* Handle a `null` return from `llvmFieldIndex`.
* Add a behavior test to test this code path.
* Reword this test name, which incorrectly described how pointers to
zero-bit fields behave, and instead describe the actual test.
This was a poor naming choice; these are parameters, not arguments.
Parameters specify what kind of arguments are expected, whereas the arguments are the actual values passed.
This matches `cmd.exe` behavior. For example, if there is only a file named `mycommand` in the cwd but it is a Linux executable, then running the command `mycommand` will result in:
'mycommand' is not recognized as an internal or external command, operable program or batch file.
However, if there is *both* a `mycommand` (that is a Linux executable) and a `mycommand.exe` that is a valid Windows exe, then running the command `mycommand` will successfully run `mycommand.exe`.
Avoid a lot of unnecessary utf8 -> utf16 conversion and use a single ArrayList buffer for all the joined paths instead of a separate allocation for each join
For example, if the command is specified as `something.exe`, the retry will now try:
```
C:\some\path\something.exe
C:\some\path\something.exe.COM
C:\some\path\something.exe.EXE
C:\some\path\something.exe.BAT
... etc ...
```
whereas before it would only try the versions with an added extension from `PATHEXT`, which would cause the retry to fail on things that it should find.
Given `main.go`:
package main
import _ "os/user"
func main() {}
Compiling it to linux/arm64:
$ CGO_CFLAGS='-O0' GOOS=linux GOARCH=arm64 CGO_ENABLED=1 CC="zig cc -target aarch64-linux-gnu.2.28" go build main.go
Results in this error:
runtime/cgo(.text): unknown symbol memset in callarm64
runtime/cgo(.text): unknown symbol memset in callarm64
runtime/cgo(.text): relocation target memset not defined
In the midst of intermediate compilations files we can see this commmand:
ld.lld -o _cgo_.o <...> /tmp/go-build206961058/b043/_x009.o <...> ~/.cache/zig/.../libcompiler_rt.a <...> ~/.cache/.../libc.so.6
`_x009.o` needs memset:
$ readelf -Ws ./b043/_x009.o | grep memset
22: 0000000000000000 0 NOTYPE GLOBAL DEFAULT UND memset
Both `libcompiler_rt.a` and `libc.so.6` provide it:
$ readelf -Ws ~/.cache/zig/.../libcompiler_rt.a | grep memset
870: 0000000000000000 318 FUNC WEAK DEFAULT 519 memset
$ readelf -Ws ~/.cache/zig/.../libc.so.6 | grep -w memset
476: 000000000001d34c 0 FUNC GLOBAL DEFAULT 7 memset@@GLIBC_2.2.5
Since `libcompiler_rt.a` comes before libc in the linker line, the
resulting `_cgo_.o` still links to a weak, unversioned memset:
$ readelf -Ws ./b043/_cgo_.o | grep -w memset
40: 000000000022c07c 160 FUNC WEAK DEFAULT 14 memset
719: 000000000022c07c 160 FUNC WEAK DEFAULT 14 memset
Since the final linking step is done by Golang's linker, it does not
know of `libcompiler_rt.a`, and fails to link with the error message
above. However, Go linker does recognize memset from glibc. If we
specify an `-lc` equivalent before the `libcompiler_rt.a`, it will link
to memset from libc:
$ readelf -Wa ./b043/_x009.o |grep memset
14: 0000000000000000 0 FUNC GLOBAL DEFAULT UND memset@GLIBC_2.17 (2)
157: 0000000000000000 0 FUNC GLOBAL DEFAULT UND memset@GLIBC_2.17
... and then `main.go` will compile+link successfully.
Why doesn't Go linker take memset from glibc? An educated guess: Go
determines whether to link with glibc from what the program asks (I
presume `.dynsym`). Since `memset` is no longer attributed to glibc, Go
skips linking to glibc altogether.
Bonus question: curious why `-O0` is necessary? Because when
optimizations are enabled (the default), the C compiler replaces
`memset` function call with plain `stp` instructions (on aarch64).
