Many file-related security vulnerabilities result from a program accessing an unintended file object. This often happens because file names are only loosely bound to underlying file objects. File names provide no information regarding the nature of the file object itself. Furthermore, the binding of a file name to a file object is reassumed every reevaluated each time the file name is used in an operation. This reevaluation can introduce a time-of-check, time-of-use (TOCTOU) race condition into an application. Objects of type java.io.File and of type java.nio.file.Path are bound to underlying file objects by the operating system only when the file is accessed.
The java.io.File constructors and the java.io.File methods renameTo() and delete() rely solely on file names for file identification. The same holds for the java.nio.file.Path.get() methods for creating Path objects and the move and delete methods of java.nio.file.Files. Use all of these methods with caution.
Fortunately, files can often be identified by other attributes in addition to the file name, for name—for example, by comparing file creation time or modification times. Information about a file that has been created and closed can be stored and then used to validate the identity of the file when it is reopened. Comparing multiple attributes of the file increases the likelihood that the reopened file is the same file that was previously operated onopened.
File identification is less of an issue if applications crucial for applications that maintain their files in secure directories where they can be accessed only by the owner of the file and (possibly) by a system administrator (see FIO00-J. Do not operate on files in shared directories).
Noncompliant Code Example
In this noncompliant code example, the file identified by the string filename is opened, processed, closed, and then reopened for reading:
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public void processFile(String filename){ // Identify a file by its path String filename = // Initialized Path file1 = Paths.get(filename); // Open the file for writing try (BufferedWriter bw = new BufferedWriter(new OutputStreamWriter(Files.newOutputStream(file1)))) { // Write to file... } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); } // Handle error } // Close the file /* * A race condition here allows for an attacker to switch * out the file for another */ // Reopen the file for reading Path file2 = Paths.get(filename); try try (BufferedReader br = new BufferedReader(new InputStreamReader(Files.newInputStream(file2)))) { String line; while ((line = br.readLine()) != null) { System.out.println(line); } } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); } // Handle error } } |
Because the binding between the file name and the underlying file object is reevaluated when the BufferedReader is created, this code cannot There is no guarantee that the file opened for reading is the same file that was previously opened for writing. An attacker can might have replace the original file (for example, with a symbolic link, for example) between the first call to close() and the subsequent creation of the BufferedReader.
Noncompliant Code Example (Files.isSameFile())
In this noncompliant code example, the programmer attempts to ensure that the file opened for reading is the same as the file previously opened for writing by calling the method Files.isSameFile():
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public void processFile(String filename){ // Identify a file by its path String filename = // Initialization Path file1 = Paths.get(filename); // Open the file for writing try(BufferedWriter bw = new BufferedWriter(new OutputStreamWriter(Files.newOutputStream(file1)))) { // Write to file } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); } // Handle error } // ... // Reopen the file for reading Path file2 = Paths.get(filename); if (!Files.isSameFile(file1, file2)) { System.out.println("File // File was tampered with"); , handle //error Handle error } try(BufferedReader br = new BufferedReader(new InputStreamReader(Files.newInputStream(file2)))) { String line; while ((line = br.readLine()) != null) { System.out.println(line); } } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); // Handle error } } |
Unfortunately, there is no the Java API lacks any guarantee that the method isSameFile() really actually checks that whether the files are the same file. The Java 7 API for isSameFile() [API 2011] says:
If both
Pathobjects are equal then this method returnstruewithout checking if the file exists.
That is, isSameFile() may simply check that the paths to the two files are the same . The possibility that and cannot detect if the file at that path has had been replaced by a different file between the two open operations is not excluded.
Compliant Solution (Multiple Attributes)
This compliant solution checks the creation and last-modified times of the files to ensure increase the likelihood that the file opened for reading is the same file that was written:
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public void processFile(String filename) throws IOException{ // Identify a file by its path String filename = // Initialized Path file1 = Paths.get(filename); BasicFileAttributes attr1 = Files.readAttributes(file1, BasicFileAttributes.class); FileTime creation1 = attr1.creationTime(); FileTime modified1 = attr1.lastModifiedTime(); // Open the file for writing try (BufferedWriter bw = new BufferedWriter(new OutputStreamWriter(Files.newOutputStream(file1)))) { // Write to file... } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); } // Handle error } // Reopen the file for reading Path file2 = Paths.get(filename); BasicFileAttributes attr2 = Files.readAttributes(file2, BasicFileAttributes.class); FileTime creation2 = attr2.creationTime(); FileTime modified2 = attr2.lastModifiedTime(); if ( (!creation1.equals(creation2)) || (!modified1.equals(modified2)) ) { System.out.println(" // File was tampered with"); , handle //error Handle error } try(BufferedReader br = new BufferedReader(new new InputStreamReader(Files.newInputStream(file2)))) { String line; while ((line = br.readLine()) != null) { System.out.println(line); } } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e);// Handle error } } |
Although this solution is reasonably secure, a determined attacker could create a symbolic link with the same creation and last-modified times as the original file. Also, a time-of-check, time-of-use ( TOCTOU ) race condition occurs between the time the file's attributes are first read and the time the file is first opened. Likewise, a second another TOCTOU condition occurs the second time the attributes are read and the file is reopened.
Compliant Solution (POSIX fileKey Attribute)
In environments that support the fileKey attribute, a more reliable approach is to check that the fileKey attributes of the two files are the same. The fileKey attribute is an object that "uniquely identifies the file" [API 2011], as shown in this compliant solution:
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public void processFile(String filename) throws IOException{ // Identify a file by its path String filename = // Initialized Path file1 = Paths.get(filename); BasicFileAttributes attr1 = Files.readAttributes(file1, BasicFileAttributes.class); Object key1 = attr1.fileKey(); // Open the file for writing try(BufferedWriter bw = new BufferedWriter(new OutputStreamWriter(Files.newOutputStream(file1)))) { // Write to file } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e); } // Handle error } // Reopen the file for reading Path file2 = Paths.get(filename); BasicFileAttributes attr2 = Files.readAttributes(file2, BasicFileAttributes.class); Object key2 = attr2.fileKey(); if ( !key1.equals(key2) ) { System.out.println("File tampered with"); // Handle File was tampered with, handle error } try(BufferedReader br = new BufferedReader(new InputStreamReader(Files.newInputStream(file2)))) { String line; while ((line = br.readLine()) != null) { System.out.println(line); } } catch (ExceptionIOException e) { System.out.println("Exception during file access" + e);// Handle error } } |
This approach will not work on all platforms. For example, on an Intel Core i5-2400 machine running Windows 7 Enterprise Edition, all fileKey attributes are null.
This solution is not perfectThe file key returned by the fileKey() method is guaranteed to be unique only if the file system and files remain static. A file system may reuse an identifier, for example, after a file is deleted. Like the previous compliant solution, it has there is a TOCTOU race window between the time the file's attributes are first read and the time the file is first opened. A second Another TOCTOU condition occurs the second time the attributes are read and the file is reopened.
Compliant Solution (RandomAccessFile)
A better approach is to avoid reopening a file. The following compliant solution demonstrates use of a RandomAccessFile, which can be opened for both reading and writing. Since Because the file is never closedonly closed automatically by the try-with-resources statement, no race condition is possiblecan occur.
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public void processFile(String filename) throws IOException{ // Identify a file by its path String filename = // Initialized try (RandomAccessFile file = new RandomAccessFile( filename, "rw");) { // Write to file... // Go back to beginning and read contents file.seek(0); try { string line; while (true(line=file.readLine()) != null { System.out.println(line); } } } |
Noncompliant Code Example (File Size)
This noncompliant code example tries to ensure that the file it opens contains exactly 1024 bytes:
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static long goodSize = 1024; public void doSomethingWithFile(String s = file.readUTF filename) { long size = new File( filename).length(); if (size != goodSize) { System.out.print(s)println("File has wrong size!"); return; } try (BufferedReader br = new BufferedReader(new InputStreamReader(new FileInputStream( filename)))) { // ... Work with file } catch (EOFExceptionIOException xe) { // Ignore, this breaks out of while loop } br.close(); |
Applicability
// Handle error
}
} |
This code is subject to a TOCTOU race condition between when the file size is checked and when the file is opened. If an attacker replaces a 1024-byte file with another file during this race window, he or she can cause this program to open any file, defeating the check.
Compliant Solution (File Size)
This compliant solution uses the FileChannel.size() method to obtain the file size. Because this method is applied to the FileInputStream only after the file has been opened, this solution eliminates the race window.
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static long goodSize = 1024;
public void doSomethingWithFile(String filename) {
try (FileInputStream in = new FileInputStream( filename);
BufferedReader br = new BufferedReader(
new InputStreamReader(in))) {
long size = in.getChannel().size();
if (size != goodSize) {
System.out.println("File has wrong size!");
return;
}
String line;
while ((line = br.readLine()) != null) {
System.out.println(line);
}
} catch (IOException e) {
// Handle error
}
} |
Applicability
Attackers frequently exploit file-related vulnerabilities to cause programs Many file-related vulnerabilities are exploited to cause a program to access an unintended file. Proper file identification is necessary to prevent exploitation.
Bibliography
[API 2011] | Class |
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