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I think I understand strong typing, but every time I look for examples for what is weak typing I end up finding examples of programming languages that simply coerce/convert types automatically.

For instance, in this article named Typing: Strong vs. Weak, Static vs. Dynamic says that Python is strongly typed because you get an exception if you try to:

Python

1 + "1"
Traceback (most recent call last):
File "", line 1, in ? 
TypeError: unsupported operand type(s) for +: 'int' and 'str'

However, such thing is possible in Java and in C#, and we do not consider them weakly typed just for that.

Java

  int a = 10;
  String b = "b";
  String result = a + b;
  System.out.println(result);

C#

int a = 10;
string b = "b";
string c = a + b;
Console.WriteLine(c);

In this another article named Weakly Type Languages the author says that Perl is weakly typed simply because I can concatenate a string to a number and viceversa without any explicit conversion.

Perl

$a=10;
$b="a";
$c=$a.$b;
print $c; #10a

So the same example makes Perl weakly typed, but not Java and C#?.

Gee, this is confusing enter image description here

The authors seem to imply that a language that prevents the application of certain operations on values of different types is strongly typed and the contrary means weakly typed.

Therefore, at some point I have felt prompted to believe that if a language provides a lot of automatic conversions or coercion between types (as perl) may end up being considered weakly typed, whereas other languages that provide only a few conversions may end up being considered strongly typed.

I am inclined to believe, though, that I must be wrong in this interepretation, I just do not know why or how to explain it.

So, my questions are:

  • What does it really mean for a language to be truly weakly typed?
  • Could you mention any good examples of weakly typing that are not related to automatic conversion/automatic coercion done by the language?
  • Can a language be weakly typed and strongly typed at the same time?

Thanks in advance for any references, use cases or examples that you provide that can lead me into the right direction.

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4  
Strong versus weak typing is all about type conversion (what else could it be about?) If you want an example of a "very" weak language, watch this: destroyallsoftware.com/talks/wat. –  Wilduck Mar 29 '12 at 16:41
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@Wildduck All languages provide type conversions, but not all of them are considered weakly typed. My examples shown below demonstrate how programmers consider a language weakly typed based on the same examples that are possible on other languages considered strongly typed. As such my question still prevails. What is the difference? –  Edwin Dalorzo Mar 29 '12 at 16:55
2  
I believe this is better suited for Programmers. –  zzzzBov Mar 29 '12 at 19:39
1  
@Wilduck hilarious, thanks! –  antony.trupe Mar 30 '12 at 1:43
2  
@Brendan What about summing a float and an integer? Isn't the integer coerced into a float in Python? Would you say now that Python is not absolutely strongly typed? –  Edwin Dalorzo Mar 30 '12 at 4:43
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9 Answers

up vote 170 down vote accepted

UPDATE: This question was the subject of my blog on the 15th of October, 2012. Thanks for the great question!


What does it really mean for a language to be "weakly typed"?

It means "this language uses a type system that I find distasteful". A "strongly typed" language by contrast is a language with a type system that I find pleasant.

The terms are essentially meaningless and you should avoid them. Wikipedia lists eleven different meanings for "strongly typed", several of which are contradictory. This indicates that the odds of confusion being created are high in any conversation involving the term "strongly typed" or "weakly typed".

All that you can really say with any certainty is that a "strongly typed" language under discussion has some additional restriction in the type system, either at runtime or compile time, that a "weakly typed" language under discussion lacks. What that restriction might be cannot be determined without further context.

Instead of using "strongly typed" and "weakly typed", you should describe in detail what kind of type safety you mean. For example, C# is a statically typed language and a type safe language and a memory safe language, for the most part. C# allows all three of those forms of "strong" typing to be violated. The cast operator violates static typing; it says to the compiler "I know more about the runtime type of this expression than you do". If the developer is wrong, then the runtime will throw an exception in order to protect type safety. If the developer wishes to break type safety or memory safety, they can do so by turning off the type safety system by making an "unsafe" block. In an unsafe block you can use pointer magic to treat an int as a float (violating type safety) or to write to memory you do not own. (Violating memory safety.)

C# imposes type restrictions that are checked at both compile-time and at runtime, thereby making it a "strongly typed" language compared to languages that do less compile-time checking or less runtime checking. C# also allows you to in special circumstances do an end-run around those restrictions, making it a "weakly typed" language compared with languages which do not allow you to do such an end-run.

Which is it really? It is impossible to say; it depends on the point of view of the speaker and their attitude towards the various language features.

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12  
@edalorzo: It is based on taste and personal opinions about (1) what aspects of type theory are relevant and which are irrelevant, and (2) whether a language is required to enforce or merely encourage type restrictions. As I pointed out, one could reasonably say that C# is strongly typed because it allows and encourages static typing, and one could just as reasonably say that it is weakly typed because it allows the possibility to violate type safety. –  Eric Lippert Mar 29 '12 at 17:02
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@edalorzo: As for assembly, again, it is a matter of opinion. An assembly language compiler will not allow you to move a 64 bit double from the stack into a 32 bit register; it will allow you to move a 32 bit pointer to a 64 bit double from the stack into a 32 bit register. In that sense the language is "typesafe" -- it imposes a restriction on the legality of the program based on a type classification of data. Whether that restriction is "strong" or "weak" is a matter of opinion, but it is clearly a restriction. –  Eric Lippert Mar 29 '12 at 17:09
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I think I see your point now, a truly weakly typed language would have to be totally untyped or monotyped, which in real life is practically impossible. As such, any language has certain definition of types, which are safe, and depending on the number of holes that the language provides to violate or manipulate its data or data types you may end up considering it more or less weakly typed, maybe even in certain contexts only. –  Edwin Dalorzo Mar 29 '12 at 17:13
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@edalorzo: Correct. For example, the untyped lambda calculus is about as weakly typed as you can get. Every function is a function from a function to a function; any data can be passed to any function without restriction because everything is of "the same type". The validity of an expression in untyped lambda calculus depends only on its syntactic form, not on a semantic analysis that classifies certain expressions as having certain types. –  Eric Lippert Mar 29 '12 at 17:30
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@edalorzo I should say, although I agree with Eric's answer, he got the +1 just on his first sentence! –  Mark Hurd Mar 30 '12 at 1:36
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As others have noted, the terms "strongly typed" and "weakly typed" have so many different meanings that there's no single answer to your question. However, since you specifically mentioned Perl in your question, let me try to explain in what sense Perl is weakly typed.

The point is that, in Perl, there is no such thing as an "integer variable", a "float variable", a "string variable" or a "boolean variable". In fact, as far as the user can (usually) tell, there aren't even integer, float, string or boolean values: all you have are "scalars", which are all of these things at the same time. So you can, for example, write:

$foo = "123" + "456";           # $foo = 579
$bar = substr($foo, 2, 1);      # $bar = 9
$bar .= " lives";               # $bar = "9 lives"
$foo -= $bar;                   # $foo = 579 - 9 = 570

Of course, as you correctly note, all of this can be seen as just type coercion. But the point is that, in Perl, types are always coerced. In fact, it's quite hard for a user to tell what the internal "type" of a variable might be: at line 2 in my example above, asking whether the value of $bar is the string "9" or the number 9 is pretty much meaningless, since, as far as Perl is concerned, those are the same thing. Indeed, it's even possible for a Perl scalar to internally have both a string and a numeric value at the same time, as is e.g. the case for $foo after line 2 above.

The flip side of all this is that, since Perl variables are untyped (or, rather, don't expose their internal type to the user), operators cannot be overloaded to do different things for different types of arguments; you can't just say "this operator will do X for numbers and Y for strings", because the operator can't (won't) tell which kind of values its arguments are.

Thus, for example, Perl has and needs both a numeric addition operator (+) and a string concatenation operator (.): as you saw above, it's perfectly fine to add strings ("1" + "2" == "3") or to concatenate numbers (1 . 2 == 12). Similarly, the numeric comparison operators ==, !=, <, >, <=, >= and <=> compare the numeric values of their arguments, while the string comparison operators eq, ne, lt, gt, le, ge and cmp compare them lexicographically as strings. So 2 < 10, but 2 gt 10 (but "02" lt 10, while "02" == 2). (Mind you, certain other languages, like JavaScript, try to accommodate Perl-like weak typing while also doing operator overloading. This often leads to ugliness, like the loss of associativity for +.)

(The fly in the ointment here is that, for historical reasons, Perl 5 does have a few corner cases, like the bitwise logical operators, whose behavior depends on the internal representation of their arguments. Those are generally considered an annoying design flaw, since the internal representation can change for surprising reasons, and so predicting just what those operators do in a given situation can be tricky.)

All that said, one could argue that Perl does have strong types; they're just not the kind of types you might expect. Specifically, in addition to the "scalar" type discussed above, Perl also has two structured types: "array" and "hash". Those are very distinct from scalars, to the point where Perl variables have different sigils indicating their type ($ for scalars, @ for arrays, % for hashes)1. There are coercion rules between these types, so you can write e.g. %foo = @bar, but many of them are quite lossy: for example, $foo = @bar assigns the length of the array @bar to $foo, not its contents. (Also, there are a few other strange types, like typeglobs and I/O handles, that you don't often see exposed.)

Also, a slight chink in this nice design is the existence of reference types, which are a special kind of scalars (and which can be distinguished from normal scalars, using the ref operator). It's possible to use references as normal scalars, but their string/numeric values are not particularly useful, and they tend to lose their special reference-ness if you modify them using normal scalar operations. Also, any Perl variable2 can be blessed to a class, turning it into an object of that class; the OO class system in Perl is somewhat orthogonal to the primitive type (or typelessness) system described above, although it's also "weak" in the sense of following the duck typing paradigm. The general opinion is that, if you find yourself checking the class of an object in Perl, you're doing something wrong.


1 Actually, the sigil denotes the type of the value being accessed, so that e.g. the first scalar in the array @foo is denoted $foo[0]. See perlfaq4 for more details.

2 Objects in Perl are (normally) accessed through references to them, but what actually gets blessed is the (possibly anonymous) variable the reference points to. However, the blessing is indeed a property of the variable, not of its value, so e.g. that assigning the actual blessed variable to another one just gives you a shallow, unblessed copy of it. See perlobj for more details.

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8  
+1 For the great lecture on perl. I wish I could upvote you more than once. Your explanation on perl weakly typing is the best I've read. –  Edwin Dalorzo Mar 30 '12 at 12:26
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In addition to what Eric has said, consider the following C code:

void f(void* x);

f(42);
f("hello");

In contrast to languages such as Python, C#, Java or whatnot, the above is weakly typed because we lose type information. Eric correctly pointed out that in C# we can circumvent the compiler by casting, effectively telling it “I know more about the type of this variable than you”.

But even then, the runtime will still check the type! If the cast is invalid, the runtime system will catch it and throw an exception.

With type erasure, this doesn’t happen – type information is thrown away. A cast to void* in C does exactly that. In this regard, the above is fundamentally different from a C# method declaration such as void f(Object x).

(Technically, C# also allows type erasure through unsafe code or marshalling.)

This is as weakly typed as it gets. Everything else is just a matter of static vs. dynamic type checking, i.e. of the time when a type is checked.

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+1 Good point, you now made me think of type erasure as a feature that can also imply "weakly-typedness". There is type erasure also in Java, and at runtime, the type system will let you violate constraints that the compiler would never approve. The C example is excellent to illustrate the point. –  Edwin Dalorzo Mar 29 '12 at 23:37
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Agreed, there are layers to the onion, or the inferno. These seems a more significant definition of type weakness. –  Jodrell Mar 30 '12 at 10:20
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@edalorzo I don’t think this is quite the same since even though Java allows you to circumvent the compiler, the runtime type system will still catch the violation. So the Java runtime type system is strongly typed in this regard (there are exceptions, e.g. where reflection can be used to circumvent access control). –  Konrad Rudolph Mar 30 '12 at 10:35
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@edalorzo You can only circumvent the compiler this way, not the runtime system. It’s important to realise that languages such as Java and C# (and to a certain extent also C++) have a type system that is ensured twice: once at compile time, and once at runtime. void* breaks through both type checks. Generic type erasure doesn’t, it only circumvents the compile-time checks. It’s exactly like explicit casts (mentioned by Eric) in this regard. –  Konrad Rudolph Mar 30 '12 at 12:20
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@edalorzo Re your confusion: we shouldn’t. The distinction is fluent. And yes, type erasure makes Java weakly typed in this regard. My point was that even with generic type erasure you still cannot circumvent the runtime type checks unless you also use reflection. –  Konrad Rudolph Mar 30 '12 at 12:58
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A perfect example comes from the wikipedia article of Strong Typing:

Generally strong typing implies that the programming language places severe restrictions on the intermixing that is permitted to occur.

Weak Typing

a = 2
b = "2"

concatenate(a, b) # returns "22"
add(a, b) # returns 4

Strong Typing

a = 2
b = "2"

concatenate(a, b) # Type Error
add(a, b) # Type Error
concatenate(str(a), b) #Returns "22"
add(a, int(b)) # Returns 4

Notice that a weak typing language can intermix different types without errors. A strong type language requires the input types to be the expected types. In a strong type language a type can be converted (str(a) converts an integer to a string) or cast (int(b)).

This all depends on the interpretation of typing.

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2  
But this leads to the contradictory examples provided in the question. A Strongly Typed language may include implicit coercion that means either (or both) of your two "Type Error" examples are automatically converted to the relevant of the second two examples, but generally that language is still Strongly Typed. –  Mark Hurd Mar 30 '12 at 1:31
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True. I guess you could say there are varying degrees of strong typing and weak typing. Implicit conversion could mean that the language is less strongly typed than a language that does not do implicit conversion. –  SaulBack Mar 30 '12 at 14:48
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I would like to contribute to the discussion with my own research on the subject, as others comment and contribute I have been reading their answers and following their references and I have found interesting information. As suggested, it is probable that most of this would be better discussed in the Programmers forum, since it appears to be more theoretical than practical.

From a theoretical standpoint, I think the article by Luca Cardelli and Peter Wegner named On Understanding Types, Data Abstraction and Polymorphism has one of the best arguments I have read.

A type may be viewed as a set of clothes (or a suit of armor) that protects an underlying untyped representation from arbitrary or unintended use. It provides a protective covering that hides the underlying representation and constrains the way objects may interact with other objects. In an untyped system untyped objects are naked in that the underlying representation is exposed for all to see. Violating the type system involves removing the protective set of clothing and operating directly on the naked representation.

This statement seems to suggest that weakly typing would let us access the inner structure of a type and manipulate it as if it was something else (another type). Perhaps what we could do with unsafe code (mentioned by Eric) or with c type-erased pointers mentioned by Konrad.

The article continues...

Languages in which all expressions are type-consistent are called strongly typed languages. If a language is strongly typed its compiler can guarantee that the programs it accepts will execute without type errors. In general, we should strive for strong typing, and adopt static typing whenever possible. Note that every statically typed language is strongly typed but the converse is not necessarily true.

As such, strong typing means the absence of type errors, I can only assume that weak typing means the contrary: the likely presence of type errors. At runtime or compile time? Seems irrelevant here.

Funny thing, as per this definition, a language with powerful type coercions like Perl would be considered strongly typed, because the system is not failing, but it is dealing with the types by coercing them into appropriate and well defined equivalences.

On the other hand, could I say than the allowance of ClassCastException and ArrayStoreException (in Java) and InvalidCastException, ArrayTypeMismatchException (in C#) would indicate a level of weakly typing, at least at compile time? Eric's answer seems to agree with this.

In a second article named Typeful Programming provided in one of the references provided in one of the answers in this question, Luca Cardelli delves into the concept of type violations:

Most system programming languages allow arbitrary type violations, some indiscriminately, some only in restricted parts of a program. Operations that involve type violations are called unsound. Type violations fall in several classes [among which we can mention]:

Basic-value coercions: These include conversions between integers, booleans, characters, sets, etc. There is no need for type violations here, because built-in interfaces can be provided to carry out the coercions in a type-sound way.

As such, type coercions like those provided by operators could be considered type violations, but unless they break the consistency of the type system, we might say that they do not lead to a weakly typed system.

Based on this neither Python, Perl, Java or C# are weakly typed.

Cardelli mentions two type vilations that I very well consider cases of truly weak typing:

Address arithmetic. If necessary, there should be a built-in (unsound) interface, providing the adequate operations on addresses and type conversions. Various situations involve pointers into the heap (very dangerous with relocating collectors), pointers to the stack, pointers to static areas, and pointers into other address spaces. Sometimes array indexing can replace address arithmetic. Memory mapping. This involves looking at an area of memory as an unstructured array, although it contains structured data. This is typical of memory allocators and collectors.

This kind of things possible in languages like C (mentioned by Konrad) or through unsafe code in .Net (mentioned by Eric) would truly imply weakly typing.

I believe the best answer so far is Eric's, because the definition of this concepts is very theoretical, and when it comes to a particular language, the interpretations of all these concepts may lead to different debatable conclusions.

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Weak typing does indeed mean that a high percentage of types can be implicitly coerced, attempting to guess what the coder intended.

Strong typing means that types are not coerced, or at least coerced less.

Static typing means your variables' types are determined at compile time.

Many people have recently been confusing "manifestly typed" with "strongly typed". "Manifestly typed" means that you declare your variables' types explicitly.

Python is mostly strongly typed, though you can use almost anything in a boolean context, and booleans can be used in an integer context, and you can use an integer in a float context. It is not manifestly typed, because you don't need to declare your types (except for Cython, which isn't entirely python, albeit interesting). It is also not statically typed.

C and C++ are manifestly typed, statically typed, and somewhat strongly typed, because you declare your types, types are determined at compile time, and you can mix integers and pointers, or integers and doubles, or even cast a pointer to one type into a pointer to another type.

Haskell is an interesting example, because it is not manifestly typed, but it's also statically and strongly typed.

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+1 Because I like the coined term "manifestly typed", which categorizes languages like Java and C# where you have to explicitly declare types and distinguish them from other statically-type languages like Haskell and Scala where type inference plays an important role and this typically confuses people, as you say, and makes them believe these languages are dynamically-typed. –  Edwin Dalorzo Oct 19 '12 at 17:12
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I like @Eric Lippert's answer, but to address the question - strongly typed languages typically have explicit knowledge of the types of variables at each point of the program. Weakly typed languages do not, so they can attempt to perform an operation that may not be possible for a particular type. It think the easiest way to see this is in a function. C++:

void func(string a) {...}

The variable a is known to be of type string and any incompatible operation will be caught at compile time.

Python:

def func(a)
  ...

The variable a could be anything and we can have code that calls an invalid method, which will only get caught at runtime.

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11  
I think you may be confusing dynamic typing vs static typing with strong typing vs weak typing. In both versions of your code, the runtime type systems knows very well that a is a string. It is just that in the first case, the compiler can tell you that, in the second it can't. But this does not make any of these languages weakly-typed. –  Edwin Dalorzo Mar 29 '12 at 17:02
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As many others have expressed, the entire notion of "strong" vs "weak" typing is problematic.

As a archetype, Smalltalk is very strongly typed -- it will always raise an exception if an operation between two objects is incompatible. However, I suspect few on this list would call Smalltalk a strongly-typed language, because it is dynamically typed.

I find the notion of "static" versus "dynamic" typing more useful than "strong" versus "weak." A statically-typed language has all the types figured out at compile-time, and the programmer has to explicitly declare if otherwise.

Contrast with a dynamically-typed language, where typing is performed at run-time. This is typically a requirement for polymorphic languages, so that decisions about whether an operation between two objects is legal does not have to be decided by the programmer in advance.

In polymorphic, dynamically-typed languages (like Smalltalk and Ruby), it's more useful to think of a "type" as a "conformance to protocol." If an object obeys a protocol the same way another object does -- even if the two objects do not share any inheritance or mixins or other voodoo -- they are considered the same "type" by the run-time system. More correctly, an object in such systems is autonomous, and can decide if it makes sense to respond to any particular message referring to any particular argument.

Want an object that can make some meaningful response to the message "+" with an object argument that describes the colour blue? You can do that in dynamically-typed languages, but it is a pain in statically-typed languages.

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I think that the concept of dynamic vs static typing is not under discussion. Although I have to say that I do not believe that polymorphism is in anyway handicaped in statically type languages. Ultimately, the type system verifies if a given operation is applicable to the given operands, whether at runtime or at compile time. Also, other forms of polymorphism, like parametric functions and classes permit combining types in statically type languages in ways that you described as very difficult when compared to dynamically typed, even nicer if type inference is provided. –  Edwin Dalorzo Apr 4 '12 at 18:30
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I think there is some debate about what weakly typed means... http://en.wikipedia.org/wiki/Weak_typing

For practical purposes, a weakly typed languages don't have to declare types in the definition, and don't have type safety (compile time errors for incorrectly assigned types).

Java string class was designed to to behave similar a weakly typed language for convenience.

Weakly typed and strongly typed together... No.

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7  
a language that does not need to declare types in its definition is what you call dynamically typed, but not necessarily weakly typed. Python does not need to declare the type of variable, but it is still strongly type as per the definition of its type system at runtime. –  Edwin Dalorzo Mar 29 '12 at 16:56
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