# Is overflow defined for VHDL numeric_std signed/unsigned

If I have an `unsigned(MAX downto 0)` containing the value `2**MAX - 1`, do the VHDL (87|93|200X) standards define what happens when I increment it by one? (Or, similarly, when I decrement it by one from zero?)

## 3 Answers

Short answer:

There is no overflow handling, the overflow carry is simply lost. Thus the result is simply the integer result of your operation modulo 2^MAX.

Longer answer:

The `numeric_std` package is a standard package but it is not is the Core the VHDL standards (87,93,200X). For reference : numeric_std.vhd

The `+` operator in the end calls the `ADD_UNSIGNED (L, R : unsigned; C : std_logic)` function (with `C = '0'`). Note that any integer/natural operand is first converted into an `unsigned`.

The function's definition is:

``````function ADD_UNSIGNED (L, R : unsigned; C : std_logic) return unsigned is
constant L_left : integer   := L'length-1;
alias XL        : unsigned(L_left downto 0) is L;
alias XR        : unsigned(L_left downto 0) is R;
variable RESULT : unsigned(L_left downto 0);
variable CBIT   : std_logic := C;
begin
for i in 0 to L_left loop
RESULT(i) := CBIT xor XL(i) xor XR(i);
CBIT      := (CBIT and XL(i)) or (CBIT and XR(i)) or (XL(i) and XR(i));
end loop;
return RESULT;
end ADD_UNSIGNED;
``````

As you can see an "overflow" occurs if `CBIT='1'` (carry bit) for `i = L_left`. The result bit `RESULT(i)` is calculated normally and the last carry bot value is ignored.

• Exactly the sort of reference I wanted, thanks :) (Please ignore my previous comment about the carry bit, I misread the function!) – detly Aug 2 '12 at 12:41
• This answer is also erroneous assuming role over with a length of MAX + 1. It's a problem with using the name MAX. For somename declared as an unsigned with a subtype indication (index range) of 31 downto 0 and a length of 32 (somename'length) the Maximum value with a right index of 0 is 2**32 -1. – user1155120 Jun 3 '15 at 2:58

I've had the problem with wanting an `unsigned` to overflow/underflow as in C or in Verilog and here is what I came up with (`result` and `delta` are `unsigned`):

``````result <= unsigned(std_logic_vector(resize(('1' & result) - delta, result'length))); -- proper underflow
result <= unsigned(std_logic_vector(resize(('0' & result) + delta, result'length))); -- proper overflow
``````

For overflow `'0' & result` makes an `unsigned` which is 1 bit larger to be able to correctly accommodate the value of the addition. The MSB is then removed by the `resize` command which yields the correct overflow value. Same for underflow.

For a value of MAX equal to 7 adding 1 to 2**7 - 1 (127) will result in the value 2**7 (128).

The maximum unsigned value is determined by the length of an unsigned array type:

``````library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;

entity foo is
end entity;

architecture faa of foo is
constant  MAX: natural := 7;
signal somename:  unsigned (MAX downto 0) := (others => '1');
begin
UNLABELED:
process
begin
report "somename'length = " & integer'image(somename'length);
report "somename maximum value = " &integer'image(to_integer(somename));
wait;
end process;
end architecture;
``````

The aggregate `(others => '1')` represents a '1' in each element of `somename` which is an unsigned array type and represents the maximum binary value possible.

This gives:

foo.vhdl:15:9:@0ms:(report note): somename'length = 8
foo.vhdl:16:9:@0ms:(report note): somename maximum value = 255

The length is 8 and the numerical value range representable by the unsigned array type is from 0 to 2**8 - 1 (255), the maximum possible value is greater than 2**7 (128) and there is no overflow.

This was noticed in a newer question VHDL modulo 2^32 addition. In the context of your accepted answer it assumes you meant length instead of the leftmost value.

The decrement from zero case does result in a value of 2**8 - 1 (255) (MAX = 7). An underflow or an overflow depending on your math religion.

Hat tip to Jonathan Drolet for pointing this out in the linked newer question.