]>
code.octet-stream.net Git - hashgood/blob - src/main.rs
2c7e1899dbbf4fab3f72f60ba79570bd86fc6c6d
2 use std
::path
::PathBuf
;
4 use structopt
::StructOpt
;
6 /// Calculate digests for given input data
9 /// Display output nicely in the terminal
12 /// Collect candidate hashes based on options and match them against a calculated hash
16 #[structopt(name = "hashgood")]
18 /// Read the hash from the clipboard
19 #[cfg(feature = "paste")]
20 #[structopt(short = "p", long = "paste")]
23 /// Disable ANSI colours in output
24 #[structopt(short = "C", long = "no-colour")]
27 /// A file containing the hash to verify. It can either be a raw hash or a SHASUMS-style listing. Use `-` for standard input.
28 #[structopt(short = "c", long = "check", parse(from_os_str))]
29 hash_file
: Option
<PathBuf
>,
31 /// The file to be verified or `-` for standard input
32 #[structopt(name = "input", parse(from_os_str))]
35 /// A hash to verify, supplied directly on the command line
36 #[structopt(name = "hash")]
41 fn get_paste(&self) -> bool
{
42 #[cfg(feature = "paste")]
46 #[cfg(not(feature = "paste"))]
53 /// Types of supported digest algorithm
54 #[derive(Debug, PartialEq, Copy, Clone)]
62 /// Assume a hash type from the binary length. Fortunately the typical 3 algorithms we care about are different lengths.
63 pub fn from_len(len
: usize) -> Result
<Algorithm
, String
> {
65 16 => Ok(Algorithm
::Md5
),
66 20 => Ok(Algorithm
::Sha1
),
67 32 => Ok(Algorithm
::Sha256
),
68 _
=> Err(format
!("Unrecognised hash length: {} bytes", len
)),
73 /// The method by which one or more hashes were supplied to verify the calculated digest
74 #[derive(Debug, PartialEq)]
75 pub enum VerificationSource
{
82 /// A complete standalone hash result
90 pub fn new(alg
: Algorithm
, bytes
: Vec
<u8>, path
: &PathBuf
) -> Self {
91 // Taking the filename component should always work?
92 // If not, just fall back to the full path
93 let filename
= match path
.file
_name
() {
94 Some(filename
) => filename
.to_string_lossy(),
95 None
=> path
.to_string_lossy(),
100 filename
: filename
.to_string(),
105 /// A possible hash to match against. The algorithm is assumed.
106 #[derive(Debug, PartialEq)]
107 pub struct CandidateHash
{
109 filename
: Option
<String
>,
112 /// A list of candidate hashes that our input could potentially match. At this point it is
113 /// assumed that we will be verifying a digest of a particular, single algorithm.
114 #[derive(Debug, PartialEq)]
115 pub struct CandidateHashes
{
117 hashes
: Vec
<CandidateHash
>,
118 source
: VerificationSource
,
121 /// Summary of an atetmpt to match the calculated digest against candidates
122 pub enum MatchLevel
{
128 /// The severity of any informational messages to be printed before the final result
129 pub enum MessageLevel
{
135 /// Overall details of an attempt to match the calculated digest against candidates
136 pub struct Verification
<'a
> {
137 match_level
: MatchLevel
,
138 comparison_hash
: Option
<&'a CandidateHash
>,
139 messages
: Vec
<(MessageLevel
, String
)>,
142 /// Entry point - run the program and handle errors ourselves cleanly.
144 /// At the moment there aren't really any errors that can be handled by the application. Therefore
145 /// stringly-typed errors are used and they are all captured here, where the problem is printed
146 /// and the application terminates with a non-zero return code.
148 hashgood().unwrap
_or
_else
(|e
| {
149 eprintln
!("Error: {}", e
);
154 /// Main application logic
155 fn hashgood() -> Result
<(), Box
<dyn Error
>> {
156 let opt
= get_verified_options()?
;
157 let candidates
= verify
::get_candidate_hashes(&opt
)?
;
158 let input
= calculate
::get_input_reader(&opt
.inp
ut
)?
;
159 if let Some(c
) = candidates
{
160 // If we have a candidate hash of a particular type, use that specific algorithm
161 let hashes
= calculate
::create_digests(&[c
.alg
], input
)?
;
162 for (alg
, bytes
) in hashes
{
163 // Should always be true
165 let hash
= Hash
::new(alg
, bytes
, &opt
.inp
ut
);
166 let verification
= verify
::verify_hash(&hash
, &c
);
169 verification
.comparison_hash
,
173 display
::print_messages(verification
.messages
, opt
.no_colour
)?
;
174 display
::print_match_level(verification
.match_level
, opt
.no_colour
)?
;
178 // If no candidate, calculate all three common digest types for output
179 let hashes
= calculate
::create_digests(
180 &[Algorithm
::Md5
, Algorithm
::Sha1
, Algorithm
::Sha256
],
183 for (alg
, bytes
) in hashes
{
187 filename
: opt
.inp
ut
.file
_name
().unwrap
().to_string_lossy().to_string(),
189 display
::print_hash(&hash
, None
, None
, opt
.no_colour
)?
;
195 /// Parse the command line options and check for ambiguous or inconsistent settings
196 fn get_verified_options() -> Result
<Opt
, String
> {
197 let opt
= Opt
::from_args();
199 opt
.hash
.is
_some
() as i32 + opt
.get_paste() as i32 + opt
.hash_file
.is
_some
() as i32;
200 if hash_methods
> 1 {
201 if opt
.hash
.is
_some
() {
202 eprintln
!("* specified as command line argument");
205 eprintln
!("* paste from clipboard (-p)")
207 if opt
.hash_file
.is
_some
() {
208 eprintln
!("* check hash from file (-c)")
210 return Err("Error: Hashes were provided by multiple methods. Use only one.".to_owned());
212 if opt
.inp
ut
.to_str() == Some("-")
213 && opt
.hash_file
.as_ref().and_then(|h
| h
.to_str()) == Some("-")
215 return Err("Error: Cannot use use stdin for both hash file and input data".to_owned());