First, if `x`

is zero, return zero.

Next find the index of the highest-order non-zero bit in `x`

. Call it `i`

.

If `i`

is less than 24, left-shift `x`

by `23 - i`

to get a normalized significand. Now clear bit 23 to hide the implicit bit, and set bits 23:30 to `127 + i`

, which is the biased exponent. Return the result.

Otherwise, right-shift `x`

by `i - 23`

to get a normalized significand via truncation, and clear the implicit bit and set the exponent as above. If your desired rounding mode is truncation or round-to-minus-infinity, you are done. Otherwise, you will need to look at the bits that were shifted off the bottom of `x`

. If the desired rounding mode is round-to-plus-infinity and any of those bits are set, add one to the result and return. Finally, if the desired rounding mode is round-to-nearest-ties-to-even (IEEE-754 default), there are three cases:

- the trailing bits are
`b0...`

: return the truncated result.
- the trailing bits are
`b1000...`

: this is an exact halfway case. If we call the truncated result `t`

, you need to return `t + (t&1)`

; i.e. round up only if `t`

is odd.
- the trailing bits are
`b1...1...`

: add one to the truncated result and return.

`0x43b28000`

? Do you mean it returns`357.0`

? (The first page you linked answers this question at the bottom, second question in their FAQ.) The question is meaningless. This is like asking how to convert the "two" in "two mushrooms" into the "two" in "two cars". There's nothing to do. – David Schwartz Mar 15 '13 at 7:34