```
long oneYearWithL = 1000*60*60*24*365L;
long oneYearWithoutL = 1000*60*60*24*365;
```

Your first value is actually a long (Since `365L`

is a `long`

, and `1000*60*60*24`

is an `integer`

, so the result of `multiplying`

a `long`

value with an `integer`

value is a `long`

value.

But 2nd value is an integer (Since you are mulitplying an `integer`

value with an `integer`

value only. So the result will be a `32-bit`

integer. Now the result obtained for that `multiplication`

is outside the actual range of integer. So, before getting assigned to the variable, it is truncated to fit into valid integer range.

Take a look at the following print statement: -

```
System.out.println(1000*60*60*24*365L);
System.out.println(1000*60*60*24*365);
System.out.println(Integer.MAX_VALUE);
```

When you run the above code: -

**Output: -**

```
31536000000
1471228928
2147483647
```

So, you can see the difference..

```
011101010111101100010010110000000000 -- Binary equivalent of 1000*60*60*24*365L
01111111111111111111111111111111 -- Binary equivalent of Integer.MAX_VALUE
```

So, if you don't add that `L`

at the end of your number, the 4 most significant bit is removed from the first binary string..

So, the string becomes..

```
(0111)01010111101100010010110000000000 -- Remove the most significant bits..
01010111101100010010110000000000 -- Binary equivalent of 1471228928
```

**(which you get as output)**

**UPDATE: -**
From the above explanation, you can also understand that, even in the first assignment, if the result of your `multiplication`

of `integers`

before multiplying it with `365L`

goes out of range, then again it will be truncated to fit in integer range, or converted to `2's complement representation`

if required, and then only it will be multiplied with the `long value - 365L`

.

For e.g: -

```
long thirtyYearWithL = 1000*60*60*24*30*365L;
```

In the above example, consider the first part - `1000*60*60*24*30`

. The result of this multiplication is: - `2592000000`

. Now lets' see how it is represented in `binary equivalent`

: -

```
2592000000 = 10011010011111101100100000000000 -- MSB is `1`, a negative value
01100101100000010011100000000001 -- 2's complement representation
```

Decimal representation of the `2's complement`

representation is `1702967297`

. So, `2592000000`

is converted to `-1702967297`

, before getting multiplied to `365L`

. Now since, this value fits in the `integer range`

which is : - `[-2147483648 to 2147483647]`

, so it will not be truncated further.

So, the actual result will be: -

```
long thirtyYearWithL = 1000*60*60*24*30*365L;
= 2592000000 * 365L;
= -1702967297 * 365L = -621583063040
```

So, all these stuffs just considers the actual `type`

of final result on applying the arithmetic operation. And this check is performed on each temporary result of operations moving from `left to right`

(considering operators with `left-to-right`

associativity). If any temporary result is found to be out of range, then that is converted accordingly to fit in the required range, before moving forward with next operation.

**UPDATE 2: -**

So, instead of: -

```
long thirtyYearWithL = 1000*60*60*24*30*365L;
```

if you move your `365L`

at the start, then you will get the correct result: -

```
long thirtyYearWithL = 365L*1000*60*60*24*30; // will give you correct result
```

Because, now your `temporary`

result will be of type `long`

, and is capable of holding that value.