mbed-os/tools/toolchains/gcc.py

"""
mbed SDK
Copyright (c) 2011-2013 ARM Limited

Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at

    http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
"""
import re
from os.path import join, basename, splitext, dirname, exists
from os import getenv
from distutils.spawn import find_executable
from distutils.version import LooseVersion

from tools.targets import CORE_ARCH
from tools.toolchains.mbed_toolchain import mbedToolchain, TOOLCHAIN_PATHS
from tools.utils import run_cmd


class GCC(mbedToolchain):
    OFFICIALLY_SUPPORTED = True
    LINKER_EXT = '.ld'
    LIBRARY_EXT = '.a'

    STD_LIB_NAME = "lib%s.a"
    DIAGNOSTIC_PATTERN = re.compile('((?P<file>[^:]+):(?P<line>\d+):)(?P<col>\d+):? (?P<severity>warning|[eE]rror|fatal error): (?P<message>.+)')

    GCC_RANGE = (LooseVersion("6.0.0"), LooseVersion("7.0.0"))
    GCC_VERSION_RE = re.compile(b"\d+\.\d+\.\d+")

    def __init__(self, target,  notify=None, macros=None, build_profile=None,
                 build_dir=None):
        mbedToolchain.__init__(
            self,
            target,
            notify,
            macros,
            build_profile=build_profile,
            build_dir=build_dir
        )

        tool_path = TOOLCHAIN_PATHS['GCC_ARM']
        # Add flags for current size setting
        default_lib = "std"
        if hasattr(target, "default_lib"):
            default_lib = target.default_lib
        elif hasattr(target, "default_build"):
            default_lib = target.default_build

        if default_lib == "small":
            self.flags["common"].append("-DMBED_RTOS_SINGLE_THREAD")
            self.flags["ld"].append("--specs=nano.specs")

        core = target.core
        self.cpu = []
        if CORE_ARCH[target.core] == 8:
            # Add linking time preprocessor macro DOMAIN_NS
            if target.core.endswith("-NS"):
                self.flags["ld"].append("-DDOMAIN_NS=1")
                core = target.core[:-3]
            else:
                self.cpu.append("-mcmse")
                self.flags["ld"].extend([
                    "-Wl,--cmse-implib",
                    "-Wl,--out-implib=%s" % join(build_dir, "cmse_lib.o")
                ])

        cpu = {
            "Cortex-M0+": "cortex-m0plus",
            "Cortex-M4F": "cortex-m4",
            "Cortex-M7F": "cortex-m7",
            "Cortex-M7FD": "cortex-m7",
            "Cortex-M33F": "cortex-m33+nodsp",
            "Cortex-M33FE": "cortex-m33"}.get(core, core)

        if core == "Cortex-M33":
            self.cpu.append("-march=armv8-m.main")
        else:
            self.cpu.append("-mcpu={}".format(cpu.lower()))

        if target.core.startswith("Cortex-M"):
            self.cpu.append("-mthumb")

        # FPU handling, M7 possibly to have double FPU
        if core == "Cortex-M4F":
            self.cpu.append("-mfpu=fpv4-sp-d16")
            self.cpu.append("-mfloat-abi=softfp")
        elif core == "Cortex-M7F":
            self.cpu.append("-mfpu=fpv5-sp-d16")
            self.cpu.append("-mfloat-abi=softfp")
        elif core == "Cortex-M7FD":
            self.cpu.append("-mfpu=fpv5-d16")
            self.cpu.append("-mfloat-abi=softfp")
        elif core.startswith("Cortex-M33F"):
            self.cpu.append("-mfpu=fpv5-sp-d16")
            self.cpu.append("-mfloat-abi=softfp")

        if target.core == "Cortex-A9":
            self.cpu.append("-mthumb-interwork")
            self.cpu.append("-marm")
            self.cpu.append("-march=armv7-a")
            self.cpu.append("-mfpu=vfpv3")
            self.cpu.append("-mfloat-abi=hard")
            self.cpu.append("-mno-unaligned-access")

        self.flags["common"] += self.cpu

        main_cc = join(tool_path, "arm-none-eabi-gcc")
        main_cppc = join(tool_path, "arm-none-eabi-g++")
        self.asm = [main_cc] + self.flags['asm'] + self.flags["common"]
        self.cc = [main_cc]
        self.cppc = [main_cppc]
        self.cc += self.flags['c'] + self.flags['common']
        self.cppc += self.flags['cxx'] + self.flags['common']

        self.flags['ld'] += self.cpu
        self.ld = [join(tool_path, "arm-none-eabi-gcc")] + self.flags['ld']
        self.sys_libs = ["stdc++", "supc++", "m", "c", "gcc", "nosys"]
        self.preproc = [join(tool_path, "arm-none-eabi-cpp"), "-E", "-P"]

        self.ar = join(tool_path, "arm-none-eabi-ar")
        self.elf2bin = join(tool_path, "arm-none-eabi-objcopy")

        self.use_distcc = (bool(getenv("DISTCC_POTENTIAL_HOSTS", False))
                           and not getenv("MBED_DISABLE_DISTCC", False))

    def version_check(self):
        stdout, _, retcode = run_cmd([self.cc[0], "--version"], redirect=True)
        msg = None
        match = self.GCC_VERSION_RE.search(stdout.encode("utf-8"))
        if match:
            found_version = LooseVersion(match.group(0).decode('utf-8'))
        else:
            found_version = None
        min_ver, max_ver = self.GCC_RANGE
        if found_version and (found_version < min_ver
                              or found_version >= max_ver):
            msg = ("Compiler version mismatch: Have {}; "
                   "expected version >= {} and < {}"
                   .format(found_version, min_ver, max_ver))
        elif not match:
            msg = ("Compiler version mismatch: Could not detect version; "
                   "expected version >= {} and < {}"
                   .format(min_ver, max_ver))
        if msg:
            self.notify.cc_info({
                "message": msg,
                "file": "",
                "line": "",
                "col": "",
                "severity": "Warning",
            })

    def is_not_supported_error(self, output):
        return "error: #error [NOT_SUPPORTED]" in output

    def parse_output(self, output):
        # The warning/error notification is multiline
        msg = None
        for line in output.splitlines():
            match = self.DIAGNOSTIC_PATTERN.search(line)
            if match is not None:
                if msg is not None:
                    self.notify.cc_info(msg)
                    msg = None
                msg = {
                    'severity': match.group('severity').lower(),
                    'file': match.group('file'),
                    'line': match.group('line'),
                    'col': match.group('col'),
                    'message': match.group('message'),
                    'text': '',
                    'target_name': self.target.name,
                    'toolchain_name': self.name
                }

        if msg is not None:
            self.notify.cc_info(msg)

    def get_dep_option(self, object):
        base, _ = splitext(object)
        dep_path = base + '.d'
        return ["-MD", "-MF", dep_path]

    def get_config_option(self, config_header):
        return ['-include', config_header]

    def get_compile_options(self, defines, includes, for_asm=False):
        opts = ['-D%s' % d for d in defines]
        if self.RESPONSE_FILES:
            opts += ['@%s' % self.get_inc_file(includes)]
        else:
            opts += ["-I%s" % i for i in includes]

        config_header = self.get_config_header()
        if config_header is not None:
            opts = opts + self.get_config_option(config_header)
        return opts

    def assemble(self, source, object, includes):
        # Build assemble command
        cmd = self.asm + self.get_compile_options(
            self.get_symbols(True), includes
        ) + ["-o", object, source]

        # Return command array, don't execute
        return [cmd]

    def compile(self, cc, source, object, includes):
        # Build compile command
        cmd = cc + self.get_compile_options(self.get_symbols(), includes)

        cmd.extend(self.get_dep_option(object))

        cmd.extend(["-o", object, source])

        if self.use_distcc:
            cmd = ["distcc"] + cmd

        return [cmd]

    def compile_c(self, source, object, includes):
        return self.compile(self.cc, source, object, includes)

    def compile_cpp(self, source, object, includes):
        return self.compile(self.cppc, source, object, includes)

    def link(self, output, objects, libraries, lib_dirs, mem_map):
        libs = []
        for l in libraries:
            name, _ = splitext(basename(l))
            libs.append("-l%s" % name[3:])
        libs.extend(["-l%s" % l for l in self.sys_libs])

        # Preprocess
        if mem_map:
            preproc_output = join(dirname(output), ".link_script.ld")
            cmd = (
                self.preproc + [mem_map] + self.ld[1:] + ["-o", preproc_output]
            )
            self.notify.cc_verbose("Preproc: %s" % ' '.join(cmd))
            self.default_cmd(cmd)
            mem_map = preproc_output

        # Build linker command
        map_file = splitext(output)[0] + ".map"
        cmd = (
            self.ld +
            ["-o", output, "-Wl,-Map=%s" % map_file] +
            objects +
            ["-Wl,--start-group"] +
            libs +
            ["-Wl,--end-group"]
        )

        if mem_map:
            cmd.extend(['-T', mem_map])

        for L in lib_dirs:
            cmd.extend(['-L', L])
        cmd.extend(libs)

        if self.RESPONSE_FILES:
            # Split link command to linker executable + response file
            cmd_linker = cmd[0]
            link_files = self.get_link_file(cmd[1:])
            cmd = [cmd_linker, "@%s" % link_files]

        # Exec command
        self.notify.cc_verbose("Link: %s" % ' '.join(cmd))
        self.default_cmd(cmd)

    def archive(self, objects, lib_path):
        if self.RESPONSE_FILES:
            param = ["@%s" % self.get_arch_file(objects)]
        else:
            param = objects

        # Exec command
        self.default_cmd([self.ar, 'rcs', lib_path] + param)

    def binary(self, resources, elf, bin):
        # Build binary command
        _, fmt = splitext(bin)
        bin_arg = {'.bin': 'binary', '.hex': 'ihex'}[fmt]
        cmd = [self.elf2bin, "-O", bin_arg, elf, bin]

        # Exec command
        self.notify.cc_verbose("FromELF: %s" % ' '.join(cmd))
        self.default_cmd(cmd)

    @staticmethod
    def name_mangle(name):
        return "_Z%i%sv" % (len(name), name)

    @staticmethod
    def make_ld_define(name, value):
        return "-D%s=%s" % (name, value)

    @staticmethod
    def redirect_symbol(source, sync, build_dir):
        return "-Wl,--defsym=%s=%s" % (source, sync)

    @staticmethod
    def check_executable():
        """Returns True if the executable (arm-none-eabi-gcc) location
        specified by the user exists OR the executable can be found on the
        PATH. Returns False otherwise."""
        if (
            not TOOLCHAIN_PATHS['GCC_ARM'] or
            not exists(TOOLCHAIN_PATHS['GCC_ARM'])
        ):
            if find_executable('arm-none-eabi-gcc'):
                TOOLCHAIN_PATHS['GCC_ARM'] = ''
                return True
            else:
                return False
        else:
            exec_name = join(TOOLCHAIN_PATHS['GCC_ARM'], 'arm-none-eabi-gcc')
            return exists(exec_name) or exists(exec_name + '.exe')


class GCC_ARM(GCC):
    pass