Currently we have quite a few functions (normal CDF, inverse CDF, Vasicek and all kinds of derivatives) coded out in PL/SQL, but they are very slow.

I can get much better performance by streaming the data over a workstation where I have coded out things in C# and then bulk insert the results back. This appproach however leaves the network as the bottleneck, it would be much better if I could 'put the mill where the wood is' by having faster functions inside the Oracle DB.

I want to see how I can speed that up by coding it out in either c(++) or Java (or any other alternative you may have). Does anyone here have any experience with this? Hopefully one of you has tried all approaches and can explain wich has worked best overall.

Extra complication here is that IT is busy as it is, so if I want a waiver to use some feature on the DB I need to make a solid case. I don;t get to play around much on that box, else I would do that.

We're on Oracle Database 11g Enterprise Edition Release 11.2.0.2.0 - 64bit Production

Thanks in advance,

Gert-Jan

**EDIT**

Here's an example of what a function, wich is the Normal CDF by Cody.

The difference between this and the `cume_dist`

is that `cume_dist`

finds the distribution within a set of rows. I just need to convert a probability into standard deviations and back (a lot of times), like the `NORMDIST`

and `NORMINV`

functions in Excel.

```
function stdnormal_cdf(u number) return number is
z number;
y Number;
begin
y:=abs(u);
if y <= 0.6629126073623883041257915894732959743297 then
z:=y * y;
y:=u * ((((1.161110663653770e-002 * z + 3.951404679838207e-001) * z + 2.846603853776254e + 001) * z + 1.887426188426510e + 002) * z + 3.209377589138469e + 003)/((((1.767766952966369e-001 * z + 8.344316438579620) * z + 1.725514762600375e + 002) * z + 1.813893686502485e + 003) * z + .044716608901563e + 003);
return 0.5 + y ;
else
z:=exp(-y * y/2)/2;
if y <= 5.65685424949238019520675489683879231428 then
y:=y/1.41421356237309504880168872420969807857;
y:=((((((((2.15311535474403846e-8 * y + 5.64188496988670089e-1) * y + 8.88314979438837594) * y + 6.61191906371416295e01) * y + 2.98635138197400131e02) * y + 8.81952221241769090e02) * y + 1.71204761263407058e03) * y + 2.05107837782607147e03) * y + 1.23033935479799725e03)/((((((((1.00000000000000000e00 * y + 1.57449261107098347e01) * y + 1.17693950891312499e02) * y + 5.37181101862009858e02) * y + 1.62138957456669019e03) * y + 3.29079923573345963e03) * y + 4.36261909014324716e03) * y + 3.43936767414372164e03) * + 1.23033935480374942e03);
y:=z * y;
else
z:=z * 1.41421356237309504880168872420969807857/y;
y:=2/(y * y);
y:=y * (((((1.63153871373020978e-2 * y + 3.05326634961232344e-1) * y + 3.60344899949804439e-1) * y + 1.25781726111229246e-1) * y + 1.60837851487422766e-2) * y + 6.58749161529837803e-4)/(((((y + 2.56852019228982242) * y + 1.87295284992346047) * y + 5.27905102951428412e-1) * y + 6.05183413124413191e-2) * y + 2.33520497626869185e-3);
y:=z * (1/1.77245385102123321827450760252310431421-y);
end if;
if u < 0 then
return y;
else
return 1-y;
end if;
end if;
end;
```

**EDIT 2**

Ok so here are the benchmarks. Test table with 100k rows. The functions between Oracle and F# are pretty straight translations of each other and give the same result.

The qeury: `select sum(get_rwa(approach, exposure_class_code, pd_r, lgd_r, ead_r, maturity_r, net_sale, rwf_r)) from functest`

Interpreted: 12.8 sec

Native: 13.2 sec

.Net (F#): 0.04 sec.

This would make the .Net function 320x (!) faster than the Oracle implementation, I really don't understand where this difference could come from. Anything up to 3-10x would seem reasonable. I really think I'm missing something here. Anyone?

In F# I loaded the 100k rows into a List first. (seemed fair, just summing up any other column in Oracle cost 0.06 seconds, so it seemed fair to exclude the data acces time in both cases. It takes about 3 sec to load the data into a list, so even if I include the time it takes to open up the connection, execute and stream over the networks etc, then still it's 4x faster.)