Top Level Namespace
Included Modules
Extended Modules
Defined in:
Constant Summary
-
ARGF =
IO::ARGF.new(ARGV, STDIN)
-
An
IO
for reading files fromARGV
.Usage example:
program.cr
:puts ARGF.gets_to_end
A file to read from: (
file
)123
$ crystal build program.cr $ ./program file 123 $ ./program file file 123123 $ # If ARGV is empty, ARGF reads from STDIN instead: $ echo "hello" | ./program hello $ ./program unknown Unhandled exception: Error opening file with mode 'r': 'unknown': No such file or directory (File::NotFoundError) ...
After a file from
ARGV
has been read, it's removed fromARGV
.You can manipulate
ARGV
yourself to control whatARGF
operates on. If you remove a file fromARGV
, it is ignored byARGF
; if you add files toARGV
,ARGF
will read from it.ARGV.replace ["file1"] ARGF.gets_to_end # => Content of file1 ARGV # => [] ARGV << "file2" ARGF.gets_to_end # => Content of file2
-
ARGV =
Array.new(ARGC_UNSAFE - 1) do |i| String.new(ARGV_UNSAFE[1 + i]) end
-
An array of arguments passed to the program.
-
EOL =
{% if flag?(:windows) %} "\r\n" {% else %} "\n" {% end %}
-
The newline constant
-
PROGRAM_NAME =
String.new(ARGV_UNSAFE.value)
-
The name, the program was called with.
The result may be a relative or absolute path (including symbolic links), just the command name or the empty string.
See
Process.executable_path
for a more convenient alternative that always returns the absolute real path to the executable file (if it exists). -
STDERR =
IO::FileDescriptor.from_stdio(2)
-
The standard error file descriptor.
Typically used to output error messages and diagnostics.
At the start of the program STDERR is configured like this:
- if it's a TTY device (like the console) then
sync
istrue
, meaning that output will be outputted as soon as it is written to STDERR. This is so users can see real time output data. - if it's not a TTY device (like a file, or because the output
was piped to a file) then
sync
isfalse
butflush_on_newline
istrue
. This is so that if you pipe the output to a file, and, for example, youtail -f
, you can see data on a line-per-line basis. This is convenient but slower than withflush_on_newline
set tofalse
. If you need a bit more performance and you don't care about near real-time output you can doSTDERR.flush_on_newline = false
.
On Unix systems, if the file descriptor is a TTY, the runtime duplicates it. So
STDERR.fd
might not be2
. The reason for this is to enable non-blocking writes for concurrency. Other fibers can run while waiting on IO. The original file descriptor is inherited from the parent process. Setting it to non-blocking mode would reflect back which can cause problems.On Windows,
STDERR
is always blocking. - if it's a TTY device (like the console) then
-
STDIN =
IO::FileDescriptor.from_stdio(0)
-
The standard input file descriptor. Contains data piped to the program.
On Unix systems, if the file descriptor is a TTY, the runtime duplicates it. So
STDIN.fd
might not be0
. The reason for this is to enable non-blocking reads for concurrency. Other fibers can run while waiting on user input. The original file descriptor is inherited from the parent process. Setting it to non-blocking mode would reflect back, which can cause problems.On Windows,
STDIN
is always blocking. -
STDOUT =
IO::FileDescriptor.from_stdio(1)
-
The standard output file descriptor.
Typically used to output data and information.
At the start of the program STDOUT is configured like this:
- if it's a TTY device (like the console) then
sync
istrue
, meaning that output will be outputted as soon as it is written to STDOUT. This is so users can see real time output data. - if it's not a TTY device (like a file, or because the output
was piped to a file) then
sync
isfalse
butflush_on_newline
istrue
. This is so that if you pipe the output to a file, and, for example, youtail -f
, you can see data on a line-per-line basis. This is convenient but slower than withflush_on_newline
set tofalse
. If you need a bit more performance and you don't care about near real-time output you can doSTDOUT.flush_on_newline = false
.
On Unix systems, if the file descriptor is a TTY, the runtime duplicates it. So
STDOUT.fd
might not be1
. The reason for this is to enable non-blocking writes for concurrency. Other fibers can run while waiting on IO. The original file descriptor is inherited from the parent process. Setting it to non-blocking mode would reflect back which can cause problems.On Windows,
STDOUT
is always blocking. - if it's a TTY device (like the console) then
Method Summary
-
`(command) : String
Returns the standard output of executing command in a subshell.
-
abort(message = nil, status = 1) : NoReturn
Terminates execution immediately, printing message to
STDERR
and then callingexit(status)
. -
at_exit(&handler : Int32, Exception | Nil -> ) : Nil
Registers the given
Proc
for execution when the program exits regularly. -
caller : Array(String)
Returns the current execution stack as an array containing strings usually in the form file:line:column or file:line:column in 'method'.
-
exit(status = 0) : NoReturn
Terminates execution immediately, returning the given status code to the invoking environment.
-
gets(*args, **options)
Reads a line from
STDIN
. -
instance_sizeof(type : Class) : Int32
Returns the instance size of the given class as number of bytes.
-
loop(&)
Repeatedly executes the block.
-
main(argc : Int32, argv : Pointer(Pointer(UInt8)))
Main function that acts as C's main function.
-
offsetof(type : Class, offset) : Int32
Returns the byte offset of an instance variable in a struct or class type.
-
p(object)
Inspects object to
STDOUT
followed by a newline. -
p(*objects)
Inspects each object in objects to
STDOUT
, followed by a newline. -
p(**objects)
Inspects objects to
STDOUT
, followed by a newline. -
pointerof(variable : T) : Pointer(T) forall T
Returns a
Pointer
to the contents of a variable. -
pp(object)
Pretty prints object to
STDOUT
followed by a newline. -
pp(*objects)
Pretty prints each object in objects to
STDOUT
, followed by a newline. -
pp(**objects)
Pretty prints objects to
STDOUT
, followed by a newline. -
print(*objects : _) : Nil
Prints objects to
STDOUT
and then invokesSTDOUT.flush
. -
printf(format_string, args : Array | Tuple) : Nil
Prints a formatted string to
STDOUT
. -
printf(format_string, *args) : Nil
Prints a formatted string to
STDOUT
. - puts(*objects) : Nil
-
raise(exception : Exception) : NoReturn
Raises the exception.
-
raise(message : String) : NoReturn
Raises an Exception with the message.
-
rand(x)
See
Random#rand(x)
. -
rand : Float64
See
Random#rand
. -
read_line(*args, **options)
Reads a line from
STDIN
. -
sizeof(type : Class) : Int32
Returns the size of the given type as number of bytes.
-
sleep(seconds : Number) : Nil
Blocks the current fiber for the specified number of seconds.
-
sleep(time : Time::Span) : Nil
Blocks the current Fiber for the specified time span.
-
sleep : Nil
Blocks the current fiber forever.
-
spawn(*, name : String | Nil = nil, same_thread = false, &block)
Spawns a new fiber.
-
sprintf(format_string, args : Array | Tuple) : String
Returns a formatted string.
-
sprintf(format_string, *args) : String
Returns a formatted string.
-
system(command : String, args = nil) : Bool
Executes the given command in a subshell.
-
timeout_select_action(timeout : Time::Span) : Channel::TimeoutAction
Timeout keyword for use in
select
. -
typeof(*expression) : Class
Returns the type of an expression.
Macro Summary
- debugger
-
p!(*exps)
Prints a series of expressions together with their inspected values.
-
pp!(*exps)
Prints a series of expressions together with their pretty printed values.
-
record(__name name, *properties, **kwargs)
Defines a
Struct
type called name with the given properties. - spawn(call, *, name = nil, same_thread = false, &block)
Instance methods inherited from module Spec::Methods
after_all(&block)
after_all,
after_each(&block)
after_each,
around_all(&block : ExampleGroup::Procsy -> )
around_all,
around_each(&block : Example::Procsy -> )
around_each,
before_all(&block)
before_all,
before_each(&block)
before_each,
context(description = nil, file = __FILE__, line = __LINE__, end_line = __END_LINE__, focus : Bool = false, tags : String | Enumerable(String) | Nil = nil, &block)
context,
describe(description = nil, file = __FILE__, line = __LINE__, end_line = __END_LINE__, focus : Bool = false, tags : String | Enumerable(String) | Nil = nil, &block)
describe,
fail(msg, file = __FILE__, line = __LINE__)
fail,
it(description = "assert", file = __FILE__, line = __LINE__, end_line = __END_LINE__, focus : Bool = false, tags : String | Enumerable(String) | Nil = nil, &block)
it,
pending(description = "assert", file = __FILE__, line = __LINE__, end_line = __END_LINE__, focus : Bool = false, tags : String | Enumerable(String) | Nil = nil, &)pending(description = "assert", file = __FILE__, line = __LINE__, end_line = __END_LINE__, focus : Bool = false, tags : String | Enumerable(String) | Nil = nil) pending, pending!(msg = "Cannot run example", file = __FILE__, line = __LINE__) pending!
Macros inherited from module Spec::Methods
assert_iterates_iterator(expected, method, *, infinite = false)
assert_iterates_iterator,
assert_iterates_yielding(expected, method, *, infinite = false, tuple = false)
assert_iterates_yielding,
assert_prints(call, *, should expectation, file = __FILE__, line = __LINE__)assert_prints(call, str, *, file = __FILE__, line = __LINE__) assert_prints, it_iterates(description, expected, method, *, infinite = false, tuple = false, file = __FILE__, line = __LINE__) it_iterates
Instance methods inherited from module Spec::Expectations
be(value)be be, be_close(expected, delta) be_close, be_empty be_empty, be_false be_false, be_falsey be_falsey, be_nil be_nil, be_true be_true, be_truthy be_truthy, contain(expected) contain, end_with(expected) end_with, eq(value) eq, expect_raises(klass : T.class, message : String | Regex | Nil = nil, file = __FILE__, line = __LINE__, &) forall T expect_raises, match(value) match, start_with(expected) start_with
Macros inherited from module Spec::Expectations
be_a(type)
be_a
Method Detail
Returns the standard output of executing command in a subshell.
Standard input, and error are inherited.
The special $?
variable is set to a Process::Status
associated with this execution.
It is impossible to call this method with any regular call syntax. There is an associated literal type which calls the method with the literal content as command:
`echo hi` # => "hi\n"
$?.success? # => true
See Command
literals in the language reference.
Terminates execution immediately, printing message to STDERR
and
then calling exit(status)
.
Registers the given Proc
for execution when the program exits regularly.
A regular exit happens when either
- the main fiber reaches the end of the program,
- the main fiber rescues an unhandled exception, or
::exit
is called.
Process.exit
does not trigger at_exit
handlers, nor does external process
termination (see Process.on_terminate
for handling that).
If multiple handlers are registered, they are executed in reverse order of registration.
def do_at_exit(str1)
at_exit { print str1 }
end
at_exit { puts "cruel world" }
do_at_exit("goodbye ")
exit
Produces:
goodbye cruel world
The exit status code that will be returned by this program is passed to
the block as its first argument. In case of any unhandled exception, it is
passed as the second argument to the block, if the program terminates
normally or exit(status)
is called explicitly, then the second argument
will be nil
.
NOTE If at_exit
is called inside an at_exit
handler, it will be called
right after the current at_exit
handler ends, and then other handlers
will be invoked.
Returns the current execution stack as an array containing strings usually in the form file:line:column or file:line:column in 'method'.
Terminates execution immediately, returning the given status code to the invoking environment.
Registered at_exit
procs are executed.
Returns the instance size of the given class as number of bytes.
type must be a constant or typeof()
expression. It cannot be evaluated at runtime.
instance_sizeof(String) # => 16
instance_sizeof(Exception) # => 48
See sizeof
for determining the size of value types.
NOTE This is a pseudo-method provided directly by the Crystal compiler. It cannot be redefined nor overridden.
Main function that acts as C's main function.
Invokes Crystal.main
.
Can be redefined. See Crystal.main
for examples.
On Windows the actual entry point is wmain
, but there is no need to redefine
that. See the file required below for details.
Returns the byte offset of an instance variable in a struct or class type.
type must be a constant or typeof()
expression. It cannot be evaluated at runtime.
offset must be the name of an instance variable of type, prefixed by @
,
or the index of an element in a Tuple, starting from 0, if type is a Tuple
.
offsetof(String, @bytesize) # => 4
offsetof(Exception, @message) # => 8
offsetof(Time, @location) # => 16
offsetof({Int32, Int8, Int32}, 0) # => 0
offsetof({Int32, Int8, Int32}, 1) # => 4
offsetof({Int32, Int8, Int32}, 2) # => 8
NOTE This is a pseudo-method provided directly by the Crystal compiler. It cannot be redefined nor overridden.
Inspects object to STDOUT
followed
by a newline. Returns object.
See also: Object#inspect(io)
.
Inspects each object in objects to STDOUT
, followed
by a newline. Returns objects.
See also: Object#inspect(io)
.
Inspects objects to STDOUT
, followed
by a newline. Returns objects.
p foo: 23, bar: 42 # => {foo: 23, bar: 42}
See Object#inspect(io)
Returns a Pointer
to the contents of a variable.
variable must be a variable (local, instance, class or library).
a = 1
ptr = pointerof(a)
ptr.value = 2
a # => 2
NOTE This is a pseudo-method provided directly by the Crystal compiler. It cannot be redefined nor overridden.
Pretty prints object to STDOUT
followed
by a newline. Returns object.
See also: Object#pretty_print(pp)
.
Pretty prints each object in objects to STDOUT
, followed
by a newline. Returns objects.
See also: Object#pretty_print(pp)
.
Pretty prints objects to STDOUT
, followed
by a newline. Returns objects.
p foo: 23, bar: 42 # => {foo: 23, bar: 42}
See Object#pretty_print(pp)
Prints objects to STDOUT
and then invokes STDOUT.flush
.
See also: IO#print
.
Prints objects to STDOUT
, each followed by a newline character unless
the object is a String
and already ends with a newline.
See also: IO#puts
.
Raises the exception.
This will set the exception's callstack if it hasn't been already. Re-raising a previously caught exception won't replace the callstack.
Returns the size of the given type as number of bytes.
type must be a constant or typeof()
expression. It cannot be evaluated
at runtime.
sizeof(Int32) # => 4
sizeof(Int64) # => 8
sizeof(typeof(true)) # => 1
For Reference
types, the size is the same as the size of a pointer:
# On a 64 bits machine
sizeof(Pointer(Int32)) # => 8
sizeof(String) # => 8
This is because a Reference
's memory is allocated on the heap and a pointer
to it is passed around. The size of a class on the heap can be determined
using #instance_sizeof
.
NOTE This is a pseudo-method provided directly by the Crystal compiler. It cannot be redefined nor overridden.
Blocks the current fiber for the specified number of seconds.
While this fiber is waiting this time, other ready-to-execute fibers might start their execution.
Blocks the current Fiber for the specified time span.
While this fiber is waiting this time, other ready-to-execute fibers might start their execution.
Blocks the current fiber forever.
Meanwhile, other ready-to-execute fibers might start their execution.
Spawns a new fiber.
The newly created fiber doesn't run as soon as spawned.
Example:
# Write "1" every 1 second and "2" every 2 seconds for 6 seconds.
ch = Channel(Nil).new
spawn do
6.times do
sleep 1
puts 1
end
ch.send(nil)
end
spawn do
3.times do
sleep 2
puts 2
end
ch.send(nil)
end
2.times { ch.receive }
Returns a formatted string. The string is produced according to the format_string with format specifiers being replaced by values from args formatted according to the specifier.
Within the format string, any characters other than format specifiers
(specifiers beginning with %
) are copied to the result. The formatter
supports the following kinds of format specifiers:
- Sequential (
%.1f
). The first%
consumes the first argument, the second consumes the second argument, and so on. - Positional (
%3$.1f
). The one-based argument index is specified as part of the flags. - Named substitution (
%<name>.1f
,%{name}
). The angle bracket form accepts flags and the curly bracket form doesn't. Exactly oneHash
orNamedTuple
must be passed as the argument.
Mixing of different kinds of format specifiers is disallowed, except that the two named forms may be used together.
A simple format specifier consists of a percent sign, followed by optional flags, width, and precision indicators, then terminated with a field type character.
%[flags][width][.precision]type
A formatted substitution is similar but after the percent sign follows the mandatory name of the substitution wrapped in angle brackets.
%<name>[flags][width][.precision]type
The percent sign itself is escaped by %%
. No format modifiers are allowed,
and no arguments are consumed.
The field type controls how the corresponding argument value is to be interpreted, while the flags modify that interpretation.
The field type characters are:
Field | Integer Format
------+------------------------------------------------------------------
b | Formats argument as a binary number.
d | Formats argument as a decimal number.
i | Same as d.
o | Formats argument as an octal number.
x | Formats argument as a hexadecimal number using lowercase letters.
X | Same as x, but uses uppercase letters.
Field | Float Format
------+---------------------------------------------------------------
e | Formats floating point argument into exponential notation
| with one digit before the decimal point as [-]d.dddddde[+-]dd.
| The precision specifies the number of digits after the decimal
| point (defaulting to six).
E | Equivalent to e, but uses an uppercase E to indicate
| the exponent.
f | Formats floating point argument as [-]ddd.dddddd,
| where the precision specifies the number of digits after
| the decimal point.
g | Formats a floating point number using exponential form
| if the exponent is less than -4 or greater than or
| equal to the precision, or in dd.dddd form otherwise.
| The precision specifies the number of significant digits.
G | Equivalent to g, but use an uppercase E in exponent form.
a | Formats floating point argument as [-]0xh.hhhhp[+-]dd,
| which consists of an optional sign, "0x", fraction part
| as hexadecimal, "p", and exponential part as decimal.
A | Equivalent to a, but uses uppercase X and P.
Field | Other Format
------+------------------------------------------------------------
c | Argument is a single character itself.
s | Argument is a string to be substituted. If the format
| sequence contains a precision, at most that many characters
| will be copied.
Flags modify the behavior of the format specifiers:
Flag | Applies to | Meaning
---------+---------------+----------------------------------------------------
space | bdiouxX | Add a leading space character to
| aAeEfgG | non-negative numbers. Has no effect if the plus
| (numeric fmt) | flag is also given.
---------+---------------+----------------------------------------------------
# | boxX | Use an alternative format.
| aAeEfgG | For x, X, b, prefix any non-zero result with
| | 0x, 0X, or 0b respectively.
| | For o, prefix any non-zero result with 0o. Note
| | that this prefix is different from C and Ruby.
| | For a, A, e, E, f, g, G,
| | force a decimal point to be added,
| | even if no digits follow.
| | For g and G, do not remove trailing zeros.
---------+---------------+----------------------------------------------------
+ | bdiouxX | Add a leading plus sign to non-negative
| aAeEfgG | numbers.
| (numeric fmt) |
---------+---------------+----------------------------------------------------
- | all | Left-justify the result of this conversion.
---------+---------------+----------------------------------------------------
0 (zero) | bdiouxX | Pad with zeros, not spaces. Has no effect if the
| aAeEfgG | number is left-justified, or a precision is given
| (numeric fmt) | to an integer field type.
---------+---------------+----------------------------------------------------
* | all | Use the next argument as the field width or
| | precision. If width is negative, set the minus flag
| | and use the argument's absolute value as field
| | width. If precision is negative, it is ignored.
---------+---------------+----------------------------------------------------
1$ 2$ 3$ | all | As a flag, specifies the one-based argument index
... | | for a positional format specifier.
| | Immediately after *, use the argument at the given
| | one-based index as the width or precision, instead
| | of the next argument. The entire format string must
| | also use positional format specifiers throughout.
Examples of flags:
Decimal number conversion:
sprintf "%d", 123 # => "123"
sprintf "%+d", 123 # => "+123"
sprintf "% d", 123 # => " 123"
Octal number conversion:
sprintf "%o", 123 # => "173"
sprintf "%+o", 123 # => "+173"
sprintf "%o", -123 # => "-173"
sprintf "%+o", -123 # => "-173"
Hexadecimal number conversion:
sprintf "%x", 123 # => "7b"
sprintf "%+x", 123 # => "+7b"
sprintf "%x", -123 # => "-7b"
sprintf "%+x", -123 # => "-7b"
sprintf "%#x", 0 # => "0"
sprintf "% x", 123 # => " 7b"
sprintf "% x", -123 # => "-7b"
sprintf "%X", 123 # => "7B"
sprintf "%#X", -123 # => "-0X7B"
Binary number conversion:
sprintf "%b", 123 # => "1111011"
sprintf "%+b", 123 # => "+1111011"
sprintf "%+b", -123 # => "-1111011"
sprintf "%b", -123 # => "-1111011"
sprintf "%#b", 0 # => "0"
sprintf "% b", 123 # => " 1111011"
sprintf "%+ b", 123 # => "+1111011"
sprintf "% b", -123 # => "-1111011"
sprintf "%+ b", -123 # => "-1111011"
sprintf "%#b", 123 # => "0b1111011"
Floating point conversion:
sprintf "%a", 123 # => "0x1.ecp+6"
sprintf "%A", 123 # => "0X1.ECP+6"
Exponential form conversion:
sprintf "%g", 123.4 # => "123.4"
sprintf "%g", 123.4567 # => "123.457"
sprintf "%20.8g", 1234.56789 # => " 1234.5679"
sprintf "%20.8g", 123456789 # => " 1.2345679e+08"
sprintf "%20.8G", 123456789 # => " 1.2345679E+08"
sprintf "%20.8g", -123456789 # => " -1.2345679e+08"
sprintf "%20.8G", -123456789 # => " -1.2345679E+08"
The field width is an optional integer, followed optionally by a period and a precision. The width specifies the minimum number of characters that will be written to the result for this field.
Examples of width:
sprintf "%20d", 123 # => " 123"
sprintf "%+20d", 123 # => " +123"
sprintf "%020d", 123 # => "00000000000000000123"
sprintf "%+020d", 123 # => "+0000000000000000123"
sprintf "% 020d", 123 # => " 0000000000000000123"
sprintf "%-20d", 123 # => "123 "
sprintf "%-+20d", 123 # => "+123 "
sprintf "%- 20d", 123 # => " 123 "
sprintf "%020x", -123 # => "-000000000000000007b"
sprintf "%020X", -123 # => "-000000000000000007B"
For numeric fields, the precision controls the number of decimal places displayed.
For string fields, the precision determines the maximum number of characters to be copied from the string.
Examples of precisions:
Precision for d
, o
, x
and b
is
minimum number of digits:
sprintf "%20.8d", 123 # => " 00000123"
sprintf "%020.8d", 123 # => " 00000123"
sprintf "%20.8o", 123 # => " 00000173"
sprintf "%020.8o", 123 # => " 00000173"
sprintf "%20.8x", 123 # => " 0000007b"
sprintf "%020.8x", 123 # => " 0000007b"
sprintf "%20.8b", 123 # => " 01111011"
sprintf "%20.8d", -123 # => " -00000123"
sprintf "%020.8d", -123 # => " -00000123"
sprintf "%20.8o", -123 # => " -00000173"
sprintf "%20.8x", -123 # => " -0000007b"
sprintf "%20.8b", -11 # => " -00001011"
Precision for e
is number of digits after the decimal point:
sprintf "%20.8e", 1234.56789 # => " 1.23456789e+03"
Precision for f
is number of digits after the decimal point:
sprintf "%20.8f", 1234.56789 # => " 1234.56789000"
Precision for g
is number of significant digits:
sprintf "%20.8g", 1234.56789 # => " 1234.5679"
sprintf "%20.8g", 123456789 # => " 1.2345679e+08"
sprintf "%-20.8g", 123456789 # => "1.2345679e+08 "
Precision for s
is maximum number of characters:
sprintf "%20.8s", "string test" # => " string t"
Additional examples:
sprintf "%d %04x", 123, 123 # => "123 007b"
sprintf "%08b '%4s'", 123, 123 # => "01111011 ' 123'"
sprintf "%+g:% g:%-g", 1.23, 1.23, 1.23 # => "+1.23: 1.23:1.23"
sprintf "%-3$*1$.*2$s", 10, 5, "abcdefghij" # => "abcde "
Returns a formatted string. The string is produced according to the format_string with format specifiers being replaced by values from args formatted according to the specifier.
Within the format string, any characters other than format specifiers
(specifiers beginning with %
) are copied to the result. The formatter
supports the following kinds of format specifiers:
- Sequential (
%.1f
). The first%
consumes the first argument, the second consumes the second argument, and so on. - Positional (
%3$.1f
). The one-based argument index is specified as part of the flags. - Named substitution (
%<name>.1f
,%{name}
). The angle bracket form accepts flags and the curly bracket form doesn't. Exactly oneHash
orNamedTuple
must be passed as the argument.
Mixing of different kinds of format specifiers is disallowed, except that the two named forms may be used together.
A simple format specifier consists of a percent sign, followed by optional flags, width, and precision indicators, then terminated with a field type character.
%[flags][width][.precision]type
A formatted substitution is similar but after the percent sign follows the mandatory name of the substitution wrapped in angle brackets.
%<name>[flags][width][.precision]type
The percent sign itself is escaped by %%
. No format modifiers are allowed,
and no arguments are consumed.
The field type controls how the corresponding argument value is to be interpreted, while the flags modify that interpretation.
The field type characters are:
Field | Integer Format
------+------------------------------------------------------------------
b | Formats argument as a binary number.
d | Formats argument as a decimal number.
i | Same as d.
o | Formats argument as an octal number.
x | Formats argument as a hexadecimal number using lowercase letters.
X | Same as x, but uses uppercase letters.
Field | Float Format
------+---------------------------------------------------------------
e | Formats floating point argument into exponential notation
| with one digit before the decimal point as [-]d.dddddde[+-]dd.
| The precision specifies the number of digits after the decimal
| point (defaulting to six).
E | Equivalent to e, but uses an uppercase E to indicate
| the exponent.
f | Formats floating point argument as [-]ddd.dddddd,
| where the precision specifies the number of digits after
| the decimal point.
g | Formats a floating point number using exponential form
| if the exponent is less than -4 or greater than or
| equal to the precision, or in dd.dddd form otherwise.
| The precision specifies the number of significant digits.
G | Equivalent to g, but use an uppercase E in exponent form.
a | Formats floating point argument as [-]0xh.hhhhp[+-]dd,
| which consists of an optional sign, "0x", fraction part
| as hexadecimal, "p", and exponential part as decimal.
A | Equivalent to a, but uses uppercase X and P.
Field | Other Format
------+------------------------------------------------------------
c | Argument is a single character itself.
s | Argument is a string to be substituted. If the format
| sequence contains a precision, at most that many characters
| will be copied.
Flags modify the behavior of the format specifiers:
Flag | Applies to | Meaning
---------+---------------+----------------------------------------------------
space | bdiouxX | Add a leading space character to
| aAeEfgG | non-negative numbers. Has no effect if the plus
| (numeric fmt) | flag is also given.
---------+---------------+----------------------------------------------------
# | boxX | Use an alternative format.
| aAeEfgG | For x, X, b, prefix any non-zero result with
| | 0x, 0X, or 0b respectively.
| | For o, prefix any non-zero result with 0o. Note
| | that this prefix is different from C and Ruby.
| | For a, A, e, E, f, g, G,
| | force a decimal point to be added,
| | even if no digits follow.
| | For g and G, do not remove trailing zeros.
---------+---------------+----------------------------------------------------
+ | bdiouxX | Add a leading plus sign to non-negative
| aAeEfgG | numbers.
| (numeric fmt) |
---------+---------------+----------------------------------------------------
- | all | Left-justify the result of this conversion.
---------+---------------+----------------------------------------------------
0 (zero) | bdiouxX | Pad with zeros, not spaces. Has no effect if the
| aAeEfgG | number is left-justified, or a precision is given
| (numeric fmt) | to an integer field type.
---------+---------------+----------------------------------------------------
* | all | Use the next argument as the field width or
| | precision. If width is negative, set the minus flag
| | and use the argument's absolute value as field
| | width. If precision is negative, it is ignored.
---------+---------------+----------------------------------------------------
1$ 2$ 3$ | all | As a flag, specifies the one-based argument index
... | | for a positional format specifier.
| | Immediately after *, use the argument at the given
| | one-based index as the width or precision, instead
| | of the next argument. The entire format string must
| | also use positional format specifiers throughout.
Examples of flags:
Decimal number conversion:
sprintf "%d", 123 # => "123"
sprintf "%+d", 123 # => "+123"
sprintf "% d", 123 # => " 123"
Octal number conversion:
sprintf "%o", 123 # => "173"
sprintf "%+o", 123 # => "+173"
sprintf "%o", -123 # => "-173"
sprintf "%+o", -123 # => "-173"
Hexadecimal number conversion:
sprintf "%x", 123 # => "7b"
sprintf "%+x", 123 # => "+7b"
sprintf "%x", -123 # => "-7b"
sprintf "%+x", -123 # => "-7b"
sprintf "%#x", 0 # => "0"
sprintf "% x", 123 # => " 7b"
sprintf "% x", -123 # => "-7b"
sprintf "%X", 123 # => "7B"
sprintf "%#X", -123 # => "-0X7B"
Binary number conversion:
sprintf "%b", 123 # => "1111011"
sprintf "%+b", 123 # => "+1111011"
sprintf "%+b", -123 # => "-1111011"
sprintf "%b", -123 # => "-1111011"
sprintf "%#b", 0 # => "0"
sprintf "% b", 123 # => " 1111011"
sprintf "%+ b", 123 # => "+1111011"
sprintf "% b", -123 # => "-1111011"
sprintf "%+ b", -123 # => "-1111011"
sprintf "%#b", 123 # => "0b1111011"
Floating point conversion:
sprintf "%a", 123 # => "0x1.ecp+6"
sprintf "%A", 123 # => "0X1.ECP+6"
Exponential form conversion:
sprintf "%g", 123.4 # => "123.4"
sprintf "%g", 123.4567 # => "123.457"
sprintf "%20.8g", 1234.56789 # => " 1234.5679"
sprintf "%20.8g", 123456789 # => " 1.2345679e+08"
sprintf "%20.8G", 123456789 # => " 1.2345679E+08"
sprintf "%20.8g", -123456789 # => " -1.2345679e+08"
sprintf "%20.8G", -123456789 # => " -1.2345679E+08"
The field width is an optional integer, followed optionally by a period and a precision. The width specifies the minimum number of characters that will be written to the result for this field.
Examples of width:
sprintf "%20d", 123 # => " 123"
sprintf "%+20d", 123 # => " +123"
sprintf "%020d", 123 # => "00000000000000000123"
sprintf "%+020d", 123 # => "+0000000000000000123"
sprintf "% 020d", 123 # => " 0000000000000000123"
sprintf "%-20d", 123 # => "123 "
sprintf "%-+20d", 123 # => "+123 "
sprintf "%- 20d", 123 # => " 123 "
sprintf "%020x", -123 # => "-000000000000000007b"
sprintf "%020X", -123 # => "-000000000000000007B"
For numeric fields, the precision controls the number of decimal places displayed.
For string fields, the precision determines the maximum number of characters to be copied from the string.
Examples of precisions:
Precision for d
, o
, x
and b
is
minimum number of digits:
sprintf "%20.8d", 123 # => " 00000123"
sprintf "%020.8d", 123 # => " 00000123"
sprintf "%20.8o", 123 # => " 00000173"
sprintf "%020.8o", 123 # => " 00000173"
sprintf "%20.8x", 123 # => " 0000007b"
sprintf "%020.8x", 123 # => " 0000007b"
sprintf "%20.8b", 123 # => " 01111011"
sprintf "%20.8d", -123 # => " -00000123"
sprintf "%020.8d", -123 # => " -00000123"
sprintf "%20.8o", -123 # => " -00000173"
sprintf "%20.8x", -123 # => " -0000007b"
sprintf "%20.8b", -11 # => " -00001011"
Precision for e
is number of digits after the decimal point:
sprintf "%20.8e", 1234.56789 # => " 1.23456789e+03"
Precision for f
is number of digits after the decimal point:
sprintf "%20.8f", 1234.56789 # => " 1234.56789000"
Precision for g
is number of significant digits:
sprintf "%20.8g", 1234.56789 # => " 1234.5679"
sprintf "%20.8g", 123456789 # => " 1.2345679e+08"
sprintf "%-20.8g", 123456789 # => "1.2345679e+08 "
Precision for s
is maximum number of characters:
sprintf "%20.8s", "string test" # => " string t"
Additional examples:
sprintf "%d %04x", 123, 123 # => "123 007b"
sprintf "%08b '%4s'", 123, 123 # => "01111011 ' 123'"
sprintf "%+g:% g:%-g", 1.23, 1.23, 1.23 # => "+1.23: 1.23:1.23"
sprintf "%-3$*1$.*2$s", 10, 5, "abcdefghij" # => "abcde "
Executes the given command in a subshell.
Standard input, output and error are inherited.
Returns true
if the command gives zero exit code, false
otherwise.
The special $?
variable is set to a Process::Status
associated with this execution.
If command contains no spaces and args is given, it will become its argument list.
If command contains spaces and args is given, command must include
"${@}"
(including the quotes) to receive the argument list.
No shell interpretation is done in args.
Example:
system("echo *")
Produces:
LICENSE shard.yml Readme.md spec src
Timeout keyword for use in select
.
select
when x = ch.receive
puts "got #{x}"
when timeout(1.seconds)
puts "timeout"
end
NOTE It won't trigger if the select
has an else
case (i.e.: a non-blocking select).
Returns the type of an expression.
typeof(1) # => Int32
It accepts multiple arguments, and the result is the union of the expression types:
typeof(1, "a", 'a') # => (Int32 | String | Char)
The expressions passed as arguments to typeof
do not evaluate. The compiler
only analyzes their return type.
NOTE This is a pseudo-method provided directly by the Crystal compiler. It cannot be redefined nor overridden.
Macro Detail
Prints a series of expressions together with their inspected values. Useful for print style debugging.
a = 1
p! a # => "a # => 1"
p! [1, 2, 3].map(&.to_s) # => "[1, 2, 3].map(&.to_s) # => ["1", "2", "3"]"
See also: p
, Object#inspect
.
Prints a series of expressions together with their pretty printed values. Useful for print style debugging.
a = 1
pp! a # => "a # => 1"
pp! [1, 2, 3].map(&.to_s) # => "[1, 2, 3].map(&.to_s) # => ["1", "2", "3"]"
See also: pp
, Object#pretty_inspect
.
Defines a Struct
type called name with the given properties.
The generated struct has a constructor with the given properties in the same order as declared. The struct only provides getters, not setters, making it immutable by default.
record Point, x : Int32, y : Int32
p = Point.new 1, 2 # => #<Point(@x=1, @y=2)>
p.x # => 1
p.y # => 2
The properties are a sequence of type declarations (x : Int32
, x : Int32 = 0
)
or assigns (x = 0
).
They declare instance variables and respective getter methods of their name with
optional type restrictions and default value.
When passing a block to this macro its body is inserted inside the struct definition. This allows to define additional methods or include modules into the record type (reopening the type would work as well).
record Person, first_name : String, last_name : String do
def full_name
"#{first_name} #{last_name}"
end
end
person = Person.new "John", "Doe"
person.full_name # => "John Doe"
An example with type declarations and default values:
record Point, x : Int32 = 0, y : Int32 = 0
Point.new # => #<Point(@x=0, @y=0)>
Point.new y: 2 # => #<Point(@x=0, @y=2)>
An example with assignments (in this case the compiler must be able to infer the types from the default values):
record Point, x = 0, y = 0
Point.new # => #<Point(@x=0, @y=0)>
Point.new y: 2 # => #<Point(@x=0, @y=2)>
This macro also provides a #copy_with
method which returns
a copy of the record with the provided properties altered.
record Point, x = 0, y = 0
p = Point.new y: 2 # => #<Point(@x=0, @y=2)>
p.copy_with x: 3 # => #<Point(@x=3, @y=2)>
p # => #<Point(@x=0, @y=2)>
Spawns a fiber by first creating a Proc
, passing the call's
expressions to it, and letting the Proc
finally invoke the call.
Compare this:
i = 0
while i < 5
spawn { print(i) }
i += 1
end
Fiber.yield
# Output: 55555
To this:
i = 0
while i < 5
spawn print(i)
i += 1
end
Fiber.yield
# Output: 01234
This is because in the first case all spawned fibers refer to
the same local variable, while in the second example copies of
i are passed to a Proc
that eventually invokes the call.