| Partitions |
| ========== |
| |
| .. warning:: |
| |
| This feature is currently experimental, and its interface is subject |
| to change. |
| |
| LLD's partitioning feature allows a program (which may be an executable |
| or a shared library) to be split into multiple pieces, or partitions. A |
| partitioned program consists of a main partition together with a number of |
| loadable partitions. The loadable partitions depend on the main partition |
| in a similar way to a regular ELF shared object dependency, but unlike a |
| shared object, the main partition and the loadable partitions share a virtual |
| address space at link time, and each loadable partition is assigned a fixed |
| offset from the main partition. This allows the loadable partitions to refer |
| to code and data in the main partition directly without the binary size and |
| performance overhead of PLTs, GOTs or symbol table entries. |
| |
| Usage |
| ----- |
| |
| A program that uses the partitioning feature must decide which symbols are |
| going to be used as the "entry points" for each partition. An entry point |
| could, for example, be the equivalent of the partition's ``main`` function, or |
| there could be a group of functions that expose the functionality implemented |
| by the partition. The intent is that in order to use a loadable partition, |
| the program will use ``dlopen``/``dlsym`` or similar functions to dynamically |
| load the partition at its assigned address, look up an entry point by name |
| and call it. Note, however, that the standard ``dlopen`` function does not |
| allow specifying a load address. On Android, the ``android_dlopen_ext`` |
| function may be used together with the ``ANDROID_DLEXT_RESERVED_ADDRESS`` |
| flag to load a shared object at a specific address. |
| |
| Once the entry points have been decided, the translation unit(s) |
| containing the entry points should be compiled using the Clang compiler flag |
| ``-fsymbol-partition=<soname>``, where ``<soname>`` is the intended soname |
| of the partition. The resulting object files are passed to the linker in |
| the usual way. |
| |
| The linker will then use these entry points to automatically split the program |
| into partitions according to which sections of the program are reachable from |
| which entry points, similarly to how ``--gc-sections`` removes unused parts of |
| a program. Any sections that are only reachable from a loadable partition's |
| entry point are assigned to that partition, while all other sections are |
| assigned to the main partition, including sections only reachable from |
| loadable partitions. |
| |
| The following diagram illustrates how sections are assigned to partitions. Each |
| section is colored according to its assigned partition. |
| |
| .. image:: partitions.svg |
| |
| The result of linking a program that uses partitions is essentially an |
| ELF file with all of the partitions concatenated together. This file is |
| referred to as a combined output file. To extract a partition from the |
| combined output file, the ``llvm-objcopy`` tool should be used together |
| with the flag ``--extract-main-partition`` to extract the main partition, or |
| ``-extract-partition=<soname>`` to extract one of the loadable partitions. |
| An example command sequence is shown below: |
| |
| .. code-block:: shell |
| |
| # Compile the main program. |
| clang -ffunction-sections -fdata-sections -c main.c |
| |
| # Compile a feature to be placed in a loadable partition. |
| # Note that this is likely to be a separate build step to the main partition. |
| clang -ffunction-sections -fdata-sections -fsymbol-partition=libfeature.so -c feature.c |
| |
| # Link the combined output file. |
| clang main.o feature.o -fuse-ld=lld -shared -o libcombined.so -Wl,-soname,libmain.so -Wl,--gc-sections |
| |
| # Extract the partitions. |
| llvm-objcopy libcombined.so libmain.so --extract-main-partition |
| llvm-objcopy libcombined.so libfeature.so --extract-partition=libfeature.so |
| |
| In order to allow a program to discover the names of its loadable partitions |
| and the locations of their reserved regions, the linker creates a partition |
| index, which is an array of structs with the following definition: |
| |
| .. code-block:: c |
| |
| struct partition_index_entry { |
| int32_t name_offset; |
| int32_t addr_offset; |
| uint32_t size; |
| }; |
| |
| The ``name_offset`` field is a relative pointer to a null-terminated string |
| containing the soname of the partition, the ``addr_offset`` field is a |
| relative pointer to its load address and the ``size`` field contains the |
| size of the region reserved for the partition. To derive an absolute pointer |
| from the relative pointer fields in this data structure, the address of the |
| field should be added to the value stored in the field. |
| |
| The program may discover the location of the partition index using the |
| linker-defined symbols ``__part_index_begin`` and ``__part_index_end``. |
| |
| Restrictions |
| ------------ |
| |
| This feature is currently only supported in the ELF linker. |
| |
| The partitioning feature may not currently be used together with the |
| ``SECTIONS`` or ``PHDRS`` linker script features, nor may it be used with the |
| ``--section-start``, ``-Ttext``, ``-Tdata`` or ``-Tbss`` flags. All of these |
| features assume a single set of output sections and/or program headers, which |
| makes their semantics ambiguous in the presence of more than one partition. |
| |
| The partitioning feature may not currently be used on the MIPS architecture |
| because it is unclear whether the MIPS multi-GOT ABI is compatible with |
| partitions. |
| |
| The current implementation only supports creating up to 254 partitions due |
| to implementation limitations. This limit may be relaxed in the future. |
