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Rizin tests

Rizin uses both regression and unit tests.

Directory Hierarchy

  • db/: The regressions tests sources
  • unit/: Unit tests (written in C, using minunit).
  • fuzz/: Fuzzing helper scripts
  • bins/: Sample binaries (fetched from the external repository)

Requirements

  • rizin installed and in $PATH (you can also use a rizin not in $PATH, but other files like calling convention files, format files, etc. must have been installed).
  • rz-test compiled and/or installed, which is done by default automatically when building Rizin.

Usage

Regression tests

To run regressions tests use rz-test from within the test directory. By default it will run all tests under the db subdirectory, however you can also specify which tests you want to run, by providing its name as argument to rz-test.

For example, to run only the asm tests for x86_64, you can do rz-test db/asm/x86_64. rz-test provides other interesting options that you can check out by doing rz-test -h.

An option that you may find interesting, in particular when doing changes that may affect the output of multiple tests, is the -i option, which enables interactive mode. When running tests in this mode, rz-test will warn you for each failed test and it will ask for your input on how to treat the issue. It can automatically fix the test so that it matches the new output (if that is the right behaviour!) or it can mark it as broken for you.

Unit tests

To run unit tests, just use ninja -C build test (or meson test -C build) from the top directory (replace build with the name of the directory you used to build Rizin). You can run one specific testcase category (e.g. the whole test_bin.c file) using meson test -C build bin. If you are using meson test, you should consider using the --print-errorlogs flag.

Failure Levels

A test can have one of the following results:

  • success: The test passed, and that was expected.
  • fixed: The test passed, but failure was expected.
  • broken: Failure was expected, and happened.
  • failed: The test failed unexpectedly. This is a regression.

Writing Assembly tests

Tests for the assembly and disassembly (in db/asm/*) have a different format: General format:

type "assembly" opcode [offset] [IL]

where type can be any of:

  • a meaning "assemble"
  • d meaning "disassemble"
  • B meaning "broken"
  • E stands for cfg.bigendian=true

offset

Some architectures are going to assemble an instruction differently depending on the offset it's written to. Optional.

Examples:

a "ret" c3
d "ret" c3
a "nop" 90 # Assembly is correct
dB "nopppp" 90 # Disassembly test is broken

IL

To also test lifting an instruction to RzIL, you can append the readable IL representation like so:

d "inc ptr" 3e 0 set(v:ptr, x:add(x:var(v:ptr), y:bitv(bits:0x0000000000000001, len:64)))

This means that rz-test will also perform the lifting from bytes to RzIL, run the validation pass on the result and compare it against the given string.

In this case, passing an offset is mandatory, otherwise the argument would be ambiguous.

General hints

You can merge lines:

adB "nop" 90

acts the same as

aB "nop" 90
dB "nop" 90

The filename is very important. It is used to tell rizin which architecture to use: arch[[_cpu]_bits].

Examples:

  • x86_32 means -a x86 -b 32
  • arm_v7_64 means -a arm -b 64

Writing JSON tests

The JSON tests db/json are executed on 3 standard files (1 ELF, 1 MachO, 1 PE). The tests need to be working on the 3 files to pass.

Commands tests

Example commands tests for the other db/ folders:

NAME=test_db
FILE=bins/elf/ls
CMDS=<<EOF
pd 4
EOF
EXPECT=<<EOF
        ;-- main:
        ;-- entry0:
        ;-- func.100001174:
        0x100001174      55             Push rbp
        0x100001175      4889e5         Mov  rbp, rsp
        0x100001178      4157           Push r15
EOF
RUN

It is also possible to match specific parts of the output in EXPECT and EXPECT_ERR using regex (with REGEXP_FILTER_OUT and REGEXP_FILTER_ERR respectively) in case some of the test's output is dynamic:

NAME=bp rebase
FILE=bins/elf/analysis/pie
ARGS=-d
CMDS=<<EOF
aa
db @ main
dbl~main
doc
dbl~main
EOF
REGEXP_FILTER_OUT=([a-zA-Z="]+\s+)
EXPECT=<<EOF
0x000005c5 0x000005c6 1    --x  sw    break enabled valid             main
0x000005c5 0x000005c6 1    --x  sw    break enabled valid             main
EOF
RUN

Without the regex that filtered out the non-deterministic file path and addresses, the expected output would have been the following:

0x566495c5 - 0x566495c6 1 --x sw break enabled valid cmd="" cond="" name="main" module="/home/user/rizin/test/bins/elf/analysis/pie"
0x000005c5 - 0x000005c6 1 --x sw break enabled valid cmd="" cond="" name="main" module="/home/user/rizin/test/bins/elf/analysis/pie"
  • NAME is the name of the test, it must be unique
  • FILE is the path of the file used for the test
  • ARGS (optional) are the command line argument passed to rizin (e.g -b 16)
  • CMDS are the commands to be executed by the test
  • EXPECT is the expected output of the test from stdout. If REGEXP_FILTER_OUT is used, EXPECT matches only the filtered output.
  • EXPECT_ERR (optional) is the expected output of the test from stderr. Can be specified in addition or instead of EXPECT
  • BROKEN (optional) is 1 if the tests is expected to be fail, 0 or unspecified otherwise
  • TIMEOUT (optional) is the number of seconds to wait before considering the test timeout
  • REGEXP_FILTER_OUT (optional) apply given regex on stdout before comparing the output to EXPECT (e.g. REGEXP_FILTER_OUT=([a-zA-Z]+)). This is similar to piping stdout to grep -E "<regex>" and then comparing the matched text with EXPECT.
  • REGEXP_FILTER_ERR (optional) apply given regex on stderr before comparing the ouput to EXPECT_ERR

You must end the test by adding RUN keyword

Advices

  • For portability reasons do not use shell pipes, use ~
  • dont use pd if not necessary, use pi
  • All tests use the UTC timezone for consistency.

Unit tests

Assembly, JSON and commands tests are useful to test the overall behaviour of Rizin, but to test new API or new code we suggest to write small unit tests.

The basic structure of a unit test is the following:

#include <rz_XXXXX.h>
#include "minunit.h" // Place at the bottom of includes.

static bool test_my_feature(void) {
	// code to test the behaviour
	mu_end;
}

static bool all_tests() {
	mu_run_test(test_my_feature);
	return tests_passed != tests_run;
}

mu_main (all_tests)

Minunit provides various functions to check the actual output of a function with the expected one. For example:

  • mu_assert_true(actual, message) checks that actual evaluates to true, otherwise it prints message on stderr.
  • mu_assert_false(actual, message) checks that actual evaluates to false, otherwise it prints message on stderr.
  • mu_assert_eq(actual, expected, message) checks that the integer (ut64 at most) actual is equal to the integer expected, otherwise it prints message on stderr.
  • mu_assert_ptreq(actual, expected, message) checks that the pointer actual is equal to expected.
  • mu_assert_null(actual, message)
  • mu_assert_streq(actual, expected, message)
  • mu_assert_memeq(actual, expected, len, message)
  • etc.

If you add a unit test file, be sure to also add it to unit/meson.build, so it is compiled when you compile Rizin.

License

The test files are licensed under GPL 3 (or later).