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com.johnsnowlabs.ml.ai.t5.T5EncoderDecoder.scala Maven / Gradle / Ivy
package com.johnsnowlabs.ml.ai.t5
import com.johnsnowlabs.ml.tensorflow.sentencepiece.SentencePieceWrapper
import com.johnsnowlabs.nlp.{Annotation, AnnotatorType}
import scala.collection.mutable
import scala.math.exp
abstract class T5EncoderDecoder(
val spp: SentencePieceWrapper,
val additionalTokens: Map[Int, String] = Map()) {
protected val paddingTokenId = 0
protected val eosTokenId = 1
protected val pieceSize: Int = spp.getSppModel.getPieceSize
protected val vocabSize = 32128
def sessionWarmup(): Unit = {
val dummyInput = Array.fill(1)(0) ++ Array(eosTokenId)
tag(
Seq(dummyInput),
maxNewTokens = 1,
maxTextLength = 1,
doSample = false,
temperature = 0f,
topK = 0,
topP = 0f,
repetitionPenalty = 0f,
noRepeatNgramSize = 0,
randomSeed = Option(0L),
stopAtEos = true,
ignoreTokenIds = Array(0))
}
protected def decode(sentences: Array[Array[Int]]): Seq[String] = {
sentences.map { s =>
val filteredPieceIds = s.filter(x => x <= pieceSize || additionalTokens.contains(x))
val additionalTokenPositions =
filteredPieceIds.zipWithIndex.filter(x => additionalTokens.contains(x._1)).map(_._2)
val decodedStrings = if (additionalTokenPositions.nonEmpty) {
var offset = 0
additionalTokenPositions.map(i => {
val slice = spp.getSppModel.decodeIds(
filteredPieceIds.slice(offset, i).map(_.toInt): _*) + additionalTokens(
filteredPieceIds(i))
offset = i + 1
slice
}) ++ Array(
spp.getSppModel.decodeIds(
filteredPieceIds.slice(offset, filteredPieceIds.length).map(_.toInt): _*))
} else {
Array(spp.getSppModel.decodeIds(filteredPieceIds.map(_.toInt): _*))
}
decodedStrings.mkString("")
}
}
protected def encode(sentences: Seq[Annotation], task: String): Seq[Array[Int]] = {
sentences.map(s => {
val sentWithTask = if (task.nonEmpty) task.concat(" ").concat(s.result) else s.result
spp.getSppModel.encodeAsIds(sentWithTask) ++ Array(this.eosTokenId)
})
}
protected def encodeS(sentences: Seq[String], task: String): Seq[Array[Int]] = {
sentences.map(s => {
val sentWithTask = if (task.nonEmpty) task.concat(" ").concat(s) else s
spp.getSppModel.encodeAsIds(sentWithTask) ++ Array(this.eosTokenId)
})
}
protected def getGeneratedNgrams(
prevInputIds: Seq[Array[Int]],
generatedNgrams: Array[mutable.Map[IndexedSeq[Int], List[Int]]],
hypoIdx: Int,
curLen: Int,
noRepeatNgramSize: Int): Array[Int] = {
// Before decoding the next token, prevent decoding of ngrams that have already appeared
val startIdx = curLen + 1 - noRepeatNgramSize
val ngramIdx = prevInputIds(hypoIdx).slice(startIdx, curLen)
generatedNgrams(hypoIdx).getOrElse(ngramIdx, List.empty[Int]).toArray
}
protected def setTensorByIndicesToValue(
prevInputIds: Array[Float],
indices: IndexedSeq[Boolean],
value: Float): Array[Float] = {
for ((inputId, index) <- prevInputIds.zip(indices)) yield if (index) value else inputId
}
protected def calcBannedNgramTokens(
prevInputIds: Seq[Array[Int]],
numHypos: Int,
noRepeatNgramSize: Int,
curLen: Int): Array[Array[Int]] = {
// based on fairseq for noRepeatNgram in beam_search
if (curLen + 1 < noRepeatNgramSize)
// return no banned tokens if we haven't generated noRepeatNgram_size tokens yet
return Array.ofDim[Int](numHypos, 0)
val generatedNgrams =
Array.tabulate(numHypos)(_ => mutable.Map.empty[IndexedSeq[Int], List[Int]])
for (idx <- 0 until numHypos) {
val genTokens = prevInputIds(idx)
val generatedNgram = generatedNgrams(idx)
val ngramArrays = for (e <- 0 until noRepeatNgramSize) yield genTokens.drop(e)
for (ngramInd <- ngramArrays.last.indices) {
val ngram = for (e <- ngramArrays) yield e(ngramInd)
val prevNgramTuple = ngram.dropRight(1)
generatedNgram(prevNgramTuple) =
generatedNgram.getOrElse(prevNgramTuple, List.empty[Int]) :+ ngram.last
}
}
(for (hypoIdx <- 0 until numHypos)
yield getGeneratedNgrams(
prevInputIds,
generatedNgrams,
hypoIdx,
curLen,
noRepeatNgramSize)).toArray
}
protected def tag(
batch: Seq[Array[Int]],
maxNewTokens: Int,
maxTextLength: Int,
doSample: Boolean,
topK: Int,
topP: Double,
temperature: Double,
noRepeatNgramSize: Int,
repetitionPenalty: Double,
randomSeed: Option[Long],
ignoreTokenIds: Array[Int] = Array(),
stopAtEos: Boolean): Array[Array[Int]]
def predict(
sentences: Seq[Annotation],
task: String,
batchSize: Int,
maxNewTokens: Int,
maxTextLength: Int,
doSample: Boolean,
topK: Int,
topP: Double,
temperature: Double,
randomSeed: Option[Long] = None,
ignoreTokenIds: Array[Int] = Array(),
isCaseSensitive: Boolean,
stopAtEos: Boolean,
noRepeatNgramSize: Int,
repetitionPenalty: Double): Seq[Annotation] = {
val batchDecoder = sentences.grouped(batchSize).toArray.flatMap { batch =>
val batchSP = encode(batch, task)
val spIds = tag(
batch = batchSP,
maxNewTokens = maxNewTokens,
maxTextLength = maxTextLength,
doSample = doSample,
topK = topK,
topP = topP,
temperature = temperature,
randomSeed = randomSeed,
ignoreTokenIds = ignoreTokenIds,
stopAtEos = stopAtEos,
noRepeatNgramSize = noRepeatNgramSize,
repetitionPenalty = repetitionPenalty)
decode(spIds)
}
var sentBegin, nextSentEnd = 0
batchDecoder.zip(sentences).map { case (content, sent) =>
nextSentEnd += content.length - 1
val newAnnotation = new Annotation(
annotatorType = AnnotatorType.DOCUMENT,
begin = sentBegin,
end = nextSentEnd,
result = content,
metadata = sent.metadata)
sentBegin += nextSentEnd + 1
newAnnotation
}
}
def generate(
prompts: Seq[Annotation],
batchSize: Int,
maxNewTokens: Int,
maxContextLength: Int,
doSample: Boolean,
topK: Int,
topP: Double,
temperature: Double,
randomSeed: Option[Long],
ignoreTokenIds: Array[Int],
isCaseSensitive: Boolean,
stopAtEos: Boolean,
noRepeatNgramSize: Int,
repetitionPenalty: Double): Seq[Annotation] = {
predict(
sentences = prompts,
task = "",
batchSize = batchSize,
maxNewTokens = maxNewTokens,
maxTextLength = maxContextLength,
doSample = doSample,
topK = topK,
topP = topP,
temperature = temperature,
randomSeed = randomSeed,
ignoreTokenIds = ignoreTokenIds,
isCaseSensitive = isCaseSensitive,
stopAtEos = stopAtEos,
noRepeatNgramSize = noRepeatNgramSize,
repetitionPenalty = repetitionPenalty)
}
class DecoderProcessor(
val batchSize: Int,
val maxTextLength: Int,
val sequenceLength: Int,
val doSample: Boolean,
val topK: Int,
val topP: Double,
val temperature: Double,
val vocabSize: Int,
val noRepeatNgramSize: Int,
val repetitionPenalty: Double,
val randomSeed: Option[Long],
val stopTokens: Array[Int],
val ignoreTokenIds: Array[Int],
val maxNewTokens: Int) {
var unfinishedSentences: List[Int] = List.fill(batchSize)(1)
var sentenceLengths: List[Int] = List.fill(batchSize)(maxTextLength)
var currentLength = sequenceLength
var nPredictedTokens = 0
def stopDecoding(decoderInputIds: Array[Array[Int]]): Boolean = {
// stop when there is a eos in each sentence, or if we exceed the maximum length
// stopDecoder = curLen < maxOutputLength || unfinishedSents.max == 0
(decoderInputIds.forall(o => o exists (t => stopTokens.contains(t)))
|| (nPredictedTokens >= maxNewTokens)
|| (decoderInputIds.head.length > maxTextLength))
}
def stopDecoding(decoderInputIds: Array[Array[Long]]): Boolean = {
stopDecoding(decoderInputIds.map(x => x.map(_.toInt)))
}
def processLogits(
batchLogits: Array[Array[Float]],
decoderInputIds: Array[Array[Long]]): Array[Array[Long]] = {
processLogits(batchLogits, decoderInputIds.map(x => x.map(_.toInt))).map(x =>
x.map(_.toLong))
}
def createNextTokenLogitsPenalties(
inputIds: Seq[Array[Int]],
logits: Array[Array[Float]],
repetitionPenalty: Double): Array[Array[Float]] = {
// create logit penalties for already seen inputIds
val nextTokenLogits = Array.ofDim[Array[Float]](logits.length)
for (i <- logits.indices) {
var nextTokenLogit = logits(i)
val prevInputIds = inputIds.head.distinct
for ((prevInputId, _) <- prevInputIds.zipWithIndex) {
var logitPenalty = 1.0
if (logits(i)(prevInputId) < 0) {
logitPenalty = repetitionPenalty
} else {
logitPenalty = 1 / repetitionPenalty
}
nextTokenLogit = nextTokenLogit.updated(
prevInputId,
(logitPenalty * nextTokenLogit(prevInputId)).toFloat)
}
nextTokenLogits(i) = nextTokenLogit
}
nextTokenLogits
}
private def softmax(values: Array[Float]): Array[Float] = {
val expElem = values.map(exp(_))
val total = expElem.sum
expElem.map(_ / total).map(_.toFloat)
}
private def categoricalSample(dist: Array[Float], randomSeed: Option[Long]): Int = {
val (distFiltered, indices) =
dist.zipWithIndex.filter { case (elem, index) => !elem.isInfinite }.sorted.unzip
if (distFiltered.length == 1)
return indices(0)
// val distMinValue = distFiltered.min
// val distRange = distFiltered.max - distMinValue
// val normalized = distFiltered.map(i => (i - distMinValue)/distRange)
val normalized = softmax(distFiltered)
var randomDouble = 0.0
if (randomSeed.isDefined)
randomDouble = new scala.util.Random(randomSeed.get).nextDouble()
else
randomDouble = scala.util.Random.nextDouble()
var accum = 0.0
for ((itemProb, i) <- normalized.zip(indices)) {
accum += itemProb
if (accum >= randomDouble) {
return i
}
}
indices(0)
}
private def scanLeft[a, b](xs: Iterable[a])(s: b)(f: (b, a) => b) =
xs.foldLeft(List(s))((acc, x) => f(acc.head, x) :: acc).reverse
private def scatterValuesOnBatchIndices(
values: List[Boolean],
batchIndices: Array[Int]): List[Boolean] = {
// scatter values to pair indices
val (_, initArray) = batchIndices.zip(values).sorted.unzip
initArray.toList
}
private def topKTopPFiltering(
logits: Array[Array[Float]],
topK: Int,
topP: Double,
filterValue: Float = Float.NegativeInfinity,
minTokensToKeep: Int = 1): Array[Array[Float]] = {
/** Filter a distribution of logits using top-k and/or nucleus (top-p) filtering * Args:
* logits: logits distribution shape (batch size, vocabulary size) if topK > 0: keep only
* top k tokens with highest probability (top-k filtering). if topP < 1.0: keep the top
* tokens with cumulative probability >= topP (nucleus filtering). Nucleus filtering is
* described in Holtzman et al. (http://arxiv.org/abs/1904.09751) Make sure we keep at
* least minTokensToKeep per batch example in the output From:
* https://gist.github.com/thomwolf/1a5a29f6962089e871b94cbd09daf317
*/
var logitsUpd = logits
val logitsShape = Array(logits.length, logits(0).length)
if (topK > 0) {
val topKup = topK.max(minTokensToKeep).min(logitsShape.last) // Safety check
/** Remove all tokens with a probability less than the last token of the top-k */
val removeLimit = logits(0).sortWith(_ > _).take(topKup).min
val indicesToRemove =
for (logit <- logits)
yield for (elem <- logit) yield if (elem < removeLimit) true else false
logitsUpd =
for ((nextTokenLogit, indexToRemove) <- logits.zip(indicesToRemove))
yield setTensorByIndicesToValue(nextTokenLogit, indexToRemove, Float.NegativeInfinity)
}
if (topP < 1.0) {
val (sortedLogits, sortedIndices) = logits(0).zipWithIndex.sorted.reverse.unzip
val cumulativeProbs = scanLeft(softmax(sortedLogits))(0.0)(_ + _).drop(1)
/** Remove tokens with cumulative probability above the threshold (token with 0 are kept)
*/
var sortedIndicesToRemove =
for (prob <- cumulativeProbs)
yield if (prob > topP) true else false
if (minTokensToKeep > 1) {
/** Keep at least minTokensToKeep (set to minTokensToKeep-1 because we add the first one
* below)
*/
sortedIndicesToRemove = List.fill(sortedIndicesToRemove.take(minTokensToKeep).length)(
false) ++ sortedIndicesToRemove.drop(minTokensToKeep)
}
/** Shift the indices to the right to keep also the first token above the threshold */
sortedIndicesToRemove = sortedIndicesToRemove.takeRight(1) ++ sortedIndicesToRemove
.dropRight(1)
sortedIndicesToRemove =
List.fill(sortedIndicesToRemove.take(1).length)(false) ++ sortedIndicesToRemove
.drop(1)
/** scatter sorted tensors to original indexing */
val indicesToRemove = scatterValuesOnBatchIndices(sortedIndicesToRemove, sortedIndices)
logitsUpd =
for ((nextTokenLogit, indexToRemove) <- logits.zip(
IndexedSeq.fill(logits.length)(indicesToRemove)))
yield setTensorByIndicesToValue(
nextTokenLogit,
indexToRemove.toIndexedSeq,
Float.NegativeInfinity)
}
logitsUpd
}
def processLogits(
batchLogits: Array[Array[Float]],
decoderInputIds: Array[Array[Int]]): Array[Array[Int]] = {
nPredictedTokens += 1
var nextTokenLogits = batchLogits.map(logits => {
logits.indices
.map(i => {
if (ignoreTokenIds.contains(i)) Float.NegativeInfinity else logits(i)
})
.toArray
})
// repetition penalty from CTRL paper (https://arxiv.org/abs/1909.05858)
if (repetitionPenalty != 1.0) {
nextTokenLogits =
createNextTokenLogitsPenalties(decoderInputIds, nextTokenLogits, repetitionPenalty)
}
if (noRepeatNgramSize > 0) {
// calculate a list of banned tokens to prevent repetitively generating the same ngrams
// from fairseq: https://github.com/pytorch/fairseq/blob/a07cb6f40480928c9e0548b737aadd36ee66ac76/fairseq/sequence_generator.py#L345
val bannedTokens =
calcBannedNgramTokens(decoderInputIds, batchSize, noRepeatNgramSize, currentLength)
// create bannedTokens boolean mask
var bannedTokensIndicesMask = Array.empty[IndexedSeq[Boolean]]
for (bannedTokensSlice <- bannedTokens) {
bannedTokensIndicesMask = bannedTokensIndicesMask :+
(for (token <- 0 until vocabSize)
yield if (bannedTokensSlice.contains(token)) true else false)
}
if (!bannedTokensIndicesMask.isEmpty) {
nextTokenLogits =
for ((nextTokenLogit, bannedTokensIndexMask) <- nextTokenLogits.zip(
bannedTokensIndicesMask))
yield setTensorByIndicesToValue(
nextTokenLogit,
bannedTokensIndexMask,
Float.NegativeInfinity)
}
}
if (randomSeed.isDefined)
scala.util.Random.setSeed(randomSeed.get)
val predictions = if (doSample) {
// Temperature (higher temperature => more likely to sample low probability tokens)
if (temperature != 1.0)
nextTokenLogits =
for (nextTokenLogit <- nextTokenLogits)
yield nextTokenLogit.map(_ / temperature.toFloat)
// Top-p/top-k filtering
nextTokenLogits = topKTopPFiltering(nextTokenLogits, topK, topP)
// Sample
nextTokenLogits.map(input => categoricalSample(input, randomSeed))
} else {
nextTokenLogits.map(x => x.zipWithIndex.maxBy(_._1)._2)
}
// var tokensToAdd = Array.ofDim[Int](decoderInputIds.length)
val tokensToAdd =
predictions.zip(unfinishedSentences).map(x => x._1 * x._2 + paddingTokenId * (1 - x._2))
currentLength += 1
val eosInSentences = tokensToAdd.map(x => if (stopTokens.contains(x)) 1 else 0)
// if sentence is unfinished and the token to add is eos, sent_lengths is filled with current length
val areSentencesUnfinishedAndTokenToAddIsEos =
unfinishedSentences.zip(eosInSentences).map(x => x._1 * x._2)
sentenceLengths = sentenceLengths
.zip(areSentencesUnfinishedAndTokenToAddIsEos)
.map(x => x._1 * (1 - x._2) + currentLength * x._2)
// unfinishedSents is set to zero if eos in sentence
unfinishedSentences =
unfinishedSentences.zip(areSentencesUnfinishedAndTokenToAddIsEos).map(x => x._1 - x._2)
decoderInputIds
.zip(tokensToAdd)
.map(x => {
x._1 ++ Array(x._2)
})
}
}
}