#
# Currently, Object is also used to collect all top-level methods.
interface Object
+ # Type of this instance, automatically specialized in every class
+ #
+ # A common use case of the virtual type `SELF` is to type an attribute and
+ # store another instance of the same type as `self`. It can also be used as as
+ # return type to a method producing a copy of `self` or returning an instance
+ # expected to be the exact same type as self.
+ #
+ # This virtual type must be used with caution as it can hinder specialization.
+ # In fact, it imposes strict restrictions on all sub-classes and their usage.
+ # For example, using `SELF` as a return type of a method `foo`
+ # forces all subclasses to ensure that `foo` returns the correct and updated
+ # type.
+ # A dangerous usage take the form of a method typed by `SELF` which creates
+ # and returns a new instance.
+ # If not correctly specialized, this method would break when invoked on a
+ # sub-class.
+ #
+ # A general rule for safe usage of `SELF` is to ensure that inputs typed
+ # `SELF` are stored in attributes typed `SELF` and returned by methods typed
+ # `SELF`, pretty much the same things as you would do with parameter types.
+ type SELF: Object
+
# The unique object identifier in the class.
# Unless specific code, you should not use this method.
# The identifier is used internally to provide a hash value.
fun is_same_instance(other: nullable Object): Bool is intern
# Have `self` and `other` the same value?
- ##
+ #
# The exact meaning of "same value" is let to the subclasses.
# Implicitly, the default implementation, is `is_same_instance`
fun ==(other: nullable Object): Bool do return self.is_same_instance(other)
# Have `self` and `other` different values?
- ##
+ #
# != is equivalent with "not ==".
fun !=(other: nullable Object): Bool do return not (self == other)
# The hash code of the object.
# Assuming that a == b -> a.hash == b.hash
- ##
+ #
# Without redefinition, it is based on the `object_id` of the instance.
fun hash: Int do return object_id / 8
end
# Instructions outside classes implicitly redefine this method.
fun main do end
+ # The entry point for the execution of the whole program.
+ # Its job is to call `main` but some modules may want to refine it
+ # and inject specific work before or after the main part.
+ fun run do main
+
# Number of the last error
fun errno: Int is extern `{
return errno;
end
end
+# Something that can be cloned
+#
+# This interface introduces the `clone` method used to duplicate an instance
+# Its specific semantic is let to the subclasses.
+interface Cloneable
+ # Duplicate `self`
+ #
+ # The specific semantic of this method is let to the subclasses;
+ # Especially, if (and how) attributes are cloned (depth vs. shallow).
+ #
+ # As a rule of thumb, the principle of least astonishment should
+ # be used to guide the semantic.
+ #
+ # Note that as the returned clone depends on the semantic,
+ # the `==` method, if redefined, should ensure the equality
+ # between an object and its clone.
+ fun clone: SELF is abstract
+end
+
# A numeric value supporting mathematical operations
interface Numeric
super Comparable
# Native Booleans.
# `true` and `false` are the only instances.
+#
# Boolean are manipulated trough three special operators:
-# `and`, `or`, `not`.
+# `and`, `or`, `not`.
+#
# Booleans are mainly used by conditional statement and loops.
universal Bool
redef fun object_id is intern
redef type OTHER: Float
redef fun object_id is intern
+ redef fun ==(i) is intern
+ redef fun !=(i) is intern
redef fun output is intern
redef fun <=(i): Bool is intern
redef fun zero do return 0.0
redef fun value_of(val) do return val.to_f
+
+ redef fun <=>(other)
+ do
+ if self < other then
+ return -1
+ else if other < self then
+ return 1
+ else
+ return 0
+ end
+ end
+
+ redef fun is_between(c, d)
+ do
+ if self < c or d < self then
+ return false
+ else
+ return true
+ end
+ end
+
+ # Compare float numbers with a given precision.
+ #
+ # Because of the loss of precision in floating numbers,
+ # the `==` method is often not the best way to compare them.
+ #
+ # ~~~
+ # assert 0.01.is_approx(0.02, 0.1) == true
+ # assert 0.01.is_approx(0.02, 0.001) == false
+ # ~~~
+ fun is_approx(other, precision: Float): Bool
+ do
+ assert precision >= 0.0
+ return self <= other + precision and self >= other - precision
+ end
+
+ redef fun max(other)
+ do
+ if self < other then
+ return other
+ else
+ return self
+ end
+ end
+
+ redef fun min(c)
+ do
+ if c < self then
+ return c
+ else
+ return self
+ end
+ end
end
# Native integer numbers.
redef fun -(i) is intern
redef fun *(i) is intern
redef fun /(i) is intern
+
+ # Modulo of `self` with `i`.
+ #
+ # Finds the remainder of division of `self` by `i`.
+ #
+ # assert 5 % 2 == 1
+ # assert 10 % 2 == 0
fun %(i: Int): Int is intern
redef fun zero do return 0
# The character whose ASCII value is `self`.
#
- # assert 65.ascii == 'A'
- # assert 10.ascii == '\n'
+ # assert 65.ascii == 'A'
+ # assert 10.ascii == '\n'
fun ascii: Char is intern
# Number of digits of an integer in base `b` (plus one if negative)
do
return is_lower or is_upper
end
+
+ # Is self a whitespace character?
+ #
+ # These correspond to the "Other" and "Separator" groups of the Unicode.
+ #
+ # In the ASCII encoding, this is those <= to space (0x20) plus delete (0x7F).
+ #
+ # assert 'A'.is_whitespace == false
+ # assert ','.is_whitespace == false
+ # assert ' '.is_whitespace == true
+ # assert '\t'.is_whitespace == true
+ fun is_whitespace: Bool
+ do
+ var i = ascii
+ return i <= 0x20 or i == 0x7F
+ end
end
# Pointer classes are used to manipulate extern C structures.
fun address_is_null: Bool is extern "address_is_null"
# Free the memory pointed by this pointer
- fun free `{ free(recv); `}
+ fun free is extern "free"
end