Refactoring to Improve Modularity and Error Handling
To improve our program, we’ll fix four problems that have to do with the program’s structure and how it’s handling potential errors.
First, our main
function now performs two tasks: it parses arguments and
opens files. For such a small function, this isn’t a major problem. However, if
we continue to grow our program inside main
, the number of separate tasks the
main
function handles will increase. As a function gains responsibilities, it
becomes more difficult to reason about, harder to test, and harder to change
without breaking one of its parts. It’s best to separate functionality so each
function is responsible for one task.
This issue also ties into the second problem: although query
and filename
are configuration variables to our program, variables like f
and contents
are used to perform the program’s logic. The longer main
becomes, the more
variables we’ll need to bring into scope; the more variables we have in scope,
the harder it will be to keep track of the purpose of each. It’s best to group
the configuration variables into one structure to make their purpose clear.
The third problem is that we’ve used expect
to print an error message when
opening the file fails, but the error message just prints file not found
.
Opening a file can fail in a number of ways besides the file being missing: for
example, the file might exist, but we might not have permission to open it.
Right now, if we’re in that situation, we’d print the file not found
error
message, which would give the user the wrong information!
Fourth, we use expect
repeatedly to handle different errors, and if the user
runs our program without specifying enough arguments, they’ll get an index out of bounds
error from Rust that doesn’t clearly explain the problem. It would
be best if all the error-handling code were in one place so future maintainers
had only one place to consult in the code if the error-handling logic needed to
change. Having all the error-handling code in one place will also ensure that
we’re printing messages that will be meaningful to our end users.
Let’s address these four problems by refactoring our project.
Separation of Concerns for Binary Projects
The organizational problem of allocating responsibility for multiple tasks to
the main
function is common to many binary projects. As a result, the Rust
community has developed a process to use as a guideline for splitting the
separate concerns of a binary program when main
starts getting large. The
process has the following steps:
- Split your program into a main.rs and a lib.rs and move your program’s logic to lib.rs.
- As long as your command line parsing logic is small, it can remain in main.rs.
- When the command line parsing logic starts getting complicated, extract it from main.rs and move it to lib.rs.
The responsibilities that remain in the main
function after this process
should be limited to the following:
- Calling the command line parsing logic with the argument values
- Setting up any other configuration
- Calling a
run
function in lib.rs - Handling the error if
run
returns an error
This pattern is about separating concerns: main.rs handles running the
program, and lib.rs handles all the logic of the task at hand. Because you
can’t test the main
function directly, this structure lets you test all of
your program’s logic by moving it into functions in lib.rs. The only code
that remains in main.rs will be small enough to verify its correctness by
reading it. Let’s rework our program by following this process.
Extracting the Argument Parser
We’ll extract the functionality for parsing arguments into a function that
main
will call to prepare for moving the command line parsing logic to
src/lib.rs. Listing 12-5 shows the new start of main
that calls a new
function parse_config
, which we’ll define in src/main.rs for the moment.
Filename: src/main.rs
fn main() {
let args: Vec<String> = env::args().collect();
let (query, filename) = parse_config(&args);
// --snip--
}
fn parse_config(args: &[String]) -> (&str, &str) {
let query = &args[1];
let filename = &args[2];
(query, filename)
}
We’re still collecting the command line arguments into a vector, but instead of
assigning the argument value at index 1 to the variable query
and the
argument value at index 2 to the variable filename
within the main
function, we pass the whole vector to the parse_config
function. The
parse_config
function then holds the logic that determines which argument
goes in which variable and passes the values back to main
. We still create
the query
and filename
variables in main
, but main
no longer has the
responsibility of determining how the command line arguments and variables
correspond.
This rework may seem like overkill for our small program, but we’re refactoring in small, incremental steps. After making this change, run the program again to verify that the argument parsing still works. It’s good to check your progress often, to help identify the cause of problems when they occur.
Grouping Configuration Values
We can take another small step to improve the parse_config
function further.
At the moment, we’re returning a tuple, but then we immediately break that
tuple into individual parts again. This is a sign that perhaps we don’t have
the right abstraction yet.
Another indicator that shows there’s room for improvement is the config
part
of parse_config
, which implies that the two values we return are related and
are both part of one configuration value. We’re not currently conveying this
meaning in the structure of the data other than by grouping the two values into
a tuple; we could put the two values into one struct and give each of the
struct fields a meaningful name. Doing so will make it easier for future
maintainers of this code to understand how the different values relate to each
other and what their purpose is.
Note: Some people call this anti-pattern of using primitive values when a complex type would be more appropriate primitive obsession.
Listing 12-6 shows the improvements to the parse_config
function.
Filename: src/main.rs
# use std::env; # use std::fs::File; # fn main() { let args: Vec<String> = env::args().collect(); let config = parse_config(&args); println!("Searching for {}", config.query); println!("In file {}", config.filename); let mut f = File::open(config.filename).expect("file not found"); // --snip-- } struct Config { query: String, filename: String, } fn parse_config(args: &[String]) -> Config { let query = args[1].clone(); let filename = args[2].clone(); Config { query, filename } }
We’ve added a struct named Config
defined to have fields named query
and
filename
. The signature of parse_config
now indicates that it returns a
Config
value. In the body of parse_config
, where we used to return string
slices that reference String
values in args
, we now define Config
to
contain owned String
values. The args
variable in main
is the owner of
the argument values and is only letting the parse_config
function borrow
them, which means we’d violate Rust’s borrowing rules if Config
tried to take
ownership of the values in args
.
We could manage the String
data in a number of different ways, but the
easiest, though somewhat inefficient, route is to call the clone
method on
the values. This will make a full copy of the data for the Config
instance to
own, which takes more time and memory than storing a reference to the string
data. However, cloning the data also makes our code very straightforward
because we don’t have to manage the lifetimes of the references; in this
circumstance, giving up a little performance to gain simplicity is a worthwhile
trade-off.
The Trade-Offs of Using
clone
There’s a tendency among many Rustaceans to avoid using
clone
to fix ownership problems because of its runtime cost. In Chapter 13, you’ll learn how to use more efficient methods in this type of situation. But for now, it’s okay to copy a few strings to continue making progress because you’ll make these copies only once and your filename and query string are very small. It’s better to have a working program that’s a bit inefficient than to try to hyperoptimize code on your first pass. As you become more experienced with Rust, it’ll be easier to start with the most efficient solution, but for now, it’s perfectly acceptable to callclone
.
We’ve updated main
so it places the instance of Config
returned by
parse_config
into a variable named config
, and we updated the code that
previously used the separate query
and filename
variables so it now uses
the fields on the Config
struct instead.
Now our code more clearly conveys that query
and filename
are related and
that their purpose is to configure how the program will work. Any code that
uses these values knows to find them in the config
instance in the fields
named for their purpose.
Creating a Constructor for Config
So far, we’ve extracted the logic responsible for parsing the command line
arguments from main
and placed it in the parse_config
function. Doing so
helped us to see that the query
and filename
values were related and that
relationship should be conveyed in our code. We then added a Config
struct to
name the related purpose of query
and filename
and to be able to return the
values’ names as struct field names from the parse_config
function.
So now that the purpose of the parse_config
function is to create a Config
instance, we can change parse_config
from a plain function to a function
named new
that is associated with the Config
struct. Making this change
will make the code more idiomatic. We can create instances of types in the
standard library, such as String
, by calling String::new
. Similarly, by
changing parse_config
into a new
function associated with Config
, we’ll
be able to create instances of Config
by calling Config::new
. Listing 12-7
shows the changes we need to make.
Filename: src/main.rs
# use std::env; # fn main() { let args: Vec<String> = env::args().collect(); let config = Config::new(&args); // --snip-- } # struct Config { # query: String, # filename: String, # } # // --snip-- impl Config { fn new(args: &[String]) -> Config { let query = args[1].clone(); let filename = args[2].clone(); Config { query, filename } } }
We’ve updated main
where we were calling parse_config
to instead call
Config::new
. We’ve changed the name of parse_config
to new
and moved it
within an impl
block, which associates the new
function with Config
. Try
compiling this code again to make sure it works.
Fixing the Error Handling
Now we’ll work on fixing our error handling. Recall that attempting to access
the values in the args
vector at index 1 or index 2 will cause the program to
panic if the vector contains fewer than three items. Try running the program
without any arguments; it will look like this:
$ cargo run
Compiling minigrep v0.1.0 (file:///projects/minigrep)
Finished dev [unoptimized + debuginfo] target(s) in 0.0 secs
Running `target/debug/minigrep`
thread 'main' panicked at 'index out of bounds: the len is 1
but the index is 1', src/main.rs:29:21
note: Run with `RUST_BACKTRACE=1` for a backtrace.
The line index out of bounds: the len is 1 but the index is 1
is an error
message intended for programmers. It won’t help our end users understand what
happened and what they should do instead. Let’s fix that now.
Improving the Error Message
In Listing 12-8, we add a check in the new
function that will verify that the
slice is long enough before accessing index 1 and 2. If the slice isn’t long
enough, the program panics and displays a better error message than the index out of bounds
message.
Filename: src/main.rs
// --snip--
fn new(args: &[String]) -> Config {
if args.len() < 3 {
panic!("not enough arguments");
}
// --snip--
This code is similar to the Guess::new
function we wrote in Listing 9-9,
where we called panic!
when the value
argument was out of the range of
valid values. Instead of checking for a range of values here, we’re checking
that the length of args
is at least 3 and the rest of the function can
operate under the assumption that this condition has been met. If args
has
fewer than three items, this condition will be true, and we call the panic!
macro to end the program immediately.
With these extra few lines of code in new
, let’s run the program without any
arguments again to see what the error looks like now:
$ cargo run
Compiling minigrep v0.1.0 (file:///projects/minigrep)
Finished dev [unoptimized + debuginfo] target(s) in 0.0 secs
Running `target/debug/minigrep`
thread 'main' panicked at 'not enough arguments', src/main.rs:30:12
note: Run with `RUST_BACKTRACE=1` for a backtrace.
This output is better: we now have a reasonable error message. However, we also
have extraneous information we don’t want to give to our users. Perhaps using
the technique we used in Listing 9-9 isn’t the best to use here: a call to
panic!
is more appropriate for a programming problem than a usage problem, as
discussed in Chapter 9. Instead, we can use the other technique you learned
about in Chapter 9—returning a Result
that indicates either success or an
error.
Returning a Result
from new
Instead of Calling panic!
We can instead return a Result
value that will contain a Config
instance in
the successful case and will describe the problem in the error case. When
Config::new
is communicating to main
, we can use the Result
type to
signal there was a problem. Then we can change main
to convert an Err
variant into a more practical error for our users without the surrounding text
about thread 'main'
and RUST_BACKTRACE
that a call to panic!
causes.
Listing 12-9 shows the changes we need to make to the return value of
Config::new
and the body of the function needed to return a Result
. Note
that this won’t compile until we update main
as well, which we’ll do in the
next listing.
Filename: src/main.rs
impl Config {
fn new(args: &[String]) -> Result<Config, &'static str> {
if args.len() < 3 {
return Err("not enough arguments");
}
let query = args[1].clone();
let filename = args[2].clone();
Ok(Config { query, filename })
}
}
Our new
function now returns a Result
with a Config
instance in the
success case and a &'static str
in the error case. Recall from “The Static
Lifetime” section in Chapter 10 that &'static str
is the type of string
literals, which is our error message type for now.
We’ve made two changes in the body of the new
function: instead of calling
panic!
when the user doesn’t pass enough arguments, we now return an Err
value, and we’ve wrapped the Config
return value in an Ok
. These changes
make the function conform to its new type signature.
Returning an Err
value from Config::new
allows the main
function to
handle the Result
value returned from the new
function and exit the process
more cleanly in the error case.
Calling Config::new
and Handling Errors
To handle the error case and print a user-friendly message, we need to update
main
to handle the Result
being returned by Config::new
, as shown in
Listing 12-10. We’ll also take the responsibility of exiting the command line
tool with a nonzero error code from panic!
and implement it by hand. A
nonzero exit status is a convention to signal to the process that called our
program that the program exited with an error state.
Filename: src/main.rs
use std::process;
fn main() {
let args: Vec<String> = env::args().collect();
let config = Config::new(&args).unwrap_or_else(|err| {
println!("Problem parsing arguments: {}", err);
process::exit(1);
});
// --snip--
In this listing, we’ve used a method we haven’t covered before:
unwrap_or_else
, which is defined on Result<T, E>
by the standard library.
Using unwrap_or_else
allows us to define some custom, non-panic!
error
handling. If the Result
is an Ok
value, this method’s behavior is similar
to unwrap
: it returns the inner value Ok
is wrapping. However, if the value
is an Err
value, this method calls the code in the closure, which is an
anonymous function we define and pass as an argument to unwrap_or_else
. We’ll
cover closures in more detail in Chapter 13. For now, you just need to know
that unwrap_or_else
will pass the inner value of the Err
, which in this
case is the static string not enough arguments
that we added in Listing 12-9,
to our closure in the argument err
that appears between the vertical pipes.
The code in the closure can then use the err
value when it runs.
We’ve added a new use
line to import process
from the standard library. The
code in the closure that will be run in the error case is only two lines: we
print the err
value and then call process::exit
. The process::exit
function will stop the program immediately and return the number that was
passed as the exit status code. This is similar to the panic!
-based handling
we used in Listing 12-8, but we no longer get all the extra output. Let’s try
it:
$ cargo run
Compiling minigrep v0.1.0 (file:///projects/minigrep)
Finished dev [unoptimized + debuginfo] target(s) in 0.48 secs
Running `target/debug/minigrep`
Problem parsing arguments: not enough arguments
Great! This output is much friendlier for our users.
Extracting Logic from main
Now that we’ve finished refactoring the configuration parsing, let’s turn to
the program’s logic. As we stated in “Separation of Concerns for Binary
Projects”, we’ll extract a function named run
that will hold all the logic
currently in the main
function that isn’t involved with setting up
configuration or handling errors. When we’re done, main
will be concise and
easy to verify by inspection, and we’ll be able to write tests for all the
other logic.
Listing 12-11 shows the extracted run
function. For now, we’re just making
the small, incremental improvement of extracting the function. We’re still
defining the function in src/main.rs.
Filename: src/main.rs
fn main() {
// --snip--
println!("Searching for {}", config.query);
println!("In file {}", config.filename);
run(config);
}
fn run(config: Config) {
let mut f = File::open(config.filename).expect("file not found");
let mut contents = String::new();
f.read_to_string(&mut contents)
.expect("something went wrong reading the file");
println!("With text:\n{}", contents);
}
// --snip--
The run
function now contains all the remaining logic from main
, starting
from reading the file. The run
function takes the Config
instance as an
argument.
Returning Errors from the run
Function
With the remaining program logic separated into the run
function, we can
improve the error handling, as we did with Config::new
in Listing 12-9.
Instead of allowing the program to panic by calling expect
, the run
function will return a Result<T, E>
when something goes wrong. This will let
us further consolidate into main
the logic around handling errors in a
user-friendly way. Listing 12-12 shows the changes we need to make to the
signature and body of run
.
Filename: src/main.rs
use std::error::Error;
// --snip--
fn run(config: Config) -> Result<(), Box<Error>> {
let mut f = File::open(config.filename)?;
let mut contents = String::new();
f.read_to_string(&mut contents)?;
println!("With text:\n{}", contents);
Ok(())
}
We’ve made three significant changes here. First, we changed the return type of
the run
function to Result<(), Box<Error>>
. This function previously
returned the unit type, ()
, and we keep that as the value returned in the
Ok
case.
For the error type, we used the trait object Box<Error>
(and we’ve brought
std::error::Error
into scope with a use
statement at the top). We’ll cover
trait objects in Chapter 17. For now, just know that Box<Error>
means the
function will return a type that implements the Error
trait, but we don’t
have to specify what particular type the return value will be. This gives us
flexibility to return error values that may be of different types in different
error cases.
Second, we’ve removed the calls to expect
in favor of the ?
operator, as we
talked about in Chapter 9. Rather than panic!
on an error, the ?
operator
will return the error value from the current function for the caller to handle.
Third, the run
function now returns an Ok
value in the success case. We’ve
declared the run
function’s success type as ()
in the signature, which
means we need to wrap the unit type value in the Ok
value. This Ok(())
syntax might look a bit strange at first, but using ()
like this is the
idiomatic way to indicate that we’re calling run
for its side effects only;
it doesn’t return a value we need.
When you run this code, it will compile but will display a warning:
warning: unused `std::result::Result` which must be used
--> src/main.rs:18:5
|
18 | run(config);
| ^^^^^^^^^^^^
= note: #[warn(unused_must_use)] on by default
Rust tells us that our code ignored the Result
value and the Result
value
might indicate that an error occurred. But we’re not checking to see whether or
not there was an error, and the compiler reminds us that we probably meant to
have some error-handling code here! Let’s rectify that problem now.
Handling Errors Returned from run
in main
We’ll check for errors and handle them using a technique similar to one we used
with Config::new
in Listing 12-10, but with a slight difference:
Filename: src/main.rs
fn main() {
// --snip--
println!("Searching for {}", config.query);
println!("In file {}", config.filename);
if let Err(e) = run(config) {
println!("Application error: {}", e);
process::exit(1);
}
}
We use if let
rather than unwrap_or_else
to check whether run
returns an
Err
value and call process::exit(1)
if it does. The run
function doesn’t
return a value that we want to unwrap
in the same way that Config::new
returns the Config
instance. Because run
returns ()
in the success case,
we only care about detecting an error, so we don’t need unwrap_or_else
to
return the unwrapped value because it would only be ()
.
The bodies of the if let
and the unwrap_or_else
functions are the same in
both cases: we print the error and exit.
Splitting Code into a Library Crate
Our minigrep
project is looking good so far! Now we’ll split the
src/main.rs file and put some code into the src/lib.rs file so we can test
it and have a src/main.rs file with fewer responsibilities.
Let’s move all the code that isn’t the main
function from src/main.rs to
src/lib.rs:
- The
run
function definition - The relevant
use
statements - The definition of
Config
- The
Config::new
function definition
The contents of src/lib.rs should have the signatures shown in Listing 12-13 (we’ve omitted the bodies of the functions for brevity). Note that this won’t compile until we modify src/main.rs in Listing 12-14.
Filename: src/lib.rs
use std::error::Error;
use std::fs::File;
use std::io::prelude::*;
pub struct Config {
pub query: String,
pub filename: String,
}
impl Config {
pub fn new(args: &[String]) -> Result<Config, &'static str> {
// --snip--
}
}
pub fn run(config: Config) -> Result<(), Box<Error>> {
// --snip--
}
We’ve made liberal use of the pub
keyword: on Config
, on its fields and its
new
method, and on the run
function. We now have a library crate that has a
public API that we can test!
Now we need to bring the code we moved to src/lib.rs into the scope of the binary crate in src/main.rs, as shown in Listing 12-14.
Filename: src/main.rs
extern crate minigrep;
use std::env;
use std::process;
use minigrep::Config;
fn main() {
// --snip--
if let Err(e) = minigrep::run(config) {
// --snip--
}
}
To bring the library crate into the binary crate, we use extern crate minigrep
. Then we add a use minigrep::Config
line to bring the Config
type
into scope, and we prefix the run
function with our crate name. Now all the
functionality should be connected and should work. Run the program with cargo run
and make sure everything works correctly.
Whew! That was a lot of work, but we’ve set ourselves up for success in the future. Now it’s much easier to handle errors, and we’ve made the code more modular. Almost all of our work will be done in src/lib.rs from here on out.
Let’s take advantage of this newfound modularity by doing something that would have been difficult with the old code but is easy with the new code: we’ll write some tests!