This is the main function of the pROC package. It builds a ROC
curve and returns a “roc” object, a list of class
“roc”. This object can be `prin`

ted, `plot`

ted, or
passed to the functions `auc`

, `ci`

,
`smooth.roc`

and `coords`

. Additionally, two
`roc`

objects can be compared with `roc.test`

.

```
roc(...)
# S3 method for formula
roc(formula, data, ...)
# S3 method for data.frame
roc(data, response, predictor,
ret = c("roc", "coords", "all_coords"), ...)
# S3 method for default
roc(response, predictor, controls, cases,
density.controls, density.cases,
levels=base::levels(as.factor(response)), percent=FALSE, na.rm=TRUE,
direction=c("auto", "<", "="">"), algorithm = 6, quiet = FALSE,
smooth=FALSE, auc=TRUE, ci=FALSE, plot=FALSE, smooth.method="binormal",
smooth.n=512, ci.method=NULL, density=NULL, ...)
roc_(data, response, predictor, ret = c("roc", "coords", "all_coords"), ...)
```

response

a factor, numeric or character vector of
responses, typically encoded with 0 (controls) and 1 (cases).
Only two classes can be used in a ROC curve. If the vector
contains more than two unique values, or if their order could be
ambiguous, use `levels`

to specify which values must be used as
control and case value.
If the first argument was a `data.frame`

, `response`

should be the name of the column in `data`

containing the
response, quoted for `roc_`

, and optionally quoted for
`roc.data.frame`

(non-standard evaluation or NSE).

predictor

a `numeric`

or `ordered`

vector
of the same length than `response`

, containing the predicted
value of each observation.
If the first argument was a `data.frame`

, `predictor`

should be the name of the column in `data`

containing the
predictor, quoted for `roc_`

, and optionally quoted for
`roc.data.frame`

(non-standard evaluation or NSE).

controls, cases

density.controls, density.cases

a smoothed ROC curve can be
built directly from two densities on identical `x`

points, as in
`smooth`

.

formula, data

a formula of the type `response~predictor`

. If mulitple predictors
are passed, a named list of `roc`

objects will be returned. Additional arguments
`data`

and `subset`

, but not `na.action`

are supported, see
`model.frame`

for more details.

levels

the value of the response for controls and cases
respectively. By default, the first two values of
`levels(as.factor(response))`

are taken, and the remaining levels are ignored.
It usually captures two-class factor data correctly, but will
frequently fail for other data types (response factor with more than 2 levels,
or for example if your response is coded “controls” and “cases”,
the levels will be inverted) and must then be specified here.
If your data is coded as `0`

and `1`

with `0`

being the controls, you can safely omit this argument.

percent

if the sensitivities, specificities and AUC must be
given in percent (`TRUE`

) or in fraction (`FALSE`

, default).

na.rm

if `TRUE`

, the `NA`

values will be removed
(ignored by `roc.formula`

).

direction

in which direction to make the comparison? “auto” (default): automatically define in which group the median is higher and take the direction accordingly. “>”: if the predictor values for the control group are higher than the values of the case group (controls > t >= cases). “<”: if the predictor values for the control group are lower or equal than the values of the case group (controls < t <= cases). You should set this explicity to “>” or “<” whenever you are resampling or randomizing the data, otherwise the curves will be biased towards higher AUC values.

algorithm

the method used to compute sensitivity and specificity,
an integer of length 1 between `0`

and `6`

.
`1`

: a safe, well-tested, pure-R code that is efficient when the
number of thresholds is low. It goes with O(T*N).
`2`

: an alternative pure-R algorithm that goes in
O(N). Typically faster than `1`

when the number of thresholds of
the ROC curve is above 1000. Less tested than `1`

.
`3`

: a C++
implementation of `1`

, about 3-5x faster. Typically the fastest with
ROC curves with less than 50-100 thresholds, but has a very bad worst-case
when that number increases.
`4`

(debug only, slow):
runs algorithms 1 to 3 and makes sure they return the same values.
`5`

: select `2`

or `3`

based on the number of thresholds.
`6`

(default): quickly select the algorithm on the class of the data: `2`

for `numeric`

and `3`

for `ordered`

.
`0`

: use microbenchmark to choose between `2`

and `3`

.

ret

for `roc.data.frame`

only, whether to return the
threshold sensitivity and specificity at all thresholds (“coords”),
all the coordinates at all thresholds (“all_coords”) or the
`roc`

object (“roc”).

quiet

set to `TRUE`

to turn off `message`

s
when `direction`

and `levels`

are auto-detected.

smooth

if TRUE, the ROC curve is passed to `smooth`

to be smoothed.

auc

compute the area under the curve (AUC)? If `TRUE`

(default), additional arguments can be passed to `auc`

.

ci

compute the confidence interval (CI)? If set to `TRUE`

,
additional arguments can be passed to `ci`

.

plot

plot the ROC curve? If `TRUE`

, additional
arguments can be passed to `plot.roc`

.

smooth.method, smooth.n, ci.method

in `roc.formula`

and
`roc.default`

, the `method`

and `n`

arguments to
`smooth`

(if `smooth=TRUE`

) and
`of="auc"`

) must be passed as
`smooth.method`

, `smooth.n`

and `ci.method`

to avoid confusions.

density

`density`

argument passed to `smooth`

.

…

further arguments passed to or from other methods, and especially:

`auc`

:`partial.auc`

,`partial.auc.focus`

,`partial.auc.correct`

.`ci`

:`of`

,`conf.level`

,`boot.n`

,`boot.stratified`

,`progress`

`ci.auc`

:,`reuse.auc`

,`method`

`ci.thresholds`

:`thresholds`

`ci.se`

:`sensitivities`

`ci.sp`

:`specificities`

`plot.roc`

:`add`

,`col`

and most other arguments to the`plot.roc`

function. See`plot.roc`

directly for more details.`smooth`

:`method`

,`n`

, and all other arguments. See`smooth`

for more details.

If the data contained any `NA`

value and `na.rm=FALSE`

, `NA`

is
returned. Otherwise, if `smooth=FALSE`

, a list of class
“roc” with the following fields:

if called with `auc=TRUE`

, a numeric of class “auc” as
defined in `auc`

.

if called with `ci=TRUE`

, a numeric of class “ci” as
defined in `ci`

.

the response vector. Patients whose response is not
`%in%`

`levels`

are discarded. If `NA`

values
were removed, a `na.action`

attribute similar
to `na.omit`

stores the row numbers.

the predictor vector converted to numeric as used to build the ROC
curve. Patients whose response is not `%in%`

`levels`

are discarded. If
`NA`

values were removed, a `na.action`

attribute similar
to `na.omit`

stores the row numbers.

the response and predictor vectors as passed in argument.

the levels of the response as defined in argument.

the predictor values for the control observations.

the predictor values for the cases.

if the sensitivities, specificities and AUC are reported in percent, as defined in argument.

the direction of the comparison, as defined in argument.

the function used to compute sensitivities and specificities. Will be re-used in bootstrap operations.

the sensitivities defining the ROC curve.

the specificities defining the ROC curve.

the thresholds at which the sensitivities and specificities were computed. See below for details.

how the function was called. See `match.call`

for
more details.

If smooth=TRUE a list of class smooth.roc as returned by smooth, with or without additional elements auc and ci (according to the call).

Thresholds are selected as the means between any two consecutive values observed in the data. This choice is aimed to facilitate their interpretation, as any data point will be unambiguously positive or negative regardless of whether the comparison operator includes equality or not.

In rare cases it might not be possible to represent the
mean between two consecutive values, or one might want to use a custom
threshold. In those cases, the semantic of the comparison
is as follows: with `direction = '>'`

,
observations are positive when they are smaller than or equal
(`<=`

) to the threshold.
With `direction = '<'`

, observations are positive when they
are greater than or equal (`>=`

) to the threshold.

As a corollary, thresholds do not correspond to actual values in the data.

Since version 1.15.0, the `roc`

function can be used in pipelines, for instance with dplyr or magrittr. This is still a highly experimental feature and will change significantly in future versions (see issue 54).
The `roc.data.frame`

method supports both standard and non-standard evaluation (NSE):

library(dplyr) # Standard evaluation: aSAH %>% filter(gender == "Female") %>% roc("outcome", "s100b") # Non-Standard Evaluation: aSAH %>% filter(gender == "Female") %>% roc(outcome, s100b)

For tasks involving programming and variable column names, the `roc_`

function provides
standard evaluation:

# Standard evaluation: aSAH %>% filter(gender == "Female") %>% roc_("outcome", "s100b")

By default it returns the `roc`

object, which can then be piped to
the `coords`

function to extract coordinates that can be used
in further pipelines.

# Returns thresholds, sensitivities and specificities: aSAH %>% roc(outcome, s100b) %>% coords(transpose = FALSE) %>% filter(sensitivity > 0.6, specificity > 0.6)# Returns all existing coordinates, then select precision and recall: aSAH %>% roc(outcome, s100b) %>% coords(ret = "all", transpose = FALSE) %>% select(precision, recall)

If no control or case observation exist for the given levels of response, no ROC curve can be built and an error is triggered with message “No control observation” or “No case observation”.

If the predictor is not a numeric or ordered, as defined by
`as.numeric`

or `as.ordered`

, the message
“Predictor must be numeric or ordered” is returned.

The message “No valid data provided” is issued when the data
wasn't properly passed. Remember you need both `response`

and
`predictor`

of the same (not null) length, or both `controls`

and `cases`

. Combinations such as `predictor`

and
`cases`

are not valid and will trigger this error.

Infinite values of the predictor cannot always be thresholded by
infinity and can cause ROC curves to not reach 0 or 100%
specificity or sensitivity. Since version 1.13.0, pROC returns `NaN`

with a warning message “Infinite value(s) in predictor” if
`predictor`

contains any infinite values.

This function's main job is to build a ROC object. See the
“Value” section to this page for more details. Before
returning, it will call (in this order) the `smooth`

,
`auc`

, `ci`

and `plot.roc`

functions if `smooth`

`auc`

, `ci`

and `plot.roc`

(respectively) arguments are set to TRUE. By default, only `auc`

is called.

Data can be provided as `response, predictor`

, where the
predictor is the numeric (or ordered) level of the evaluated signal, and
the response encodes the observation class (control or case). The
`level`

argument specifies which response level must be taken as
controls (first value of `level`

) or cases (second). It can
safely be ignored when the response is encoded as `0`

and
`1`

, but it will frequently fail otherwise. By default, the first
two values of `levels(as.factor(response))`

are taken, and the
remaining levels are ignored. This means that if your response is
coded “control” and “case”, the levels will be
inverted.

In some cases, it is more convenient to pass the data as
`controls, cases`

, but both arguments are ignored if
`response, predictor`

was specified to non-`NULL`

values.
It is also possible to pass density data with ```
density.controls,
density.cases
```

, which will result in a smoothed ROC curve even if
`smooth=FALSE`

, but are ignored if `response, predictor`

or
`controls, cases`

are provided.

Specifications for `auc`

, `ci`

and
`plot.roc`

are not kept if `auc`

, `ci`

or `plot`

are set to
`FALSE`

. Especially, in the following case:

myRoc <- roc(..., auc.polygon=TRUE, grid=TRUE, plot=FALSE) plot(myRoc)

the plot will not have the AUC polygon nor the grid. Similarly, when comparing “roc” objects, the following is not possible:

roc1 <- roc(..., partial.auc=c(1, 0.8), auc=FALSE) roc2 <- roc(..., partial.auc=c(1, 0.8), auc=FALSE) roc.test(roc1, roc2)

This will produce a test on the full AUC, not the partial AUC. To make
a comparison on the partial AUC, you must repeat the specifications
when calling `roc.test`

:

roc.test(roc1, roc2, partial.auc=c(1, 0.8))

Note that if `roc`

was called with `auc=TRUE`

, the latter syntax will not
allow redefining the AUC specifications. You must use `reuse.auc=FALSE`

for that.

Tom Fawcett (2006) ``An introduction to ROC analysis''. *Pattern
Recognition Letters* **27**, 861--874. DOI:
10.1016/j.patrec.2005.10.010.

Xavier Robin, Natacha Turck, Alexandre Hainard, *et al.*
(2011) ``pROC: an open-source package for R and S+ to analyze and
compare ROC curves''. *BMC Bioinformatics*, **7**, 77.
DOI: 10.1186/1471-2105-12-77.

# NOT RUN { data(aSAH) # Basic example roc(aSAH$outcome, aSAH$s100b, levels=c("Good", "Poor")) # As levels aSAH$outcome == c("Good", "Poor"), # this is equivalent to: roc(aSAH$outcome, aSAH$s100b) # In some cases, ignoring levels could lead to unexpected results # Equivalent syntaxes: roc(outcome ~ s100b, aSAH) roc(aSAH$outcome ~ aSAH$s100b) with(aSAH, roc(outcome, s100b)) with(aSAH, roc(outcome ~ s100b)) # With a formula: roc(outcome ~ s100b, data=aSAH) # } # NOT RUN { library(dplyr) aSAH %>% filter(gender == "Female") %>% roc(outcome, s100b) # } # NOT RUN { # Using subset (only with formula) roc(outcome ~ s100b, data=aSAH, subset=(gender == "Male")) roc(outcome ~ s100b, data=aSAH, subset=(gender == "Female")) # With numeric controls/cases roc(controls=aSAH$s100b[aSAH$outcome=="Good"], cases=aSAH$s100b[aSAH$outcome=="Poor"]) # With ordered controls/cases roc(controls=aSAH$wfns[aSAH$outcome=="Good"], cases=aSAH$wfns[aSAH$outcome=="Poor"]) # Inverted the levels: "Poor" are now controls and "Good" cases: roc(aSAH$outcome, aSAH$s100b, levels=c("Poor", "Good")) # The result was exactly the same because of direction="auto". # The following will give an AUC < 0.5: roc(aSAH$outcome, aSAH$s100b, levels=c("Poor", "Good"), direction="<") # If we are sure about levels and direction auto-detection, # we can turn off the messages: roc(aSAH$outcome, aSAH$s100b, quiet = TRUE) # If we prefer counting in percent: roc(aSAH$outcome, aSAH$s100b, percent=TRUE) # Plot and CI (see plot.roc and ci for more options): roc(aSAH$outcome, aSAH$s100b, percent=TRUE, plot=TRUE, ci=TRUE) # Smoothed ROC curve roc(aSAH$outcome, aSAH$s100b, smooth=TRUE) # this is not identical to smooth(roc(aSAH$outcome, aSAH$s100b)) # because in the latter case, the returned object contains no AUC # }