RDBMS are based on Relational Algebra as well as Codd's Model. Do we have something similar to that for Programming languages or OOP?



Heavens, yes. And because there are so many programming languages, there are multiple models to choose from. Most important first:
I'm not as well educated as I should be about abstract models used for OOP. The models I'm most familiar with are very closely connected to implementation strategies. If I wanted to investigate this area further I would start with William Cook's denotational semantics for Smalltalk. (Smalltalk as a language is very simple, almost as simple as the lambda calculus, so it makes a good case study for modeling more complicated objectoriented languages.) Wei Hu reminds me that Martin Abadi and Luca Cardelli have put together an ambitious body of work on foundational calculi (analogous to the lambda calculus) for objectoriented languages. I don't understand the work well enough to summarize it, but here is a passage from the Prologue of their book, which I feel is worth quoting:
I hope this quotation gives you an idea of the flavor of the work. 


Lisp is based on Lambda Calculus, and is the inspiration for much of what we see in modern languages today. VonNeumann machines are the foundation of modern computers, which were first programmed in assembler language, then in FORmula TRANslator. Then the formal linguistic theory of contextfreegrammars was applied, and underlies the syntax of all modern languages. Computability theory (formal automata) has a hierachy of machinetypes that parallels the hierarchy of formal grammars, for example, regulargrammar = finitestatemachine, contextfreegrammar = pushdownautomaton, contextsensitivegrammar = turingmachine. There also is information theory, of two types, Shannon and Kolmogorov, that can be applied to computing. There are lesserknown models of computing, such as recursivefunctiontheory, registermachines, and Postmachines. And don't forget predicatelogic in its various forms. Added: I forgot to mention discrete math  group theory and lattice theory. Lattices in particular are (IMHO) a particularly nifty concept underlying all boolean logic, and some models of computation, such as denotational semantics. 


Functional languages like lisp inherit their basic concepts from Church's "lambda calculs" (wikipedia article here). Regards 


One concept may be Turing Machine. 


If you study programming languages (eg: at a University), there is quite a lot of theory, and not a little math involved. Examples are:



The history section of Wikipedia's Objectoriented programming could be enlightening. 


Programming languages is product of application of following theories:



The closest analogy I can think of is Gurevich Evolving Algebras that, nowadays, are more known under the name of "Gurevich Abstract State Machines" (GASM). I've long hoped to see more real applications of the theory when Gurevich joined Microsoft, but it seems that very few is coming out. You can check the ASML page on the Microsoft site. The good point about GASM is that they closely resemble pseudocode even if their semantic is formally specified. This means that practitioners can easily grasp them. After all, I think that part of the success of Relational Algebra is that it is the formal foundation of concepts that can be easily grasped, namely tables, foreign keys, joins, etc. I think we need something similar for the dynamic components of a software system. 


As I know, Formal grammars is used for description of syntax. 


There are many dimensions to address your question, scattering in the answers. First of all, to describe the syntax of a language and specify how a parser would work, we use contextfree grammars. Then you need to assign meanings to the syntax. Formal semantics come in handy; the main players are operational semantics, denotational semantics, and axiomatic semantics. To rule out bad programs you have the type system. In the end, all computer programs can reduce to (or compile to, if you will) very simple computation models. Imperative programs are more easily mapped to Turing machines, and functional programs are mapped to lambda calculus. If you're learning all this stuff by yourself, I highly recommend http://www.unikoblenz.de/~laemmel/paradigms0910/, because the lectures are videotaped and put online. 


Plenty has been mentioned of the application of math to computational theory and semantics. I like the mention of type theory and I'm glad someone mentioned lattice theory. Here are just a few more. No one has explicitly mentioned category theory, which shows up more in functional languages than elsewhere, such as through the concepts of monads and functors. Then there's model theory and the various incarnations of logic that actually show up in theorem provers or the logic language Prolog. There are also mathematical applications to foundations of and problems in concurrent languages. 

