• Russ Cox's avatar
    liblink: introduce TLS register on 386 and amd64 · 90093f06
    Russ Cox authored
    When I did the original 386 ports on Linux and OS X, I chose to
    define GS-relative expressions like 4(GS) as relative to the actual
    thread-local storage base, which was usually GS but might not be
    (it might be FS, or it might be a different constant offset from GS or FS).
    
    The original scope was limited but since then the rewrites have
    gotten out of control. Sometimes GS is rewritten, sometimes FS.
    Some ports do other rewrites to enable shared libraries and
    other linking. At no point in the code is it clear whether you are
    looking at the real GS/FS or some synthesized thing that will be
    rewritten. The code manipulating all these is duplicated in many
    places.
    
    The first step to fixing issue 7719 is to make the code intelligible
    again.
    
    This CL adds an explicit TLS pseudo-register to the 386 and amd64.
    As a register, TLS refers to the thread-local storage base, and it
    can only be loaded into another register:
    
            MOVQ TLS, AX
    
    An offset from the thread-local storage base is written off(reg)(TLS*1).
    Semantically it is off(reg), but the (TLS*1) annotation marks this as
    indexing from the loaded TLS base. This emits a relocation so that
    if the linker needs to adjust the offset, it can. For example:
    
            MOVQ TLS, AX
            MOVQ 8(AX)(TLS*1), CX // load m into CX
    
    On systems that support direct access to the TLS memory, this
    pair of instructions can be reduced to a direct TLS memory reference:
    
            MOVQ 8(TLS), CX // load m into CX
    
    The 2-instruction and 1-instruction forms correspond roughly to
    ELF TLS initial exec mode and ELF TLS local exec mode, respectively.
    
    Liblink applies this rewrite on systems that support the 1-instruction form.
    The decision is made using only the operating system (and probably
    the -shared flag, eventually), not the link mode. If some link modes
    on a particular operating system require the 2-instruction form,
    then all builds for that operating system will use the 2-instruction
    form, so that the link mode decision can be delayed to link time.
    
    Obviously it is late to be making changes like this, but I despair
    of correcting issue 7719 and issue 7164 without it. To make sure
    I am not changing existing behavior, I built a "hello world" program
    for every GOOS/GOARCH combination we have and then worked
    to make sure that the rewrite generates exactly the same binaries,
    byte for byte. There are a handful of TODOs in the code marking
    kludges to get the byte-for-byte property, but at least now I can
    explain exactly how each binary is handled.
    
    The targets I tested this way are:
    
            darwin-386
            darwin-amd64
            dragonfly-386
            dragonfly-amd64
            freebsd-386
            freebsd-amd64
            freebsd-arm
            linux-386
            linux-amd64
            linux-arm
            nacl-386
            nacl-amd64p32
            netbsd-386
            netbsd-amd64
            openbsd-386
            openbsd-amd64
            plan9-386
            plan9-amd64
            solaris-amd64
            windows-386
            windows-amd64
    
    There were four exceptions to the byte-for-byte goal:
    
    windows-386 and windows-amd64 have a time stamp
    at bytes 137 and 138 of the header.
    
    darwin-386 and plan9-386 have five or six modified
    bytes in the middle of the Go symbol table, caused by
    editing comments in runtime/sys_{darwin,plan9}_386.s.
    
    Fixes #7164.
    
    LGTM=iant
    R=iant, aram, minux.ma, dave
    CC=golang-codereviews
    https://golang.org/cl/87920043
    90093f06
obj6.c 25.8 KB