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Run juicer tests Coverage Status

Table of Contents

  1. Dependencies
  2. Building it
  3. What is it?
  4. GCC Compatibility
  5. Padding
  6. Environment Setup
  7. Testing
  8. DWARF Support
  9. Notes on Macros
  10. Extra Elf Features
  11. vxWorks Support
  12. Notes On Multiple DWARF Versions
  13. Bitfields
  14. Docker Dev Environments
  15. Union Support

Dependencies

  • libdwarf-dev
  • libelf-dev
  • libsqlite3-dev
  • C++14
  • Catch2
  • g++>=5.4.0
  • gcovr
  • libarchive-zip-perl (Needed for unit test verification of crc32)

Building it

  1. Clone the repo
git clone https://github.com/WindhoverLabs/juicer.git
cd juicer
  1. Update the git submodules:
git submodule update --init
  1. Right now the working branch is develop, so switch to it
git checkout develop
  1. Our build system has a few build recipes. If all you want is to get jucier up and running,
make

This will build the executable for you, which you'll find on build/juicer.

If you would like to run unit tests, you can do that too:

make run-tests

NOTE: Make sure you have all the dependencies mentioned above. If you are missing any of those dependencies, juicer will not build.

What is it?

juicer extracts structs, arrays, enumerations, macros and intrinsic types(support for everything else is planned for the future, but it is not a priority at the moment) from executable elf files and stores them in a SQLite database.

An Example

Imagine we wrote some elf_file.cpp that looks like this.

#include "stdint.h"

#define ARRAY_1D_SIZE 2

typedef struct
{
    int32_t width = 101;
    uint16_t stuff;
    uint16_t padding1;
    int32_t length;
    uint16_t more_stuff;
    uint16_t padding2;
    float       floating_stuff;
    float       matrix3D[ARRAY_1D_SIZE][4][4];
    float       matrix1D[ARRAY_1D_SIZE];
}Square;

Square sq = {};

juicer uses DWARF debug information to extract all the information. Because of this, you must pass the -g flag to gcc when compiling your source code:

g++ -std=c++14  elf_file.cpp -g -c -o elf_file

To include macros in the output, make sure to pass "-g3" when compiling:

g++ -std=c++14  elf_file.cpp -g -g3 -c -o elf_file

NOTE:Please beware that compiler switchess may have different names for different compilers. Here we use gcc as an example since it is a compiler that is accessible to most teams.

Assuming you've built juicer successfully, you can give this binary file to juicer:

./build/juicer --input path_to_file --mode SQLITE --output build/new_db.sqlite -v4

This tells juicer to squeeze and extract as much as possible out of the binary at path_to_file and write all of that data to the sqlite database at build/new_db.sqlite. v4 is for verbosity level 4, which is the highest level and will output every message from the log.

After juicer is done, you will find a database populated with data about our binary file at build/new_db.sqlite. The database should have the following schemas:

"*" = PRIMARY KEY
"+" = FOREIGN KEY

elfs

id* name md5 date little_endian short_description long_description
INTEGER TEXT INTEGER DATETIME BOOLEAN TEXT TEXT

enumerations

symbol* value* name short_description long_description
INTEGER INTEGER TEXT TEXT TEXT

fields

id* name symbol+ byte_offset type+ little_endian bit_size bit_offset
INTEGER TEXT INTEGER INTEGER INTEGER BOOLEAN INTEGER INTEGER

dimension_lists

id* field_id+ dim_order upper_bound
INTEGER INTEGER TEXT INTEGER

symbols

id* elf+ name byte_size artifact* target_symbol* encoding* short_description long_descriptions
INTEGER INTEGER TEXT INTEGER INTEGER INTEGER INTEGER TEXT TEXT

In our specific example, the symbols and fields tables are the ones we are interested in.

NOTE: Notice the bit_size and bit_offset columns in the fields table; these values are used for struct members that are bit-packed. When the fields are not bit-packed, bit_size and bit_offset are set to 0.

symbols

As you can see in the image above, our Square struct that we defined in our source file is in row 15!

You might ask where are its members...that's what the fields table is for.

symbols

As you can see we have a few fields that match our Square struct's id, which is 15. Those fields belong to our struct Square. Also note the type column; this tells us the particular type a field is.

What about our matrix arrays such as matrix3D and matrix1D? That's what the dimension_lists table is for.

symbols

Notice how the three records in dimension_lists have a field_id of 8. If we look at our fields table we notice that matrix3D has an id of 8 as well. The dimension_lists tells us that field with id 8 is 3 dimensional array; the first dimension has an upper bound of 1(inclusive; size 2); the second one(which has dim_order of 1) is 3; the third one has an upper bound of 3. These are the dimensions of matrix3D. This design is modeled after the DWARF4 and XTCE standards. Hopefully this schema is clear enough.

This is how juicer stores data in the database.

NOTE: Beware that it is absolutely fine to run juicer multiple times on different binary files but on the same database. In fact juicer has been designed with this mind so that users can run juicer multiple times against any code base, no matter how large in size.

GCC Compatibility

Sincejuicer is reading ELF files, the compiler one uses or the specific linux version can affect the behavior of the libelf libraries. Because of this we have tested juicer (and continuously test in CI)on the specified platforms in the table below.

Ubuntu Version GCC Version(s) DWARF Version
Ubuntu 18.04.1 LTS 7.5.0 4
Ubuntu 20.04.1 LTS 9.4.0 4
Ubuntu 22.04.5 LTS 11.4.0 5

Padding

Different compilers and sometimes programmers insert padding into C Structures. Padding in the database is captured by juicer as well. Padding fields will have a name in the "_spare[N]" fashion in the database. N is for distinguishing different fields. For exampe a struct that has three fields of padding will have _spare0, _spare1 and _spare2. Padding that is inserted at the end of the struct has a field with the name of _padding_end. Hopefully this naming scheme makes sense.

Padding Types

When juicer finds padding, a new type is created for the number of bytes of padding that are found. For instance, if there is 3 bytes of padding then a type _padding24 will be created. The 24 is the size of the padding in bits. Please note that if more padding is found elsewhere and the number of bytes is 3, then the _padding24 type will be used for that field to avoid over-populating the database with unnecessary data.

Environment Setup

Most of this project is written in C++14, with some parts in C because of libraries like sqlite3 and libdwarf.

  • Eclipse CDT 9.7.0.201903092251
  • C++14
  • Ubuntu 16.04.6 LTS

We currently use Eclipse to maintain this project and we are trying to not make that a painful dependency that developers have to deal with. This is why the Eclipse project is under juicer/juicer. We know it's not the best solution, but we'll try to make this a little more modular in the future to be usable in other IDEs and environments. For now, if you want to get started on Juicer, your best bet is using Eclipse. Hopefully we'll find a more modular non-Eclipse way of doing this.

Debugging in Eclipse

By default this version of Eclipse uses gdb 7.11.1, but this version does not have support for inspecting smart pointers. You need to setup lldb, llvm's debugger.

Setting up lldb on Eclipse

  1. sudo apt-get install lldb

  2. Now on Elcipse go to Help->Install New Software... and Install LLDB Debugger eclipse

  3. Then right-click on your project and go to Juicer->Debug As->Debug Configurations

  4. Click on the select other... option at the bottom of the window eclipse

  5. Set LLDB as your default debugger

eclipse

And you are all set!

Debugging libdwarf

Sometimes it is often useful to be able to step through code inside of libdwarf, which juicer heavily depends on. This can be done by installing libdwarf1-dbgsym with the following commands:

sudo apt install ubuntu-dbgsym-keyring
echo "deb http://ddebs.ubuntu.com $(lsb_release -cs) main restricted universe multiverse
deb http://ddebs.ubuntu.com $(lsb_release -cs)-updates main restricted universe multiverse
deb http://ddebs.ubuntu.com $(lsb_release -cs)-proposed main restricted universe multiverse" | \
sudo tee -a /etc/apt/sources.list.d/ddebs.list
sudo apt-get install libdwarf1-dbgsym

Testing

We currently use the Catch2 framework for our Unit testing. It is integrated into the repo as a submodule. You can find all of our testing under the Testing folder. Just like Juicer, it is an Eclipse project. So, if you already use Eclipse, then just import the project and you can test away!

Writing Unit Tests

Catch2 allows to easily write very readable tests that are very easy to maintain and write. Below is an example of this that tests the correctness of an ElfFile's name on Testing/TestElfFile.cpp:

#include "catch.hpp"
#include "ElfFile.h"

TEST_CASE("Test name correctness", "[ElfFile]")
{
    ElfFile elffy{};
    std::string elffyName{"elffy.o"};
    elffy.setName(elffyName);

    REQUIRE(elffy.getName() == elffyName);
}

This test called "Test name correctness" will construct a very simple ElfFile object and check that when we set a name with setName we get the same exact name back when we call getName. The REQUIRE macro is the actual assertion that verifies this. If the test fails(meaning the REQUIRE macro is false), then our test and any other tests that follow stop executing. Catch2 has more interesting features like CHECK and syntax like WHEN for behavior-driven development that you can read all about in the link above.

Note that we don't define a main function here so we define one very easily in Testing/main.cpp:

/*This tells Catch to provide a main() - only do this in one cpp file*/
#define CATCH_CONFIG_MAIN


/**This disables coloring output so that Eclipse CDT(Version: 9.7.0.201903092251)
 *will be able to render it. If you really like colored output, you'll have to use
 *something else other than Eclipse's console(such as GNOME shell) to run the tests
 *and comment out the CATCH_CONFIG_COLOUR_NONE macro.
 */
#define CATCH_CONFIG_COLOUR_NONE

#include "catch.hpp"

Yes, that's it! Catch2 will read the CATCH_CONFIG_MAIN and generate a main function for you. The CATCH_CONFIG_COLOUR_NONE is not necessary to run Catch2, but if you run into problems where the output will not render properly because it is colored(like in Eclipse), then you might find this macro useful.

Now all you have to do is build your project on Eclipse(or from the terminal) and then run all of your tests.

You can run your tests like this:

make run-tests

To run a specific test:

cd build
./juicer-ut "[ElfFile]"

Notice the tag "[ElfFile]" which was defined for the test case above.

Generating Coverage Report

make coverage

This will run all unit tests on juicer and generate a test coverage report for you. After make is done, the test coverage report can be found on build/coverage/index.html.

Dwarf Support

At the moment juicer follows the DWARF4 and DWARF5 specifications. If this changes, then this document will be updated accordingly.

As juicer evolves, dwarf support will grow and evolve as well. At the moment, we don't adhere to a particular DWARF version as we add support to the things that we need for our code base, which is airliner. In other words, we mostly support C code, or C++ code without any cutting edge/modern features. For example, modern features such as templates or namespaces are not supported. If juicer finds these things in your elf files, it will simply ignore them. To have a more concrete idea of what we do support in the DWARF, take a look at the table below which records all DWARF tags we support.

Dwarf Tags

Name Description
DW_TAG_base_type This is the tag that represents intrinsic types such as int and char.
DW_TAG_typedef This is the tag that represents anything that is typdef'd in code such as typedef struct{...} typedef int16 my_int. This is what the "target_symbol" column is for in the symbols table.
DW_TAG_structure_type This is the tag that represents structs such as struct Square{ int width; int length; };
DW_TAG_array_type This is the tag that represents statically allocated arrays such as int flat_array[] = {1,2,3,4,5,6};. Note that this does not include dynamic arrays such as those allocated by malloc or new calls.
DW_TAG_pointer_type This is the tag that represents pointers in code such as int* ptr = nullptr
DW_TAG_enumeration_type This is the tag that represents enumerations such as enum Color{RED,BLUE,YELLOW};
DW_TAG_const_type This is the tag that represents C/C++ const qualified type such as sizetype, which is used by containers(like std::vector) in the STL C++ library.
DW_MACRO_define This tag represents define macros such as "#define CFE_MISSION_ES_PERF_MAX_IDS 128"
DW_AT_decl_file This tag represents the file where a certain symbol is declared. Very useful for traceability of source code.
DW_AT_encoding The encoding of base type. For example; "unsigned int" will have encoding "DW_ATE_unsigned". This is what the "encodings" table is for in the SQLITE db.
DW_TAG_union_type The tag used for unions. For example; union Object { int32_t id; int32_t bit_field : 10; uint8_t data[4];};.

For more details on the DWARF debugging format, go on here.

void*

DWARF version 4 and 5 has this to say about void pointers:

The interpretation of this debugging information entry is intentionally left flexible to allow it to be interpreted appropriately in different languages. For example, in C and C++ the language implementation can provide an unspecified type entry with the name “void” which can be referenced by the type attribute of pointer types and typedef declarations for 'void' (see Sections 0 and 5.3, respectively) -- Section 5.2 of DWARF4

juicer behaves accordingly. If a pointer does not have a type(meaning it does not have a DW_AT_type attribute), then it is assumed that the pointer in question is of the void* type.

Notes On #define Macros

During testing we found that some pattern causes the macro being defined to "disappear" from the DWARF section:

When this happens, it is most likely a case of the macro being on a seperate group number inside of the DWARF.

To ensure juicer queries all macros, users can pass the "group number" via the "-g" flag.

For example the command:

./juicer -g 5 --input elf_file --mode SQLITE --output build/new_db.sqlite -v4

tells juicer to get macros from group "5". The default is group "0", which is enough for most cases.

This seems to happen on unlinked compiled ELF files that have the following define pattern where there is an #include between #define(s):

#define MAC1 2
#define MAC2 3
#include "macro_test.h"
#define MAC3 4

This is rare(especially unlinked files), but it does happen. In any case "-g" flag can be used to query macros (or any other DWARF data) from as many groups(starting at 0) as the the ELF file has.

For more details on this issue and other macro issues:#35

Extra ELF Features

jucier's main focus is to extract DWARF, however, it can extract ELF sections too. To extract elf sections pass the extras "-x" flag:

./juicer -x --input elf_file --mode SQLITE --output build/new_db.sqlite -v4

This can be useful for extracting data from object files such as static variables that are assigned at build time and whose contents are stored in the elf symbols table. For an example of this see the "query_symbols.py" script under this repo.

To learn more about the different ELF sections and how they're structured, there is a copy of the ELF standard under the docs directory on the repo.

VxWorks Support

At the moment vxWorks support is a work in progress. Support is currently not tested, so at the moment it is on its own [branch] (https://github.com/WindhoverLabs/juicer/tree/vxWorks).

Print Backtrace even after a segfault

catchsegv ./juicer-ut "[main_test#3]"
addr2line -e ./juicer-ut 0x19646c

Notes On Multiple DWARF Versions

  • At the time of writing, juicer has been tested on DWARF4 and DWARF5.
  • Do not use DWARF experimental support from your compiler. Use the default DWARF version, whether that is 5 or 4. When using a DWARF version that still is experimental for your compiler, it is not guaranteed juicer will parse the binary correctly.

Bitfields

For a bit-packed struct

struct S
{
    uint8_t before;
    int     j : 5;
    int     k : 6;
    int     m : 5;
    uint8_t p;
    int     n : 8;
    uint8_t after;
};

The fields table looks like this:

bit_packed_fields

Notice for the bitpacked fields(j,k,m,n) the bit_offset and bit_size columns are nonzero.

Docker Dev Environment

It is often useful to use a virtualized environment for development. There are several recipes on this repo that make this easier. For example make docker-ubuntu22-build-dev will start a dev environment inside of Docker with Ubuntu22. The repo is mounted as a volume under "/home/docker/juicer" so developers can make their changes on the host and build inside the container.

Union Support

Given the following union:

union Object
{
    int32_t id;
    int32_t bit_field : 10;
    uint8_t data[4];
};

The union is represented as such in the SQLITE db:

union_symbol

union_fields

Notice that the byte_offset is NULL for the fields that belong to the union. This is how consumers (such as auto-yamcs) can make a distinction between unions and structs.

Documentation updated on September 19, 2024