vendor/github.com/Shopify/sarama/partitioner.go - voltctl - Gitiles

 package sarama

 import (
 	"hash"
 	"hash/fnv"
 	"math/rand"
 	"time"
 )

 // Partitioner is anything that, given a Kafka message and a number of partitions indexed [0...numPartitions-1],
 // decides to which partition to send the message. RandomPartitioner, RoundRobinPartitioner and HashPartitioner are provided
 // as simple default implementations.
 type Partitioner interface {
 	// Partition takes a message and partition count and chooses a partition
 	Partition(message *ProducerMessage, numPartitions int32) (int32, error)

 	// RequiresConsistency indicates to the user of the partitioner whether the
 	// mapping of key->partition is consistent or not. Specifically, if a
 	// partitioner requires consistency then it must be allowed to choose from all
 	// partitions (even ones known to be unavailable), and its choice must be
 	// respected by the caller. The obvious example is the HashPartitioner.
 	RequiresConsistency() bool
 }

 // DynamicConsistencyPartitioner can optionally be implemented by Partitioners
 // in order to allow more flexibility than is originally allowed by the
 // RequiresConsistency method in the Partitioner interface. This allows
 // partitioners to require consistency sometimes, but not all times. It's useful
 // for, e.g., the HashPartitioner, which does not require consistency if the
 // message key is nil.
 type DynamicConsistencyPartitioner interface {
 	Partitioner

 	// MessageRequiresConsistency is similar to Partitioner.RequiresConsistency,
 	// but takes in the message being partitioned so that the partitioner can
 	// make a per-message determination.
 	MessageRequiresConsistency(message *ProducerMessage) bool
 }

 // PartitionerConstructor is the type for a function capable of constructing new Partitioners.
 type PartitionerConstructor func(topic string) Partitioner

 type manualPartitioner struct{}

 // HashPartitionOption lets you modify default values of the partitioner
 type HashPartitionerOption func(*hashPartitioner)

 // WithAbsFirst means that the partitioner handles absolute values
 // in the same way as the reference Java implementation
 func WithAbsFirst() HashPartitionerOption {
 	return func(hp *hashPartitioner) {
 		hp.referenceAbs = true
 	}
 }

 // WithCustomHashFunction lets you specify what hash function to use for the partitioning
 func WithCustomHashFunction(hasher func() hash.Hash32) HashPartitionerOption {
 	return func(hp *hashPartitioner) {
 		hp.hasher = hasher()
 	}
 }

 // WithCustomFallbackPartitioner lets you specify what HashPartitioner should be used in case a Distribution Key is empty
 func WithCustomFallbackPartitioner(randomHP *hashPartitioner) HashPartitionerOption {
 	return func(hp *hashPartitioner) {
 		hp.random = hp
 	}
 }

 // NewManualPartitioner returns a Partitioner which uses the partition manually set in the provided
 // ProducerMessage's Partition field as the partition to produce to.
 func NewManualPartitioner(topic string) Partitioner {
 	return new(manualPartitioner)
 }

 func (p *manualPartitioner) Partition(message *ProducerMessage, numPartitions int32) (int32, error) {
 	return message.Partition, nil
 }

 func (p *manualPartitioner) RequiresConsistency() bool {
 	return true
 }

 type randomPartitioner struct {
 	generator *rand.Rand
 }

 // NewRandomPartitioner returns a Partitioner which chooses a random partition each time.
 func NewRandomPartitioner(topic string) Partitioner {
 	p := new(randomPartitioner)
 	p.generator = rand.New(rand.NewSource(time.Now().UTC().UnixNano()))
 	return p
 }

 func (p *randomPartitioner) Partition(message *ProducerMessage, numPartitions int32) (int32, error) {
 	return int32(p.generator.Intn(int(numPartitions))), nil
 }

 func (p *randomPartitioner) RequiresConsistency() bool {
 	return false
 }

 type roundRobinPartitioner struct {
 	partition int32
 }

 // NewRoundRobinPartitioner returns a Partitioner which walks through the available partitions one at a time.
 func NewRoundRobinPartitioner(topic string) Partitioner {
 	return &roundRobinPartitioner{}
 }

 func (p *roundRobinPartitioner) Partition(message *ProducerMessage, numPartitions int32) (int32, error) {
 	if p.partition >= numPartitions {
 		p.partition = 0
 	}
 	ret := p.partition
 	p.partition++
 	return ret, nil
 }

 func (p *roundRobinPartitioner) RequiresConsistency() bool {
 	return false
 }

 type hashPartitioner struct {
 	random       Partitioner
 	hasher       hash.Hash32
 	referenceAbs bool
 }

 // NewCustomHashPartitioner is a wrapper around NewHashPartitioner, allowing the use of custom hasher.
 // The argument is a function providing the instance, implementing the hash.Hash32 interface. This is to ensure that
 // each partition dispatcher gets its own hasher, to avoid concurrency issues by sharing an instance.
 func NewCustomHashPartitioner(hasher func() hash.Hash32) PartitionerConstructor {
 	return func(topic string) Partitioner {
 		p := new(hashPartitioner)
 		p.random = NewRandomPartitioner(topic)
 		p.hasher = hasher()
 		p.referenceAbs = false
 		return p
 	}
 }

 // NewCustomPartitioner creates a default Partitioner but lets you specify the behavior of each component via options
 func NewCustomPartitioner(options ...HashPartitionerOption) PartitionerConstructor {
 	return func(topic string) Partitioner {
 		p := new(hashPartitioner)
 		p.random = NewRandomPartitioner(topic)
 		p.hasher = fnv.New32a()
 		p.referenceAbs = false
 		for _, option := range options {
 			option(p)
 		}
 		return p
 	}
 }

 // NewHashPartitioner returns a Partitioner which behaves as follows. If the message's key is nil then a
 // random partition is chosen. Otherwise the FNV-1a hash of the encoded bytes of the message key is used,
 // modulus the number of partitions. This ensures that messages with the same key always end up on the
 // same partition.
 func NewHashPartitioner(topic string) Partitioner {
 	p := new(hashPartitioner)
 	p.random = NewRandomPartitioner(topic)
 	p.hasher = fnv.New32a()
 	p.referenceAbs = false
 	return p
 }

 // NewReferenceHashPartitioner is like NewHashPartitioner except that it handles absolute values
 // in the same way as the reference Java implementation. NewHashPartitioner was supposed to do
 // that but it had a mistake and now there are people depending on both behaviours. This will
 // all go away on the next major version bump.
 func NewReferenceHashPartitioner(topic string) Partitioner {
 	p := new(hashPartitioner)
 	p.random = NewRandomPartitioner(topic)
 	p.hasher = fnv.New32a()
 	p.referenceAbs = true
 	return p
 }

 func (p *hashPartitioner) Partition(message *ProducerMessage, numPartitions int32) (int32, error) {
 	if message.Key == nil {
 		return p.random.Partition(message, numPartitions)
 	}
 	bytes, err := message.Key.Encode()
 	if err != nil {
 		return -1, err
 	}
 	p.hasher.Reset()
 	_, err = p.hasher.Write(bytes)
 	if err != nil {
 		return -1, err
 	}
 	var partition int32
 	// Turns out we were doing our absolute value in a subtly different way from the upstream
 	// implementation, but now we need to maintain backwards compat for people who started using
 	// the old version; if referenceAbs is set we are compatible with the reference java client
 	// but not past Sarama versions
 	if p.referenceAbs {
 		partition = (int32(p.hasher.Sum32()) & 0x7fffffff) % numPartitions
 	} else {
 		partition = int32(p.hasher.Sum32()) % numPartitions
 		if partition < 0 {
 			partition = -partition
 		}
 	}
 	return partition, nil
 }

 func (p *hashPartitioner) RequiresConsistency() bool {
 	return true
 }

 func (p *hashPartitioner) MessageRequiresConsistency(message *ProducerMessage) bool {
 	return message.Key != nil
 }
	package sarama

	import (
	"hash"
	"hash/fnv"
	"math/rand"
	"time"
	)

	// Partitioner is anything that, given a Kafka message and a number of partitions indexed [0...numPartitions-1],
	// decides to which partition to send the message. RandomPartitioner, RoundRobinPartitioner and HashPartitioner are provided
	// as simple default implementations.
	type Partitioner interface {
	// Partition takes a message and partition count and chooses a partition
	Partition(message *ProducerMessage, numPartitions int32) (int32, error)

	// RequiresConsistency indicates to the user of the partitioner whether the
	// mapping of key->partition is consistent or not. Specifically, if a
	// partitioner requires consistency then it must be allowed to choose from all
	// partitions (even ones known to be unavailable), and its choice must be
	// respected by the caller. The obvious example is the HashPartitioner.
	RequiresConsistency() bool
	}

	// DynamicConsistencyPartitioner can optionally be implemented by Partitioners
	// in order to allow more flexibility than is originally allowed by the
	// RequiresConsistency method in the Partitioner interface. This allows
	// partitioners to require consistency sometimes, but not all times. It's useful
	// for, e.g., the HashPartitioner, which does not require consistency if the
	// message key is nil.
	type DynamicConsistencyPartitioner interface {
	Partitioner

	// MessageRequiresConsistency is similar to Partitioner.RequiresConsistency,
	// but takes in the message being partitioned so that the partitioner can
	// make a per-message determination.
	MessageRequiresConsistency(message *ProducerMessage) bool
	}

	// PartitionerConstructor is the type for a function capable of constructing new Partitioners.
	type PartitionerConstructor func(topic string) Partitioner

	type manualPartitioner struct{}

	// HashPartitionOption lets you modify default values of the partitioner
	type HashPartitionerOption func(*hashPartitioner)

	// WithAbsFirst means that the partitioner handles absolute values
	// in the same way as the reference Java implementation
	func WithAbsFirst() HashPartitionerOption {
	return func(hp *hashPartitioner) {
	hp.referenceAbs = true
	}
	}

	// WithCustomHashFunction lets you specify what hash function to use for the partitioning
	func WithCustomHashFunction(hasher func() hash.Hash32) HashPartitionerOption {
	return func(hp *hashPartitioner) {
	hp.hasher = hasher()
	}
	}

	// WithCustomFallbackPartitioner lets you specify what HashPartitioner should be used in case a Distribution Key is empty
	func WithCustomFallbackPartitioner(randomHP *hashPartitioner) HashPartitionerOption {
	return func(hp *hashPartitioner) {
	hp.random = hp
	}
	}

	// NewManualPartitioner returns a Partitioner which uses the partition manually set in the provided
	// ProducerMessage's Partition field as the partition to produce to.
	func NewManualPartitioner(topic string) Partitioner {
	return new(manualPartitioner)
	}

	func (p manualPartitioner) Partition(message ProducerMessage, numPartitions int32) (int32, error) {
	return message.Partition, nil
	}

	func (p *manualPartitioner) RequiresConsistency() bool {
	return true
	}

	type randomPartitioner struct {
	generator *rand.Rand
	}

	// NewRandomPartitioner returns a Partitioner which chooses a random partition each time.
	func NewRandomPartitioner(topic string) Partitioner {
	p := new(randomPartitioner)
	p.generator = rand.New(rand.NewSource(time.Now().UTC().UnixNano()))
	return p
	}

	func (p randomPartitioner) Partition(message ProducerMessage, numPartitions int32) (int32, error) {
	return int32(p.generator.Intn(int(numPartitions))), nil
	}

	func (p *randomPartitioner) RequiresConsistency() bool {
	return false
	}

	type roundRobinPartitioner struct {
	partition int32
	}

	// NewRoundRobinPartitioner returns a Partitioner which walks through the available partitions one at a time.
	func NewRoundRobinPartitioner(topic string) Partitioner {
	return &roundRobinPartitioner{}
	}

	func (p roundRobinPartitioner) Partition(message ProducerMessage, numPartitions int32) (int32, error) {
	if p.partition >= numPartitions {
	p.partition = 0
	}
	ret := p.partition
	p.partition++
	return ret, nil
	}

	func (p *roundRobinPartitioner) RequiresConsistency() bool {
	return false
	}

	type hashPartitioner struct {
	random Partitioner
	hasher hash.Hash32
	referenceAbs bool
	}

	// NewCustomHashPartitioner is a wrapper around NewHashPartitioner, allowing the use of custom hasher.
	// The argument is a function providing the instance, implementing the hash.Hash32 interface. This is to ensure that
	// each partition dispatcher gets its own hasher, to avoid concurrency issues by sharing an instance.
	func NewCustomHashPartitioner(hasher func() hash.Hash32) PartitionerConstructor {
	return func(topic string) Partitioner {
	p := new(hashPartitioner)
	p.random = NewRandomPartitioner(topic)
	p.hasher = hasher()
	p.referenceAbs = false
	return p
	}
	}

	// NewCustomPartitioner creates a default Partitioner but lets you specify the behavior of each component via options
	func NewCustomPartitioner(options ...HashPartitionerOption) PartitionerConstructor {
	return func(topic string) Partitioner {
	p := new(hashPartitioner)
	p.random = NewRandomPartitioner(topic)
	p.hasher = fnv.New32a()
	p.referenceAbs = false
	for _, option := range options {
	option(p)
	}
	return p
	}
	}

	// NewHashPartitioner returns a Partitioner which behaves as follows. If the message's key is nil then a
	// random partition is chosen. Otherwise the FNV-1a hash of the encoded bytes of the message key is used,
	// modulus the number of partitions. This ensures that messages with the same key always end up on the
	// same partition.
	func NewHashPartitioner(topic string) Partitioner {
	p := new(hashPartitioner)
	p.random = NewRandomPartitioner(topic)
	p.hasher = fnv.New32a()
	p.referenceAbs = false
	return p
	}

	// NewReferenceHashPartitioner is like NewHashPartitioner except that it handles absolute values
	// in the same way as the reference Java implementation. NewHashPartitioner was supposed to do
	// that but it had a mistake and now there are people depending on both behaviours. This will
	// all go away on the next major version bump.
	func NewReferenceHashPartitioner(topic string) Partitioner {
	p := new(hashPartitioner)
	p.random = NewRandomPartitioner(topic)
	p.hasher = fnv.New32a()
	p.referenceAbs = true
	return p
	}

	func (p hashPartitioner) Partition(message ProducerMessage, numPartitions int32) (int32, error) {
	if message.Key == nil {
	return p.random.Partition(message, numPartitions)
	}
	bytes, err := message.Key.Encode()
	if err != nil {
	return -1, err
	}
	p.hasher.Reset()
	_, err = p.hasher.Write(bytes)
	if err != nil {
	return -1, err
	}
	var partition int32
	// Turns out we were doing our absolute value in a subtly different way from the upstream
	// implementation, but now we need to maintain backwards compat for people who started using
	// the old version; if referenceAbs is set we are compatible with the reference java client
	// but not past Sarama versions
	if p.referenceAbs {
	partition = (int32(p.hasher.Sum32()) & 0x7fffffff) % numPartitions
	} else {
	partition = int32(p.hasher.Sum32()) % numPartitions
	if partition < 0 {
	partition = -partition
	}
	}
	return partition, nil
	}

	func (p *hashPartitioner) RequiresConsistency() bool {
	return true
	}

	func (p hashPartitioner) MessageRequiresConsistency(message ProducerMessage) bool {
	return message.Key != nil
	}