See my comments.

This is well-defined. The intermediate expression for `z`

will undergo widening into `double`

, so `y * z`

will be a `double`

expression. An implicit narrowing conversion will then convert it to `float`

for storing in `res2`

. This same narrowing applies to `res1`

.

This is reflected by **§5¶9 Expressions [expr]** of the C++11 standard.

Many binary operators that expect operands of arithmetic or enumeration type cause conversions and yield result types in a similar way. The purpose is to yield a common type, which is also the type of the result. This pattern is called the *usual arithmetic conversions*, which are defined as follows:

...

- Otherwise, if either operand is
`double`

, the other shall be converted to `double`

.
- Otherwise, if either operand is
`float`

, the other shall be converted to `float`

.

...

This, however, does not sure that the equality will hold.

That being said, `res1`

need not necessarily be equivalent to `res2`

-- it is highly dependent on the precision of `float`

and `double`

in the environment. The two literals could potentially not even be equal -- `4.23423451f`

not need even be equivalent to `4.23423451`

. You can not be sure that `static_cast<double>(static_cast<float>(4.23423451))`

will be equal to `4.23423451`

.

See **§5.17¶3 Assignment and compound assignment operators [expr.ass]**.

If the left operand is not of class type, the expression is implicitly converted (Clause 4) to the cv-unqualified type of the left operand.

**§4 Standard conversions [conv]** states as follows:

Standard conversions are implicit conversions with built-in meaning. Clause 4 enumerates the full set of such conversions. A *standard conversion sequence* is a sequence of standard conversions in the following order:

...

- Zero or one conversion from the following set: integral promotions, floating point promotion, integral conversions, floating point conversions, floating-integral conversions, pointer conversions, pointer to member conversions, and boolean conversions.

As elaborated in **§4.6 Floating point promotion [conv.fpprom]**,

- A prvalue of type
`float`

can be converted to a prvalue of type `double`

. The value is unchanged.
- This conversion is called
*floating point promotion*.

... and **§4.8 Floating point conversions [conv.double]**,

A prvalue of floating point type can be converted to a prvalue of another floating point type. If the source value can be exactly represented in the destination type, the result of the conversion is that exact representation. If the source value is between two adjacent destination values, the result of the conversion is an implementation-defined choice of either of those values. Otherwise, the behavior is undefined.

The conversions allowed as floating point promotions are excluded from the set of floating point conversions.

The problem here is that we have multiple cases where our conversion is not *promotion*, but rather narrowing to a potentially lower-precision type (`double`

to `float`

).

Essentially, any time you convert `double`

to `float`

, you may potentially lose precision.

`z`

will undergo widening into`double`

, so`y * z`

will be a`double`

expression. An implicit narrowing conversion will then convert it to`float`

for storing in`res2`

. Same applies to`res1`

. – oldrinb Sep 12 '12 at 21:03`res1`

need not necessarily be equivalent to`res2`

-- it is highly dependent on the precision of`float`

and`double`

in the environment. The two literals could potentially not even be equal --`4.23423451f`

not need be equivalent to`4.23423451`

. – oldrinb Sep 12 '12 at 21:05castis something you write in your source code. It tells the compiler to do aconversion. There are also situations where the compiler will do aconversionwithout acast. These are calledimplicit conversions. – Pete Becker Sep 12 '12 at 21:24