2019-01-09 11:48:36 +00:00
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.. index:: ! type;conversion, ! cast
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.. _types-conversion-elementary-types:
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Conversions between Elementary Types
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====================================
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Implicit Conversions
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--------------------
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2019-06-24 10:40:16 +00:00
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If an operator is applied to different types, the compiler tries to implicitly
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convert one of the operands to the type of the other (the same is true for assignments).
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This means that operations are always performed in the type of one of the operands.
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In general, an implicit conversion between value-types is possible if it makes
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sense semantically and no information is lost.
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For example, ``uint8`` is convertible to
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``uint16`` and ``int128`` to ``int256``, but ``int8`` is not convertible to ``uint256``,
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because ``uint256`` cannot hold values such as ``-1``.
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2019-01-09 11:48:36 +00:00
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For more details, please consult the sections about the types themselves.
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Explicit Conversions
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--------------------
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2019-06-24 10:40:16 +00:00
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If the compiler does not allow implicit conversion but you are confident a conversion will work,
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an explicit type conversion is sometimes possible. This may
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result in unexpected behaviour and allows you to bypass some security
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2019-01-09 11:48:36 +00:00
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features of the compiler, so be sure to test that the
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2019-06-24 10:40:16 +00:00
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result is what you want and expect!
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Take the following example that converts a negative ``int`` to a ``uint``:
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2019-01-09 11:48:36 +00:00
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::
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2019-04-30 14:46:43 +00:00
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int y = -3;
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2019-01-09 11:48:36 +00:00
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uint x = uint(y);
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At the end of this code snippet, ``x`` will have the value ``0xfffff..fd`` (64 hex
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characters), which is -3 in the two's complement representation of 256 bits.
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If an integer is explicitly converted to a smaller type, higher-order bits are
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cut off::
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uint32 a = 0x12345678;
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uint16 b = uint16(a); // b will be 0x5678 now
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2019-06-24 10:40:16 +00:00
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If an integer is explicitly converted to a larger type, it is padded on the left (i.e., at the higher order end).
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2019-01-09 11:48:36 +00:00
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The result of the conversion will compare equal to the original integer::
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uint16 a = 0x1234;
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uint32 b = uint32(a); // b will be 0x00001234 now
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assert(a == b);
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Fixed-size bytes types behave differently during conversions. They can be thought of as
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sequences of individual bytes and converting to a smaller type will cut off the
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sequence::
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bytes2 a = 0x1234;
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bytes1 b = bytes1(a); // b will be 0x12
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If a fixed-size bytes type is explicitly converted to a larger type, it is padded on
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the right. Accessing the byte at a fixed index will result in the same value before and
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after the conversion (if the index is still in range)::
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bytes2 a = 0x1234;
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bytes4 b = bytes4(a); // b will be 0x12340000
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assert(a[0] == b[0]);
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assert(a[1] == b[1]);
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Since integers and fixed-size byte arrays behave differently when truncating or
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padding, explicit conversions between integers and fixed-size byte arrays are only allowed,
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if both have the same size. If you want to convert between integers and fixed-size byte arrays of
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different size, you have to use intermediate conversions that make the desired truncation and padding
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rules explicit::
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bytes2 a = 0x1234;
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uint32 b = uint16(a); // b will be 0x00001234
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uint32 c = uint32(bytes4(a)); // c will be 0x12340000
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uint8 d = uint8(uint16(a)); // d will be 0x34
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uint8 e = uint8(bytes1(a)); // e will be 0x12
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.. _types-conversion-literals:
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Conversions between Literals and Elementary Types
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=================================================
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Integer Types
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-------------
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Decimal and hexadecimal number literals can be implicitly converted to any integer type
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that is large enough to represent it without truncation::
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uint8 a = 12; // fine
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uint32 b = 1234; // fine
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uint16 c = 0x123456; // fails, since it would have to truncate to 0x3456
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Fixed-Size Byte Arrays
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----------------------
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Decimal number literals cannot be implicitly converted to fixed-size byte arrays. Hexadecimal
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number literals can be, but only if the number of hex digits exactly fits the size of the bytes
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type. As an exception both decimal and hexadecimal literals which have a value of zero can be
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converted to any fixed-size bytes type::
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bytes2 a = 54321; // not allowed
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bytes2 b = 0x12; // not allowed
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bytes2 c = 0x123; // not allowed
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bytes2 d = 0x1234; // fine
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bytes2 e = 0x0012; // fine
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bytes4 f = 0; // fine
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bytes4 g = 0x0; // fine
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String literals and hex string literals can be implicitly converted to fixed-size byte arrays,
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if their number of characters matches the size of the bytes type::
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bytes2 a = hex"1234"; // fine
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bytes2 b = "xy"; // fine
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bytes2 c = hex"12"; // not allowed
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bytes2 d = hex"123"; // not allowed
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bytes2 e = "x"; // not allowed
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bytes2 f = "xyz"; // not allowed
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Addresses
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---------
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As described in :ref:`address_literals`, hex literals of the correct size that pass the checksum
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test are of ``address`` type. No other literals can be implicitly converted to the ``address`` type.
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Explicit conversions from ``bytes20`` or any integer type to ``address`` result in ``address payable``.
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2019-09-04 15:45:12 +00:00
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An ``address a`` can be converted to ``address payable`` via ``payable(a)``.
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