tra-analysis/dep/2019/superscripts/titanlearn.py

#Titan Robotics Team 2022: ML Module
#Written by Arthur Lu & Jacob Levine
#Notes:
#   this should be imported as a python module using 'import titanlearn'
#   this should be included in the local directory or environment variable
#   this module has not been optimized for multhreaded computing
#   this module learns from its mistakes far faster than 2022's captains
#setup:

__version__ = "1.0.0.001"

#changelog should be viewed using print(analysis.__changelog__)
__changelog__ = """changelog:
1.0.0.xxx:
    -added generation of ANNS, basic SGD training"""
__author__ = (
    "Arthur Lu <arthurlu@ttic.edu>, "
    "Jacob Levine <jlevine@ttic.edu>,"
    )
__all__ = [
    'linear_nn',
    'train_sgd_minibatch',
    'train_sgd_simple'
    ]
#imports
import torch
import warnings
from collections import OrderedDict
from sklearn import metrics, datasets
import numpy as np
import matplotlib.pyplot as plt
import math
import time

#enable CUDA if possible
device = torch.device("cpu")

#linear_nn: creates a fully connected network given params
def linear_nn(in_dim, hidden_dim, out_dim, num_hidden, act_fn="tanh", end="none"):
    if act_fn.lower()=="tanh":
        k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])
        for i in range(num_hidden):
            k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "tanh"+str(i+1):torch.nn.Tanh()})

    elif act_fn.lower()=="sigmoid":
        k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])
        for i in range(num_hidden):
            k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "sig"+str(i+1):torch.nn.Sigmoid()})

    elif act_fn.lower()=="relu":
        k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])
        for i in range(num_hidden):
            k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "relu"+str(i+1):torch.nn.ReLU()})

    elif act_fn.lower()=="leaky relu":
        k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])
        for i in range(num_hidden):
            k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "lre"+str(i+1):torch.nn.LeakyReLU()})
    else:
        warnings.warn("Did not specify a valid inner activation function. Returning nothing.")
        return None

    if end.lower()=="softmax":
        k.update({"out": torch.nn.Linear(hidden_dim,out_dim), "softmax": torch.nn.Softmax()})
    elif end.lower()=="none":
        k.update({"out": torch.nn.Linear(hidden_dim,out_dim)})
    elif end.lower()=="sigmoid":
        k.update({"out": torch.nn.Linear(hidden_dim,out_dim), "sigmoid": torch.nn.Sigmoid()})
    else:
        warnings.warn("Did not specify a valid final activation function. Returning nothing.")
        return None

    return torch.nn.Sequential(k)

#train_sgd_simple: trains network using SGD
def train_sgd_simple(net, evalType, data, ground, dev=None, devg=None, iters=1000, learnrate=1e-4, testevery=1, graphsaveloc=None, modelsaveloc=None, loss="mse"):
    model=net.to(device)
    data=data.to(device)
    ground=ground.to(device)
    if dev != None:
        dev=dev.to(device)
    losses=[]
    dev_losses=[]
    if loss.lower()=="mse":
        loss_fn = torch.nn.MSELoss()
    elif loss.lower()=="cross entropy":
        loss_fn = torch.nn.CrossEntropyLoss()
    elif loss.lower()=="nll":
        loss_fn = torch.nn.NLLLoss()
    elif loss.lower()=="poisson nll":
        loss_fn = torch.nn.PoissonNLLLoss()
    else:
        warnings.warn("Did not specify a valid loss function. Returning nothing.")
        return None
    optimizer=torch.optim.SGD(model.parameters(), lr=learnrate)
    for i in range(iters):
        if i%testevery==0:
            with torch.no_grad():
                output = model(data)
                if evalType == "ap":
                    ap = metrics.average_precision_score(ground.cpu().numpy(), output.cpu().numpy())
                if evalType == "regression":
                    ap = metrics.explained_variance_score(ground.cpu().numpy(), output.cpu().numpy())
                losses.append(ap)
                print(str(i)+": "+str(ap))
                plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="train AP")
                if dev != None:
                    output = model(dev)
                    print(evalType)
                    if evalType == "ap":

                        ap = metrics.average_precision_score(devg.numpy(), output.numpy())
                        dev_losses.append(ap)
                        plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev AP")
                    elif evalType == "regression":
                        ev = metrics.explained_variance_score(devg.numpy(), output.numpy())
                        dev_losses.append(ev)
                        plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev EV")


                if graphsaveloc != None:
                    plt.savefig(graphsaveloc+".pdf")
        with torch.enable_grad():
            optimizer.zero_grad()
            output = model(data)
            loss = loss_fn(output, ground)
            print(loss.item())
            loss.backward()
            optimizer.step()
    if modelsaveloc != None:
        torch.save(model, modelsaveloc)
    plt.show()
    return model

#train_sgd_minibatch: same as above, but with minibatches
def train_sgd_minibatch(net, data, ground, dev=None, devg=None, epoch=100, batchsize=20, learnrate=1e-4, testevery=20, graphsaveloc=None, modelsaveloc=None, loss="mse"):
    model=net.to(device)
    data=data.to(device)
    ground=ground.to(device)
    if dev != None:
        dev=dev.to(device)
    losses=[]
    dev_losses=[]
    if loss.lower()=="mse":
        loss_fn = torch.nn.MSELoss()
    elif loss.lower()=="cross entropy":
        loss_fn = torch.nn.CrossEntropyLoss()
    elif loss.lower()=="nll":
        loss_fn = torch.nn.NLLLoss()
    elif loss.lower()=="poisson nll":
        loss_fn = torch.nn.PoissonNLLLoss()
    else:
        warnings.warn("Did not specify a valid loss function. Returning nothing.")
        return None
    optimizer=torch.optim.LBFGS(model.parameters(), lr=learnrate)
    itercount=0
    for i in range(epoch):
        print("EPOCH "+str(i)+" OF "+str(epoch-1))
        batches=math.ceil(data.size()[0].item()/batchsize)
        for j in range(batches):
            batchdata=[]
            batchground=[]
            for k in range(j*batchsize, min((j+1)*batchsize, data.size()[0].item()),1):
                batchdata.append(data[k])
                batchground.append(ground[k])
            batchdata=torch.stack(batchdata)
            batchground=torch.stack(batchground)
            if itercount%testevery==0:
                with torch.no_grad():
                    output = model(data)
                    ap = metrics.average_precision_score(ground.numpy(), output.numpy())
                    losses.append(ap)
                    print(str(i)+": "+str(ap))
                    plt.plot(np.array(range(0,i+1,testevery)),np.array(losses))
                    if dev != None:
                        output = model(dev)
                        ap = metrics.average_precision_score(devg.numpy(), output.numpy())
                        dev_losses.append(ap)
                        plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev AP")
                    if graphsaveloc != None:
                        plt.savefig(graphsaveloc+".pdf")
            with torch.enable_grad():
                optimizer.zero_grad()
                output = model(batchdata)
                loss = loss_fn(output, ground)
                loss.backward()
                optimizer.step()
            itercount +=1
    if modelsaveloc != None:
        torch.save(model, modelsaveloc)
    plt.show()
    return model

def retyuoipufdyu():

    data = torch.tensor(datasets.fetch_california_housing()['data']).to(torch.float)
    ground = datasets.fetch_california_housing()['target']
    ground = torch.tensor(ground).to(torch.float)
    model = linear_nn(8, 100, 1, 20, act_fn = "relu")
    print(model)
    return train_sgd_simple(model,"regression", data, ground, learnrate=1e-4, iters=1000)

start = time.time()
retyuoipufdyu()
end = time.time()
print(end-start)
worked 2020-03-10 03:58:51 +00:00			`#Titan Robotics Team 2022: ML Module`
			`#Written by Arthur Lu & Jacob Levine`
			`#Notes:`
			`# this should be imported as a python module using 'import titanlearn'`
			`# this should be included in the local directory or environment variable`
			`# this module has not been optimized for multhreaded computing`
			`# this module learns from its mistakes far faster than 2022's captains`
			`#setup:`

			`__version__ = "1.0.0.001"`

			`#changelog should be viewed using print(analysis.__changelog__)`
			`__changelog__ = """changelog:`
			`1.0.0.xxx:`
			`-added generation of ANNS, basic SGD training"""`
			`__author__ = (`
			`"Arthur Lu <arthurlu@ttic.edu>, "`
			`"Jacob Levine <jlevine@ttic.edu>,"`
			`)`
			`__all__ = [`
			`'linear_nn',`
			`'train_sgd_minibatch',`
			`'train_sgd_simple'`
			`]`
			`#imports`
			`import torch`
			`import warnings`
			`from collections import OrderedDict`
			`from sklearn import metrics, datasets`
			`import numpy as np`
			`import matplotlib.pyplot as plt`
			`import math`
			`import time`

			`#enable CUDA if possible`
			`device = torch.device("cpu")`

			`#linear_nn: creates a fully connected network given params`
			`def linear_nn(in_dim, hidden_dim, out_dim, num_hidden, act_fn="tanh", end="none"):`
			`if act_fn.lower()=="tanh":`
			`k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])`
			`for i in range(num_hidden):`
			`k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "tanh"+str(i+1):torch.nn.Tanh()})`

			`elif act_fn.lower()=="sigmoid":`
			`k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])`
			`for i in range(num_hidden):`
			`k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "sig"+str(i+1):torch.nn.Sigmoid()})`

			`elif act_fn.lower()=="relu":`
			`k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])`
			`for i in range(num_hidden):`
			`k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "relu"+str(i+1):torch.nn.ReLU()})`

			`elif act_fn.lower()=="leaky relu":`
			`k=OrderedDict([("in", torch.nn.Linear(in_dim,hidden_dim))])`
			`for i in range(num_hidden):`
			`k.update({"lin"+str(i+1): torch.nn.Linear(hidden_dim,hidden_dim), "lre"+str(i+1):torch.nn.LeakyReLU()})`
			`else:`
			`warnings.warn("Did not specify a valid inner activation function. Returning nothing.")`
			`return None`

			`if end.lower()=="softmax":`
			`k.update({"out": torch.nn.Linear(hidden_dim,out_dim), "softmax": torch.nn.Softmax()})`
			`elif end.lower()=="none":`
			`k.update({"out": torch.nn.Linear(hidden_dim,out_dim)})`
			`elif end.lower()=="sigmoid":`
			`k.update({"out": torch.nn.Linear(hidden_dim,out_dim), "sigmoid": torch.nn.Sigmoid()})`
			`else:`
			`warnings.warn("Did not specify a valid final activation function. Returning nothing.")`
			`return None`

			`return torch.nn.Sequential(k)`

			`#train_sgd_simple: trains network using SGD`
			`def train_sgd_simple(net, evalType, data, ground, dev=None, devg=None, iters=1000, learnrate=1e-4, testevery=1, graphsaveloc=None, modelsaveloc=None, loss="mse"):`
			`model=net.to(device)`
			`data=data.to(device)`
			`ground=ground.to(device)`
			`if dev != None:`
			`dev=dev.to(device)`
			`losses=[]`
			`dev_losses=[]`
			`if loss.lower()=="mse":`
			`loss_fn = torch.nn.MSELoss()`
			`elif loss.lower()=="cross entropy":`
			`loss_fn = torch.nn.CrossEntropyLoss()`
			`elif loss.lower()=="nll":`
			`loss_fn = torch.nn.NLLLoss()`
			`elif loss.lower()=="poisson nll":`
			`loss_fn = torch.nn.PoissonNLLLoss()`
			`else:`
			`warnings.warn("Did not specify a valid loss function. Returning nothing.")`
			`return None`
			`optimizer=torch.optim.SGD(model.parameters(), lr=learnrate)`
			`for i in range(iters):`
			`if i%testevery==0:`
			`with torch.no_grad():`
			`output = model(data)`
			`if evalType == "ap":`
			`ap = metrics.average_precision_score(ground.cpu().numpy(), output.cpu().numpy())`
			`if evalType == "regression":`
			`ap = metrics.explained_variance_score(ground.cpu().numpy(), output.cpu().numpy())`
			`losses.append(ap)`
			`print(str(i)+": "+str(ap))`
			`plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="train AP")`
			`if dev != None:`
			`output = model(dev)`
			`print(evalType)`
			`if evalType == "ap":`

			`ap = metrics.average_precision_score(devg.numpy(), output.numpy())`
			`dev_losses.append(ap)`
			`plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev AP")`
			`elif evalType == "regression":`
			`ev = metrics.explained_variance_score(devg.numpy(), output.numpy())`
			`dev_losses.append(ev)`
			`plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev EV")`


			`if graphsaveloc != None:`
			`plt.savefig(graphsaveloc+".pdf")`
			`with torch.enable_grad():`
			`optimizer.zero_grad()`
			`output = model(data)`
			`loss = loss_fn(output, ground)`
			`print(loss.item())`
			`loss.backward()`
			`optimizer.step()`
			`if modelsaveloc != None:`
			`torch.save(model, modelsaveloc)`
			`plt.show()`
			`return model`

			`#train_sgd_minibatch: same as above, but with minibatches`
			`def train_sgd_minibatch(net, data, ground, dev=None, devg=None, epoch=100, batchsize=20, learnrate=1e-4, testevery=20, graphsaveloc=None, modelsaveloc=None, loss="mse"):`
			`model=net.to(device)`
			`data=data.to(device)`
			`ground=ground.to(device)`
			`if dev != None:`
			`dev=dev.to(device)`
			`losses=[]`
			`dev_losses=[]`
			`if loss.lower()=="mse":`
			`loss_fn = torch.nn.MSELoss()`
			`elif loss.lower()=="cross entropy":`
			`loss_fn = torch.nn.CrossEntropyLoss()`
			`elif loss.lower()=="nll":`
			`loss_fn = torch.nn.NLLLoss()`
			`elif loss.lower()=="poisson nll":`
			`loss_fn = torch.nn.PoissonNLLLoss()`
			`else:`
			`warnings.warn("Did not specify a valid loss function. Returning nothing.")`
			`return None`
			`optimizer=torch.optim.LBFGS(model.parameters(), lr=learnrate)`
			`itercount=0`
			`for i in range(epoch):`
			`print("EPOCH "+str(i)+" OF "+str(epoch-1))`
			`batches=math.ceil(data.size()[0].item()/batchsize)`
			`for j in range(batches):`
			`batchdata=[]`
			`batchground=[]`
			`for k in range(jbatchsize, min((j+1)batchsize, data.size()[0].item()),1):`
			`batchdata.append(data[k])`
			`batchground.append(ground[k])`
			`batchdata=torch.stack(batchdata)`
			`batchground=torch.stack(batchground)`
			`if itercount%testevery==0:`
			`with torch.no_grad():`
			`output = model(data)`
			`ap = metrics.average_precision_score(ground.numpy(), output.numpy())`
			`losses.append(ap)`
			`print(str(i)+": "+str(ap))`
			`plt.plot(np.array(range(0,i+1,testevery)),np.array(losses))`
			`if dev != None:`
			`output = model(dev)`
			`ap = metrics.average_precision_score(devg.numpy(), output.numpy())`
			`dev_losses.append(ap)`
			`plt.plot(np.array(range(0,i+1,testevery)),np.array(losses), label="dev AP")`
			`if graphsaveloc != None:`
			`plt.savefig(graphsaveloc+".pdf")`
			`with torch.enable_grad():`
			`optimizer.zero_grad()`
			`output = model(batchdata)`
			`loss = loss_fn(output, ground)`
			`loss.backward()`
			`optimizer.step()`
			`itercount +=1`
			`if modelsaveloc != None:`
			`torch.save(model, modelsaveloc)`
			`plt.show()`
			`return model`

			`def retyuoipufdyu():`

			`data = torch.tensor(datasets.fetch_california_housing()['data']).to(torch.float)`
			`ground = datasets.fetch_california_housing()['target']`
			`ground = torch.tensor(ground).to(torch.float)`
			`model = linear_nn(8, 100, 1, 20, act_fn = "relu")`
			`print(model)`
			`return train_sgd_simple(model,"regression", data, ground, learnrate=1e-4, iters=1000)`

			`start = time.time()`
			`retyuoipufdyu()`
			`end = time.time()`
			`print(end-start)`