R/python.R
In rstudio/reticulate: Interface to 'Python'
Defines functions
.py_last_error_full_callstack_hint
.py_last_error_hint
format_py_exception_traceback_with_clickable_filepaths
cat_h1
print.py_error
type_sum.python.builtin.object
make_filepaths_clickable
py_last_error
py_clear_last_error
format.python.builtin.traceback
py_set_interrupt
chooseOpsMethod.python.builtin.object
nameOfClass.python.builtin.type
py_register_load_hook
py_module_loaded
py_module_onload
py_inject_hooks
py_resolve_envir
py_inject_r
py_filter_classes
py_get_submodule
py_get_name
py_resolve_module_proxy
py_is_module_proxy
py_is_module
split_named_unnamed
py_callable_as_function
py_ellipsis
py_eval
py_run_file
py_run_string
py_capture_output
register_class_filter
register_suppress_warnings_handler
py_suppress_warnings
.print.via.format
py_collection_str
py_str.python.builtin.tuple
py_str.python.builtin.dict
py_str.python.builtin.list
py_str.python.builtin.module
py_str.python.builtin.bytearray
format.python.builtin.object
format.python.builtin.module
py_str.python.builtin.object
py_str.default
py_str
py_list_attributes
py_none
py_call
iter_next
iterate
with.python.builtin.object
py_unicode
py_bool
length.python.builtin.object
length.python.builtin.list
py_len
length.python.builtin.tuple
tuple
py_dict
dict
plot.numpy.ndarray
as.double.numpy.ndarray
as.vector.numpy.ndarray
as.matrix.numpy.ndarray
as.array.numpy.ndarray
names.python.builtin.module
names.python.builtin.object
.DollarNames.python.builtin.object
.DollarNames.python.builtin.module
`$<-.python.builtin.object`
as.environment.python.builtin.object
`$.python.builtin.module`
`[[.python.builtin.object`
`$.python.builtin.object`
py_get_attr_or_item
py_maybe_convert
summary.python.builtin.object
`%*%.python.builtin.object`
`!.python.builtin.object`
`|.python.builtin.object`
`&.python.builtin.object`
`^.python.builtin.object`
`%%.python.builtin.object`
`%/%.python.builtin.object`
`/.python.builtin.object`
`*.python.builtin.object`
`-.python.builtin.object`
`+.python.builtin.object`
py_compare
fetch_op
as.character.python.builtin.bytes
as.character.python.builtin.object
str.python.builtin.module
str.python.builtin.object
print.python.builtin.object
Documented in
as.character.python.builtin.bytes
dict
iterate
iter_next
nameOfClass.python.builtin.type
py_bool
py_call
py_capture_output
py_clear_last_error
py_dict
py_ellipsis
py_eval
py_last_error
py_len
py_list_attributes
py_none
py_run_file
py_run_string
py_str
py_suppress_warnings
py_unicode
register_class_filter
register_suppress_warnings_handler
tuple
with.python.builtin.object
#' @export
print.python.builtin.object <- function(x, ...) {
writeLines(py_repr(x))
invisible(x)
}
#' @importFrom utils str
#' @export
str.python.builtin.object <- function(object, ...) {
if (!py_available() || py_is_null_xptr(object))
cat("<pointer: 0x0>\n")
else
cat(py_str(object), "\n", sep = "")
}
#' @export
str.python.builtin.module <- function(object, ...) {
if (py_is_module_proxy(object)) {
cat("Module(", get("module", envir = object), ")\n", sep = "")
} else {
cat(py_str(object), "\n", sep = "")
}
}
#' @export
as.character.python.builtin.object <- function(x, ...) {
py_str(x)
}
#' Convert Python bytes to an R character vector
#'
#' @inheritParams base::as.character
#'
#' @param encoding Encoding to use for conversion (defaults to utf-8)
#' @param errors Policy for handling conversion errors. Default is 'strict'
#' which raises an error. Other possible values are 'ignore' and 'replace'.
#'
#' @export
as.character.python.builtin.bytes <- function(x, encoding = "utf-8", errors = "strict", ...) {
x$decode(encoding = encoding, errors = errors)
}
.operators <- new.env(parent = emptyenv())
fetch_op <- function(nm, op, nargs = 1L) {
if (is.null(fn <- .operators[[nm]])) {
force(op)
if (nargs == 1L) {
call_op_and_maybe_convert <- function(...)
py_maybe_convert(op(...), py_has_convert(..1))
} else if (nargs == 2L) {
# Ops group generics
call_op_and_maybe_convert <- function(...) {
result <- op(...)
# if either dispatch object has convert=FALSE, don't convert
convert <-
!((is_py_object(..1) && !py_has_convert(..1)) ||
(is_py_object(..2) && !py_has_convert(..2)))
py_maybe_convert(result, convert)
}
} else stop("invalid nargs value: ", nargs)
fn <- .operators[[nm]] <- call_op_and_maybe_convert
}
fn
}
#' S3 Ops Methods for Python Objects
#'
#' Reticulate provides S3 Ops Group Generic Methods for Python objects. The methods
#' invoke the equivalent python method of the object.
#'
#' @param e1,e2,x,y A python object.
#'
#' @section Operator Mappings:
#'
#' | R expression | Python expression | First python method invoked |
#' | ------------- | ----------------- | --------------------------- |
#' | `x == y` | `x == y` | `type(x).__eq__(x, y)` |
#' | `x != y` | `x != y` | `type(x).__ne__(x, y)` |
#' | `x < y` | `x < y` | `type(x).__lt__(x, y)` |
#' | `x > y` | `x > y` | `type(x).__gt__(x, y)` |
#' | `x >= y` | `x >= y` | `type(x).__ge__(x, y)` |
#' | `x <= y` | `x <= y` | `type(x).__le__(x, y)` |
#' | `+ x ` | `+ x` | `type(x).__pos__(x)` |
#' | `- y` | `- x` | `type(x).__neg__(x)` |
#' | `x + y` | `x + y` | `type(x).__add__(x, y)` |
#' | `x - y` | `x - y` | `type(x).__sub__(x, y)` |
#' | `x * y` | `x * y` | `type(x).__mul__(x, y)` |
#' | `x / y` | `x / y` | `type(x).__truediv__(x, y)` |
#' | `x %/% y` | `x // y` | `type(x).__floordiv__(x, y)` |
#' | `x %% y` | `x % y` | `type(x).__mod__(x, y)` |
#' | `x ^ y` | `x ** y` | `type(x).__pow__(x, y)` |
#' | `x & y` | `x & y` | `type(x).__and__(x, y)` |
#' | \code{x | y} | \code{x | y} | `type(x).__or__(x, y)` |
#' | `!x` | `~x` | `type(x).__not__(x)` |
#' | `x %*% y` | `x @ y` | `type(x).__matmul__(x, y)`|
#'
#' Note: If the initial Python method invoked raises a `NotImplemented`
#' Exception, the Python interpreter will attempt to use the reflected
#' variant of the method from the second argument. The arithmetic operators
#' will call the equivalent double underscore (dunder) method with an "r" prefix. For
#' instance, when evaluating the expression `x + y`, if `type(x).__add__(x, y)`
#' raises a `NotImplemented` exception, then the interpreter will attempt
#' `type(y).__radd__(y, x)`. The comparison operators follow a different
#' sequence of fallbacks; refer to the Python documentation for more details.
#'
#' @return Result from evaluating the Python expression. If either of the
#' arguments to the operator was a Python object with `convert=FALSE`, then
#' the result will also be a Python object with `convert=FALSE` set.
#' Otherwise, the result will be converted to an R object if possible.
#' @rdname Ops-python-methods
#' @export
"==.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("eq", py_eval("lambda e1, e2: e1 == e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"!=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("ne", py_eval("lambda e1, e2: e1 != e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"<.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("lt", py_eval("lambda e1, e2: e1 < e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
">.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("gt", py_eval("lambda e1, e2: e1 > e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
">=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("ge", py_eval("lambda e1, e2: e1 >= e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"<=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("le", py_eval("lambda e1, e2: e1 <= e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
# This uses PyObject_RichCompareBool(), which expects only py bools.
# It will throw an exception on, e.g., with numpy arrays,
# even though numpy.ndarray defines an __eq__() method.
py_compare <- function(a, b, op) {
py_validate_xptr(a)
if (!inherits(b, "python.builtin.object"))
b <- r_to_py(b)
py_validate_xptr(b)
py_compare_impl(a, b, op)
}
#' @rdname Ops-python-methods
#' @export
`+.python.builtin.object` <- function(e1, e2) {
if (missing(e2)) {
op <- fetch_op("pos", py_eval("lambda e1: +e1", convert = FALSE))
return(op(e1))
}
op <- fetch_op("add", py_eval("lambda e1, e2: e1 + e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`-.python.builtin.object` <- function(e1, e2) {
if (missing(e2)) {
op <- fetch_op("neg", py_eval("lambda e1: -e1", convert = FALSE))
return(op(e1))
}
op <- fetch_op("sub", py_eval("lambda e1, e2: e1 - e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`*.python.builtin.object` <-function(e1, e2) {
op <- fetch_op("*", py_eval("lambda e1, e2: e1 * e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`/.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("/", py_eval("lambda e1, e2: e1 / e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`%/%.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("//", py_eval("lambda e1, e2: e1 // e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`%%.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("%", py_eval("lambda e1, e2: e1 % e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`^.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("pow", import_builtins(FALSE)$pow,
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`&.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("&", py_eval("lambda e1, e2: e1 & e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`|.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("|", py_eval("lambda e1, e2: e1 | e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`!.python.builtin.object` <- function(e1) {
op <- fetch_op("~", py_eval("lambda e1: ~ e1", convert = FALSE))
op(e1)
}
#' @rdname Ops-python-methods
#' @rawNamespace if (getRversion() >= "4.3.0") S3method("%*%",python.builtin.object)
`%*%.python.builtin.object` <-function(x, y) {
op <- fetch_op("@", py_eval("lambda x, y: x @ y", convert = FALSE),
nargs = 2L)
op(x, y)
}
#' @export
summary.python.builtin.object <- function(object, ...) {
str(object)
}
py_has_convert <- py_get_convert
py_maybe_convert <- function(x, convert) {
if(convert)
x <- py_to_r(x)
x
}
# helper function for accessing attributes or items from a
# Python object, after validating that we do indeed have
# a valid Python object reference
py_get_attr_or_item <- function(x, name, prefer_attr) {
# skip if this is a NULL xptr
if (py_is_null_xptr(x))
return(NULL)
# re-cast numeric values as integers
if (is.numeric(name))
name <- as.integer(name)
# attributes must always be indexed by strings, so if
# we receive a non-string 'name', we call py_get_item
if (!is.character(name)) {
item <- py_get_item(x, name)
return(py_maybe_convert(item, py_has_convert(x)))
}
# get the attrib and convert as needed
object <- NULL
if (prefer_attr) {
object <- py_get_attr(x, name)
} else {
# if we have an attribute, attempt to get the item
# but allow for fallback to that attribute. note that
# the logic here is fairly convoluted but is necessary
# to maintain backwards compatibility with a number of
# CRAN packages (hopefully we can simplify this in the
# future)
if (py_has_attr(x, name)) {
# try to get item
if (py_has_attr(x, "__getitem__"))
object <- py_get_item(x, name, silent = TRUE)
# fallback to attribute
if (is.null(object))
object <- py_get_attr(x, name)
} else {
# we don't have an attribute; only attempt item
# access and allow normal error propagation
object <- py_get_item(x, name)
}
}
py_maybe_convert(object, py_has_convert(x))
}
#' @export
`$.python.builtin.object` <- function(x, name) {
py_get_attr_or_item(x, name, TRUE)
}
#' @export
`[[.python.builtin.object` <- function(x, name) {
py_get_attr_or_item(x, name, FALSE)
}
#' @export
`$.python.builtin.module` <- function(x, name) {
attr <- py_get_attr(x, name, TRUE)
if(!is.null(attr))
return(py_maybe_convert(attr, py_has_convert(x)))
# special handling for embedded modules (which don't always show
# up as "attributes")
module <- py_get_submodule(x, name, py_has_convert(x))
if (!is.null(module))
return(module)
# fall back to raising the AttributeError
py_get_attr(x, name, FALSE)
}
# the as.environment generic enables python objects that manifest
# as R functions (e.g. for functions, classes, callables, etc.) to
# be resolve the environment containing the external pointer (the "refenv")
# This is still useful e.g., for passing to assign("convert", x, as.environment(x)).
# This was previously the primary mechanism that allowed for constructing
# PyObjectRefs from closures, before PyObjectRefs was refactored. The S3 generic
# is retained for backwards-compatability.
#' @export
as.environment.python.builtin.object <- function(x) {
if (is.function(x))
attr(x, "py_object")
else
x
}
#' @export
`$<-.python.builtin.object` <- function(x, name, value) {
if (!py_is_null_xptr(x) && py_available())
py_set_attr(x, name, value)
else
stop("Unable to assign value (object reference is NULL)")
x
}
#' @export
`[[<-.python.builtin.object` <- `$<-.python.builtin.object`
#' @export
.DollarNames.python.builtin.module <- function(x, pattern = "") {
# resolve module proxies (ignore errors since this is occurring during completion)
if (py_is_module_proxy(x)) {
result <- tryCatch({
py_resolve_module_proxy(x)
TRUE
}, error = clear_error_handler(FALSE))
if (!result)
return(character())
}
# delegate
.DollarNames.python.builtin.object(x, pattern)
}
#' @importFrom utils .DollarNames
#' @export
.DollarNames.python.builtin.object <- function(x, pattern = "") {
# skip if this is a NULL xptr
if (py_is_null_xptr(x) || !py_available())
return(character())
# check for dictionary
if (inherits(x, "python.builtin.dict")) {
names <- py_dict_get_keys_as_str(x)
names <- names[substr(names, 1, 1) != '_']
Encoding(names) <- "UTF-8"
types <- rep_len(0L, length(names))
} else {
# get the names and filter out internal attributes (_*)
names <- py_suppress_warnings(py_list_attributes(x))
names <- names[substr(names, 1, 1) != '_']
# replace function with `function`
names <- sub("^function$", "`function`", names)
names <- sort(names, decreasing = FALSE)
# get the types
types <- py_suppress_warnings(py_get_attr_types(x, names))
}
# if this is a module then add submodules
if (inherits(x, "python.builtin.module")) {
name <- py_get_name(x)
if (!is.null(name)) {
submodules <- sort(py_list_submodules(name), decreasing = FALSE)
Encoding(submodules) <- "UTF-8"
names <- c(names, submodules)
types <- c(types, rep_len(5L, length(submodules)))
}
}
idx <- grepl(pattern, names)
names <- names[idx]
types <- types[idx]
if (length(names) > 0) {
# set types
oidx <- order(names)
names <- names[oidx]
attr(names, "types") <- types[oidx]
# specify a help_handler
attr(names, "helpHandler") <- "reticulate:::help_handler"
}
# return
names
}
#' @export
names.python.builtin.object <- function(x) {
as.character(.DollarNames(x))
}
#' @export
names.python.builtin.module <- function(x) {
as.character(.DollarNames(x))
}
#' @export
as.array.numpy.ndarray <- function(x, ...) {
py_to_r(x)
}
#' @export
as.matrix.numpy.ndarray <- function(x, ...) {
py_to_r(x)
}
#' @export
as.vector.numpy.ndarray <- function(x, mode = "any") {
a <- as.array(x)
as.vector(a, mode = mode)
}
#' @export
as.double.numpy.ndarray <- function(x, ...) {
a <- as.array(x)
as.double(a)
}
#' @importFrom graphics plot
#' @export
plot.numpy.ndarray <- function(x, y, ...) {
plot(as.array(x))
}
#' Create Python dictionary
#'
#' Create a Python dictionary object, including a dictionary whose keys are
#' other Python objects rather than character vectors.
#'
#' @param ... Name/value pairs for dictionary (or a single named list to be
#' converted to a dictionary).
#' @param keys Keys to dictionary (can be Python objects)
#' @param values Values for dictionary
#' @param convert `TRUE` to automatically convert Python objects to their R
#' equivalent. If you pass `FALSE` you can do manual conversion using the
#' [py_to_r()] function.
#'
#' @return A Python dictionary
#'
#' @note The returned dictionary will not automatically convert its elements
#' from Python to R. You can do manual conversion with the [py_to_r()]
#' function or pass `convert = TRUE` to request automatic conversion.
#'
#' @export
dict <- function(..., convert = FALSE) {
# get the args
values <- list(...)
# flag indicating whether we should scan the parent frame for python
# objects that should serve as the key (e.g. a Tensor)
scan_parent_frame <- TRUE
# if there is a single element and it's a list then use that
if (length(values) == 1L && is.null(names(values)) && is.list(values[[1L]])) {
values <- values[[1]]
scan_parent_frame <- FALSE
}
# get names
names <- names(values)
# evaluate names in parent env to get keys
frame <- parent.frame()
keys <- lapply(names, function(name) {
# allow python objects to serve as keys
if (scan_parent_frame && exists(name, envir = frame, inherits = TRUE)) {
key <- get(name, envir = frame, inherits = TRUE)
if (is_py_object(key))
key
else
name
} else {
if (grepl("^[0-9]+$", name))
name <- as.integer(name)
else
name
}
})
# construct dict
py_dict_impl(keys, values, convert = convert)
}
#' @rdname dict
#' @export
py_dict <- function(keys, values, convert = FALSE) {
py_dict_impl(keys, values, convert = convert)
}
#' Create Python tuple
#'
#' Create a Python tuple object
#'
#' @inheritParams dict
#' @param ... Values for tuple (or a single list to be converted to a tuple).
#'
#' @return A Python tuple
#' @note The returned tuple will not automatically convert its elements from
#' Python to R. You can do manual conversion with the [py_to_r()] function or
#' pass `convert = TRUE` to request automatic conversion.
#'
#' @export
tuple <- function(..., convert = FALSE) {
# get the args
values <- list(...)
# if it's a single value then maybe do some special resolution
if (length(values) == 1L) {
# alias value
value <- values[[1L]]
# reflect tuples back
if (inherits(value, "python.builtin.tuple"))
return(value)
# if it's a list then use the list as the values
if (is.list(value))
values <- value
}
# construct tuple
py_tuple(values, convert = convert)
}
#' @export
length.python.builtin.tuple <- function(x) {
if (py_is_null_xptr(x) || !py_available())
0L
else
py_tuple_length(x)
}
#' Length of Python object
#'
#' Get the length of a Python object. This is equivalent to calling
#' the Python builtin `len()` function on the object.
#'
#' Not all Python objects have a defined length. For objects without a defined
#' length, calling `py_len()` will throw an error. If you'd like to instead
#' infer a default length in such cases, you can set the `default` argument
#' to e.g. `1L`, to treat Python objects without a `__len__` method as having
#' length one.
#'
#' @param x A Python object.
#'
#' @param default The default length value to return, in the case that
#' the associated Python object has no `__len__` method. When `NULL`
#' (the default), an error is emitted instead.
#'
#' @return The length of the object, as a numeric value.
#'
#' @export
py_len <- function(x, default = NULL) {
# return 0 if Python not yet available
if (py_is_null_xptr(x) || !py_available())
return(0L)
# delegate to C++
py_len_impl(x, default)
}
#' @export
length.python.builtin.list <- function(x) {
py_list_length(x)
}
#' @export
length.python.builtin.object <- function(x) {
# return 0 if Python not yet available
if (py_is_null_xptr(x) || !py_available())
return(0L)
# otherwise, try to invoke the object's __len__ method
n <- py_len_impl(x, NA_integer_)
# if the object didn't have a __len__() method, or __len__() raised an
# Exception, try instead to invoke its __bool__() method.
if (is.na(n)) {
n <- as.integer(py_bool_impl(x, TRUE))
# py_bool_impl( ,TRUE) can also return NA if __bool__() raised an exception.
# length() is used extensively in R and must be safe to call, so we don't
# want to propagate the Python Exception and signal an R error, but also
# don't want to return a false result. We balance concerns by returning NA.
}
n
}
#' Python Truthiness
#'
#' Equivalent to `bool(x)` in Python, or `not not x`.
#'
#' If the Python object defines a `__bool__` method, then that is invoked.
#' Otherwise, if the object defines a `__len__` method, then `TRUE` is
#' returned if the length is nonzero. If neither `__len__` nor `__bool__`
#' are defined, then the Python object is considered `TRUE`.
#'
#' @param x, A python object.
#'
#' @return An R scalar logical: `TRUE` or `FALSE`. If `x` is a
#' null pointer or Python is not initialized, `FALSE` is returned.
#' @export
py_bool <- function(x) {
if (py_is_null_xptr(x) || !py_available())
FALSE
else
py_bool_impl(x)
}
#' Convert to Python Unicode Object
#'
#' @param str Single element character vector to convert
#'
#' @details By default R character vectors are converted to Python strings.
#' In Python 3 these values are unicode objects however in Python 2
#' they are 8-bit string objects. This function enables you to
#' obtain a Python unicode object from an R character vector
#' when running under Python 2 (under Python 3 a standard Python
#' string object is returned).
#'
#' @export
py_unicode <- function(str) {
if (is_python3()) {
r_to_py(str)
} else {
py <- import_builtins()
py_call(py_get_attr(py, "unicode"), str)
}
}
#' Evaluate an expression within a context.
#'
#' The \code{with} method for objects of type \code{python.builtin.object}
#' implements the context manager protocol used by the Python \code{with}
#' statement. The passed object must implement the
#' \href{https://docs.python.org/3/reference/datamodel.html#context-managers}{context
#' manager} (\code{__enter__} and \code{__exit__} methods.
#'
#' @param data Context to enter and exit
#' @param expr Expression to evaluate within the context
#' @param as Name of variable to assign context to for the duration of the
#' expression's evaluation (optional).
#' @param ... Unused
#'
#' @export
with.python.builtin.object <- function(data, expr, as = NULL, ...) {
# enter the context
context <- data$`__enter__`()
# check for as and as_envir
if (!missing(as)) {
as <- deparse(substitute(as))
as <- gsub("\"", "", as)
} else {
as <- attr(data, "as")
}
envir <- attr(data, "as_envir")
if (is.null(envir))
envir <- parent.frame()
# assign the context if we have an as parameter
if (!is.null(as)) {
assign(as, context, envir = envir)
}
# evaluate the expression and exit the context
tryCatch(force(expr),
finally = {
data$`__exit__`(NULL, NULL, NULL)
}
)
}
#' Create local alias for objects in \code{with} statements.
#'
#' @param object Object to alias
#' @param name Alias name
#'
#' @name with-as-operator
#'
#' @keywords internal
#' @export
"%as%" <- function(object, name) {
as <- deparse(substitute(name))
as <- gsub("\"", "", as)
attr(object, "as") <- as
attr(object, "as_envir") <- parent.frame()
object
}
#' Traverse a Python iterator or generator
#'
#' @param x Python iterator or iterable
#' @param it Python iterator or generator
#' @param f Function to apply to each item. By default applies the
#' \code{identity} function which just reflects back the value of the item.
#' @param simplify Should the result be simplified to a vector if possible?
#' @param completed Sentinel value to return from `iter_next()` if the iteration
#' completes (defaults to `NULL` but can be any R value you specify).
#'
#' @return For `iterate()`, A list or vector containing the results of calling
#' \code{f} on each item in \code{x} (invisibly); For `iter_next()`, the next
#' value in the iteration (or the sentinel `completed` value if the iteration
#' is complete).
#'
#' @details Simplification is only attempted all elements are length 1 vectors
#' of type "character", "complex", "double", "integer", or "logical".
#'
#' @export
iterate <- function(it, f = base::identity, simplify = TRUE) {
invisible(py_iterate(it, f, simplify))
}
#' @rdname iterate
#' @export
iter_next <- function(it, completed = NULL) {
py_iter_next(it, completed)
}
#' Call a Python callable object
#'
#' @param ... Arguments to function (named and/or unnamed)
#'
#' @return Return value of call as a Python object.
#'
#' @keywords internal
#'
#' @export
py_call <- function(x, ...) {
dots <- split_named_unnamed(list(...))
py_call_impl(x, dots$unnamed, dots$named)
}
#' The Python None object
#'
#' Get a reference to the Python `None` object.
#'
#' @export
py_none <- function() {
py_none_impl()
}
#' List all attributes of a Python object
#'
#'
#' @param x Python object
#'
#' @return Character vector of attributes
#' @export
py_list_attributes <- function(x) {
attrs <- py_list_attributes_impl(x)
Encoding(attrs) <- "UTF-8"
attrs
}
#' String representation of a python object.
#'
#' This is equivalent to calling `str(object)` or `repr(object)` in Python.
#'
#' In Python, calling `print()` invokes the builtin `str()`, while auto-printing
#' an object at the REPL invokes the builtin `repr()`.
#'
#' In \R, the default print method for python objects invokes `py_repr()`, and
#' the default `format()` and `as.character()` methods invoke `py_str()`.
#'
#' For historical reasons, `py_str()` is also an \R S3 method that allows R
#' authors to customize the the string representation of a Python object from R.
#' New code is recommended to provide a `format()` and/or `print()` S3 R method
#' for python objects instead.
#'
#' @param object Python object
#' @param ... Unused
#'
#' @return Character vector
#'
#' @details The default implementation will call `PyObject_Str` on the object.
#'
#' @export
py_str <- function(object, ...) {
if (!is_py_object(object))
"<not a python object>"
else if (py_is_null_xptr(object) || !py_available())
"<pointer: 0x0>"
else
UseMethod("py_str")
}
#' @export
py_str.default <- function(object, ...) {
"<not a python object>"
}
#' @export
py_str.python.builtin.object <- function(object, ...) {
py_str_impl(object)
}
#' @export
format.python.builtin.module <- function(x, ...) {
if(py_is_module_proxy(x))
return(paste0("Module(", get("module", envir = x), ")", sep = ""))
NextMethod()
}
#' @export
format.python.builtin.object <- function(x, ...) {
if (py_is_null_xptr(x) || !py_available())
return("<pointer: 0x0>")
# get default rep, potentially user defined S3
str <- py_str(x)
# remove e.g. 'object at 0x10d084710'
str <- gsub(" object at 0x\\w{4,}", "", str)
# return
str
}
#' @export
py_str.python.builtin.bytearray <- function(object, ...) {
paste0("python.builtin.bytearray (", py_len_impl(object), " bytes)")
}
#' @export
py_str.python.builtin.module <- function(object, ...) {
paste0("Module(", py_get_name(object), ")")
}
#' @export
py_str.python.builtin.list <- function(object, ...) {
py_collection_str("List", object)
}
#' @export
py_str.python.builtin.dict <- function(object, ...) {
py_collection_str("Dict", object)
}
#' @export
py_str.python.builtin.tuple <- function(object, ...) {
py_collection_str("Tuple", object)
}
py_collection_str <- function(name, object) {
len <- py_len_impl(object)
if (len > 10)
paste0(name, " (", len, " items)")
else
py_str.python.builtin.object(object)
}
.print.via.format <- function(x, ...) {
writeLines(format(x, ...))
invisible(x)
}
#' @export
print.python.builtin.bytearray <- .print.via.format
#' @export
print.python.builtin.tuple <- .print.via.format
#' @export
print.python.builtin.module <- .print.via.format
#' @export
print.python.builtin.list <- .print.via.format
#' @export
print.python.builtin.dict <- .print.via.format
#' Suppress Python warnings for an expression
#'
#' @param expr Expression to suppress warnings for
#'
#' @return Result of evaluating expression
#'
#' @export
py_suppress_warnings <- function(expr) {
ensure_python_initialized()
# ignore any registered warning output types (e.g. tf warnings)
contexts <- lapply(.globals$suppress_warnings_handlers, function(handler) {
handler$suppress()
})
on.exit({
if (length(contexts) > 0) {
for (i in 1:length(contexts)) {
handler <- .globals$suppress_warnings_handlers[[i]]
handler$restore(contexts[[i]])
}
}
}, add = TRUE)
# evaluate while ignoring python warnings
warnings <- import("warnings")
with(warnings$catch_warnings(), expr)
}
#' Register a handler for calls to py_suppress_warnings
#'
#' @param handler Handler
#'
#' @details Enables packages to register a pair of functions
#' to be called to suppress and then re-enable warnings
#'
#' @keywords internal
#' @export
register_suppress_warnings_handler <- function(handler) {
.globals$suppress_warnings_handlers[[length(.globals$suppress_warnings_handlers) + 1]] <- handler
}
#' Register a filter for class names
#'
#' @param filter Function which takes a class name and maps it to an alternate
#' name
#'
#' @keywords internal
#' @export
register_class_filter <- function(filter) {
.globals$class_filters[[length(.globals$class_filters) + 1]] <- filter
}
#' Capture and return Python output
#'
#' @param expr Expression to capture stdout for
#' @param type Streams to capture (defaults to both stdout and stderr)
#'
#' @return Character vector with output
#'
#' @export
py_capture_output <- function(expr, type = c("stdout", "stderr")) {
# initialize python if necessary
# without expressing an implict venv preference
# via an internal import() call
ensure_python_initialized()
# resolve type argument
type <- match.arg(type, several.ok = TRUE)
# get output tools helper functions
output_tools <- import("rpytools.output")
# scope output capture
capture_stdout <- "stdout" %in% type
capture_stderr <- "stderr" %in% type
context_manager <- output_tools$OutputCaptureContext(
capture_stdout, capture_stderr
)
context_manager$`__enter__`()
tryCatch(
force(expr),
finally = {
context_manager$`__exit__`()
}
)
# collect output
context_manager$collect_output()
}
#' Run Python code
#'
#' Execute code within the scope of the \code{__main__} Python module.
#'
#' @inheritParams import
#'
#' @param code The Python code to be executed.
#' @param file The Python script to be executed.
#' @param local Boolean; should Python objects be created as part of
#' a local / private dictionary? If `FALSE`, objects will be created within
#' the scope of the Python main module.
#' @param prepend_path Boolean; should the script directory be added to the
#' Python module search path? The default, `TRUE`, matches the behavior of
#' `python <path/to/script.py>` at the command line.
#'
#' @return A Python dictionary of objects. When `local` is `FALSE`, this
#' dictionary captures the state of the Python main module after running
#' the provided code. Otherwise, only the variables defined and used are
#' captured.
#'
#' @name py_run
#'
#' @export
py_run_string <- function(code, local = FALSE, convert = TRUE) {
invisible(py_run_string_impl(code, local, convert))
}
#' @rdname py_run
#' @export
py_run_file <- function(file, local = FALSE, convert = TRUE, prepend_path = TRUE) {
ensure_python_initialized()
file <- path.expand(file)
if (prepend_path) {
sys <- import("sys", convert = FALSE)
sys$path$insert(0L, dirname(file))
on.exit(sys$path$remove(dirname(file)), add = TRUE)
}
invisible(py_run_file_impl(file, local, convert))
}
#' Evaluate a Python Expression
#'
#' Evaluate a single Python expression, in a way analogous to the Python
#' `eval()` built-in function.
#'
#' @param code A single Python expression.
#' @param convert Boolean; automatically convert Python objects to R?
#'
#' @return The result produced by evaluating `code`, converted to an `R`
#' object when `convert` is set to `TRUE`.
#'
#' @section Caveats:
#'
#' `py_eval()` only supports evaluation of 'simple' Python expressions.
#' Other expressions (e.g. assignments) will fail; e.g.
#'
#' ```
#' > py_eval("x = 1")
#' Error in py_eval_impl(code, convert) :
#' SyntaxError: invalid syntax (reticulate_eval, line 1)
#' ```
#'
#' and this mirrors what one would see in a regular Python interpreter:
#'
#' ```
#' >>> eval("x = 1")
#' Traceback (most recent call last):
#' File "<stdin>", line 1, in <module>
#' File "<string>", line 1
#' x = 1
#' ^
#' SyntaxError: invalid syntax
#' ```
#'
#' The [py_run_string()] method can be used if the evaluation of arbitrary
#' Python code is required.
#'
#' @export
py_eval <- function(code, convert = TRUE) {
py_eval_impl(code, convert)
}
#' The builtin constant Ellipsis
#'
#' @export
py_ellipsis <- function() {
builtins <- import_builtins(convert = FALSE)
builtins$Ellipsis
}
#' @importFrom rlang list2
py_callable_as_function <- function(callable) {
force(callable)
as.function.default(c(py_get_formals(callable), quote({
cl <- sys.call()
cl[[1L]] <- list2
call_args <- split_named_unnamed(eval(cl, parent.frame()))
result <- py_call_impl(callable, call_args$unnamed, call_args$named)
if(py_get_convert(callable))
result <- py_to_r(result)
if (is.null(result))
invisible(result)
else
result
})))
}
split_named_unnamed <- function(x) {
nms <- names(x)
if (is.null(nms))
return(list(unnamed = x, named = list()))
named <- nzchar(nms)
list(unnamed = x[!named], named = x[named])
}
py_is_module <- function(x) {
inherits(x, "python.builtin.module")
}
py_is_module_proxy <- function(x) {
typeof(x) == "environment" &&
exists("module", envir = x, inherits = FALSE) &&
inherits(x, "python.builtin.module")
}
py_resolve_module_proxy <- function(proxy) {
if(!py_is_module_proxy(proxy))
return(FALSE)
# collect module proxy hooks
collect_value <- function(name, clear = TRUE) {
if (exists(name, envir = proxy, inherits = FALSE)) {
value <- get(name, envir = proxy, inherits = FALSE)
if (clear)
remove(list = name, envir = proxy)
value
} else {
NULL
}
}
# name of module to import (allow just in time customization via hook)
get_module <- collect_value("get_module")
if (!is.null(get_module))
assign("module", get_module(), envir = proxy)
# get module name
module <- get("module", envir = proxy)
# execute before load handler
before_load <- collect_value("before_load", clear = TRUE)
if (is.function(before_load))
before_load()
# perform the import -- capture error and amend it with
# python configuration information if we have it
result <- tryCatch(import(module), error = clear_error_handler())
if (inherits(result, "error")) {
# load and error handlers
on_error <- collect_value("on_error", clear = FALSE)
if (!is.null(on_error)) {
# call custom error handler
if (is.function(on_error))
on_error(result)
# error handler can and should call `stop`, this is just a failsafe
stop("Error loading Python module ", module, call. = FALSE)
} else {
# default error message/handler
message <- py_config_error_message(paste("Python module", module, "was not found."))
stop(message, call. = FALSE)
}
}
# clear any custom 'on_error' hook
collect_value("on_error", clear = TRUE)
# clear the global tracking of delay load modules
.globals$delay_load_imports <- NULL
# fixup the proxy. Note, the proxy may have already been fixed up,
# if `import(module)` triggered hooks to run registered via
# (unexported) py_register_load_hook()
py_module_proxy_import(proxy)
# call on_load if provided
on_load <- collect_value("on_load", clear = TRUE)
if (is.function(on_load))
on_load()
TRUE
}
py_get_name <- function(x) {
py_to_r(py_get_attr(x, "__name__"))
}
py_get_submodule <- function(x, name, convert = TRUE) {
module_name <- paste(py_get_name(x), name, sep=".")
result <- tryCatch(import(module_name, convert = convert),
error = clear_error_handler())
if (inherits(result, "error"))
NULL
else
result
}
py_filter_classes <- function(classes) {
for (filter in .globals$class_filters)
classes <- filter(classes)
classes
}
py_inject_r <- function() {
# don't inject 'r' if there's already an 'r' object defined
main <- import_main(convert = FALSE)
if (py_has_attr(main, "r"))
return(FALSE)
# define our 'R' class
py_run_string("class R(object): pass")
# extract it from the main module
main <- import_main(convert = FALSE)
R <- main$R
# define the getters, setters we'll attach to the Python class
getter <- function(self, code) {
envir <- py_resolve_envir()
object <- eval(parse(text = as_r_value(code)), envir = envir)
r_to_py(object, convert = is.function(object))
}
setter <- function(self, name, value) {
envir <- py_resolve_envir()
name <- as_r_value(name)
value <- as_r_value(value)
assign(name, value, envir = envir)
}
py_set_attr(R, "__getattr__", getter)
py_set_attr(R, "__setattr__", setter)
py_set_attr(R, "__getitem__", getter)
py_set_attr(R, "__setitem__", setter)
# now define the R object
py_run_string("r = R()")
# remove the 'R' class object
py_del_attr(main, "R")
# indicate success
TRUE
}
py_resolve_envir <- function() {
# if an environment has been set, use it
envir <- getOption("reticulate.engine.environment")
if (is.environment(envir))
return(envir)
# if we're running in a knitr document, use the knit env
if ("knitr" %in% loadedNamespaces()) {
.knitEnv <- yoink("knitr", ".knitEnv")
envir <- .knitEnv$knit_global
if (is.environment(envir))
return(envir)
}
# if we're running in a testthat test, use the rlang reported envir
envir <- getOption("rlang_trace_top_env")
if (is.environment(envir))
return(envir)
# otherwise, default to the global environment
envir %||% globalenv()
}
py_inject_hooks <- function() {
builtins <- import_builtins(convert = TRUE)
input <- function(prompt = "") {
response <- tryCatch(
readline(prompt),
interrupt = identity
)
if (inherits(response, "interrupt"))
stop("KeyboardInterrupt", call. = FALSE)
r_to_py(response)
}
# override input function
if (interactive() && was_python_initialized_by_reticulate()) {
name <- if (is_python3()) "input" else "raw_input"
builtins[[name]] <- input
}
# register module import callback
useImportHook <- getOption("reticulate.useImportHook", default = is_python3())
if (useImportHook) {
loader <- import("rpytools.loader", convert = TRUE)
loader$initialize(py_module_onload)
}
}
py_module_onload <- function(module) {
# log module loading if requested
if (getOption("reticulate.logModuleLoad", default = FALSE)) {
writeLines(sprintf("Loaded module '%s'", module))
}
# retrieve and clear list of hooks
hookName <- paste("reticulate", module, "load", sep = "::")
hooks <- getHook(hookName)
setHook(hookName, NULL, action = "replace")
# run hooks
for (hook in hooks)
tryCatch(hook(), error = warning)
}
py_module_loaded <- function(module) {
if(is_python_initialized()) {
sys <- import("sys", convert = TRUE)
modules <- names(sys$modules)
} else
modules <- NULL
module %in% modules
}
py_register_load_hook <- function(module, hook) {
# if the module is already loaded, just run the hook
if (py_module_loaded(module))
return(hook())
# otherwise, register the hook to be run on next load
name <- paste("reticulate", module, "load", sep = "::")
setHook(name, hook)
}
#' `nameOfClass()` for Python objects
#'
#' This generic enables passing a `python.builtin.type` object as the 2nd
#' argument to `base::inherits()`.
#'
#' @param x A Python class
#'
#' @return A scalar string matching the S3 class of objects constructed from the
#' type.
#'
#' @rawNamespace if (getRversion() >= "4.3.0") S3method(nameOfClass,python.builtin.type)
#' @examples
#' \dontrun{
#' numpy <- import("numpy")
#' x <- r_to_py(array(1:3))
#' inherits(x, numpy$ndarray)
#' }
nameOfClass.python.builtin.type <- function(x) {
paste(
as_r_value(py_get_attr(x, "__module__")),
as_r_value(py_get_attr(x, "__name__")),
sep = "."
)
}
#' @rawNamespace if (getRversion() >= "4.3.0") S3method(chooseOpsMethod,python.builtin.object)
chooseOpsMethod.python.builtin.object <- function(x, y, mx, my, cl, reverse) {
# If both objects are python objects, and
# 'my' is the default Ops method provided by reticulate
# (e.g, its environment is the reticulate namespace)
# then 'mx' must be the more specific method, select mx.
# e.g.,:
# x class: tensorflow.tensor ... python.builtin.object
# y class: numpy.ndarray python.builtin.object
# 'x * y' gives
# Warning: Incompatible methods ("*.tensorflow.tensor", "*.python.builtin.object") for "*"
# Error in img * x : non-numeric argument to binary operator
inherits(y, "python.builtin.object") &&
identical(environment(my), parent.env(environment()))
}
py_set_interrupt <- function() {
py_set_interrupt_impl()
}
#' @export
format.python.builtin.traceback <- function(x, ..., limit = NULL) {
import("traceback")$format_tb(x, limit)
}
#' @rdname py_last_error
#' @export
py_clear_last_error <- function() {
py_last_error(NULL)
}
#' Get or (re)set the last Python error encountered.
#'
#' @param exception A python exception object. If provided, the provided
#' exception is set as the last exception.
#'
#' @return For `py_last_error()`, `NULL` if no error has yet been encountered.
#' Otherwise, a named list with entries:
#'
#' + `"type"`: R string, name of the exception class.
#'
#' + `"value"`: R string, formatted exception message.
#'
#' + `"traceback"`: R character vector, the formatted python traceback,
#'
#' + `"message"`: The full formatted raised exception, as it would be printed in
#' Python. Includes the traceback, type, and value.
#'
#' + `"r_trace"`: A `data.frame` with class `rlang_trace` and columns:
#'
#' - `call`: The R callstack, `full_call`, summarized for pretty printing.
#' - `full_call`: The R callstack. (Output of `sys.calls()` at the error callsite).
#' - `parent`: The parent of each frame in callstack. (Output of `sys.parents()` at the error callsite).
#' - Additional columns for internals use: `namespace`, `visible`, `scope`.
#'
#'
#'
#' And attribute `"exception"`, a `'python.builtin.Exception'` object.
#'
#' The named list has `class` `"py_error"`, and has a default `print` method
#' that is the equivalent of `cat(py_last_error()$message)`.
#'
#' @examples
#' \dontrun{
#'
#' # see last python exception with R traceback
#' reticulate::py_last_error()
#'
#' # see the full R callstack from the last Python exception
#' reticulate::py_last_error()$r_trace$full_call
#'
#' # run python code that might error,
#' # without modifying the user-visible python exception
#'
#' safe_len <- function(x) {
#' last_err <- py_last_error()
#' tryCatch({
#' # this might raise a python exception if x has no `__len__` method.
#' import_builtins()$len(x)
#' }, error = function(e) {
#' # py_last_error() was overwritten, is now "no len method for 'object'"
#' py_last_error(last_err) # restore previous exception
#' -1L
#' })
#' }
#'
#' safe_len(py_eval("object"))
#' }
#'
#' @export
py_last_error <- function(exception) {
if (!missing(exception)) {
if (is.null(exception))
return(.globals$py_last_exception <- .globals$last_r_trace <- NULL)
# set as the last exception
r_trace <- NULL
if (inherits(exception, "py_error")) {
r_trace <- exception$trace
exception <- attr(exception, "exception", TRUE)
}
if (is.null(r_trace))
r_trace <- as_r_value(py_get_attr(exception, "trace", TRUE))
if (!is.null(exception) &&
!inherits(exception, "python.builtin.Exception"))
stop("`exception` must be NULL, a `py_error`, or a 'python.builtin.Exception'")
on.exit({
.globals$py_last_exception <- exception
.globals$last_r_trace <- r_trace
})
return(invisible(.globals$py_last_exception))
}
e <- .globals$py_last_exception
if (is.null(e))
return(NULL)
if (!py_available() || py_is_null_xptr(e)) {
.globals$py_last_exception <- NULL
return(NULL)
}
etype <- py_get_attr(e, "__class__")
etb <- py_get_attr(e, "__traceback__", TRUE)
traceback <- import("traceback")
if(is.null(etb))
formatted_traceback <- NULL
else
formatted_traceback <- traceback$format_tb(etb)
out <- list(
type = py_get_attr(etype, "__name__", TRUE),
value = py_str_impl(e),
traceback = formatted_traceback,
message = paste0(traceback$format_exception(etype, e, etb),
collapse = "")
)
out$r_call <- conditionCall(e)
out$r_class <- as_r_value(py_get_attr(e, "r_class", TRUE)) %||% class(e)
out$r_trace <- py_get_attr(e, "trace", TRUE) %||% .globals$last_r_trace
out <- lapply(out, as_r_value)
attr(out, "exception") <- e
class(out) <- "py_error"
out
}
make_filepaths_clickable <- function(formatted_python_traceback) {
# Note, a first draft of this iterated over the list of FrameSummarys in
# the exception.__traceback__, but that approach breaks with keras.
# So now we use a regex instead (:sad:).
# See format_py_exception_traceback_with_clickable_filepaths()
# for the previous approach
x <- strsplit(formatted_python_traceback, "\n", fixed = TRUE)[[1L]]
if (!length(x))
return(formatted_python_traceback)
m <- regexec('File "([^"]+)", line ([0-9]+), in', x, perl = TRUE)
new <- lapply(regmatches(x, m), function(match) {
if (!length(match))
return(character())
filepath <- match[2]
lineno <- match[3]
if(!file.exists(file.path(filepath)))
return(filepath)
link <- cli::style_hyperlink(
filepath,
paste0("file://", normalizePath(filepath, mustWork = FALSE)),
params = c(line = lineno))
cli::col_grey(link)
})
m2 <- lapply(m, function(match_pos) {
if(identical(as.vector(match_pos), -1L))
return(match_pos)
out <- match_pos[2] # only match filepath
attr(out, "match.length") <- attr(match_pos, "match.length")[2]
out
})
regmatches(x, m2) <- new
if(x[length(x)] != "")
x <- c(x, "") # ensure we end w/ a newline
paste0(x, collapse = "\n")
}
## not exported because pillar only in suggests
## exported dynamically in .onLoad()
## @exportS3Method pillar::type_sum
type_sum.python.builtin.object <- function(x) {
s <- class(x)[[1L]]
if(startsWith(s, "R6type."))
s <- substr(s, 8L, 2147483647L)
s
}
#' @export
print.py_error <- function(x, ...) {
py_error_message <- x$message
if (identical(.Platform$GUI, "RStudio") &&
requireNamespace("cli", quietly = TRUE) &&
length(etb <- attr(x, "exception")$`__traceback__`))
py_error_message <- make_filepaths_clickable(py_error_message)
cat_h1("Python Exception Message")
cat(py_error_message)
cat_h1("R Traceback")
print(x$r_trace)
cat(.py_last_error_full_callstack_hint(), "\n", sep = "")
}
cat_h1 <- function(x) {
if(requireNamespace("cli", quietly = TRUE)) {
cli::cli_h1(x, .envir = NULL)
} else {
cat("--- ", x, "\n", sep = "")
}
}
format_py_exception_traceback_with_clickable_filepaths <- function(etb) {
# This is currently unused, but preserved here in case it's useful for future
# development. This is unused because keras/tensorflow hijacks the python
# exception __traceback__, making it effectively useless. Instead, keras
# formats the actual (user relevant) traceback info directly into the
# exception message (and nicely too! albeit verbosely. It includes detailed
# info about call args in each user frame, including tensor shapes and dtypes,
# and formats with indentation matching user-generated frame depth).
# Unfortunately, that means that building up a nice formatted traceback by
# iterating over the traceback FrameSummary objects won't work correctly. The
# alternative is to apply a regex to the message, as we do in
# make_filepaths_clickable() (:sad:)
if(is.null(etb)) return(NULL)
fsl <- import("traceback")$extract_tb(etb)
if(!length(fsl)) return(NULL)
paste0(collapse = "\n", c(
"Traceback (most recent call last):",
vapply(fsl, function(fs) {
# fs == FrameSummary obj, with attrs: filename, line, lineno, locals, name
filepath <- fs$filename
lineno <- fs$lineno
clickable_filepath <-
cli::style_hyperlink(
filepath,
paste0("file://", normalizePath(filepath, mustWork = FALSE)),
params = c(line = lineno)
)
sprintf(' File "%s", line %i, in %s\n %s',
clickable_filepath, lineno, fs$name, fs$line)
}, ""),
""))
}
.py_last_error_hint <- function() {
if(!interactive() ||
!identical(.Platform$GUI, "RStudio") ||
!requireNamespace("cli", quietly = TRUE))
return("Run `reticulate::py_last_error()` for details.")
py_last_error <- cli::style_hyperlink(
"`reticulate::py_last_error()`",
"rstudio:run:reticulate::py_last_error()")
cli::col_silver(paste("Run", py_last_error, "for details."))
}
.py_last_error_full_callstack_hint <- function() {
hint <- "See `reticulate::py_last_error()$r_trace$full_call` for more details."
if(!interactive() ||
!identical(.Platform$GUI, "RStudio") ||
!requireNamespace("cli", quietly = TRUE))
return(hint)
# # ide:run: / rstudio:run: links don't support expressions like this.
# last_error_unsummarized_callstack <- cli::style_hyperlink(
# "`reticulate::py_last_error()$r_trace$full_call`",
# "rstudio:run:reticulate::py_last_error()$r_trace$full_call")
# hint <- cli::col_silver(paste("See", last_error_unsummarized_callstack,
# "for more details."))
cli::col_silver(hint)
}
rstudio/reticulate documentation built on April 20, 2024, 3:17 p.m.
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Defines functions .py_last_error_full_callstack_hint .py_last_error_hint format_py_exception_traceback_with_clickable_filepaths cat_h1 print.py_error type_sum.python.builtin.object make_filepaths_clickable py_last_error py_clear_last_error format.python.builtin.traceback py_set_interrupt chooseOpsMethod.python.builtin.object nameOfClass.python.builtin.type py_register_load_hook py_module_loaded py_module_onload py_inject_hooks py_resolve_envir py_inject_r py_filter_classes py_get_submodule py_get_name py_resolve_module_proxy py_is_module_proxy py_is_module split_named_unnamed py_callable_as_function py_ellipsis py_eval py_run_file py_run_string py_capture_output register_class_filter register_suppress_warnings_handler py_suppress_warnings .print.via.format py_collection_str py_str.python.builtin.tuple py_str.python.builtin.dict py_str.python.builtin.list py_str.python.builtin.module py_str.python.builtin.bytearray format.python.builtin.object format.python.builtin.module py_str.python.builtin.object py_str.default py_str py_list_attributes py_none py_call iter_next iterate with.python.builtin.object py_unicode py_bool length.python.builtin.object length.python.builtin.list py_len length.python.builtin.tuple tuple py_dict dict plot.numpy.ndarray as.double.numpy.ndarray as.vector.numpy.ndarray as.matrix.numpy.ndarray as.array.numpy.ndarray names.python.builtin.module names.python.builtin.object .DollarNames.python.builtin.object .DollarNames.python.builtin.module `$<-.python.builtin.object` as.environment.python.builtin.object `$.python.builtin.module` `[[.python.builtin.object` `$.python.builtin.object` py_get_attr_or_item py_maybe_convert summary.python.builtin.object `%*%.python.builtin.object` `!.python.builtin.object` `|.python.builtin.object` `&.python.builtin.object` `^.python.builtin.object` `%%.python.builtin.object` `%/%.python.builtin.object` `/.python.builtin.object` `*.python.builtin.object` `-.python.builtin.object` `+.python.builtin.object` py_compare fetch_op as.character.python.builtin.bytes as.character.python.builtin.object str.python.builtin.module str.python.builtin.object print.python.builtin.object
Documented in as.character.python.builtin.bytes dict iterate iter_next nameOfClass.python.builtin.type py_bool py_call py_capture_output py_clear_last_error py_dict py_ellipsis py_eval py_last_error py_len py_list_attributes py_none py_run_file py_run_string py_str py_suppress_warnings py_unicode register_class_filter register_suppress_warnings_handler tuple with.python.builtin.object
#' @export
print.python.builtin.object <- function(x, ...) {
writeLines(py_repr(x))
invisible(x)
}
#' @importFrom utils str
#' @export
str.python.builtin.object <- function(object, ...) {
if (!py_available() || py_is_null_xptr(object))
cat("<pointer: 0x0>\n")
else
cat(py_str(object), "\n", sep = "")
}
#' @export
str.python.builtin.module <- function(object, ...) {
if (py_is_module_proxy(object)) {
cat("Module(", get("module", envir = object), ")\n", sep = "")
} else {
cat(py_str(object), "\n", sep = "")
}
}
#' @export
as.character.python.builtin.object <- function(x, ...) {
py_str(x)
}
#' Convert Python bytes to an R character vector
#'
#' @inheritParams base::as.character
#'
#' @param encoding Encoding to use for conversion (defaults to utf-8)
#' @param errors Policy for handling conversion errors. Default is 'strict'
#' which raises an error. Other possible values are 'ignore' and 'replace'.
#'
#' @export
as.character.python.builtin.bytes <- function(x, encoding = "utf-8", errors = "strict", ...) {
x$decode(encoding = encoding, errors = errors)
}
.operators <- new.env(parent = emptyenv())
fetch_op <- function(nm, op, nargs = 1L) {
if (is.null(fn <- .operators[[nm]])) {
force(op)
if (nargs == 1L) {
call_op_and_maybe_convert <- function(...)
py_maybe_convert(op(...), py_has_convert(..1))
} else if (nargs == 2L) {
# Ops group generics
call_op_and_maybe_convert <- function(...) {
result <- op(...)
# if either dispatch object has convert=FALSE, don't convert
convert <-
!((is_py_object(..1) && !py_has_convert(..1)) ||
(is_py_object(..2) && !py_has_convert(..2)))
py_maybe_convert(result, convert)
}
} else stop("invalid nargs value: ", nargs)
fn <- .operators[[nm]] <- call_op_and_maybe_convert
}
fn
}
#' S3 Ops Methods for Python Objects
#'
#' Reticulate provides S3 Ops Group Generic Methods for Python objects. The methods
#' invoke the equivalent python method of the object.
#'
#' @param e1,e2,x,y A python object.
#'
#' @section Operator Mappings:
#'
#' | R expression | Python expression | First python method invoked |
#' | ------------- | ----------------- | --------------------------- |
#' | `x == y` | `x == y` | `type(x).__eq__(x, y)` |
#' | `x != y` | `x != y` | `type(x).__ne__(x, y)` |
#' | `x < y` | `x < y` | `type(x).__lt__(x, y)` |
#' | `x > y` | `x > y` | `type(x).__gt__(x, y)` |
#' | `x >= y` | `x >= y` | `type(x).__ge__(x, y)` |
#' | `x <= y` | `x <= y` | `type(x).__le__(x, y)` |
#' | `+ x ` | `+ x` | `type(x).__pos__(x)` |
#' | `- y` | `- x` | `type(x).__neg__(x)` |
#' | `x + y` | `x + y` | `type(x).__add__(x, y)` |
#' | `x - y` | `x - y` | `type(x).__sub__(x, y)` |
#' | `x * y` | `x * y` | `type(x).__mul__(x, y)` |
#' | `x / y` | `x / y` | `type(x).__truediv__(x, y)` |
#' | `x %/% y` | `x // y` | `type(x).__floordiv__(x, y)` |
#' | `x %% y` | `x % y` | `type(x).__mod__(x, y)` |
#' | `x ^ y` | `x ** y` | `type(x).__pow__(x, y)` |
#' | `x & y` | `x & y` | `type(x).__and__(x, y)` |
#' | \code{x | y} | \code{x | y} | `type(x).__or__(x, y)` |
#' | `!x` | `~x` | `type(x).__not__(x)` |
#' | `x %*% y` | `x @ y` | `type(x).__matmul__(x, y)`|
#'
#' Note: If the initial Python method invoked raises a `NotImplemented`
#' Exception, the Python interpreter will attempt to use the reflected
#' variant of the method from the second argument. The arithmetic operators
#' will call the equivalent double underscore (dunder) method with an "r" prefix. For
#' instance, when evaluating the expression `x + y`, if `type(x).__add__(x, y)`
#' raises a `NotImplemented` exception, then the interpreter will attempt
#' `type(y).__radd__(y, x)`. The comparison operators follow a different
#' sequence of fallbacks; refer to the Python documentation for more details.
#'
#' @return Result from evaluating the Python expression. If either of the
#' arguments to the operator was a Python object with `convert=FALSE`, then
#' the result will also be a Python object with `convert=FALSE` set.
#' Otherwise, the result will be converted to an R object if possible.
#' @rdname Ops-python-methods
#' @export
"==.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("eq", py_eval("lambda e1, e2: e1 == e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"!=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("ne", py_eval("lambda e1, e2: e1 != e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"<.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("lt", py_eval("lambda e1, e2: e1 < e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
">.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("gt", py_eval("lambda e1, e2: e1 > e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
">=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("ge", py_eval("lambda e1, e2: e1 >= e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
"<=.python.builtin.object" <- function(e1, e2) {
op <- fetch_op("le", py_eval("lambda e1, e2: e1 <= e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
# This uses PyObject_RichCompareBool(), which expects only py bools.
# It will throw an exception on, e.g., with numpy arrays,
# even though numpy.ndarray defines an __eq__() method.
py_compare <- function(a, b, op) {
py_validate_xptr(a)
if (!inherits(b, "python.builtin.object"))
b <- r_to_py(b)
py_validate_xptr(b)
py_compare_impl(a, b, op)
}
#' @rdname Ops-python-methods
#' @export
`+.python.builtin.object` <- function(e1, e2) {
if (missing(e2)) {
op <- fetch_op("pos", py_eval("lambda e1: +e1", convert = FALSE))
return(op(e1))
}
op <- fetch_op("add", py_eval("lambda e1, e2: e1 + e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`-.python.builtin.object` <- function(e1, e2) {
if (missing(e2)) {
op <- fetch_op("neg", py_eval("lambda e1: -e1", convert = FALSE))
return(op(e1))
}
op <- fetch_op("sub", py_eval("lambda e1, e2: e1 - e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`*.python.builtin.object` <-function(e1, e2) {
op <- fetch_op("*", py_eval("lambda e1, e2: e1 * e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`/.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("/", py_eval("lambda e1, e2: e1 / e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`%/%.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("//", py_eval("lambda e1, e2: e1 // e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`%%.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("%", py_eval("lambda e1, e2: e1 % e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`^.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("pow", import_builtins(FALSE)$pow,
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`&.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("&", py_eval("lambda e1, e2: e1 & e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`|.python.builtin.object` <- function(e1, e2) {
op <- fetch_op("|", py_eval("lambda e1, e2: e1 | e2", convert = FALSE),
nargs = 2L)
op(e1, e2)
}
#' @rdname Ops-python-methods
#' @export
`!.python.builtin.object` <- function(e1) {
op <- fetch_op("~", py_eval("lambda e1: ~ e1", convert = FALSE))
op(e1)
}
#' @rdname Ops-python-methods
#' @rawNamespace if (getRversion() >= "4.3.0") S3method("%*%",python.builtin.object)
`%*%.python.builtin.object` <-function(x, y) {
op <- fetch_op("@", py_eval("lambda x, y: x @ y", convert = FALSE),
nargs = 2L)
op(x, y)
}
#' @export
summary.python.builtin.object <- function(object, ...) {
str(object)
}
py_has_convert <- py_get_convert
py_maybe_convert <- function(x, convert) {
if(convert)
x <- py_to_r(x)
x
}
# helper function for accessing attributes or items from a
# Python object, after validating that we do indeed have
# a valid Python object reference
py_get_attr_or_item <- function(x, name, prefer_attr) {
# skip if this is a NULL xptr
if (py_is_null_xptr(x))
return(NULL)
# re-cast numeric values as integers
if (is.numeric(name))
name <- as.integer(name)
# attributes must always be indexed by strings, so if
# we receive a non-string 'name', we call py_get_item
if (!is.character(name)) {
item <- py_get_item(x, name)
return(py_maybe_convert(item, py_has_convert(x)))
}
# get the attrib and convert as needed
object <- NULL
if (prefer_attr) {
object <- py_get_attr(x, name)
} else {
# if we have an attribute, attempt to get the item
# but allow for fallback to that attribute. note that
# the logic here is fairly convoluted but is necessary
# to maintain backwards compatibility with a number of
# CRAN packages (hopefully we can simplify this in the
# future)
if (py_has_attr(x, name)) {
# try to get item
if (py_has_attr(x, "__getitem__"))
object <- py_get_item(x, name, silent = TRUE)
# fallback to attribute
if (is.null(object))
object <- py_get_attr(x, name)
} else {
# we don't have an attribute; only attempt item
# access and allow normal error propagation
object <- py_get_item(x, name)
}
}
py_maybe_convert(object, py_has_convert(x))
}
#' @export
`$.python.builtin.object` <- function(x, name) {
py_get_attr_or_item(x, name, TRUE)
}
#' @export
`[[.python.builtin.object` <- function(x, name) {
py_get_attr_or_item(x, name, FALSE)
}
#' @export
`$.python.builtin.module` <- function(x, name) {
attr <- py_get_attr(x, name, TRUE)
if(!is.null(attr))
return(py_maybe_convert(attr, py_has_convert(x)))
# special handling for embedded modules (which don't always show
# up as "attributes")
module <- py_get_submodule(x, name, py_has_convert(x))
if (!is.null(module))
return(module)
# fall back to raising the AttributeError
py_get_attr(x, name, FALSE)
}
# the as.environment generic enables python objects that manifest
# as R functions (e.g. for functions, classes, callables, etc.) to
# be resolve the environment containing the external pointer (the "refenv")
# This is still useful e.g., for passing to assign("convert", x, as.environment(x)).
# This was previously the primary mechanism that allowed for constructing
# PyObjectRefs from closures, before PyObjectRefs was refactored. The S3 generic
# is retained for backwards-compatability.
#' @export
as.environment.python.builtin.object <- function(x) {
if (is.function(x))
attr(x, "py_object")
else
x
}
#' @export
`$<-.python.builtin.object` <- function(x, name, value) {
if (!py_is_null_xptr(x) && py_available())
py_set_attr(x, name, value)
else
stop("Unable to assign value (object reference is NULL)")
x
}
#' @export
`[[<-.python.builtin.object` <- `$<-.python.builtin.object`
#' @export
.DollarNames.python.builtin.module <- function(x, pattern = "") {
# resolve module proxies (ignore errors since this is occurring during completion)
if (py_is_module_proxy(x)) {
result <- tryCatch({
py_resolve_module_proxy(x)
TRUE
}, error = clear_error_handler(FALSE))
if (!result)
return(character())
}
# delegate
.DollarNames.python.builtin.object(x, pattern)
}
#' @importFrom utils .DollarNames
#' @export
.DollarNames.python.builtin.object <- function(x, pattern = "") {
# skip if this is a NULL xptr
if (py_is_null_xptr(x) || !py_available())
return(character())
# check for dictionary
if (inherits(x, "python.builtin.dict")) {
names <- py_dict_get_keys_as_str(x)
names <- names[substr(names, 1, 1) != '_']
Encoding(names) <- "UTF-8"
types <- rep_len(0L, length(names))
} else {
# get the names and filter out internal attributes (_*)
names <- py_suppress_warnings(py_list_attributes(x))
names <- names[substr(names, 1, 1) != '_']
# replace function with `function`
names <- sub("^function$", "`function`", names)
names <- sort(names, decreasing = FALSE)
# get the types
types <- py_suppress_warnings(py_get_attr_types(x, names))
}
# if this is a module then add submodules
if (inherits(x, "python.builtin.module")) {
name <- py_get_name(x)
if (!is.null(name)) {
submodules <- sort(py_list_submodules(name), decreasing = FALSE)
Encoding(submodules) <- "UTF-8"
names <- c(names, submodules)
types <- c(types, rep_len(5L, length(submodules)))
}
}
idx <- grepl(pattern, names)
names <- names[idx]
types <- types[idx]
if (length(names) > 0) {
# set types
oidx <- order(names)
names <- names[oidx]
attr(names, "types") <- types[oidx]
# specify a help_handler
attr(names, "helpHandler") <- "reticulate:::help_handler"
}
# return
names
}
#' @export
names.python.builtin.object <- function(x) {
as.character(.DollarNames(x))
}
#' @export
names.python.builtin.module <- function(x) {
as.character(.DollarNames(x))
}
#' @export
as.array.numpy.ndarray <- function(x, ...) {
py_to_r(x)
}
#' @export
as.matrix.numpy.ndarray <- function(x, ...) {
py_to_r(x)
}
#' @export
as.vector.numpy.ndarray <- function(x, mode = "any") {
a <- as.array(x)
as.vector(a, mode = mode)
}
#' @export
as.double.numpy.ndarray <- function(x, ...) {
a <- as.array(x)
as.double(a)
}
#' @importFrom graphics plot
#' @export
plot.numpy.ndarray <- function(x, y, ...) {
plot(as.array(x))
}
#' Create Python dictionary
#'
#' Create a Python dictionary object, including a dictionary whose keys are
#' other Python objects rather than character vectors.
#'
#' @param ... Name/value pairs for dictionary (or a single named list to be
#' converted to a dictionary).
#' @param keys Keys to dictionary (can be Python objects)
#' @param values Values for dictionary
#' @param convert `TRUE` to automatically convert Python objects to their R
#' equivalent. If you pass `FALSE` you can do manual conversion using the
#' [py_to_r()] function.
#'
#' @return A Python dictionary
#'
#' @note The returned dictionary will not automatically convert its elements
#' from Python to R. You can do manual conversion with the [py_to_r()]
#' function or pass `convert = TRUE` to request automatic conversion.
#'
#' @export
dict <- function(..., convert = FALSE) {
# get the args
values <- list(...)
# flag indicating whether we should scan the parent frame for python
# objects that should serve as the key (e.g. a Tensor)
scan_parent_frame <- TRUE
# if there is a single element and it's a list then use that
if (length(values) == 1L && is.null(names(values)) && is.list(values[[1L]])) {
values <- values[[1]]
scan_parent_frame <- FALSE
}
# get names
names <- names(values)
# evaluate names in parent env to get keys
frame <- parent.frame()
keys <- lapply(names, function(name) {
# allow python objects to serve as keys
if (scan_parent_frame && exists(name, envir = frame, inherits = TRUE)) {
key <- get(name, envir = frame, inherits = TRUE)
if (is_py_object(key))
key
else
name
} else {
if (grepl("^[0-9]+$", name))
name <- as.integer(name)
else
name
}
})
# construct dict
py_dict_impl(keys, values, convert = convert)
}
#' @rdname dict
#' @export
py_dict <- function(keys, values, convert = FALSE) {
py_dict_impl(keys, values, convert = convert)
}
#' Create Python tuple
#'
#' Create a Python tuple object
#'
#' @inheritParams dict
#' @param ... Values for tuple (or a single list to be converted to a tuple).
#'
#' @return A Python tuple
#' @note The returned tuple will not automatically convert its elements from
#' Python to R. You can do manual conversion with the [py_to_r()] function or
#' pass `convert = TRUE` to request automatic conversion.
#'
#' @export
tuple <- function(..., convert = FALSE) {
# get the args
values <- list(...)
# if it's a single value then maybe do some special resolution
if (length(values) == 1L) {
# alias value
value <- values[[1L]]
# reflect tuples back
if (inherits(value, "python.builtin.tuple"))
return(value)
# if it's a list then use the list as the values
if (is.list(value))
values <- value
}
# construct tuple
py_tuple(values, convert = convert)
}
#' @export
length.python.builtin.tuple <- function(x) {
if (py_is_null_xptr(x) || !py_available())
0L
else
py_tuple_length(x)
}
#' Length of Python object
#'
#' Get the length of a Python object. This is equivalent to calling
#' the Python builtin `len()` function on the object.
#'
#' Not all Python objects have a defined length. For objects without a defined
#' length, calling `py_len()` will throw an error. If you'd like to instead
#' infer a default length in such cases, you can set the `default` argument
#' to e.g. `1L`, to treat Python objects without a `__len__` method as having
#' length one.
#'
#' @param x A Python object.
#'
#' @param default The default length value to return, in the case that
#' the associated Python object has no `__len__` method. When `NULL`
#' (the default), an error is emitted instead.
#'
#' @return The length of the object, as a numeric value.
#'
#' @export
py_len <- function(x, default = NULL) {
# return 0 if Python not yet available
if (py_is_null_xptr(x) || !py_available())
return(0L)
# delegate to C++
py_len_impl(x, default)
}
#' @export
length.python.builtin.list <- function(x) {
py_list_length(x)
}
#' @export
length.python.builtin.object <- function(x) {
# return 0 if Python not yet available
if (py_is_null_xptr(x) || !py_available())
return(0L)
# otherwise, try to invoke the object's __len__ method
n <- py_len_impl(x, NA_integer_)
# if the object didn't have a __len__() method, or __len__() raised an
# Exception, try instead to invoke its __bool__() method.
if (is.na(n)) {
n <- as.integer(py_bool_impl(x, TRUE))
# py_bool_impl( ,TRUE) can also return NA if __bool__() raised an exception.
# length() is used extensively in R and must be safe to call, so we don't
# want to propagate the Python Exception and signal an R error, but also
# don't want to return a false result. We balance concerns by returning NA.
}
n
}
#' Python Truthiness
#'
#' Equivalent to `bool(x)` in Python, or `not not x`.
#'
#' If the Python object defines a `__bool__` method, then that is invoked.
#' Otherwise, if the object defines a `__len__` method, then `TRUE` is
#' returned if the length is nonzero. If neither `__len__` nor `__bool__`
#' are defined, then the Python object is considered `TRUE`.
#'
#' @param x, A python object.
#'
#' @return An R scalar logical: `TRUE` or `FALSE`. If `x` is a
#' null pointer or Python is not initialized, `FALSE` is returned.
#' @export
py_bool <- function(x) {
if (py_is_null_xptr(x) || !py_available())
FALSE
else
py_bool_impl(x)
}
#' Convert to Python Unicode Object
#'
#' @param str Single element character vector to convert
#'
#' @details By default R character vectors are converted to Python strings.
#' In Python 3 these values are unicode objects however in Python 2
#' they are 8-bit string objects. This function enables you to
#' obtain a Python unicode object from an R character vector
#' when running under Python 2 (under Python 3 a standard Python
#' string object is returned).
#'
#' @export
py_unicode <- function(str) {
if (is_python3()) {
r_to_py(str)
} else {
py <- import_builtins()
py_call(py_get_attr(py, "unicode"), str)
}
}
#' Evaluate an expression within a context.
#'
#' The \code{with} method for objects of type \code{python.builtin.object}
#' implements the context manager protocol used by the Python \code{with}
#' statement. The passed object must implement the
#' \href{https://docs.python.org/3/reference/datamodel.html#context-managers}{context
#' manager} (\code{__enter__} and \code{__exit__} methods.
#'
#' @param data Context to enter and exit
#' @param expr Expression to evaluate within the context
#' @param as Name of variable to assign context to for the duration of the
#' expression's evaluation (optional).
#' @param ... Unused
#'
#' @export
with.python.builtin.object <- function(data, expr, as = NULL, ...) {
# enter the context
context <- data$`__enter__`()
# check for as and as_envir
if (!missing(as)) {
as <- deparse(substitute(as))
as <- gsub("\"", "", as)
} else {
as <- attr(data, "as")
}
envir <- attr(data, "as_envir")
if (is.null(envir))
envir <- parent.frame()
# assign the context if we have an as parameter
if (!is.null(as)) {
assign(as, context, envir = envir)
}
# evaluate the expression and exit the context
tryCatch(force(expr),
finally = {
data$`__exit__`(NULL, NULL, NULL)
}
)
}
#' Create local alias for objects in \code{with} statements.
#'
#' @param object Object to alias
#' @param name Alias name
#'
#' @name with-as-operator
#'
#' @keywords internal
#' @export
"%as%" <- function(object, name) {
as <- deparse(substitute(name))
as <- gsub("\"", "", as)
attr(object, "as") <- as
attr(object, "as_envir") <- parent.frame()
object
}
#' Traverse a Python iterator or generator
#'
#' @param x Python iterator or iterable
#' @param it Python iterator or generator
#' @param f Function to apply to each item. By default applies the
#' \code{identity} function which just reflects back the value of the item.
#' @param simplify Should the result be simplified to a vector if possible?
#' @param completed Sentinel value to return from `iter_next()` if the iteration
#' completes (defaults to `NULL` but can be any R value you specify).
#'
#' @return For `iterate()`, A list or vector containing the results of calling
#' \code{f} on each item in \code{x} (invisibly); For `iter_next()`, the next
#' value in the iteration (or the sentinel `completed` value if the iteration
#' is complete).
#'
#' @details Simplification is only attempted all elements are length 1 vectors
#' of type "character", "complex", "double", "integer", or "logical".
#'
#' @export
iterate <- function(it, f = base::identity, simplify = TRUE) {
invisible(py_iterate(it, f, simplify))
}
#' @rdname iterate
#' @export
iter_next <- function(it, completed = NULL) {
py_iter_next(it, completed)
}
#' Call a Python callable object
#'
#' @param ... Arguments to function (named and/or unnamed)
#'
#' @return Return value of call as a Python object.
#'
#' @keywords internal
#'
#' @export
py_call <- function(x, ...) {
dots <- split_named_unnamed(list(...))
py_call_impl(x, dots$unnamed, dots$named)
}
#' The Python None object
#'
#' Get a reference to the Python `None` object.
#'
#' @export
py_none <- function() {
py_none_impl()
}
#' List all attributes of a Python object
#'
#'
#' @param x Python object
#'
#' @return Character vector of attributes
#' @export
py_list_attributes <- function(x) {
attrs <- py_list_attributes_impl(x)
Encoding(attrs) <- "UTF-8"
attrs
}
#' String representation of a python object.
#'
#' This is equivalent to calling `str(object)` or `repr(object)` in Python.
#'
#' In Python, calling `print()` invokes the builtin `str()`, while auto-printing
#' an object at the REPL invokes the builtin `repr()`.
#'
#' In \R, the default print method for python objects invokes `py_repr()`, and
#' the default `format()` and `as.character()` methods invoke `py_str()`.
#'
#' For historical reasons, `py_str()` is also an \R S3 method that allows R
#' authors to customize the the string representation of a Python object from R.
#' New code is recommended to provide a `format()` and/or `print()` S3 R method
#' for python objects instead.
#'
#' @param object Python object
#' @param ... Unused
#'
#' @return Character vector
#'
#' @details The default implementation will call `PyObject_Str` on the object.
#'
#' @export
py_str <- function(object, ...) {
if (!is_py_object(object))
"<not a python object>"
else if (py_is_null_xptr(object) || !py_available())
"<pointer: 0x0>"
else
UseMethod("py_str")
}
#' @export
py_str.default <- function(object, ...) {
"<not a python object>"
}
#' @export
py_str.python.builtin.object <- function(object, ...) {
py_str_impl(object)
}
#' @export
format.python.builtin.module <- function(x, ...) {
if(py_is_module_proxy(x))
return(paste0("Module(", get("module", envir = x), ")", sep = ""))
NextMethod()
}
#' @export
format.python.builtin.object <- function(x, ...) {
if (py_is_null_xptr(x) || !py_available())
return("<pointer: 0x0>")
# get default rep, potentially user defined S3
str <- py_str(x)
# remove e.g. 'object at 0x10d084710'
str <- gsub(" object at 0x\\w{4,}", "", str)
# return
str
}
#' @export
py_str.python.builtin.bytearray <- function(object, ...) {
paste0("python.builtin.bytearray (", py_len_impl(object), " bytes)")
}
#' @export
py_str.python.builtin.module <- function(object, ...) {
paste0("Module(", py_get_name(object), ")")
}
#' @export
py_str.python.builtin.list <- function(object, ...) {
py_collection_str("List", object)
}
#' @export
py_str.python.builtin.dict <- function(object, ...) {
py_collection_str("Dict", object)
}
#' @export
py_str.python.builtin.tuple <- function(object, ...) {
py_collection_str("Tuple", object)
}
py_collection_str <- function(name, object) {
len <- py_len_impl(object)
if (len > 10)
paste0(name, " (", len, " items)")
else
py_str.python.builtin.object(object)
}
.print.via.format <- function(x, ...) {
writeLines(format(x, ...))
invisible(x)
}
#' @export
print.python.builtin.bytearray <- .print.via.format
#' @export
print.python.builtin.tuple <- .print.via.format
#' @export
print.python.builtin.module <- .print.via.format
#' @export
print.python.builtin.list <- .print.via.format
#' @export
print.python.builtin.dict <- .print.via.format
#' Suppress Python warnings for an expression
#'
#' @param expr Expression to suppress warnings for
#'
#' @return Result of evaluating expression
#'
#' @export
py_suppress_warnings <- function(expr) {
ensure_python_initialized()
# ignore any registered warning output types (e.g. tf warnings)
contexts <- lapply(.globals$suppress_warnings_handlers, function(handler) {
handler$suppress()
})
on.exit({
if (length(contexts) > 0) {
for (i in 1:length(contexts)) {
handler <- .globals$suppress_warnings_handlers[[i]]
handler$restore(contexts[[i]])
}
}
}, add = TRUE)
# evaluate while ignoring python warnings
warnings <- import("warnings")
with(warnings$catch_warnings(), expr)
}
#' Register a handler for calls to py_suppress_warnings
#'
#' @param handler Handler
#'
#' @details Enables packages to register a pair of functions
#' to be called to suppress and then re-enable warnings
#'
#' @keywords internal
#' @export
register_suppress_warnings_handler <- function(handler) {
.globals$suppress_warnings_handlers[[length(.globals$suppress_warnings_handlers) + 1]] <- handler
}
#' Register a filter for class names
#'
#' @param filter Function which takes a class name and maps it to an alternate
#' name
#'
#' @keywords internal
#' @export
register_class_filter <- function(filter) {
.globals$class_filters[[length(.globals$class_filters) + 1]] <- filter
}
#' Capture and return Python output
#'
#' @param expr Expression to capture stdout for
#' @param type Streams to capture (defaults to both stdout and stderr)
#'
#' @return Character vector with output
#'
#' @export
py_capture_output <- function(expr, type = c("stdout", "stderr")) {
# initialize python if necessary
# without expressing an implict venv preference
# via an internal import() call
ensure_python_initialized()
# resolve type argument
type <- match.arg(type, several.ok = TRUE)
# get output tools helper functions
output_tools <- import("rpytools.output")
# scope output capture
capture_stdout <- "stdout" %in% type
capture_stderr <- "stderr" %in% type
context_manager <- output_tools$OutputCaptureContext(
capture_stdout, capture_stderr
)
context_manager$`__enter__`()
tryCatch(
force(expr),
finally = {
context_manager$`__exit__`()
}
)
# collect output
context_manager$collect_output()
}
#' Run Python code
#'
#' Execute code within the scope of the \code{__main__} Python module.
#'
#' @inheritParams import
#'
#' @param code The Python code to be executed.
#' @param file The Python script to be executed.
#' @param local Boolean; should Python objects be created as part of
#' a local / private dictionary? If `FALSE`, objects will be created within
#' the scope of the Python main module.
#' @param prepend_path Boolean; should the script directory be added to the
#' Python module search path? The default, `TRUE`, matches the behavior of
#' `python <path/to/script.py>` at the command line.
#'
#' @return A Python dictionary of objects. When `local` is `FALSE`, this
#' dictionary captures the state of the Python main module after running
#' the provided code. Otherwise, only the variables defined and used are
#' captured.
#'
#' @name py_run
#'
#' @export
py_run_string <- function(code, local = FALSE, convert = TRUE) {
invisible(py_run_string_impl(code, local, convert))
}
#' @rdname py_run
#' @export
py_run_file <- function(file, local = FALSE, convert = TRUE, prepend_path = TRUE) {
ensure_python_initialized()
file <- path.expand(file)
if (prepend_path) {
sys <- import("sys", convert = FALSE)
sys$path$insert(0L, dirname(file))
on.exit(sys$path$remove(dirname(file)), add = TRUE)
}
invisible(py_run_file_impl(file, local, convert))
}
#' Evaluate a Python Expression
#'
#' Evaluate a single Python expression, in a way analogous to the Python
#' `eval()` built-in function.
#'
#' @param code A single Python expression.
#' @param convert Boolean; automatically convert Python objects to R?
#'
#' @return The result produced by evaluating `code`, converted to an `R`
#' object when `convert` is set to `TRUE`.
#'
#' @section Caveats:
#'
#' `py_eval()` only supports evaluation of 'simple' Python expressions.
#' Other expressions (e.g. assignments) will fail; e.g.
#'
#' ```
#' > py_eval("x = 1")
#' Error in py_eval_impl(code, convert) :
#' SyntaxError: invalid syntax (reticulate_eval, line 1)
#' ```
#'
#' and this mirrors what one would see in a regular Python interpreter:
#'
#' ```
#' >>> eval("x = 1")
#' Traceback (most recent call last):
#' File "<stdin>", line 1, in <module>
#' File "<string>", line 1
#' x = 1
#' ^
#' SyntaxError: invalid syntax
#' ```
#'
#' The [py_run_string()] method can be used if the evaluation of arbitrary
#' Python code is required.
#'
#' @export
py_eval <- function(code, convert = TRUE) {
py_eval_impl(code, convert)
}
#' The builtin constant Ellipsis
#'
#' @export
py_ellipsis <- function() {
builtins <- import_builtins(convert = FALSE)
builtins$Ellipsis
}
#' @importFrom rlang list2
py_callable_as_function <- function(callable) {
force(callable)
as.function.default(c(py_get_formals(callable), quote({
cl <- sys.call()
cl[[1L]] <- list2
call_args <- split_named_unnamed(eval(cl, parent.frame()))
result <- py_call_impl(callable, call_args$unnamed, call_args$named)
if(py_get_convert(callable))
result <- py_to_r(result)
if (is.null(result))
invisible(result)
else
result
})))
}
split_named_unnamed <- function(x) {
nms <- names(x)
if (is.null(nms))
return(list(unnamed = x, named = list()))
named <- nzchar(nms)
list(unnamed = x[!named], named = x[named])
}
py_is_module <- function(x) {
inherits(x, "python.builtin.module")
}
py_is_module_proxy <- function(x) {
typeof(x) == "environment" &&
exists("module", envir = x, inherits = FALSE) &&
inherits(x, "python.builtin.module")
}
py_resolve_module_proxy <- function(proxy) {
if(!py_is_module_proxy(proxy))
return(FALSE)
# collect module proxy hooks
collect_value <- function(name, clear = TRUE) {
if (exists(name, envir = proxy, inherits = FALSE)) {
value <- get(name, envir = proxy, inherits = FALSE)
if (clear)
remove(list = name, envir = proxy)
value
} else {
NULL
}
}
# name of module to import (allow just in time customization via hook)
get_module <- collect_value("get_module")
if (!is.null(get_module))
assign("module", get_module(), envir = proxy)
# get module name
module <- get("module", envir = proxy)
# execute before load handler
before_load <- collect_value("before_load", clear = TRUE)
if (is.function(before_load))
before_load()
# perform the import -- capture error and amend it with
# python configuration information if we have it
result <- tryCatch(import(module), error = clear_error_handler())
if (inherits(result, "error")) {
# load and error handlers
on_error <- collect_value("on_error", clear = FALSE)
if (!is.null(on_error)) {
# call custom error handler
if (is.function(on_error))
on_error(result)
# error handler can and should call `stop`, this is just a failsafe
stop("Error loading Python module ", module, call. = FALSE)
} else {
# default error message/handler
message <- py_config_error_message(paste("Python module", module, "was not found."))
stop(message, call. = FALSE)
}
}
# clear any custom 'on_error' hook
collect_value("on_error", clear = TRUE)
# clear the global tracking of delay load modules
.globals$delay_load_imports <- NULL
# fixup the proxy. Note, the proxy may have already been fixed up,
# if `import(module)` triggered hooks to run registered via
# (unexported) py_register_load_hook()
py_module_proxy_import(proxy)
# call on_load if provided
on_load <- collect_value("on_load", clear = TRUE)
if (is.function(on_load))
on_load()
TRUE
}
py_get_name <- function(x) {
py_to_r(py_get_attr(x, "__name__"))
}
py_get_submodule <- function(x, name, convert = TRUE) {
module_name <- paste(py_get_name(x), name, sep=".")
result <- tryCatch(import(module_name, convert = convert),
error = clear_error_handler())
if (inherits(result, "error"))
NULL
else
result
}
py_filter_classes <- function(classes) {
for (filter in .globals$class_filters)
classes <- filter(classes)
classes
}
py_inject_r <- function() {
# don't inject 'r' if there's already an 'r' object defined
main <- import_main(convert = FALSE)
if (py_has_attr(main, "r"))
return(FALSE)
# define our 'R' class
py_run_string("class R(object): pass")
# extract it from the main module
main <- import_main(convert = FALSE)
R <- main$R
# define the getters, setters we'll attach to the Python class
getter <- function(self, code) {
envir <- py_resolve_envir()
object <- eval(parse(text = as_r_value(code)), envir = envir)
r_to_py(object, convert = is.function(object))
}
setter <- function(self, name, value) {
envir <- py_resolve_envir()
name <- as_r_value(name)
value <- as_r_value(value)
assign(name, value, envir = envir)
}
py_set_attr(R, "__getattr__", getter)
py_set_attr(R, "__setattr__", setter)
py_set_attr(R, "__getitem__", getter)
py_set_attr(R, "__setitem__", setter)
# now define the R object
py_run_string("r = R()")
# remove the 'R' class object
py_del_attr(main, "R")
# indicate success
TRUE
}
py_resolve_envir <- function() {
# if an environment has been set, use it
envir <- getOption("reticulate.engine.environment")
if (is.environment(envir))
return(envir)
# if we're running in a knitr document, use the knit env
if ("knitr" %in% loadedNamespaces()) {
.knitEnv <- yoink("knitr", ".knitEnv")
envir <- .knitEnv$knit_global
if (is.environment(envir))
return(envir)
}
# if we're running in a testthat test, use the rlang reported envir
envir <- getOption("rlang_trace_top_env")
if (is.environment(envir))
return(envir)
# otherwise, default to the global environment
envir %||% globalenv()
}
py_inject_hooks <- function() {
builtins <- import_builtins(convert = TRUE)
input <- function(prompt = "") {
response <- tryCatch(
readline(prompt),
interrupt = identity
)
if (inherits(response, "interrupt"))
stop("KeyboardInterrupt", call. = FALSE)
r_to_py(response)
}
# override input function
if (interactive() && was_python_initialized_by_reticulate()) {
name <- if (is_python3()) "input" else "raw_input"
builtins[[name]] <- input
}
# register module import callback
useImportHook <- getOption("reticulate.useImportHook", default = is_python3())
if (useImportHook) {
loader <- import("rpytools.loader", convert = TRUE)
loader$initialize(py_module_onload)
}
}
py_module_onload <- function(module) {
# log module loading if requested
if (getOption("reticulate.logModuleLoad", default = FALSE)) {
writeLines(sprintf("Loaded module '%s'", module))
}
# retrieve and clear list of hooks
hookName <- paste("reticulate", module, "load", sep = "::")
hooks <- getHook(hookName)
setHook(hookName, NULL, action = "replace")
# run hooks
for (hook in hooks)
tryCatch(hook(), error = warning)
}
py_module_loaded <- function(module) {
if(is_python_initialized()) {
sys <- import("sys", convert = TRUE)
modules <- names(sys$modules)
} else
modules <- NULL
module %in% modules
}
py_register_load_hook <- function(module, hook) {
# if the module is already loaded, just run the hook
if (py_module_loaded(module))
return(hook())
# otherwise, register the hook to be run on next load
name <- paste("reticulate", module, "load", sep = "::")
setHook(name, hook)
}
#' `nameOfClass()` for Python objects
#'
#' This generic enables passing a `python.builtin.type` object as the 2nd
#' argument to `base::inherits()`.
#'
#' @param x A Python class
#'
#' @return A scalar string matching the S3 class of objects constructed from the
#' type.
#'
#' @rawNamespace if (getRversion() >= "4.3.0") S3method(nameOfClass,python.builtin.type)
#' @examples
#' \dontrun{
#' numpy <- import("numpy")
#' x <- r_to_py(array(1:3))
#' inherits(x, numpy$ndarray)
#' }
nameOfClass.python.builtin.type <- function(x) {
paste(
as_r_value(py_get_attr(x, "__module__")),
as_r_value(py_get_attr(x, "__name__")),
sep = "."
)
}
#' @rawNamespace if (getRversion() >= "4.3.0") S3method(chooseOpsMethod,python.builtin.object)
chooseOpsMethod.python.builtin.object <- function(x, y, mx, my, cl, reverse) {
# If both objects are python objects, and
# 'my' is the default Ops method provided by reticulate
# (e.g, its environment is the reticulate namespace)
# then 'mx' must be the more specific method, select mx.
# e.g.,:
# x class: tensorflow.tensor ... python.builtin.object
# y class: numpy.ndarray python.builtin.object
# 'x * y' gives
# Warning: Incompatible methods ("*.tensorflow.tensor", "*.python.builtin.object") for "*"
# Error in img * x : non-numeric argument to binary operator
inherits(y, "python.builtin.object") &&
identical(environment(my), parent.env(environment()))
}
py_set_interrupt <- function() {
py_set_interrupt_impl()
}
#' @export
format.python.builtin.traceback <- function(x, ..., limit = NULL) {
import("traceback")$format_tb(x, limit)
}
#' @rdname py_last_error
#' @export
py_clear_last_error <- function() {
py_last_error(NULL)
}
#' Get or (re)set the last Python error encountered.
#'
#' @param exception A python exception object. If provided, the provided
#' exception is set as the last exception.
#'
#' @return For `py_last_error()`, `NULL` if no error has yet been encountered.
#' Otherwise, a named list with entries:
#'
#' + `"type"`: R string, name of the exception class.
#'
#' + `"value"`: R string, formatted exception message.
#'
#' + `"traceback"`: R character vector, the formatted python traceback,
#'
#' + `"message"`: The full formatted raised exception, as it would be printed in
#' Python. Includes the traceback, type, and value.
#'
#' + `"r_trace"`: A `data.frame` with class `rlang_trace` and columns:
#'
#' - `call`: The R callstack, `full_call`, summarized for pretty printing.
#' - `full_call`: The R callstack. (Output of `sys.calls()` at the error callsite).
#' - `parent`: The parent of each frame in callstack. (Output of `sys.parents()` at the error callsite).
#' - Additional columns for internals use: `namespace`, `visible`, `scope`.
#'
#'
#'
#' And attribute `"exception"`, a `'python.builtin.Exception'` object.
#'
#' The named list has `class` `"py_error"`, and has a default `print` method
#' that is the equivalent of `cat(py_last_error()$message)`.
#'
#' @examples
#' \dontrun{
#'
#' # see last python exception with R traceback
#' reticulate::py_last_error()
#'
#' # see the full R callstack from the last Python exception
#' reticulate::py_last_error()$r_trace$full_call
#'
#' # run python code that might error,
#' # without modifying the user-visible python exception
#'
#' safe_len <- function(x) {
#' last_err <- py_last_error()
#' tryCatch({
#' # this might raise a python exception if x has no `__len__` method.
#' import_builtins()$len(x)
#' }, error = function(e) {
#' # py_last_error() was overwritten, is now "no len method for 'object'"
#' py_last_error(last_err) # restore previous exception
#' -1L
#' })
#' }
#'
#' safe_len(py_eval("object"))
#' }
#'
#' @export
py_last_error <- function(exception) {
if (!missing(exception)) {
if (is.null(exception))
return(.globals$py_last_exception <- .globals$last_r_trace <- NULL)
# set as the last exception
r_trace <- NULL
if (inherits(exception, "py_error")) {
r_trace <- exception$trace
exception <- attr(exception, "exception", TRUE)
}
if (is.null(r_trace))
r_trace <- as_r_value(py_get_attr(exception, "trace", TRUE))
if (!is.null(exception) &&
!inherits(exception, "python.builtin.Exception"))
stop("`exception` must be NULL, a `py_error`, or a 'python.builtin.Exception'")
on.exit({
.globals$py_last_exception <- exception
.globals$last_r_trace <- r_trace
})
return(invisible(.globals$py_last_exception))
}
e <- .globals$py_last_exception
if (is.null(e))
return(NULL)
if (!py_available() || py_is_null_xptr(e)) {
.globals$py_last_exception <- NULL
return(NULL)
}
etype <- py_get_attr(e, "__class__")
etb <- py_get_attr(e, "__traceback__", TRUE)
traceback <- import("traceback")
if(is.null(etb))
formatted_traceback <- NULL
else
formatted_traceback <- traceback$format_tb(etb)
out <- list(
type = py_get_attr(etype, "__name__", TRUE),
value = py_str_impl(e),
traceback = formatted_traceback,
message = paste0(traceback$format_exception(etype, e, etb),
collapse = "")
)
out$r_call <- conditionCall(e)
out$r_class <- as_r_value(py_get_attr(e, "r_class", TRUE)) %||% class(e)
out$r_trace <- py_get_attr(e, "trace", TRUE) %||% .globals$last_r_trace
out <- lapply(out, as_r_value)
attr(out, "exception") <- e
class(out) <- "py_error"
out
}
make_filepaths_clickable <- function(formatted_python_traceback) {
# Note, a first draft of this iterated over the list of FrameSummarys in
# the exception.__traceback__, but that approach breaks with keras.
# So now we use a regex instead (:sad:).
# See format_py_exception_traceback_with_clickable_filepaths()
# for the previous approach
x <- strsplit(formatted_python_traceback, "\n", fixed = TRUE)[[1L]]
if (!length(x))
return(formatted_python_traceback)
m <- regexec('File "([^"]+)", line ([0-9]+), in', x, perl = TRUE)
new <- lapply(regmatches(x, m), function(match) {
if (!length(match))
return(character())
filepath <- match[2]
lineno <- match[3]
if(!file.exists(file.path(filepath)))
return(filepath)
link <- cli::style_hyperlink(
filepath,
paste0("file://", normalizePath(filepath, mustWork = FALSE)),
params = c(line = lineno))
cli::col_grey(link)
})
m2 <- lapply(m, function(match_pos) {
if(identical(as.vector(match_pos), -1L))
return(match_pos)
out <- match_pos[2] # only match filepath
attr(out, "match.length") <- attr(match_pos, "match.length")[2]
out
})
regmatches(x, m2) <- new
if(x[length(x)] != "")
x <- c(x, "") # ensure we end w/ a newline
paste0(x, collapse = "\n")
}
## not exported because pillar only in suggests
## exported dynamically in .onLoad()
## @exportS3Method pillar::type_sum
type_sum.python.builtin.object <- function(x) {
s <- class(x)[[1L]]
if(startsWith(s, "R6type."))
s <- substr(s, 8L, 2147483647L)
s
}
#' @export
print.py_error <- function(x, ...) {
py_error_message <- x$message
if (identical(.Platform$GUI, "RStudio") &&
requireNamespace("cli", quietly = TRUE) &&
length(etb <- attr(x, "exception")$`__traceback__`))
py_error_message <- make_filepaths_clickable(py_error_message)
cat_h1("Python Exception Message")
cat(py_error_message)
cat_h1("R Traceback")
print(x$r_trace)
cat(.py_last_error_full_callstack_hint(), "\n", sep = "")
}
cat_h1 <- function(x) {
if(requireNamespace("cli", quietly = TRUE)) {
cli::cli_h1(x, .envir = NULL)
} else {
cat("--- ", x, "\n", sep = "")
}
}
format_py_exception_traceback_with_clickable_filepaths <- function(etb) {
# This is currently unused, but preserved here in case it's useful for future
# development. This is unused because keras/tensorflow hijacks the python
# exception __traceback__, making it effectively useless. Instead, keras
# formats the actual (user relevant) traceback info directly into the
# exception message (and nicely too! albeit verbosely. It includes detailed
# info about call args in each user frame, including tensor shapes and dtypes,
# and formats with indentation matching user-generated frame depth).
# Unfortunately, that means that building up a nice formatted traceback by
# iterating over the traceback FrameSummary objects won't work correctly. The
# alternative is to apply a regex to the message, as we do in
# make_filepaths_clickable() (:sad:)
if(is.null(etb)) return(NULL)
fsl <- import("traceback")$extract_tb(etb)
if(!length(fsl)) return(NULL)
paste0(collapse = "\n", c(
"Traceback (most recent call last):",
vapply(fsl, function(fs) {
# fs == FrameSummary obj, with attrs: filename, line, lineno, locals, name
filepath <- fs$filename
lineno <- fs$lineno
clickable_filepath <-
cli::style_hyperlink(
filepath,
paste0("file://", normalizePath(filepath, mustWork = FALSE)),
params = c(line = lineno)
)
sprintf(' File "%s", line %i, in %s\n %s',
clickable_filepath, lineno, fs$name, fs$line)
}, ""),
""))
}
.py_last_error_hint <- function() {
if(!interactive() ||
!identical(.Platform$GUI, "RStudio") ||
!requireNamespace("cli", quietly = TRUE))
return("Run `reticulate::py_last_error()` for details.")
py_last_error <- cli::style_hyperlink(
"`reticulate::py_last_error()`",
"rstudio:run:reticulate::py_last_error()")
cli::col_silver(paste("Run", py_last_error, "for details."))
}
.py_last_error_full_callstack_hint <- function() {
hint <- "See `reticulate::py_last_error()$r_trace$full_call` for more details."
if(!interactive() ||
!identical(.Platform$GUI, "RStudio") ||
!requireNamespace("cli", quietly = TRUE))
return(hint)
# # ide:run: / rstudio:run: links don't support expressions like this.
# last_error_unsummarized_callstack <- cli::style_hyperlink(
# "`reticulate::py_last_error()$r_trace$full_call`",
# "rstudio:run:reticulate::py_last_error()$r_trace$full_call")
# hint <- cli::col_silver(paste("See", last_error_unsummarized_callstack,
# "for more details."))
cli::col_silver(hint)
}
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