Backward Compatibility

Bazel is still in Beta and new releases may include backward incompatible changes. As we make changes and polish the extension mechanism, old features may be removed and new features that are not backward compatible may be added.

Backward incompatible changes are introduced gradually:

  1. The backward incompatible change is introduced behind a flag with its default value set to false.
  2. In a later release, the flag’s default value will be set to true. You can still use the flag to disable the change.
  3. Then in a later release, the flag will be removed and you will no longer be able to disable the change.

To check if your code will be compatible with future releases you can:

  • Build your code with the flag --all_incompatible_changes. This flag enables all backward incompatible changes, and so you can ensure your code is compatible with upcoming changes.
  • Use boolean flags to enable/disable specific backward incompatible changes.

Current backward incompatible changes

The following are the backward incompatible changes that are implemented and guarded behind flags in the current release:

Dictionary concatenation

We are removing the + operator on dictionaries. This includes the += form where the left-hand side is a dictionary. This is done to improve compatibility with Python. A possible workaround is to use the .update method instead.

  • Flag: --incompatible_disallow_dict_plus
  • Default: false

Load must appear at top of file

Previously, the load statement could appear anywhere in a .bzl file so long as it was at the top level. With this change, for .bzl files, load must appear at the beginning of the file, i.e. before any other non-load statement.

  • Flag: --incompatible_bzl_disallow_load_after_statement
  • Default: false

Depset is no longer iterable

When the flag is set to true, depset objects are not treated as iterable. This prohibits directly iterating over depsets in for loops, taking its size via len(), and passing it to many functions such as list, tuple, min, max, sorted, all, and any. It does not prohibit checking for emptiness by converting the depset to a boolean.

The goal of this change is to avoid accidental iteration on depset, which can be expensive. If you really need to iterate over a depset, you can call the .to_list() method to obtain a flattened list of its contents.

deps = depset()
[x.path for x in deps]  # deprecated
[x.path for x in deps.to_list()]  # recommended

sorted(deps)  # deprecated
sorted(deps.to_list())  # recommended
  • Flag: --incompatible_depset_is_not_iterable
  • Default: false

Depset union

To merge two sets, the following examples used to be supported, but are now deprecated:

depset1 + depset2  # deprecated
depset1 | depset2  # deprecated
depset1.union(depset2)  # deprecated

The recommended solution is to use the depset constructor:

depset(transtive=[depset1, depset2])

See the depset documentation for more information.

  • Flag: --incompatible_depset_union
  • Default: false

String is no longer iterable

When the flag is set to true, string objects are not treated as iterable. This affects for loops and many functions, e.g. list, tuple, min, max, sorted, all, and any. String iteration has been a source of errors and confusion, such as this error:

def my_macro(name, srcs):
  for src in srcs:
    # do something with src

# equivalent to: my_macro("hello", ["f", "o", "o", ".", "c", "c"])
my_macro(
  name = "hello",
  srcs = "foo.cc",
)

String indexing and len are still allowed. If you need to iterate over a string, you may explicitly use:

my_string = "hello world"
for i in range(len(my_string)):
  char = my_string[i]
  # do something with char
  • Flag: --incompatible_string_is_not_iterable
  • Default: false

Integer division operator is //

Integer division operator is now // instead of /. This aligns with Python 3 and it highlights the fact it is a floor division.

x = 7 / 2  # deprecated

x = 7 // 2  # x is 3
  • Flag: --incompatible_disallow_slash_operator
  • Default: false

Package name is a function

The current package name should be retrieved by calling package_name() in BUILD files or native.package_name() in .bzl files. The old way of referring to the magic PACKAGE_NAME variable bends the language since it is neither a parameter, local variable, nor global variable.

Likewise, the magic REPOSITORY_NAME variable is replaced by repository_name() and native.repository_name(). Both deprecations use the same flag.

  • Flag: --incompatible_package_name_is_a_function
  • Default: false

FileType is deprecated

The FileType function is going away. The main use-case was as an argument to the rule function. It’s no longer needed, you can simply pass a list of strings to restrict the file types the rule accepts.

  • Flag: --incompatible_disallow_filetype
  • Default: false

New actions API

This change removes the old methods for registering actions within rules, and requires that you use the new methods instead. The deprecated methods and their replacements are as follows.

  • ctx.new_file(...) –> ctx.actions.declare_file(...)
  • ctx.experimental_new_directory(...) –> ctx.actions.declare_directory(...)
  • ctx.action(...) –> either ctx.actions.run(...) or ctx.actions.run_shell(...)
  • ctx.file_action(...) –> ctx.actions.write(...)
  • ctx.empty_action(...) –> ctx.actions.do_nothing(...)
  • ctx.template_action(...) –> ctx.actions.expand_template(...)
  • Flag: --incompatible_new_actions_api
  • Default: false

New args API

The Args object returned by ctx.actions.args() has dedicated methods for appending the contents of a list or depset to the command line. Previously these use cases were lumped into its add() method, resulting in a more cluttered API.

With this flag, add() only works for scalar values, and its deprecated parameters are disabled. To add many arguments at once you must use add_all() or add_joined() instead.

  • Flag: --incompatible_disallow_old_style_args_add
  • Default: false

Python 3 range behavior.

When set, the result of range(...) function is a lazy range type instead of a list. Because of this repetitions using * operator are no longer supported and range slices are also lazy range instances.

  • Flag: --incompatible_range_type
  • Default: false

Disable objc provider resources

This flag disables certain deprecated resource fields on ObjcProvider.

  • Flag: --incompatible_objc_provider_resources
  • Default: false

Remove native git repository

When set, the native git_repository and new_git_repository rules are disabled. The Starlark versions

load("@bazel_tools//tools/build_defs/repo:git.bzl",
     "git_repository", "new_git_repository")

should be used instead. These are drop-in replacements of the corresponding native rules, however with the additional requirement that all label arguments be provided as a fully qualified label (usually starting with @//), for example: build_file = "@//third_party:repo.BUILD".

  • Flag: --incompatible_remove_native_git_repository
  • Default: false

Remove native http archive

When set, the native http_archive and all related rules are disabled. The Starlark version

load("@bazel_tools//tools/build_defs/repo:http.bzl", "http_archive")

should be used instead. This is a drop-in replacement, however with the additional requirement that all label arguments be provided as fully qualified labels (usually starting with @//). The Starlark http_archive is also a drop-in replacement for the native new_http_archive (with the same proviso). http.bzl also provides http_jar and http_file (the latter only supports the urls parameter, not url).

  • Flag: --incompatible_remove_native_http_archive
  • Default: false

New-style JavaInfo constructor

When set, java_common.create_provider and certain arguments to JavaInfo are deprecated. The deprecated arguments are: actions, sources, source_jars, use_ijar, java_toolchain, and host_javabase.

Example migration from create_provider:

# Before
provider = java_common.create_provider(
    ctx.actions,
    compile_time_jars = [output_jar],
    use_ijar = True,
    java_toolchain = ctx.attr._java_toolchain,
    transitive_compile_time_jars = transitive_compile_time,
    transitive_runtime_jars = transitive_runtime_jars,
)

# After
compile_jar = java_common.run_ijar(
    ctx.actions,
    jar = output_jar,
    target_label = ctx.label,
    java_toolchain = ctx.attr._java_toolchain,
)
provider = JavaInfo(
    output_jar = output_jar,
    compile_jar = compile_jar,
    deps = deps,
    runtime_deps = runtime_deps,
)

Example migration from deprecated JavaInfo arguments:

# Before
provider = JavaInfo(
  output_jar = my_jar,
  use_ijar = True,
  sources = my_sources,
  deps = my_compile_deps,
  runtime_deps = my_runtime_deps,
  actions = ctx.actions,
  java_toolchain = my_java_toolchain,
  host_javabase = my_host_javabase,
)

# After
my_ijar = java_common.run_ijar(
  ctx.actions,
  jar = my_jar,
  target_label = ctx.label,
  java_toolchain, my_java_toolchain,
)
my_source_jar = java_common.pack_sources(
  ctx.actions,
  sources = my_sources,
  java_toolchain = my_java_toolchain,
  host_javabase = my_host_javabase,
)
provider = JavaInfo(
  output_jar = my_jar,
  compile_jar = my_ijar,
  source_jar = my_source_jar,
  deps = my_compile_deps,
  runtime_deps = my_runtime_deps,
)

Disallow tools in action inputs

A tool is an input coming from an attribute of type label where the attribute has been marked executable = True. In order for an action to run a tool, it needs access to its runfiles.

Under the old API, tools are passed to ctx.actions.run() and ctx.actions.run_shell() via their inputs parameter. Bazel scans this argument (which may be a large depset) to find all the inputs that are tools, and adds their runfiles automatically.

In the new API, tools are instead passed to a dedicated tools parameter. The inputs are not scanned. If a tool is accidentally put in inputs instead of tools, the action will fail during the execution phase with an error due to missing runfiles. This may be somewhat cryptic.

To support a gradual transition, all actions with a tools argument are opted into the new API, while all actions without a tools argument still follow the old one. In the future (when this flag is removed), all actions will use the new API unconditionally.

This flag turns on a safety check that is useful for migrating existing code. The safety check applies to all actions that do not have a tools argument. It scans the inputs looking for tools, and if it finds any, it raises an error during the analysis phase that clearly identifies the offending tools.

In the rare case that your action requires a tool as input, but does not actually run the tool and therefore does not need its runfiles, the safety check will fail even though the action would have succeeded. In this case, you can bypass the check by adding a (possibly empty) tools argument to your action. Note that once an action has been modified to take a tools argument, you will no longer get helpful analysis-time errors for any remaining tools that should have been migrated from inputs.

  • Flag: --incompatible_no_support_tools_in_action_inputs
  • Default: false

Expand directories in Args

Previously, directories created by ctx.actions.declare_directory expanded to the path of the directory when added to an Args object.

With this flag enabled, directories are instead replaced by the full file contents of that directory when passed to args.add_all() or args.add_joined(). (Directories may not be passed to args.add().)

If you want the old behavior on a case-by-case basis (perhaps your tool can handle directories on the command line), you can pass expand_directories=False to the args.add_all() or args.add_joined() call.

d = ctx.action.declare_directory(“dir”)
# ... Some action runs and produces [“dir/file1”, “dir/file2”] ...
f = ctx.action.declare_file(“file”)
args = ctx.action.args()
args.add_all([d, f])
  -> Used to expand to ["dir", "file"]
     Now expands to [“dir/file1”, “dir/file2”, “file”]
  • Flag: --incompatible_expand_directories
  • Default: false

Static Name Resolution

When the flag is set, use a saner way to resolve variables. The previous behavior was buggy in a number of subtle ways. See the proposal for background and examples.

The proposal is not fully implemented yet.

  • Flag: --incompatible_static_name_resolution
  • Default: false

Disallow transitive loads

When the flag is set, load can only import symbols that were explicitly defined in the target file, using either = or def.

When the flag is unset (legacy behavior), load may also import symbols that come from other load statements.

In other words, the x below is exported only if the flag is unset:

load(":file.bzl", "x")

y = 1
  • Flag: --incompatible_no_transitive_loads
  • Default: false
  • Introduced in: 0.19.0
  • Tracking issue: https://github.com/bazelbuild/bazel/issues/5636

Disable InMemory Tools Defaults Package

If false, Bazel constructs an in-memory //tools/defaults package based on the command line options. If true, //tools/defaults:* is resolved from file system as a regular package.

  • Flag: --incompatible_disable_tools_defaults_package
  • Default: false

Motivation:

//tools/default was initially created as virtual in-memory package. It generates content dynamically based on current configuration. There is no need of having //tools/defaults any more as LateBoundAlias can do dynamic configuration-based label resolving. Also, having //tools/default makes negative impact on performance, and introduces unnecessary code complexity.

All references to //tools/defaults:* targets should be removed or replaced to corresponding target in @bazel_tools//tools/jdk: and @bazel_tools//tools/cpp: packages.

Scope of changes and impact:

Targets in //tools/default will not exist any more. If you have any references inside your BUILD or *.bzl files to any of its, then bazel will fail to resolve.

Migration plan:

Please replace all occurrences:

  • //tools/defaults:jdk
    • by @bazel_tools//tools/jdk:current_java_runtime
    • or/and @bazel_tools//tools/jdk:current_host_java_runtime
  • //tools/defaults:java_toolchain
    • by @bazel_tools//tools/jdk:current_java_toolchain
  • //tools/defaults:crosstool
    • by @bazel_tools//tools/cpp:current_cc_toolchain
    • or/and @bazel_tools//tools/cpp:current_cc_host_toolchain
    • if you need reference to libc_top, then @bazel_tools//tools/cpp:current_libc_top

These targets will not be supported any more:

  • //tools/defaults:coverage_report_generator
  • //tools/defaults:coverage_support

Disable late bound option defaults

If true, Bazel will stop retrieving the value of compiler from the cpp configuration when --compiler is not specified. This will cause a config_setting that have values = {"compiler": "x"} to not work properly when --compiler is not specified at command line.

The former behavior can be achieved by changing the config_setting to use flag_values = {"@bazel_tools/tools/cpp:compiler": "x"} instead:

# Before
config_setting(
    name = "cpu_x_compiler_y",
    values = {
        "cpu": "x",
        "compiler": "y",
    },
)

# After
config_setting(
    name = "cpu_x_compiler_y",
    values = {
        "cpu": "x",
    },
    flag_values = {
        "@bazel_tools/tools/cpp:compiler": "y",
    },
)
  • Flag: --incompatible_disable_late_bound_option_defaults
  • Default: false
  • Introduced in: 0.18.0

Disable depsets in C++ toolchain API in user flags

If true, Bazel will no longer accept depsets in user_compile_flags for create_compile_variables, and in user_link_flags for create_link_variables. Use plain lists instead.

  • Flag: --incompatible_disable_depset_in_cc_user_flags
  • Default: false
  • Introduced in: 0.18.0

Disallow using CROSSTOOL to select the cc_toolchain label

Currently Bazel selects the cc_toolchain to use from the toolchains dictionary attribute of cc_toolchain_suite. The key it uses is constructed the following way:

  • If --compiler option is specified, the key is --cpu|--compiler. Bazel errors out if the entry doesn’t exist.
  • If --compiler option was not specified on command line, Bazel checks if an entry with the key --cpu exists, and uses it if it does. If such an entry doesn’t exist, it loops through the default_toolchain list in the CROSSTOOL file, selects the first one that matches the --cpu option, finds the CToolchain whose identifier matches the default_toolchain.toolchain_identifier field, and then uses the key CToolchain.targetCpu|Ctoolchain.compiler. It errors out if the entry doesn’t exist.

We’re making selection of the cc_toolchain label independent of the CROSSTOOL file: when the flag is set to True, Bazel will no longer loop through the default_toolchain list in order to construct a key for selecting a cc_toolchain label from cc_toolchain_suite.toolchains, but throw an error instead.

In order to not be affected by this change, one should add entries in the cc_toolchain_suite.toolchains for the potential values of --cpu:

# Before
cc_toolchain_suite(
    toolchains = {
        'cpu1|compiler1' : ':cc_toolchain_label1',
        'cpu2|compiler2' : ':cc_tolchain_label2',
    }
)

# After
cc_toolchain_suite(
    toolchains = {
        'cpu1|compiler1' : ':cc_toolchain_label1',
        'cpu2|compiler2' : ':cc_toolchain_label2',
        'cpu1' : ':cc_toolchain_label3',
        'cpu2' : ':cc_tolchain_label4',
    }
)

  • Flag: --incompatible_disable_cc_toolchain_label_from_crosstool_proto
  • Default: false
  • Introduced in: 0.18.0

Disallow using C++ Specific Make Variables from the configuration

Currently Bazel allows rule authors to access certain Make variables that are implicitly provided to every rule by the CppConfiguration. This causes every target to implicitly depend on CppConfiguration, which creates an undesirable number of extra, unused, dependencies.

We are removing the implicit provision of these Make variables, and requiring rules and targets that use these Make variables to explicitly depend on a C++ toolchain in order to access them.

The list of Make variables is:

  • CC
  • AR
  • NM
  • LD
  • OBJCOPY
  • STRIP
  • GCOVTOOL
  • GLIBC_VERSION
  • C_COMPILER
  • CROSSTOOLTOP
  • ABI_GLIBC_VERSION
  • ABI

In order to not be affected by this change, one should add a C++ toolchain to the toolchains attribute for targets, or to the _toolchains attribute for Starlark rules. The best choice for this value is the alias target @bazel_tools//tools/cpp:current_cc_toolchain, which will always resolve to the currently selected C++ toolchain.

For genrules and other targets using C++ Make Variables:

# Before
genrule(
  cmd = '$(STRIP) file-to-be-stripped.o',
)

# After
genrule(
  cmd = '$(STRIP) file-to-be-stripped.o',
  toolchains = ['@bazel_tools//tools/cpp:current_cc_toolchain'],
)

For Starlark rules using C++ Make Variables:

# Before
def _impl(ctx):
  strip = ctx.vars['STRIP']
  ...

my_rule = rule(
  implementation = _impl,
  attrs = {
  },
)

# After
def _impl(ctx):
  strip = ctx.vars['STRIP']
  ...

my_rule = rule(
  implementation = _impl,
  attrs = {
    '_toolchains': attr.label_list(default = [Label('@bazel_tools//tools/cpp:current_cc_toolchain')]),
  },
)
  • Flag: --incompatible_disable_cc_configuration_make_variables
  • Default: false
  • Introduced in: 0.18.0

Disable legacy C++ configuration API

This turns off legacy Starlark access to cc toolchain information via the ctx.fragments.cpp fragment. Instead of declaring dependency on the ctx.fragments.cpp using the fragments attribute declare a dependency on the @bazel_tools//tools/cpp:current_cc_toolchain via implicit attribute named _cc_toolchain (see example below). Use find_cpp_toolchain from @bazel_tools//tools/cpp:toolchain_utils.bzl to get the current C++ toolchain in the rule implementation.

# Before
def _impl(ctx):
  ...
  ctx.fragments.cpp.compiler_options()

foo = rule(
    implementation = _impl,
    fragments = ["cpp"],
    ...
)

# After
load("@bazel_tools//tools/cpp:toolchain_utils.bzl", "find_cpp_toolchain")

def _impl(ctx):
  ...
  cc_toolchain = find_cpp_toolchain(ctx)
  cc_toolchain.compiler_options()

foo = rule(
    implementation = _impl,
    attrs = {
        "_cc_toolchain": attr.label(
            default=Label("@bazel_tools//tools/cpp:current_cc_toolchain")
        ),
    },
)

List of all legacy fields and their corresponding cc_toolchain alternative:

ctx.fragments.cpp cc_toolchain
ar_executable ar_executable()
built_in_include_directories built_in_include_directories
c_options c_options()
compiler compiler
compiler_executable compiler_executable()
compiler_options(unused_arg) compiler_options()
cpu cpu
cxx_options(unused_arg) cxx_options()
dynamic_link_options(unused_arg, bool) dynamic_link_options(bool)
fully_static_link_options(unused_arg, True) fully_static_link_options(True)
ld_executable ld_executable()
link_options link_options_do_not_use
mostly_static_link_options(unused_arg, bool) mostly_static_link_options(bool)
nm_executable nm_executable()
objcopy_executable objcopy_executable()
objdump_executable objdump_executable()
preprocessor_executable preprocessor_executable()
strip_executable strip_executable()
sysroot sysroot
target_gnu_system_name target_gnu_system_name
unfiltered_compiler_options(unused_arg) unfiltered_compiler_options(unused_arg)
  • Flag: --incompatible_disable_legacy_cpp_toolchain_skylark_api
  • Default: false
  • Introduced in: 0.18.0

Disable legacy C++ toolchain API

We have deprecated the cc_toolchain Starlark API returning legacy CROSSTOOL fields:

  • ar_executable
  • c_options
  • compiler_executable
  • compiler_options
  • cxx_options
  • dynamic_link_options
  • fully_static_link_options
  • ld_executable
  • link_options
  • mostly_static_link_options
  • nm_executable
  • objcopy_executable
  • objdump_executable
  • preprocessor_executable
  • strip_executable
  • unfiltered_compiler_options

Use the new API from cc_common

# Before:
load("@bazel_tools//tools/cpp:toolchain_utils.bzl", "find_cpp_toolchain")

def _impl(ctx):
    cc_toolchain = find_cc_toolchain(ctx)
    compiler_options = (
        cc_toolchain.compiler_options() +
        cc_toolchain.unfiltered_compiler_options([]) +
        ["-w", "-Wno-error"]
    )
    link_options = (
        ["-shared", "-static-libgcc"] +
        cc_toolchain.mostly_static_link_options(True) +
        ["-Wl,-whole-archive"] +
        [l.path for l in libs] +
        ["-Wl,-no-whole-archive"] +
        cc_toolchain.link_options_do_not_use
    )

# After
load("@bazel_tools//tools/cpp:toolchain_utils.bzl", "find_cpp_toolchain")
load(
    "@bazel_tools//tools/build_defs/cc:action_names.bzl",
    "CPP_LINK_DYNAMIC_LIBRARY_ACTION_NAME",
    "C_COMPILE_ACTION_NAME",
)

def _impl(ctx):
    cc_toolchain = find_cc_toolchain(ctx)
    feature_configuration = cc_common.configure_features(
        cc_toolchain = cc_toolchain,
        requested_features = ctx.features,
        unsupported_features = ctx.disabled_features,
    )
    compile_variables = cc_common.create_compile_variables(
        feature_configuration = feature_configuration,
        cc_toolchain = cc_toolchain,
        user_compile_flags = depset(["-w", "-Wno-error"]),
    )
    compiler_options = cc_common.get_memory_inefficient_command_line(
        feature_configuration = feature_configuration,
        action_name = C_COMPILE_ACTION_NAME,
        variables = compile_variables,
    )

    link_variables = cc_common.create_link_variables(
        feature_configuration = feature_configuration,
        cc_toolchain = cc_toolchain,
        is_linking_dynamic_library = True,
        user_link_flags =
            ["-static-libgcc"] +
            ["-Wl,-whole-archive"] +
            [lib.path for lib in libs] +
            ["-Wl,-no-whole-archive"],
    )
    link_flags = cc_common.get_memory_inefficient_command_line(
        feature_configuration = feature_configuration,
        action_name = CPP_LINK_DYNAMIC_LIBRARY_ACTION_NAME,
        variables = link_variables,
    )
  • Flag: --incompatible_disable_legacy_flags_cc_toolchain_api
  • Default: false
  • Introduced in: 0.19.0