Most ways to do what you request would probably involve adding rules to built-in functions (such as `Integrate`

, `CDF`

, `PDF`

, etc), which may not be a good option. Here is a slightly softer way, using the `Block`

trick - based macro:

```
ClearAll[withIntegrationRule];
SetAttributes[withIntegrationRule, HoldAll];
withIntegrationRule[code_] :=
Block[{CDF, PDF, Integrate, NormalDistribution},
Integrate[
CDF[NormalDistribution[0, 1], \[Alpha]_ + \[Beta]_ x_] PDF[
NormalDistribution[\[Mu]_, \[Sigma]_], x_], {x_, -\[Infinity], \[Infinity]}] :=
CDF[NormalDistribution[0, 1], (\[Alpha] + \[Beta] \[Mu])/
Sqrt[1 + \[Beta]^2 \[Sigma]^2]];
code];
```

Here is how we can use it:

```
In[27]:=
withIntegrationRule[a=Integrate[CDF[NormalDistribution[0,1],\[Alpha]+\[Beta] x]
PDF[NormalDistribution[\[Mu],\[Sigma]],x],{x,-\[Infinity],\[Infinity]}]];
a
Out[28]= 1/2 Erfc[-((\[Alpha]+\[Beta] \[Mu])/(Sqrt[2] Sqrt[1+\[Beta]^2 \[Sigma]^2]))]
```

When our rule does not match, it will still work, automatically switching to the normal evaluation route:

```
In[36]:=
Block[{$Assumptions = \[Alpha]>0&&\[Beta]==0&&\[Mu]>0&&\[Sigma]>0},
withIntegrationRule[b=Integrate[CDF[NormalDistribution[0,1],\[Alpha]+\[Beta] x]
PDF[NormalDistribution[\[Mu],\[Sigma]],x],{x,0,\[Infinity]}]]]
Out[36]= 1/4 (1+Erf[\[Alpha]/Sqrt[2]]) (1+Erf[\[Mu]/(Sqrt[2] \[Sigma])])
```

where I set `\[Alpha]`

to `0`

in assumptions to make the integration possible in a closed form.

Another alternative may be to implement your own special-purpose integrator.