--- title: Generating Random Poems with Python layout: post image: /img/blog/buzzfeed.jpg --- In this post, I will demonstrate how to generate random text using a few lines of standard python and then progressively refine the output until it looks poem-like. If you would like to follow along with this post and run the code snippets yourself, you can clone [my NLP repository](https://github.com/thallada/nlp/) and run [the Jupyter notebook](https://github.com/thallada/nlp/blob/master/edX%20Lightning%20Talk.ipynb). You might not realize it, but you probably use an app everyday that can generate random text that sounds like you: your phone keyboard. ![Suggested next words UI feature on the iOS keyboard](/img/blog/phone_keyboard.jpg) Just by tapping the next suggested word over and over, you can generate text. So how does it work? ## Corpus First, we need a **corpus**: the text our generator will recombine into new sentences. In the case of your phone keyboard, this is all the text you've ever typed into your keyboard. For our example, let's just start with one sentence: ```python corpus = 'The quick brown fox jumps over the lazy dog' ``` ## Tokenization Now we need to split this corpus into individual **tokens** that we can operate on. Since our objective is to eventually predict the next word from the previous word, we will want our tokens to be individual words. This process is called **tokenization**. The simplest way to tokenize a sentence into words is to split on spaces: ```python words = corpus.split(' ') words ``` ```python ['The', 'quick', 'brown', 'fox', 'jumps', 'over', 'the', 'lazy', 'dog'] ``` ## Bigrams Now, we will want to create **bigrams**. A bigram is a pair of two words that are in the order they appear in the corpus. To create bigrams, we will iterate through the list of the words with two indices, one of which is offset by one: ```python bigrams = [b for b in zip(words[:-1], words[1:])] bigrams ``` ```python [('The', 'quick'), ('quick', 'brown'), ('brown', 'fox'), ('fox', 'jumps'), ('jumps', 'over'), ('over', 'the'), ('the', 'lazy'), ('lazy', 'dog')] ``` How do we use the bigrams to predict the next word given the first word? Return every second element where the first element matches the **condition**: ```python condition = 'the' next_words = [bigram[1] for bigram in bigrams if bigram[0].lower() == condition] next_words ``` ```python ['quick', 'lazy'] ``` We have now found all of the possible words that can follow the condition "the" according to our corpus: "quick" and "lazy".
(The quick) (quick brown) ... (the lazy) (lazy dog)Either "quick" or "lazy" could be the next word. ## Trigrams and N-grams We can partition our corpus into groups of threes too:
(The quick brown) (quick brown fox) ... (the lazy dog)Or, the condition can be two words (`condition = 'the lazy'`):
(The quick brown) (quick brown fox) ... (the lazy dog)These are called **trigrams**. We can partition any **N** number of words together as **n-grams**. ## Conditional Frequency Distributions Earlier, we were able to compute the list of possible words to follow a condition: ```python next_words ``` ```python ['quick', 'lazy'] ``` But, in order to predict the next word, what we really want to compute is what is the most likely next word out of all of the possible next words. In other words, find the word that occurred the most often after the condition in the corpus. We can use a **Conditional Frequency Distribution (CFD)** to figure that out! A **CFD** can tell us: given a **condition**, what is **likelihood** of each possible outcome. This is an example of a CFD with two conditions, displayed in table form. It is counting words appearing in a text collection (source: nltk.org). ![Two tables, one for each condition: "News" and "Romance". The first column of each table is 5 words: "the", "cute", "Monday", "could", and "will". The second column is a tally of how often the word at the start of the row appears in the corpus.](http://www.nltk.org/images/tally2.png) Let's change up our corpus a little to better demonstrate the CFD: ```python words = ('The quick brown fox jumped over the ' 'lazy dog and the quick cat').split(' ') print words ``` ```python ['The', 'quick', 'brown', 'fox', 'jumped', 'over', 'the', 'lazy', 'dog', 'and', 'the', 'quick', 'cat'] ``` Now, let's build the CFD. I use [`defaultdicts`](https://docs.python.org/2/library/collections.html#defaultdict-objects) to avoid having to initialize every new dict. ```python from collections import defaultdict cfd = defaultdict(lambda: defaultdict(lambda: 0)) for i in range(len(words) - 2): # loop to the next-to-last word cfd[words[i].lower()][words[i+1].lower()] += 1 # pretty print the defaultdict {k: dict(v) for k, v in dict(cfd).items()} ``` ```python {'and': {'the': 1}, 'brown': {'fox': 1}, 'dog': {'and': 1}, 'fox': {'jumped': 1}, 'jumped': {'over': 1}, 'lazy': {'dog': 1}, 'over': {'the': 1}, 'quick': {'brown': 1}, 'the': {'lazy': 1, 'quick': 2}} ``` So, what's the most likely word to follow `'the'`? ```python max(cfd['the']) ``` ```python 'quick' ``` Whole sentences can be the conditions and values too. Which is basically the way [cleverbot](http://www.cleverbot.com/) works. ![An example of a conversation with Cleverbot](/img/blog/cleverbot.jpg) ## Random Text Lets put this all together, and with a little help from [nltk](http://www.nltk.org/) generate some random text. ```python import nltk import random TEXT = nltk.corpus.gutenberg.words('austen-emma.txt') # NLTK shortcuts :) bigrams = nltk.bigrams(TEXT) cfd = nltk.ConditionalFreqDist(bigrams) # pick a random word from the corpus to start with word = random.choice(TEXT) # generate 15 more words for i in range(15): print word, if word in cfd: word = random.choice(cfd[word].keys()) else: break ``` Which outputs something like: ``` her reserve and concealment towards some feelings in moving slowly together . You will shew ``` Great! This is basically what the phone keyboard suggestions are doing. Now how do we take this to the next level and generate text that looks like a poem? ## Random Poems Generating random poems is accomplished by limiting the choice of the next word by some constraint: * words that rhyme with the previous line * words that match a certain syllable count * words that alliterate with words on the same line * etc. ## Rhyming ### Written English != Spoken English English has a highly **nonphonemic orthography**, meaning that the letters often have no correspondence to the pronunciation. E.g.: > "meet" vs. "meat" The vowels are spelled differently, yet they rhyme [^1]. So if the spelling of the words is useless in telling us if two words rhyme, what can we use instead? ### International Phonetic Alphabet (IPA) The IPA is an alphabet that can represent all varieties of human pronunciation. * meet: /mit/ * meat: /mit/ Note that this is only the IPA transcription for only one **accent** of English. Some English speakers may pronounce these words differently which could be represented by a different IPA transcription. ## Syllables How can we determine the number of syllables in a word? Let's consider the two words "poet" and "does": * "poet" = 2 syllables * "does" = 1 syllable The vowels in these two words are written the same, but are pronounced differently with a different number of syllables. Can the IPA tell us the number of syllables in a word too? * poet: /ˈpoʊət/ * does: /ˈdʌz/ Not really... We cannot easily identify the number of syllables from those transcriptions. Sometimes the transcriber denotes syllable breaks with a `.` or a `'`, but sometimes they don't. ### Arpabet The Arpabet is a phonetic alphabet developed by ARPA in the 70s that: * Encodes phonemes specific to American English. * Meant to be a machine readable code. It is ASCII only. * Denotes how stressed every vowel is from 0-2. This is perfect! Because of that third bullet, a word's syllable count equals the number of digits in the Arpabet encoding. ### CMU Pronouncing Dictionary (CMUdict) A large open source dictionary of English words to North American pronunciations in Arpanet encoding. Conveniently, it is also in NLTK... ### Counting Syllables ```python import string from nltk.corpus import cmudict cmu = cmudict.dict() def count_syllables(word): lower_word = word.lower() if lower_word in cmu: return max([len([y for y in x if y[-1] in string.digits]) for x in cmu[lower_word]]) print("poet: {}\ndoes: {}".format(count_syllables("poet"), count_syllables("does"))) ``` Results in: ``` poet: 2 does: 1 ``` ## Buzzfeed Haiku Generator To see this in action, try out a haiku generator I created that uses Buzzfeed article titles as a corpus. It does not incorporate rhyming, it just counts the syllables to make sure it's [5-7-5](https://en.wikipedia.org/wiki/Haiku). You can view the full code [here](https://github.com/thallada/nlp/blob/master/generate_poem.py). ![Buzzfeed Haiku Generator](/img/blog/buzzfeed.jpg) Run it live at: [http://mule.hallada.net/nlp/buzzfeed-haiku-generator/](http://mule.hallada.net/nlp/buzzfeed-haiku-generator/) ## Syntax-aware Generation Remember these? ![Example Mad Libs: "A Visit to the Dentist"](/img/blog/madlibs.jpg) Mad Libs worked so well because they forced the random words (chosen by the players) to fit into the syntactical structure and parts-of-speech of an existing sentence. You end up with **syntactically** correct sentences that are **semantically** random. We can do the same thing! ### NLTK Syntax Trees! NLTK can parse any sentence into a [syntax tree](http://www.nltk.org/book/ch08.html). We can utilize this syntax tree during poetry generation. ```python from stat_parser import Parser parsed = Parser().parse('The quick brown fox jumps over the lazy dog.') print parsed ``` Syntax tree output as an [s-expression](https://en.wikipedia.org/wiki/S-expression): ``` (S (NP (DT the) (NN quick)) (VP (VB brown) (NP (NP (JJ fox) (NN jumps)) (PP (IN over) (NP (DT the) (JJ lazy) (NN dog))))) (. .)) ``` ```python parsed.pretty_print() ``` And the same tree visually pretty printed in ASCII: ``` S ________________________|__________________________ | VP | | ____|_____________ | | | NP | | | _________|________ | | | | PP | | | | ________|___ | NP | NP | NP | ___|____ | ___|____ | _______|____ | DT NN VB JJ NN IN DT JJ NN . | | | | | | | | | | the quick brown fox jumps over the lazy dog . ``` NLTK also performs [part-of-speech tagging](http://www.nltk.org/book/ch05.html) on the input sentence and outputs the tag at each node in the tree. Here's what each of those mean: |**S** | Sentence | |**VP** | Verb Phrase | |**NP** | Noun Phrase | |**DT** | Determiner | |**NN** | Noun (common, singular) | |**VB** | Verb (base form) | |**JJ** | Adjective (or numeral, ordinal) | |**.** | Punctuation | Now, let's use this information to swap matching syntax sub-trees between two corpora ([source for the generate function](https://github.com/thallada/nlp/blob/master/syntax_aware_generate.py)). ```python from syntax_aware_generate import generate # inserts matching syntax subtrees from trump.txt into # trees from austen-emma.txt generate('trump.txt', word_limit=10) ``` ``` (SBARQ (SQ (NP (PRP I)) (VP (VBP do) (RB not) (VB advise) (NP (DT the) (NN custard)))) (. .)) I do not advise the custard . ============================== I do n't want the drone ! (SBARQ (SQ (NP (PRP I)) (VP (VBP do) (RB n't) (VB want) (NP (DT the) (NN drone)))) (. !)) ``` Above the line is a sentence selected from a corpus of Jane Austen's *Emma*. Below it is a sentence generated by walking down the syntax tree and finding sub-trees from a corpus of Trump's tweets that match the same syntactical structure and then swapping the words in. The result can sometimes be amusing, but more often than not, this approach doesn't fare much better than the n-gram based generation. ### spaCy I'm only beginning to experiment with the [spaCy](https://spacy.io/) Python library, but I like it a lot. For one, it is much, much faster than NLTK: ![spaCy speed comparison](/img/blog/spacy_speed.jpg) [https://spacy.io/docs/api/#speed-comparison](https://spacy.io/docs/api/#speed-comparison) The [API](https://spacy.io/docs/api/) takes a little getting used to coming from NLTK. It doesn't seem to have any sort of out-of-the-box solution to printing out syntax trees like above, but it does do [part-of-speech tagging](https://spacy.io/docs/api/tagger) and [dependency relation mapping](https://spacy.io/docs/api/dependencyparser) which should accomplish about the same. You can see both of these visually with [displaCy](https://demos.explosion.ai/displacy/). ## Neural Network Based Generation If you haven't heard all the buzz about [neural networks](https://en.wikipedia.org/wiki/Artificial_neural_network), they are a particular technique for [machine learning](https://en.wikipedia.org/wiki/Machine_learning) that's inspired by our understanding of the human brain. They are structured into layers of nodes which have connections to other nodes in other layers of the network. These connections have weights which each node multiplies by the corresponding input and enters into a particular [activation function](https://en.wikipedia.org/wiki/Activation_function) to output a single number. The optimal weights for solving a particular problem with the network are learned by training the network using [backpropagation](https://en.wikipedia.org/wiki/Backpropagation) to perform [gradient descent](https://en.wikipedia.org/wiki/Gradient_descent) on a particular [cost function](https://en.wikipedia.org/wiki/Loss_function) that tries to balance getting the correct answer while also [generalizing](https://en.wikipedia.org/wiki/Regularization_(mathematics)) the network enough to perform well on data the network hasn't seen before. [Long short-term memory (LSTM)](https://en.wikipedia.org/wiki/Long_short-term_memory) is a type of [recurrent neural network (RNN)](https://en.wikipedia.org/wiki/Recurrent_neural_network) (a network with cycles) that can remember previous values for a short or long period of time. This property makes them remarkably effective at a multitude of tasks, one of which is predicting text that will follow a given sequence. We can use this to continually generate text by inputting a seed, appending the generated output to the end of the seed, removing the first element from the beginning of the seed, and then inputting the seed again, following the same process until we've generated enough text from the network ([paper on using RNNs to generate text](http://www.cs.utoronto.ca/~ilya/pubs/2011/LANG-RNN.pdf)). Luckily, a lot of smart people have done most of the legwork so you can just download their neural network architecture and train it yourself. There's [char-rnn](https://github.com/karpathy/char-rnn) which has some [really exciting results for generating texts (e.g. fake Shakespeare)](http://karpathy.github.io/2015/05/21/rnn-effectiveness/). There's also [word-rnn](https://github.com/larspars/word-rnn) which is a modified version of char-rnn that operates on words as a unit instead of characters. Follow [my last blog post on how to install TensorFlow on Ubuntu 16.04](/2017/06/20/how-to-install-tensorflow-on-ubuntu-16-04.html) and you'll be almost ready to run a TensorFlow port of word-rnn: [word-rnn-tensorflow](https://github.com/hunkim/word-rnn-tensorflow). I plan on playing around with NNs a lot more to see what kind of poetry-looking text I can generate from them. --- [^1]: Fun fact: They used to be pronounced differently in Middle English during the invention of the printing press and standardized spelling. The [Great Vowel Shift](https://en.wikipedia.org/wiki/Great_Vowel_Shift) happened after, and is why they are now pronounced the same.