The single probability check with linear probability can be easily done with:

```
function checkWithProbability($probability=0.1, $length=10000)
{
$test = mt_rand(1, $length);
return $test<=$probability*$length;
}
```

For example, this will produce:

```
for($i=0; $i<10; $i++)
{
var_dump(checkWithProbability(1/3));
}
```

Something like:

bool(false)
bool(true)
bool(false)
bool(false)
bool(false)
bool(false)
bool(false)
bool(false)
bool(true)
bool(false)

And you can use that principle to get your edges check with desired probability:

```
function checkWithSet(array $set, $length=10000)
{
$left = 0;
foreach($set as $num=>$right)
{
$set[$num] = $left + $right*$length;
$left = $set[$num];
}
$test = mt_rand(1, $length);
$left = 1;
foreach($set as $num=>$right)
{
if($test>=$left && $test<=$right)
{
return $num;
}
$left = $right;
}
return null;//debug, no event realized
}
```

The idea is to use geometry probability - i.e. split some line part into pieces with corresponding length and then check to which part our random number belongs.

0.75 0.9
| |
V V
*--------*--*-----*-*--*--* <-- (length)
^ ^ ^ ^ ^
| | | | |
0 0.4 0.5 0.8 1

Sample will be:

```
$set = [
1 => 0.4,
2 => 0.1,
3 => 0.25,
4 => 0.05,
5 => 0.1,
6 => 0.1
];
for($i=0; $i<10; $i++)
{
var_dump(checkWithSet($set));
}
```

With result like:

int(1)
int(2)
int(2)
int(6)
int(3)
int(1)
int(1)
int(6)
int(1)
int(1)

You can increase `$length`

- in theory, this will increase "quality" of randomize check, but that's not too easy thing - because `mt_rand()`

uses pseudo-random generator, Mersenne Twister (and in ideal case that's not true linear probability)