Header files have the .hh extension, source files use the .cc extension. All files must have a license and copyright blurb. Use #pragma once instead of an include guard.
Header files which contain a public part of the interface of Seastar go in the include directory. Internal header and source files which are private to the implementation go in the src directory.
Use spaces only; NEVER tabs. Rationale: tabs render differently on each system.
An indent is four spaces. A double indent is eight spaces, a half-indent is two spaces.
We follow the C++ and Boost naming conventions: class names, variables, functions, and concepts are words_separated_by_whitespace.
Private data members are prefixed by an underscore:
class my_class {
int _a_member;
public:
void foo() {
_a_member = 3;
}
};Think of the leading underscore as a shorthand for this->.
Template parameters use CamelCase
Note: because the Concept Technical Specification used CamelCase for concepts, some Seastar concepts alse use CamelCase. These will be gradually deprecated and replaced with snake_case names. New concepts should use snake_case.
In any file, to include a public header file (one in the include directory), use an absolute path with <> like this:
#include <seastar/core/future.hh>In any private file, to include a private header file (one in the src directory), use an absolute path with "" like this:
#include "core/future_impl.hh"Header files in Seastar must be self-contained, i.e., each can be included without having to include specific other headers first. To verify that your change did not break this property, run ninja checkheaders in the build directory.
All nested scopes are braced, even when the language allows omitting the braces (such as an if-statement), this makes patches simpler and is more consistent. The opening brace is merged with the line that opens the scope (class definition, function definition, if statement, etc.) and the body is indented.
void a_function() {
if (some condition) {
stmt;
} else {
stmt;
}
}An exception is namespaces -- the body is not indented, to prevent files that are almost 100% whitespace left margin.
When making a change, if you need to insert an indentation level, you can temporarily break the rules by insering a half-indent, so that the patch is easily reviewable:
void a_function() {
while (something) { // new line - half indent
if (some condition) {
stmt;
} else {
stmt;
}
} // new line
}A follow-up patch can restore the indents without any functional changes.
Avoid output parameters; use return values instead. In/out parameters are tricky, but in some cases they are relatively standard, such as serialization/deserialization.
If a function accepts a lambda or an std::function, make it the last argument, so that it can be easily provided inline:
template <typename Func>
void function_accepting_a_lambda(int a, int b, Func func);
int f() {
return function_accepting_a_lambda(2, 3, [] (int x, int y) {
return x + y;
});
}If a function returns a complicated return type, put its return type on a separate line, otherwise it becomes hard to see where the return type ends and where the function name begins:
template <typename T1, T2>
template <typename T3, T4>
std::vector<typename a_struct<T1, T2>::some_nested_class<T3, T4>> // I'm the return type
a_struct<T1, T2>::a_function(T3 a, T4 b) { // And I'm the function name
// ...
}Whitespace around operators should match their precedence: high precedence = no spaces, low precedency = add spaces:
return *a + *b; // good
return * a+* b; // badif, while, return (and template) are not function calls, so they get a space after the keyword.
If a line becomes excessively long (>120 characters?), or is just complicated, break it into two or more lines. The second (and succeeding lines) are continuation lines, and have a double indent:
if ((some_condition && some_other_condition)
|| (more complicated stuff here...) // continuation line, double indent
|| (even more complicated stuff)) { // another continuation line
do_something(); // back to single indent
}Of course, long lines or complex conditions may indicate that refactoring is in order.
Generic lambdas ([] (auto param)) are discouraged where the type is known. Generic
lambdas reduce the compiler's and other tools' ability to reason about the code.
In case the actual type of param doesn't match the programmers expectations,
the compiler will only detect an error in the lambda body, or perhaps
even lower down the stack if more generic functions are called. In the case of an
IDE, most of its functionality is disabled in a generic lambda, since it can't
assume anything about that parameter.
Of course, when there is a need to support multiple types, genericity is the correct tool. Even then, type parameters should be constrained with concepts, in order to catch type mismatches early rather than deep in the instantiation chain.