Extend documentation about explicit and implicit conversions between (u)intXX, bytesYY and literals.

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Daniel Kirchner 2018-08-14 17:39:18 +02:00 committed by chriseth
parent cc54f6c425
commit 4f3f4a916b
2 changed files with 103 additions and 11 deletions

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@ -446,6 +446,25 @@ does not fit inside this range, it is truncated. These truncations can have
above is necessary to avoid certain attacks.
Why are explicit conversions between fixed-size bytes types and integer types failing?
======================================================================================
Since version 0.5.0 explicit conversions between fixed-size byte arrays and integers are only allowed,
if both types have the same size. This prevents unexpected behaviour when truncating or padding.
Such conversions are still possible, but intermediate casts are required that make the desired
truncation and padding convention explicit. See :ref:`types-conversion-elementary-types` for a full
explanation and examples.
Why can number literals not be converted to fixed-size bytes types?
===================================================================
Since version 0.5.0 only hexadecimal number literals can be converted to fixed-size bytes
types and only if the number of hex digits matches the size of the type. See :ref:`types-conversion-literals`
for a full explanation and examples.
More Questions?
===============

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@ -1004,6 +1004,8 @@ It is important to note that ``delete a`` really behaves like an assignment to `
.. index:: ! type;conversion, ! cast
.. _types-conversion-elementary-types:
Conversions between Elementary Types
====================================
@ -1017,9 +1019,7 @@ is possible if it
makes sense semantically and no information is lost: ``uint8`` is convertible to
``uint16`` and ``int128`` to ``int256``, but ``int8`` is not convertible to ``uint256``
(because ``uint256`` cannot hold e.g. ``-1``).
Furthermore, unsigned integers can be converted to bytes of the same or larger
size, but not vice-versa. Any type that can be converted to ``uint160`` can also
be converted to ``address``.
Any integer type that can be converted to ``uint160`` can also be converted to ``address``.
Explicit Conversions
--------------------
@ -1038,17 +1038,90 @@ a negative ``int8`` to a ``uint``:
At the end of this code snippet, ``x`` will have the value ``0xfffff..fd`` (64 hex
characters), which is -3 in the two's complement representation of 256 bits.
If a type is explicitly converted to a smaller type, higher-order bits are
If an integer is explicitly converted to a smaller type, higher-order bits are
cut off::
uint32 a = 0x12345678;
uint16 b = uint16(a); // b will be 0x5678 now
Since 0.5.0 explicit conversions between integers and fixed-size byte arrays
are only allowed, if both have the same size. To convert between integers and
fixed-size byte arrays of different size, they first have to be explicitly
converted to a matching size. This makes alignment and padding explicit::
If an integer is explicitly converted to a larger type, it is padded on the left (i.e. at the higher order end).
The result of the conversion will compare equal to the original integer.
uint16 x = 0xffff;
bytes32(uint256(x)); // pad on the left
bytes32(bytes2(x)); // pad on the right
uint16 a = 0x1234;
uint32 b = uint32(a); // b will be 0x00001234 now
assert(a == b);
Fixed-size bytes types behave differently during conversions. They can be thought of as
sequences of individual bytes and converting to a smaller type will cut off the
sequence::
bytes2 a = 0x1234;
bytes1 b = bytes1(a); // b will be 0x12
If a fixed-size bytes type is explicitly converted to a larger type, it is padded on
the right. Accessing the byte at a fixed index will result in the same value before and
after the conversion (if the index is still in range)::
bytes2 a = 0x1234;
bytes4 b = bytes4(a); // b will be 0x12340000
assert(a[0] == b[0]);
assert(a[1] == b[1]);
Since integers and fixed-size byte arrays behave differently when truncating or
padding, explicit conversions between integers and fixed-size byte arrays are only allowed,
if both have the same size. If you want to convert between integers and fixed-size byte arrays of
different size, you have to use intermediate conversions that make the desired truncation and padding
rules explicit::
bytes2 a = 0x1234;
uint32 b = uint16(a); // b will be 0x00001234
uint32 c = uint32(bytes4(a)); // c will be 0x12340000
uint8 d = uint8(uint16(a)); // d will be 0x34
uint8 e = uint8(bytes1(a)); // d will be 0x12
.. _types-conversion-literals:
Conversions between Literals and Elementary Types
=================================================
Integer Types
-------------
Decimal and hexadecimal number literals can be implicitly converted to any integer type
that is large enough to represent it without truncation::
uint8 a = 12; // fine
uint32 b = 1234; // fine
uint16 c = 0x123456; // fails, since it would have to truncate to 0x3456
Fixed-Size Byte Arrays
----------------------
Decimal number literals cannot be implicitly converted to fixed-size byte arrays. Hexadecimal
number literals can be, but only if the number of hex digits exactly fits the size of the bytes
type. As an exception both decimal and hexadecimal literals which have a value of zero can be
converted to any fixed-size bytes type::
bytes2 a = 54321; // not allowed
bytes2 b = 0x12; // not allowed
bytes2 c = 0x123; // not allowed
bytes2 d = 0x1234; // fine
bytes2 e = 0x0012; // fine
bytes4 f = 0; // fine
bytes4 g = 0x0; // fine
String literals and hex string literals can be implicitly converted to fixed-size byte arrays,
if their number of characters matches the size of the bytes type::
bytes2 a = hex"1234"; // fine
bytes2 b = "xy"; // fine
bytes2 c = hex"12"; // not allowed
bytes2 d = hex"123"; // not allowed
bytes2 e = "x"; // not allowed
bytes2 f = "xyz"; // not allowed
Addresses
---------
As described in :ref:`address_literals`, hex literals of the correct size that pass the checksum
test are of ``address`` type. No other literals can be implicitly converted to the ``address`` type.