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How do people create new programming languages? Specifically:

  1. What language do they write it in?
  2. Does the language have to be one that in between a high level language and machine code?
  3. What are the stages/elements of creating a programming language For example - C or C++(From my basic research I've realised that all programming languages either need a compiler or an interpreter but I don't really understand the difference between the two)

closed as too broad by crashmstr, Mark Rotteveel, Bob Dalgleish, VDWWD, Mark Dec 10 '18 at 20:45

Please edit the question to limit it to a specific problem with enough detail to identify an adequate answer. Avoid asking multiple distinct questions at once. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

  • From the spare parts of old ones? :-) – Ami Tavory May 26 '15 at 15:06
  • And what are that spare parts? :D – user239887 May 26 '15 at 15:44
  • Question 2 you could answer yourself. For, if every new language had to be "in between a high level language and machine code", as you put it, how then do we have high level languages at all? Through some relevation from heaven, maybe? – Ingo May 27 '15 at 17:47
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I will give you a good idea of where computers started and how they've progressed.

If you want to get into the history of computers I'd look at things such as the Jacquard loom and Babbage's difference engine. These two inventions probably had the greatest early influence on early modern computing. Usage of punch cards (Jacquard) and the mechanical 'calculation' (Babbage) provided a great foundation.

So let's start with how the computer works. At the heart of every computer is a transistor (and before that vacuum tubes). The big thing behind a transistor is it can send electricity in two different ways, depending on its state*. This allows for the creation of logical flows of electricity. With this, we can create all sorts of wonderful things**: nand gates, and gates, half adders, multiplexes etc.

Now that we have these electronic building blocks in place there are essentially two types of signals that come into them. Signals that tell the electronics what to do, and actual data that the electronics compute with. So the command to add, might say take the data from register 1, and add it to the data in register 2, and store that information in register 3. What this command does, it sets the computer up in a state so that registers 1 and 2 behave as inputs to the adder, and register 3 stores the result. The same would be true for subtraction multiplication etc. There's also commands to say jump to a certain line, read information from memory etc.

These binary commands are the machine code necessary to 'set' the CPU.

Up until now, I haven't really addressed your questions, but I've laid some of the frameworks to understand what's going on. (You said you wanted to learn everything =P)

So now we have a computer that runs on machine code. Nothing more nothing less. Now, this is a very hard-to-use machine. So assembly is almost always one of the first languages that's created. To use assembly we need to create an assembler. An assembler is essentially a compiler, that turns assembly language into machine code. As a result assembly languages are 1 to 1 with the machine code commands. The idea being since we're coding this in binary, it's a good idea to keep it simple. So now we have something that can turn assembly language into machine code.

So now we have two levels of 'languages': 0 - Machine code: This is code that the CPU understands, it's in binary, and not very user-friendly. 1 - Assembly language: This uses some 'English-like' terms, but is still relatively clunky, and 1 to 1 command-wise with the machine code.

So let's add a third,

2- High-level language.

A high-level language is something that more closely resembles English, such as C. We have loops and data structures and other useful things. To use C we have to write a compiler. A compiler takes code written in the C language and creates object code (similar to assembly language). Then another program turns that object code into machine language. Nowadays these two steps are usually combined into one for efficiency sake. Now we have your first definition. A compiler turns a high-level language into an object (or machine) code***.

Now that we have our first high-level language (C) it probably seems foolish and painful to work with the assembly language again unless we have to. So now we can write new languages and compilers in C, or any other language we've now made****.

So now let's tear into an interpreter. An interpreter is a program that reads and executes a program on its own. Instead of turning a program that turns high-level code into machine code, this reads the high-level code, (usually a line at a time) and executes it.

Let's take Java for example. Java is an interpreted language, basically, that means someone has made a program (in say C). This C program reads the Java code and executes it. So there's another layer between the computer and the code.

There's a lot of stuff this response kind of glazes over, how to build a CPU, the considerations into making a language, how the same language can run on different CPUs. The advantages of interpreters over compilers etc. But hopefully, it gives a good amount of background and information that you can read up and research more on your own.

  • Java is not an interpreted language. Java code is compiled to Java Bytecode which is ran on the JVM. The JVM itself may be written in C, however. – Aaron Franke Jan 20 at 11:58
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1) What language do they write it in?

It completely depends on the programmer. Several languages are implemented on C, C++. Several others are bootstrapped. ( C is written in C). An excerpt from the link:

Bootstrapping:
Basically you start with a very minimal process/set of functions that can be used to 
compile the code that defines a slightly more functional compiler. 
This creates your next compiler which then can then be used to build code that can do even 
more. 
You repeat this process until you have a full blown compiler that can 
compile all the language features. 

Actually, it's the compiler or the interpreter that is written in some language. For example, Go is a language and has two compilers, gc and gccgo. gc is written in C and gccgo is a gcc frontend written mainly in C++.

2) Does the language have to be one that in between a high level language and machine code?

Not necessarily. As already explained, compiler or interpreter can be written in a high level language too. Writing a language basically means defining a set of rules for your language, or describing the specifications for your language.

3) What are the stages/elements of creating a programming language For example - C or C++(From my basic research I've realised that all programming languages either need a compiler or an interpreter but I don't really understand the difference between the two)

In simple terms :

  1. Prepare the semantics for your language. Draw out a grammar for your language.
  2. Decide whether your language will use a compiler or an interpreter.
    Difference between the two (More on the differences part here.) :

In the interpreted world your user will typically edit your program in an editor, and run it directly on the interpreter; while in the compile world, your user will edit your program, compile it, save the resulting executable somewhere and run it.

Compiler takes entire program as input. Interpreter takes single instruction as input .

Errors are displayed after entire program is checked in a compiler, whereas errors are displayed for every instruction interpreted (if any).

  1. Write the front end : how users will see errors, warnings etc.

  2. Use the parser information to write the object code or an intermediate representation.

  3. Write the executor or code generator that will bind everything together.

  4. Testing and documentation.

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Regarding your first question. All languages need a compiler, that is true, however each language has its own different way to be compiled. For example Java uses JDK to be compiled and JVM to be executed. Regardless of which language you have programmed (as always as its a high level language) you will be have middle layers that convert your code to machine code (aka binary code). Those middle layers are made in middle level languages (there are a bunch of them out there, you could read of them here http://en.wikipedia.org/wiki/Timeline_of_programming_languages) and most extensively used as of today for low level programming (still not machine code) is C.

Just like the first answer there have been different programming language levels, but the first and most important thing you need to remember is that computers understand binary code, which is 1 or 0, and series of 1 and 0 string together define what a program does. Everything that a computer does can be reduced to it.

So far I hope I have answered two of your questions.

About the third one the trick is always in the compiler, if you want a new programming language you need a compiler so you can translate your code into machine code. All you can see now, like certain key words with color and validations for errors before you even compile your code, those are IDES (you can read about them here http://en.wikipedia.org/wiki/Integrated_development_environment).

For example if you want "rabbit" as your key word in your code and you also want rabbit just to be used after a comma, the compiler should be a middle layer program that determines whether it has been used correctly or not by reading your code.

A compiler has different stages: You need to be able to read your code and determine if all dependencies (which are other files written in your code) and the current code lines are fine. After that you need to convert your "rabbit" into something you would like your program to do every time you use it. In the end your will generate a file that can be read directly by the machine or another application of your own, as Java uses JVM.

Hope this gives you some light.

  • @user3788135 to emphasize the first point, Java is both a compiled and an interpreted language, as it runs on a "virtual machine". – Weather Vane May 26 '15 at 15:48
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1) What language do they write it in?

Whatever they want; it depends on the focus of the language and whatever they're comfortable using. You can write a compiler in anything from assembly to Haskell. It depends on how complex the implementation needs to be, which depends on the rules of the language you're creating. For example, it's relatively easy to write a C compiler because the language rules are fairly straightforward. C++. not so much.

2) Does the language have to be one that in between a high level language and machine code?

Nope. A compiler is just another program; it reads in a bunch of text and emits either another text file or a binary file of machine code. It doesn't have to be written in a low-level language. A lot of compilers are written in C because that's what a lot of people know best, but that doesn't mean the all compilers must be written C or assembler. Using a higher-level language will probably make the task a lot easier.

3) What are the stages/elements of creating a programming language For example - C or C++(From my basic research I've realised that all programming languages either need a compiler or an interpreter but I don't really understand the difference between the two)

Typically, an interpreter runs the program as it's translating, whereas a compiler just translates the code without executing it. That line's pretty blurry these days (for example, Java code is compiled to a platform-independent byte code, which is then interpreted by the JVM into native machine code).

The big parts of the compiler are:

  • A lexer, which breaks your source text into tokens (literals, identifiers, punctuators, etc.);
  • A parser, which takes those tokens and matches them to the language grammar;
  • A code generator, which emits the target code based on results from the parser.

The code generator may also contain some kind of optimizing logic to generate machine code that's more efficient than a literal translation of the source code. For example, gcc does a neat little trick when you multiply something by an integer literal, such as i = a * 10; Instead of generating code like

movl     a, %edx  ;; write value of a to register edx
movl   $10, %eax  ;; write value of 10 to register eax
imull %edx, %eax  ;; multiply %edx by %eax, store in %eax

it generates

movl    a, %edx ;; same as above
movl %edx, %eax ;; copy %edx to %eax
sall   $2, %eax ;; shift %eax left by 2 places, effectively multiplying by 4
addl %edx, %eax ;; add %edx to %eax
addl %eax, %eax ;; double %eax

If a is 3, then this gives us

 3 << 2 == 12
12 +  3 == 15
15 + 15 == 30

For some hardware, shifts and adds are relatively fast compared to multiplication, so even though it looks less efficient because there are more instructions, it actually executes a little faster than the naive imull call.

I took a compiler class over a summer session1 almost 30 years ago, so my skills aren't exactly up-to-date. But the big stuff doesn't really change over time. The hard work of creating a new language is a) deciding on what you want it to do, b) coming up with a syntax that's both human-readable and reasonably easy to parse, and c) getting the semantics right.


1. Don't do this. Compiler construction will be one of the tougher classes in a CS curriculum, and should not be taken in a short session.

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This is a great book to help get started http://www.amazon.com/Language-Implementation-Patterns-Domain-Specific-Programming/dp/193435645X/

The stages of building a language are

  1. Lexing. Lexing means being able to read certain categories of tokens. A token can be a series of digits 12376 or text strings like 'Hello'. The lexing looks at the first character (and it may also look ahead to the second character) to determine what it is. In the case of a number, it sees a digit and then proceeds to read the series of digits (by calling a subroutine), or in the case of a string it sees a quote then proceeds to read a string. The result of the lexer is a token which is a type (a number or string in this example) and the text of the token. This is normally stored in a struct as Kind int and Text string with constants declared to represent the kinds.

  2. The next building block is the parser. The parser sees the series of tokens, so it might see Identifier then looking ahead will see an =. Then it will branch off into an assignment. The parser builds a tree. In the case of an assignment, it will build a "node" of type "assign" then it will store the identifier in the first child and the expression in the second child. All tree nodes are "operations", meaning that they do something. You will not just a string or integer as a Node, you will have "Add" or "Append" etc as nodes (unless it is an expression, but expressions are contained by operations).

  3. The last part is execution. This is done by walking the tree and executing the nodes.

There is a lot of other machinery involved such as Memory, Scope, and the look ahead machinery. This is explained in the link above.

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