}
	f.walk(ast2, ctxProg, (*File).validateIdents)
	f.walk(ast2, ctxProg, (*File).saveExprs)

	// Accumulate exported functions.
	// The comments are only on ast1 but we need to
	// save the function bodies from ast2.
	// The first walk fills in ExpFunc, and the
	// second walk changes the entries to
	// refer to ast2 instead.
	f.walk(ast1, ctxProg, (*File).saveExport)
	f.walk(ast2, ctxProg, (*File).saveExport2)

	type _Ctype_char int8
	type _Ctype_int int32
	type _Ctype_void [0]byte

The _cgo_gotypes.go file also contains the definitions of the
functions. They all have similar bodies that invoke runtime·cgocall
to make a switch from the Go runtime world to the system C (GCC-based)
world.

For example, here is the definition of _Cfunc_puts:

	//go:cgo_import_static _cgo_be59f0f25121_Cfunc_puts

</li>
<li>
	Both type parameters have a known type argument
	and the type arguments unify per the given matching modes.
</li>
</ul>

<p>
A single bound type parameter <code>P</code> and another type <code>T</code> unify
per the given matching modes if:
</p>

<ul>
<li>
	<code>P</code> doesn't have a known type argument.

				// The Loong64 RDTIME family of instructions is a bit special,
				// in that both its register operands are outputs
				prog.To = a[0]
				if a[1].Type != obj.TYPE_REG {
					p.errorf("invalid addressing modes for 2nd operand to %s instruction, must be register", op)
					return
				}
				prog.RegTo2 = a[1].Reg
				break
			}
		}
		prog.From = a[0]
		prog.To = a[1]
	case 3:
		switch p.arch.Family {

pkg syscall (linux-arm-cgo), type Timex struct, Jitter int32
pkg syscall (linux-arm-cgo), type Timex struct, Maxerror int32
pkg syscall (linux-arm-cgo), type Timex struct, Modes uint32
pkg syscall (linux-arm-cgo), type Timex struct, Offset int32
pkg syscall (linux-arm-cgo), type Timex struct, Pad_cgo_0 [44]uint8
pkg syscall (linux-arm-cgo), type Timex struct, Ppsfreq int32

	}
	prog.Scond = bits
	return true
}

// ParseARMCondition parses the conditions attached to an ARM instruction.
// The input is a single string consisting of period-separated condition
// codes, such as ".P.W". An initial period is ignored.
func ParseARMCondition(cond string) (uint8, bool) {
	return parseARMCondition(cond, armLS, armSCOND)
}

pkg syscall (linux-386), type Timex struct, Jitcnt int32
pkg syscall (linux-386), type Timex struct, Jitter int32
pkg syscall (linux-386), type Timex struct, Maxerror int32
pkg syscall (linux-386), type Timex struct, Modes uint32
pkg syscall (linux-386), type Timex struct, Offset int32
pkg syscall (linux-386), type Timex struct, Pad_cgo_0 [44]uint8
pkg syscall (linux-386), type Timex struct, Ppsfreq int32

<code>cmd/internal/obj/x86/a.out.go</code>.
</p>

<p>
The architectures share syntax for common addressing modes such as
<code>(R1)</code> (register indirect),
<code>4(R1)</code> (register indirect with offset), and
<code>$foo(SB)</code> (absolute address).
The assembler also supports some (not necessarily all) addressing modes
specific to each architecture.
The sections below list these.
</p>

<p>

		Remove prefix from recorded source file paths.
	-v
		Print debug output.

Input language:

The assembler uses mostly the same syntax for all architectures,
the main variation having to do with addressing modes. Input is
run through a simplified C preprocessor that implements #include,
#define, #ifdef/endif, but not #if or ##.

For more information, see https://golang.org/doc/asm.
*/

		return false
	}
	prog.Scond = bits
	return true
}

// parseARM64Suffix parses the suffix attached to an ARM64 instruction.
// The input is a single string consisting of period-separated condition
// codes, such as ".P.W". An initial period is ignored.
func parseARM64Suffix(cond string) (uint8, bool) {
	if cond == "" {
		return 0, true
	}
	return parseARMCondition(cond, arm64LS, nil)
}