(i-1)/2]
	i = (i - 1) / 2
	}
	return i
	}

	func heapSiftDown(heap []*batchCursor, i int) int {
	for {
	m := min3(heap, i, 2i+1, 2i+2)
	if m == i {
	// Heap invariant already applies.
	break
	}
	heap[i], heap[m] = heap[m], heap[i]
	i = m
	}
	return i
	}

	func min3(b []*batchCursor, i0, i1, i2 int) int {
	minIdx := i0
	minT := maxTime
	if i0 < len(b) {
	minT = b[i0].ev.time
	}
	if i1 < len(b) {
	if t := b[i1].ev.time; t < minT {
	minT = t
	minIdx = i1
	}
	}
	if i2 < len(b) {
	if t := b[i2].ev.time; t < minT {
	minT = t
	minIdx = i2
	}
	}
	return minIdx
	}