SystemML Algorithms Reference
2. Classification
2.1. Multinomial Logistic Regression
Description
The MultiLogReg.dml
script performs both binomial and multinomial
logistic regression. The script is given a dataset $(X, Y)$ where matrix
$X$ has $m$ columns and matrix $Y$ has one column; both $X$ and $Y$ have
$n$ rows. The rows of $X$ and $Y$ are viewed as a collection of records:
$(X, Y) = (x_i, y_i)_{i=1}^n$ where $x_i$ is a numerical vector of
explanatory (feature) variables and $y_i$ is a categorical response
variable. Each row $x_i$ in $X$ has size $\dim x_i = m$, while its corresponding $y_i$
is an integer that represents the observed response value for
record $i$.
The goal of logistic regression is to learn a linear model over the feature vector $x_i$ that can be used to predict how likely each categorical label is expected to be observed as the actual $y_i$. Note that logistic regression predicts more than a label: it predicts the probability for every possible label. The binomial case allows only two possible labels, the multinomial case has no such restriction.
Just as linear regression estimates the mean value $\mu_i$ of a numerical response variable, logistic regression does the same for category label probabilities. In linear regression, the mean of $y_i$ is estimated as a linear combination of the features: . In logistic regression, the label probability has to lie between 0 and 1, so a link function is applied to connect it to $\beta_0 + x_i\beta_{1:m}$. If there are just two possible category labels, for example 0 and 1, the logistic link looks as follows:
Here category label 0 serves as the baseline, and function shows how likely we expect to see “$y_i = 1$” in comparison to the baseline. Like in a loaded coin, the predicted odds of seeing 1 versus 0 are to 1, with each feature multiplying its own factor $\exp(\beta_j x_{i,j})$ to the odds. Given a large collection of pairs $(x_i, y_i)$, $i=1\ldots n$, logistic regression seeks to find the $\beta_j$’s that maximize the product of probabilities $Prob[y_i\mid x_i; \beta]$ for actually observed $y_i$-labels (assuming no regularization).
Multinomial logistic regression [Agresti2002] extends this link to $k \geq 3$ possible categories. Again we identify one category as the baseline, for example the $k$-th category. Instead of a coin, here we have a loaded multisided die, one side per category. Each non-baseline category $l = 1\ldots k\,{-}\,1$ has its own vector of regression parameters with the intercept, making up a matrix $B$ of size $(m\,{+}\,1)\times(k\,{-}\,1)$. The predicted odds of seeing non-baseline category $l$ versus the baseline $k$ are to 1, and the predicted probabilities are:
The goal of the regression is to estimate the parameter matrix $B$ from the provided dataset $(X, Y) = (x_i, y_i)_{i=1}^n$ by maximizing the product of over the observed labels $y_i$. Taking its logarithm, negating, and adding a regularization term gives us a minimization objective:
The optional regularization term is added to mitigate overfitting and degeneracy in the data; to reduce bias, the intercepts are not regularized. Once the $\beta_{j,l}$’s are accurately estimated, we can make predictions about the category label $y$ for a new feature vector $x$ using Eqs. (1) and (2).
Usage
hadoop jar SystemML.jar -f MultiLogReg.dml
-nvargs X=<file>
Y=<file>
B=<file>
Log=[file]
icpt=[int]
reg=[double]
tol=[double]
moi=[int]
mii=[int]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f MultiLogReg.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
B=<file>
Log=[file]
icpt=[int]
reg=[double]
tol=[double]
moi=[int]
mii=[int]
fmt=[format]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) to read the input matrix of feature vectors; each row constitutes one feature vector.
Y: Location to read the input one-column matrix of category labels that correspond to feature vectors in X. Note the following:
- Each non-baseline category label must be a positive integer.
- If all labels are positive, the largest represents the baseline category.
- If non-positive labels such as $-1$ or $0$ are present, then they represent the (same) baseline category and are converted to label $\max(\texttt{Y})\,{+}\,1$.
B: Location to store the matrix of estimated regression parameters (the ’s), with the intercept parameters $\beta_{0, l}$ at position B[$m\,{+}\,1$, $l$] if available. The size of B is $(m\,{+}\,1)\times (k\,{-}\,1)$ with the intercepts or $m \times (k\,{-}\,1)$ without the intercepts, one column per non-baseline category and one row per feature.
Log: (default: " "
) Location to store iteration-specific variables for monitoring
and debugging purposes, see
Table 5
for details.
icpt: (default: 0
) Intercept and shifting/rescaling of the features in $X$:
- 0 = no intercept (hence no $\beta_0$), no shifting/rescaling of the features;
- 1 = add intercept, but do not shift/rescale the features in $X$;
- 2 = add intercept, shift/rescale the features in $X$ to mean 0, variance 1
reg: (default: 0.0
) L2-regularization parameter (lambda)
tol: (default: 0.000001
) Tolerance ($\epsilon$) used in the convergence criterion
moi: (default: 100
) Maximum number of outer (Fisher scoring) iterations
mii: (default: 0
) Maximum number of inner (conjugate gradient) iterations, or 0
if no maximum limit provided
fmt: (default: "text"
) Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
Please see mllearn documentation for more details on the Python API.
Examples
hadoop jar SystemML.jar -f MultiLogReg.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
B=/user/ml/B.mtx
fmt=csv
icpt=2
reg=1.0
tol=0.0001
moi=100
mii=10
Log=/user/ml/log.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f MultiLogReg.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
B=/user/ml/B.mtx
fmt=csv
icpt=2
reg=1.0
tol=0.0001
moi=100
mii=10
Log=/user/ml/log.csv
Table 5: The Log
file for multinomial logistic regression
contains the following iteration variables in CSV
format, each line
containing triple (Name
, Iteration#
, Value
) with Iteration#
being 0
for initial values.
Name | Meaning |
---|---|
LINEAR_TERM_MIN | The minimum value of $X$ %*% $B$, used to check for overflows |
LINEAR_TERM_MAX | The maximum value of $X$ %*% $B$, used to check for overflows |
NUM_CG_ITERS | Number of inner (Conj. Gradient) iterations in this outer iteration |
IS_TRUST_REACHED | $1 = {}$trust region boundary was reached, $0 = {}$otherwise |
POINT_STEP_NORM | L2-norm of iteration step from old point (matrix $B$) to new point |
OBJECTIVE | The loss function we minimize (negative regularized log-likelihood) |
OBJ_DROP_REAL | Reduction in the objective during this iteration, actual value |
OBJ_DROP_PRED | Reduction in the objective predicted by a quadratic approximation |
OBJ_DROP_RATIO | Actual-to-predicted reduction ratio, used to update the trust region |
IS_POINT_UPDATED | $1 = {}$new point accepted; $0 = {}$new point rejected, old point restored |
GRADIENT_NORM | L2-norm of the loss function gradient (omitted if point is rejected) |
RUST_DELTA | Updated trust region size, the “delta” |
Details
We estimate the logistic regression parameters via L2-regularized negative log-likelihood minimization (3). The optimization method used in the script closely follows the trust region Newton method for logistic regression described in [Lin2008]. For convenience, let us make some changes in notation:
- Convert the input vector of observed category labels into an indicator matrix $Y$ of size $n \times k$ such that if the $i$-th category label is $l$ and $Y_{i, l} = 0$ otherwise.
- Append an extra column of all ones, i.e. $(1, 1, \ldots, 1)^T$, as the $m\,{+}\,1$-st column to the feature matrix $X$ to represent the intercept.
- Append an all-zero column as the $k$-th column to $B$, the matrix of regression parameters, to represent the baseline category.
- Convert the regularization constant $\lambda$ into matrix $\Lambda$ of the same size as $B$, placing 0’s into the $m\,{+}\,1$-st row to disable intercept regularization, and placing $\lambda$’s everywhere else.
Now the ($n\,{\times}\,k$)-matrix of predicted probabilities given by (1) and (2) and the objective function $f$ in (3) have the matrix form
where operations $\cdot\,$, /
, exp
, and log
are applied
cellwise, and $\textstyle\sum$ denotes the sum of all cells in a matrix.
The gradient of $f$ with respect to $B$ can be represented as a matrix
too:
The Hessian $\mathcal{H}$ of $f$ is a tensor, but, fortunately, the conjugate gradient inner loop of the trust region algorithm in [Lin2008] does not need to instantiate it. We only need to multiply $\mathcal{H}$ by ordinary matrices of the same size as $B$ and $\nabla f$, and this can be done in matrix form:
At each Newton iteration (the outer iteration) the minimization algorithm approximates the difference $\varDelta f(S; B) = f(B + S; X, Y) \,-\, f(B; X, Y)$ attained in the objective function after a step $B \mapsto B\,{+}\,S$ by a second-degree formula
This approximation is then
minimized by trust-region conjugate gradient iterations (the inner
iterations) subject to the constraint
$|S|_2 \leq \delta$
. The trust
region size $\delta$ is initialized as
$0.5\sqrt{m}\,/ \max_i |x_i|_2$
and updated as described
in [Lin2008].
Users can specify the maximum number of the outer
and the inner iterations with input parameters moi
and
mii
, respectively. The iterative minimizer terminates
successfully if
, where ${\varepsilon}> 0$ is a tolerance supplied by the user via input
parameter tol
.
Returns
The estimated regression parameters (the
)
are
populated into a matrix and written to an HDFS file whose path/name was
provided as the B
input argument. Only the non-baseline
categories ($1\leq l \leq k\,{-}\,1$) have their
in the output; to add the baseline category, just append a column of zeros.
If icpt=0
in the input command line, no intercepts are used
and B
has size
$m\times (k\,{-}\,1)$; otherwise
B
has size
$(m\,{+}\,1)\times (k\,{-}\,1)$
and the
intercepts are in the
$m\,{+}\,1$-st row. If icpt=2, then
initially the feature columns in $X$ are shifted to mean${} = 0$ and
rescaled to variance${} = 1$. After the iterations converge, the
$\hat{\beta}_{j, l}$’s are rescaled and shifted to work with the
original features.
2.2 Support Vector Machines
2.2.1 Binary-Class Support Vector Machines
Description
Support Vector Machines are used to model the relationship between a
categorical dependent variable y
and one or more explanatory variables
denoted X
. This implementation learns (and predicts with) a binary class
support vector machine (y
with domain size 2
).
Usage
Binary-Class Support Vector Machines:
hadoop jar SystemML.jar -f l2-svm.dml
-nvargs X=<file>
Y=<file>
icpt=[int]
tol=[double]
reg=[double]
maxiter=[int]
model=<file>
Log=<file>
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f l2-svm.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
icpt=[int]
tol=[double]
reg=[double]
maxiter=[int]
model=<file>
Log=<file>
fmt=[format]
Binary-Class Support Vector Machines Prediction:
hadoop jar SystemML.jar -f l2-svm-predict.dml
-nvargs X=<file>
Y=[file]
icpt=[int]
model=<file>
scores=[file]
accuracy=[file]
confusion=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f l2-svm-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=[file]
icpt=[int]
model=<file>
scores=[file]
accuracy=[file]
confusion=[file]
fmt=[format]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) to read the matrix of feature vectors; each row constitutes one feature vector.
Y: Location to read the one-column matrix of (categorical) labels
that correspond to feature vectors in X
. Binary class labels can be
expressed in one of two choices: $\pm 1$ or $1/2$. Note that this
argument is optional for prediction.
icpt: (default: 0
) If set to 1
then a constant bias
column is added to X
.
tol: (default: 0.001
) Procedure terminates early if the
reduction in objective function value is less than tolerance times
the initial objective function value.
reg: (default: 1
) Regularization constant. See details
to find out where lambda appears in the objective function. If one
were interested in drawing an analogy with the C
parameter in C-SVM,
then C = 2/lambda
. Usually, cross validation is employed to
determine the optimum value of lambda.
maxiter: (default: 100
) The maximum number
of iterations.
model: Location (on HDFS) that contains the learnt weights.
Log: Location (on HDFS) to collect various metrics (e.g., objective function value etc.) that depict progress across iterations while training.
fmt: (default: "text"
) Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
scores: Location (on HDFS) to store scores for a held-out test set. Note that this is an optional argument.
accuracy: Location (on HDFS) to store the accuracy computed on a held-out test set. Note that this is an optional argument.
confusion: Location (on HDFS) to store the confusion matrix computed using a held-out test set. Note that this is an optional argument.
Please see mllearn documentation for more details on the Python API.
Examples
Binary-Class Support Vector Machines:
hadoop jar SystemML.jar -f l2-svm.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
tol=0.001
fmt=csv
reg=1.0
maxiter=100
model=/user/ml/weights.csv
Log=/user/ml/Log.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f l2-svm.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
tol=0.001
fmt=csv
reg=1.0
maxiter=100
model=/user/ml/weights.csv
Log=/user/ml/Log.csv
Binary-Class Support Vector Machines Prediction:
hadoop jar SystemML.jar -f l2-svm-predict.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
fmt=csv
model=/user/ml/weights.csv
scores=/user/ml/scores.csv
accuracy=/user/ml/accuracy.csv
confusion=/user/ml/confusion.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f l2-svm-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
fmt=csv
model=/user/ml/weights.csv
scores=/user/ml/scores.csv
accuracy=/user/ml/accuracy.csv
confusion=/user/ml/confusion.csv
Details
Support vector machines learn a classification function by solving the following optimization problem ($L_2$-SVM):
where $x_i$ is an example from the training set with its label given by $y_i$, $w$ is the vector of parameters and $\lambda$ is the regularization constant specified by the user.
To account for the missing bias term, one may augment the data with a
column of constants which is achieved by setting the intercept argument to 1
[Hsieh2008].
This implementation optimizes the primal directly [Chapelle2007]. It uses nonlinear conjugate gradient descent to minimize the objective function coupled with choosing step-sizes by performing one-dimensional Newton minimization in the direction of the gradient.
Returns
The learnt weights produced by l2-svm.dml
are populated into a single
column matrix and written to file on HDFS (see model in section
Arguments). The number of rows in this matrix is ncol(X)
if intercept
was set to 0
during invocation and ncol(X) + 1
otherwise. The bias term,
if used, is placed in the last row. Depending on what arguments are
provided during invocation, l2-svm-predict.dml
may compute one or more
of scores, accuracy and confusion matrix in the output format
specified.
2.2.2 Multi-Class Support Vector Machines
Description
Support Vector Machines are used to model the relationship between a
categorical dependent variable y
and one or more explanatory variables
denoted X
. This implementation supports dependent variables that have
domain size greater or equal to 2
and hence is not restricted to binary
class labels.
Usage
Multi-Class Support Vector Machines:
hadoop jar SystemML.jar -f m-svm.dml
-nvargs X=<file>
Y=<file>
icpt=[int]
tol=[double]
reg=[double]
maxiter=[int]
model=<file>
Log=<file>
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f m-svm.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
icpt=[int]
tol=[double]
reg=[double]
maxiter=[int]
model=<file>
Log=<file>
fmt=[format]
Multi-Class Support Vector Machines Prediction:
hadoop jar SystemML.jar -f m-svm-predict.dml
-nvargs X=<file>
Y=[file]
icpt=[int]
model=<file>
scores=[file]
accuracy=[file]
confusion=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f m-svm-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=[file]
icpt=[int]
model=<file>
scores=[file]
accuracy=[file]
confusion=[file]
fmt=[format]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) containing the explanatory variables in a matrix. Each row constitutes an example.
Y: Location (on HDFS) containing a 1-column matrix specifying the categorical dependent variable (label). Labels are assumed to be contiguously numbered from 1 $\ldots$ #classes. Note that this argument is optional for prediction.
icpt: (default: 0
) If set to 1
then a constant bias
column is added to X
.
tol: (default: 0.001
) Procedure terminates early if the
reduction in objective function value is less than tolerance times
the initial objective function value.
reg: (default: 1
) Regularization constant. See details
to find out where lambda
appears in the objective function. If one
were interested in drawing an analogy with C-SVM, then C = 2/lambda
.
Usually, cross validation is employed to determine the optimum value
of lambda
.
maxiter: (default: 100
) The maximum number
of iterations.
model: Location (on HDFS) that contains the learnt weights.
Log: Location (on HDFS) to collect various metrics (e.g., objective function value etc.) that depict progress across iterations while training.
fmt: (default: "text"
) Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
scores: Location (on HDFS) to store scores for a held-out test set. Note that this is an optional argument.
accuracy: Location (on HDFS) to store the accuracy computed on a held-out test set. Note that this is an optional argument.
confusion: Location (on HDFS) to store the confusion matrix computed using a held-out test set. Note that this is an optional argument.
Please see mllearn documentation for more details on the Python API.
Examples
Multi-Class Support Vector Machines:
hadoop jar SystemML.jar -f m-svm.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
tol=0.001
reg=1.0
maxiter=100
fmt=csv
model=/user/ml/weights.csv
Log=/user/ml/Log.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f m-svm.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
tol=0.001
reg=1.0
maxiter=100
fmt=csv
model=/user/ml/weights.csv
Log=/user/ml/Log.csv
Multi-Class Support Vector Machines Prediction:
hadoop jar SystemML.jar -f m-svm-predict.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
fmt=csv
model=/user/ml/weights.csv
scores=/user/ml/scores.csv
accuracy=/user/ml/accuracy.csv
confusion=/user/ml/confusion.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f m-svm-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
icpt=0
fmt=csv
model=/user/ml/weights.csv
scores=/user/ml/scores.csv
accuracy=/user/ml/accuracy.csv
confusion=/user/ml/confusion.csv
Details
Support vector machines learn a classification function by solving the following optimization problem ($L_2$-SVM):
where $x_i$ is an example from the training set with its label given by $y_i$, $w$ is the vector of parameters and $\lambda$ is the regularization constant specified by the user.
To extend the above formulation (binary class SVM) to the multiclass setting, one standard approach is to learn one binary class SVM per class that separates data belonging to that class from the rest of the training data (one-against-the-rest SVM, see [Scholkopf1995]).
To account for the missing bias term, one may augment the data with a column of constants which is achieved by setting intercept argument to 1 [Hsieh2008].
This implementation optimizes the primal directly [Chapelle2007]. It uses nonlinear conjugate gradient descent to minimize the objective function coupled with choosing step-sizes by performing one-dimensional Newton minimization in the direction of the gradient.
Returns
The learnt weights produced by m-svm.dml
are populated into a matrix
that has as many columns as there are classes in the training data, and
written to file provided on HDFS (see model in section Arguments). The
number of rows in this matrix is ncol(X)
if intercept was set to 0
during invocation and ncol(X) + 1
otherwise. The bias terms, if used,
are placed in the last row. Depending on what arguments are provided
during invocation, m-svm-predict.dml
may compute one or more of scores,
accuracy and confusion matrix in the output format specified.
2.3 Naive Bayes
Description
Naive Bayes is very simple generative model used for classifying data. This implementation learns a multinomial naive Bayes classifier which is applicable when all features are counts of categorical values.
Usage
Naive Bayes:
hadoop jar SystemML.jar -f naive-bayes.dml
-nvargs X=<file>
Y=<file>
laplace=[double]
prior=<file>
conditionals=<file>
accuracy=<file>
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f naive-bayes.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
laplace=[double]
prior=<file>
conditionals=<file>
accuracy=<file>
fmt=[format]
Naive Bayes Prediction:
hadoop jar SystemML.jar -f naive-bayes-predict.dml
-nvargs X=<file>
Y=[file]
prior=<file>
conditionals=<file>
fmt=[format]
accuracy=[file]
confusion=[file]
probabilities=[file]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f naive-bayes-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=[file]
prior=<file>
conditionals=<file>
fmt=[format]
accuracy=[file]
confusion=[file]
probabilities=[file]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) to read the matrix of feature vectors; each row constitutes one feature vector.
Y: Location (on HDFS) to read the one-column matrix of (categorical)
labels that correspond to feature vectors in X
. Classes are assumed
to be contiguously labeled beginning from 1
. Note that this
argument is optional for prediction.
laplace: (default: 1
) Laplace smoothing specified by
the user to avoid creation of 0
probabilities.
prior: Location (on HDFS) that contains the class prior probabilites.
conditionals: Location (on HDFS) that contains the class conditional feature distributions.
fmt (default: "text"
): Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
probabilities: Location (on HDFS) to store class membership probabilities for a held-out test set.
accuracy: Location (on HDFS) to store the training accuracy during learning and testing accuracy from a held-out test set during prediction. Note that this is an optional argument for prediction.
confusion: Location (on HDFS) to store the confusion matrix computed using a held-out test set. Note that this is an optional argument.
Please see mllearn documentation for more details on the Python API.
Examples
Naive Bayes:
hadoop jar SystemML.jar -f naive-bayes.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
laplace=1
fmt=csv
prior=/user/ml/prior.csv
conditionals=/user/ml/conditionals.csv
accuracy=/user/ml/accuracy.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f naive-bayes.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
laplace=1
fmt=csv
prior=/user/ml/prior.csv
conditionals=/user/ml/conditionals.csv
accuracy=/user/ml/accuracy.csv
Naive Bayes Prediction:
hadoop jar SystemML.jar -f naive-bayes-predict.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
prior=/user/ml/prior.csv
conditionals=/user/ml/conditionals.csv
fmt=csv
accuracy=/user/ml/accuracy.csv
probabilities=/user/ml/probabilities.csv
confusion=/user/ml/confusion.csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f naive-bayes-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/y.mtx
prior=/user/ml/prior.csv
conditionals=/user/ml/conditionals.csv
fmt=csv
accuracy=/user/ml/accuracy.csv
probabilities=/user/ml/probabilities.csv
confusion=/user/ml/confusion.csv
Details
Naive Bayes is a very simple generative classification model. It posits that given the class label, features can be generated independently of each other. More precisely, the (multinomial) naive Bayes model uses the following equation to estimate the joint probability of a feature vector $x$ belonging to class $y$:
where $\pi_y$ denotes the prior probability of class $y$, $i$ denotes a feature present in $x$ with $n(i,x)$ denoting its count and $\theta_{iy}$ denotes the class conditional probability of feature $i$ in class $y$. The usual constraints hold on $\pi$ and $\theta$:
where $\mathcal{C}$ is the set of classes.
Given a fully labeled training dataset, it is possible to learn a naive
Bayes model using simple counting (group-by aggregates). To compute the
class conditional probabilities, it is usually advisable to avoid
setting $\theta_{iy}$ to 0
. One way to achieve this is using additive
smoothing or Laplace smoothing. Some authors have argued that this
should in fact be add-one smoothing. This implementation uses add-one
smoothing by default but lets the user specify her/his own constant, if
required.
This implementation is sometimes referred to as multinomial naive Bayes. Other flavours of naive Bayes are also popular.
Returns
The learnt model produced by naive-bayes.dml
is stored in two separate
files. The first file stores the class prior (a single-column matrix).
The second file stores the class conditional probabilities organized
into a matrix with as many rows as there are class labels and as many
columns as there are features. Depending on what arguments are provided
during invocation, naive-bayes-predict.dml
may compute one or more of
probabilities, accuracy and confusion matrix in the output format
specified.
2.4. Decision Trees
Description
Decision tree (for classification) is a classifier that is considered more interpretable than other statistical classifiers. This implementation is well-suited to handle large-scale data and builds a (binary) decision tree in parallel.
Usage
Decision Tree:
hadoop jar SystemML.jar -f decision-tree.dml
-nvargs X=<file>
Y=<file>
R=[file]
M=<file>
bins=[int]
depth=[int]
num_leaf=[int]
num_samples=[int]
impurity=[Gini|entropy]
O=[file]
S_map=[file]
C_map=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f decision-tree.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
R=[file]
M=<file>
bins=[int]
depth=[int]
num_leaf=[int]
num_samples=[int]
impurity=[Gini|entropy]
O=[file]
S_map=[file]
C_map=[file]
fmt=[format]
Decision Tree Prediction:
hadoop jar SystemML.jar -f decision-tree-predict.dml
-nvargs X=<file>
Y=[file]
R=[file]
M=<file>
P=<file>
A=[file]
CM=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f decision-tree-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=[file]
R=[file]
M=<file>
P=<file>
A=[file]
CM=[file]
fmt=[format]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) to read the matrix of feature vectors; each row constitutes one feature vector. Note that categorical features in $X$ need to be both recoded and dummy coded.
Y: Location (on HDFS) to read the matrix of (categorical) labels that correspond to feature vectors in $X$. Note that class labels are assumed to be both recoded and dummy coded. This argument is optional for prediction.
R: (default: " "
) Location (on HDFS) to read matrix $R$ which for each feature
in $X$ contains column-ids (first column), start indices (second
column), and end indices (third column). If $R$ is not provided by
default all features are assumed to be continuous-valued.
M: Location (on HDFS) to write matrix $M$ containing the learned decision tree (see below for the schema)
bins: (default: 20
) Number of thresholds to choose for each continuous-valued
feature (determined by equi-height binning).
depth: (default: 25
) Maximum depth of the learned tree
num_leaf: (default: 10
) Parameter that controls pruning. The tree is not expanded if
a node receives less than num_leaf
training examples.
num_samples: (default: 3000
) Parameter that decides when to switch to in-memory building
of subtrees. If a node $v$ receives less than num_samples
training examples then this implementation switches to an in-memory
subtree building procedure to build the subtree under $v$ in its
entirety.
impurity: (default: "Gini"
) Impurity measure used at internal nodes of the tree for
selecting which features to split on. Possible value are entropy
or
Gini
.
O: (default: " "
) Location (on HDFS) to store the training accuracy (%). Note
that this argument is optional.
A: (default: " "
) Location (on HDFS) to store the testing accuracy (%) from a
held-out test set during prediction. Note that this argument is
optional.
P: Location (on HDFS) to store predictions for a held-out test set
CM: (default: " "
) Location (on HDFS) to store the confusion matrix computed
using a held-out test set. Note that this argument is optional.
S_map: (default: " "
) Location (on HDFS) to write the mappings from the
continuous-valued feature-ids to the global feature-ids in $X$ (see
below for details). Note that this argument is optional.
C_map: (default: " "
) Location (on HDFS) to write the mappings from the categorical
feature-ids to the global feature-ids in $X$ (see below for details).
Note that this argument is optional.
fmt: (default: "text"
) Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
Examples
Decision Tree:
hadoop jar SystemML.jar -f decision-tree.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
bins=20
depth=25
num_leaf=10
num_samples=3000
impurity=Gini
fmt=csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f decision-tree.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
bins=20
depth=25
num_leaf=10
num_samples=3000
impurity=Gini
fmt=csv
Decision Tree Prediction:
hadoop jar SystemML.jar -f decision-tree-predict.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
P=/user/ml/predictions.csv
A=/user/ml/accuracy.csv
CM=/user/ml/confusion.csv
fmt=csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f decision-tree-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
P=/user/ml/predictions.csv
A=/user/ml/accuracy.csv
CM=/user/ml/confusion.csv
fmt=csv
Details
Decision trees [BreimanFOS1984] are simple models of classification that, due to their structure, are easy to interpret. Given an example feature vector, each node in the learned tree runs a simple test on it. Based on the result of the test, the example is either diverted to the left subtree or to the right subtree. Once the example reaches a leaf, then the label stored at the leaf is returned as the prediction for the example.
Building a decision tree from a fully labeled training set entails choosing appropriate splitting tests for each internal node in the tree and this is usually performed in a top-down manner. The splitting test (denoted by $s$) requires first choosing a feature $j$ and depending on the type of $j$, either a threshold $\sigma$, in case $j$ is continuous-valued, or a subset of values $S \subseteq \text{Dom}(j)$ where $\text{Dom}(j)$ denotes domain of $j$, in case it is categorical. For continuous-valued features the test is thus of form $x_j < \sigma$ and for categorical features it is of form $x_j \in S$, where $x_j$ denotes the $j$th feature value of feature vector $x$. One way to determine which test to include, is to compare impurities of the tree nodes induced by the test. The node impurity measures the homogeneity of the labels at the node. This implementation supports two commonly used impurity measures (denoted by $\mathcal{I}$): Entropy , as well as Gini impurity , where $C$ denotes the number of unique labels and $f_i$ is the frequency of label $i$. Once the impurity at the tree nodes has been obtained, the best split is chosen from a set of possible splits that maximizes the information gain at the node, i.e., , where $\mathcal{IG}(X,s)$ denotes the information gain when the splitting test $s$ partitions the feature matrix $X$. Assuming that $s$ partitions $X$ that contains $N$ feature vectors into and each including and feature vectors, respectively, is given by
where $\mathcal{I}\in{\mathcal{E},\mathcal{G}}$. In the following we
discuss the implementation details specific to
decision-tree.dml
.
Input format. In general implementations of the decision tree algorithm do not require categorical features to be dummy coded. For improved efficiency and reducing the training time, our implementation however assumes dummy coded categorical features and dummy coded class labels.
Tree construction. Learning a decision tree on large-scale data has
received some attention in the literature. The current implementation
includes logic for choosing tests for multiple nodes that belong to the
same level in the decision tree in parallel (breadth-first expansion)
and for building entire subtrees under multiple nodes in parallel
(depth-first subtree building). Empirically it has been demonstrated
that it is advantageous to perform breadth-first expansion for the nodes
belonging to the top levels of the tree and to perform depth-first
subtree building for nodes belonging to the lower levels of the
tree [PandaHBB2009]. The parameter num_samples
controls
when we switch to depth-first subtree building. Any node in the decision
tree that receives $\leq$ num_samples
training examples,
the subtree under it is built in its entirety in one shot.
Stopping rule and pruning. The splitting of data at the internal nodes stops when at least one the following criteria is satisfied:
- the depth of the internal node reaches the input parameter
depth
controlling the maximum depth of the learned tree, or - no candidate split achieves information gain.
This implementation also allows for some automated pruning via the
argument num_leaf
. If a node receives $\leq$
num_leaf
training examples, then a leaf is built in its
place.
Continuous-valued features. For a continuous-valued feature $j$ the
number of candidate thresholds $\sigma$ to choose from is of the order
of the number of examples present in the training set. Since for
large-scale data this can result in a large number of candidate
thresholds, the user can limit this number via the arguments
bins
which controls the number of candidate thresholds
considered for each continuous-valued feature. For each
continuous-valued feature, the implementation computes an equi-height
histogram to generate one candidate threshold per equi-height bin.
Categorical features. In order to determine the best value subset to split on in the case of categorical features, this implementation greedily includes values from the feature’s domain until the information gain stops improving. In particular, for a categorical feature $j$ the $|Dom(j)|$ feature values are sorted by impurity and the resulting split candidates $|Dom(j)|-1$ are examined; the sequence of feature values which results in the maximum information gain is then selected.
Description of the model. The learned decision tree is represented in a matrix $M$ that contains at least 6 rows. Each column in the matrix contains the parameters relevant to a single node in the tree. Note that for building the tree model, our implementation splits the feature matrix $X$ into containing continuous-valued features and containing categorical features. In the following, the continuous-valued (resp. categorical) feature-ids correspond to the indices of the features in (resp. ). Moreover, we refer to an internal node as a continuous-valued (categorical) node if the feature that this nodes looks at is continuous-valued (categorical). Below is a description of what each row in the matrix contains.
- Row 1: stores the node-ids. These ids correspond to the node-ids in a complete binary tree.
- Row 2: for internal nodes stores the offsets (the number of columns)
in $M$ to the left child, and otherwise
0
. - Row 3: stores the feature index of the feature (id of a
continuous-valued feature in if the feature is
continuous-valued or id of a categorical feature in
if the feature is categorical) that this node looks at if the node
is an internal node, otherwise
0
. - Row 4: store the type of the feature that this node looks at if the
node is an internal node:
1
for continuous-valued and2
for categorical features, otherwise the label this leaf node is supposed to predict. - Row 5: for the internal nodes contains
1
if the feature chosen for the node is continuous-valued, or the size of the subset of values used for splitting at the node stored in rows 6,7,$\ldots$ if the feature chosen for the node is categorical. For the leaf nodes, Row 5 contains the number of misclassified training examples reaching at this node. - Row 6,7,$\ldots$: for the internal nodes, row 6 stores the threshold
to which the example’s feature value is compared if the feature
chosen for this node is continuous-valued, otherwise if the feature
chosen for this node is categorical rows 6,7,$\ldots$ store the
value subset chosen for the node. For the leaf nodes, row 6 contains
1
if the node is impure and the number of training examples at the node is greater thannum_leaf
, otherwise0
.
As an example, Figure 2 shows a decision tree with $5$ nodes and its matrix representation.
Figure 2: (a) An example tree and its (b) matrix representation. $x$ denotes an example and $x_j$ is the value of the $j$th continuous-valued (resp. categorical) feature in (resp. ). In this example all leaf nodes are pure and no training example is misclassified.
(a)
(b)
Col 1 | Col 2 | Col 3 | Col 4 | Col 5 | |
---|---|---|---|---|---|
Row 1 | 1 | 2 | 3 | 6 | 7 |
Row 2 | 1 | 0 | 1 | 0 | 0 |
Row 3 | 3 | 0 | 5 | 0 | 0 |
Row 4 | 1 | 1 | 2 | 2 | 1 |
Row 5 | 1 | 0 | 2 | 0 | 0 |
Row 6 | 0.45 | 0 | 2 | 0 | 0 |
Row 7 | 3 |
Returns
The matrix corresponding to the learned model as well as the training
accuracy (if requested) is written to a file in the format specified.
See details where the structure of the model matrix is described. Recall
that in our implementation $X$ is split into and
. If requested, the mappings of the continuous-valued
feature-ids in (stored at S_map
) and the
categorical feature-ids in (stored at
C_map
) to the global feature-ids in $X$ will be provided.
Depending on what arguments are provided during invocation, the
decision-tree-predict.dml
script may compute one or more of
predictions, accuracy and confusion matrix in the requested output
format.
2.5. Random Forests
Description
Random forest is one of the most successful machine learning methods for classification and regression. It is an ensemble learning method that creates a model composed of a set of tree models. This implementation is well-suited to handle large-scale data and builds a random forest model for classification in parallel.
Usage
Random Forest:
hadoop jar SystemML.jar -f random-forest.dml
-nvargs X=<file>
Y=<file>
R=[file]
M=<file>
bins=[int]
depth=[int]
num_leaf=[int]
num_samples=[int]
num_trees=[int]
subsamp_rate=[double]
feature_subset=[double]
impurity=[Gini|entropy]
C=[file]
S_map=[file]
C_map=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f random-forest.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=<file>
R=[file]
M=<file>
bins=[int]
depth=[int]
num_leaf=[int]
num_samples=[int]
num_trees=[int]
subsamp_rate=[double]
feature_subset=[double]
impurity=[Gini|entropy]
C=[file]
S_map=[file]
C_map=[file]
fmt=[format]
Random Forest Prediction:
hadoop jar SystemML.jar -f random-forest-predict.dml
-nvargs X=<file>
Y=[file]
R=[file]
M=<file>
C=[file]
P=<file>
A=[file]
OOB=[file]
CM=[file]
fmt=[format]
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f random-forest-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=<file>
Y=[file]
R=[file]
M=<file>
C=[file]
P=<file>
A=[file]
OOB=[file]
CM=[file]
fmt=[format]
Arguments for Spark and Hadoop invocation
X: Location (on HDFS) to read the matrix of feature vectors; each row constitutes one feature vector. Note that categorical features in $X$ need to be both recoded and dummy coded.
Y: Location (on HDFS) to read the matrix of (categorical) labels that correspond to feature vectors in $X$. Note that classes are assumed to be both recoded and dummy coded. This argument is optional for prediction.
R: (default: " "
) Location (on HDFS) to read matrix $R$ which for each feature
in $X$ contains column-ids (first column), start indices (second
column), and end indices (third column). If $R$ is not provided by
default all features are assumed to be continuous-valued.
M: Location (on HDFS) to write matrix $M$ containing the learned random forest (see Decision Trees and below for the schema)
bins: (default: 20
) Number of thresholds to choose for each continuous-valued
feature (determined by equi-height binning).
depth: (default: 25
) Maximum depth of the learned trees in the random forest model
num_leaf: (default: 10
) Parameter that controls pruning. The tree is not expanded if
a node receives less than num_leaf
training examples.
num_samples: (default: 3000
) Parameter that decides when to switch to in-memory building
of the subtrees in each tree of the random forest model. If a node $v$
receives less than num_samples
training examples then this
implementation switches to an in-memory subtree building procedure to
build the subtree under $v$ in its entirety.
num_trees: (default: 10
) Number of trees to be learned in the random forest model
subsamp_rate: (default: 1.0
) Parameter controlling the size of each tree in the random
forest model; samples are selected from a Poisson distribution with
parameter subsamp_rate
.
feature_subset: (default: 0.5
) Parameter that controls the number of feature used as
candidates for splitting at each tree node as a power of the number of
features in the data, i.e., assuming the training set has $D$ features
are used at each tree node.
impurity: (default: "Gini"
) Impurity measure used at internal nodes of the trees in the
random forest model for selecting which features to split on. Possible
value are entropy
or Gini
.
C: (default: " "
) Location (on HDFS) to store the number of counts (generated
according to a Poisson distribution with parameter
subsamp_rate
) for each feature vector. Note that this
argument is optional. If Out-Of-Bag (OOB
) error estimate needs to be
computed this parameter is passed as input to
random-forest-predict.dml
.
A: (default: " "
) Location (on HDFS) to store the testing accuracy (%) from a
held-out test set during prediction. Note that this argument is
optional.
OOB: (default: " "
) Location (on HDFS) to store the Out-Of-Bag (OOB
) error
estimate of the training set. Note that the matrix of sample counts
(stored at C
) needs to be provided for computing OOB
error
estimate. Note that this argument is optional.
P: Location (on HDFS) to store predictions for a held-out test set
CM: (default: " "
) Location (on HDFS) to store the confusion matrix computed
using a held-out test set. Note that this argument is optional.
S_map: (default: " "
) Location (on HDFS) to write the mappings from the
continuous-valued feature-ids to the global feature-ids in $X$ (see
below for details). Note that this argument is optional.
C_map: (default: " "
) Location (on HDFS) to write the mappings from the categorical
feature-ids to the global feature-ids in $X$ (see below for details).
Note that this argument is optional.
fmt: (default: "text"
) Matrix file output format, such as text
,
mm
, or csv
; see read/write functions in
SystemML Language Reference for details.
Examples
Random Forest:
hadoop jar SystemML.jar -f random-forest.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
bins=20
depth=25
num_leaf=10
num_samples=3000
num_trees=10
impurity=Gini
fmt=csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f random-forest.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
bins=20
depth=25
num_leaf=10
num_samples=3000
num_trees=10
impurity=Gini
fmt=csv
Random Forest Prediction:
To compute predictions:
hadoop jar SystemML.jar -f random-forest-predict.dml
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
P=/user/ml/predictions.csv
A=/user/ml/accuracy.csv
CM=/user/ml/confusion.csv
fmt=csv
$SPARK_HOME/bin/spark-submit --master yarn
--deploy-mode cluster
--conf spark.driver.maxResultSize=0
SystemML.jar
-f random-forest-predict.dml
-config SystemML-config.xml
-exec hybrid_spark
-nvargs X=/user/ml/X.mtx
Y=/user/ml/Y.mtx
R=/user/ml/R.csv
M=/user/ml/model.csv
P=/user/ml/predictions.csv
A=/user/ml/accuracy.csv
CM=/user/ml/confusion.csv
fmt=csv
Details
Random forests [Breiman2001]
are learning algorithms for ensembles
of decision trees. The main idea is to build a number of decision trees
on bootstrapped training samples, i.e., by taking repeatedly samples
from a (single) training set. Moreover, instead of considering all the
features when building the trees only a random subset of the
features—typically $\approx \sqrt{D}$, where $D$ is the number of
features—is chosen each time a split test at a tree node is performed.
This procedure decorrelates the trees and makes it less
prone to overfitting. To build decision trees we utilize the techniques
discussed in Decision Trees and proposed
in [PandaHBB2009]; the implementation details are similar to those of
the decision trees script. Below we review some features of our
implementation which differ from decision-tree.dml
.
Bootstrapped sampling. Each decision tree is fitted to a
bootstrapped training set sampled with replacement (WR). To improve
efficiency, we generate $N$ sample counts according to a Poisson
distribution with parameter subsamp_rate
, where $N$
denotes the total number of training points. These sample counts
approximate WR sampling when $N$ is large enough and are generated
upfront for each decision tree.
Bagging. Decision trees suffer from high variance resulting in different models whenever trained on a random subsets of the data points. Bagging is a general-purpose method to reduce the variance of a statistical learning method like decision trees. In the context of decision trees (for classification), for a given test feature vector the prediction is computed by taking a majority vote: the overall prediction is the most commonly occurring class among all the tree predictions.
Out-Of-Bag error estimation. Note that each bagged tree in a random
forest model is trained on a subset (around $\frac{2}{3}$) of the
observations (i.e., feature vectors). The remaining ($\frac{1}{3}$ of
the) observations not used for training is called the
Out-Of-Bag (OOB
) observations. This gives us a
straightforward way to estimate the test error: to predict the class
label of each test observation $i$ we use the trees in which $i$ was
OOB
. Our random-forest-predict.dml
script provides the OOB
error estimate for a given training set if requested.
Description of the model. Similar to decision trees, the learned
random forest model is presented in a matrix $M$ with at least 7
rows.
The information stored in the model is similar to that of decision trees
with the difference that the tree-ids are stored in the second row and
rows $2,3,\ldots$ from the decision tree model are shifted by one. See
Decision Trees for a description of the model.
Returns
The matrix corresponding to the learned model is written to a file in
the format specified. See Decision Trees where the
details about the structure of the model matrix is described. Similar to
decision-tree.dml
, $X$ is split into and
. If requested, the mappings of the continuous feature-ids
in (stored at S_map
) as well as the
categorical feature-ids in (stored at
C_map
) to the global feature-ids in $X$ will be provided.
The random-forest-predict.dml
script may compute one or
more of predictions, accuracy, confusion matrix, and OOB
error estimate
in the requested output format depending on the input arguments used.