// Copyright 2012 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // // System calls and other sys.stuff for ARM, FreeBSD // /usr/src/sys/kern/syscalls.master for syscall numbers. // #include "zasm_GOOS_GOARCH.h" #include "textflag.h" // for EABI, as we don't support OABI #define SYS_BASE 0x0 #define SYS_exit (SYS_BASE + 1) #define SYS_read (SYS_BASE + 3) #define SYS_write (SYS_BASE + 4) #define SYS_open (SYS_BASE + 5) #define SYS_close (SYS_BASE + 6) #define SYS_sigaltstack (SYS_BASE + 53) #define SYS_munmap (SYS_BASE + 73) #define SYS_madvise (SYS_BASE + 75) #define SYS_setitimer (SYS_BASE + 83) #define SYS_fcntl (SYS_BASE + 92) #define SYS_getrlimit (SYS_BASE + 194) #define SYS___sysctl (SYS_BASE + 202) #define SYS_nanosleep (SYS_BASE + 240) #define SYS_clock_gettime (SYS_BASE + 232) #define SYS_sched_yield (SYS_BASE + 331) #define SYS_sigprocmask (SYS_BASE + 340) #define SYS_kqueue (SYS_BASE + 362) #define SYS_kevent (SYS_BASE + 363) #define SYS_sigaction (SYS_BASE + 416) #define SYS_thr_exit (SYS_BASE + 431) #define SYS_thr_self (SYS_BASE + 432) #define SYS_thr_kill (SYS_BASE + 433) #define SYS__umtx_op (SYS_BASE + 454) #define SYS_thr_new (SYS_BASE + 455) #define SYS_mmap (SYS_BASE + 477) TEXT runtime·sys_umtx_op(SB),NOSPLIT,$0 MOVW 0(FP), R0 MOVW 4(FP), R1 MOVW 8(FP), R2 MOVW 12(FP), R3 ADD $20, R13 // arg 5 is passed on stack MOVW $SYS__umtx_op, R7 SWI $0 SUB $20, R13 // BCS error MOVW R0, ret+20(FP) RET TEXT runtime·thr_new(SB),NOSPLIT,$0 MOVW 0(FP), R0 MOVW 4(FP), R1 MOVW $SYS_thr_new, R7 SWI $0 RET TEXT runtime·thr_start(SB),NOSPLIT,$0 // set up g MOVW m_g0(R0), g MOVW R0, g_m(g) BL runtime·emptyfunc(SB) // fault if stack check is wrong BL runtime·mstart(SB) MOVW $2, R8 // crash (not reached) MOVW R8, (R8) RET // Exit the entire program (like C exit) TEXT runtime·exit(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 exit status MOVW $SYS_exit, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET TEXT runtime·exit1(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 exit status MOVW $SYS_thr_exit, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET TEXT runtime·open(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 name MOVW 4(FP), R1 // arg 2 mode MOVW 8(FP), R2 // arg 3 perm MOVW $SYS_open, R7 SWI $0 MOVW R0, ret+12(FP) RET TEXT runtime·read(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 fd MOVW 4(FP), R1 // arg 2 buf MOVW 8(FP), R2 // arg 3 count MOVW $SYS_read, R7 SWI $0 MOVW R0, ret+12(FP) RET TEXT runtime·write(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 fd MOVW 4(FP), R1 // arg 2 buf MOVW 8(FP), R2 // arg 3 count MOVW $SYS_write, R7 SWI $0 MOVW R0, ret+12(FP) RET TEXT runtime·close(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 fd MOVW $SYS_close, R7 SWI $0 MOVW R0, ret+4(FP) RET TEXT runtime·getrlimit(SB),NOSPLIT,$-8 MOVW 0(FP), R0 MOVW 4(FP), R1 MOVW $SYS_getrlimit, R7 SWI $0 MOVW R0, ret+8(FP) RET TEXT runtime·raise(SB),NOSPLIT,$8 // thr_self(&4(R13)) MOVW $4(R13), R0 // arg 1 &4(R13) MOVW $SYS_thr_self, R7 SWI $0 // thr_kill(self, SIGPIPE) MOVW 4(R13), R0 // arg 1 id MOVW sig+0(FP), R1 // arg 2 - signal MOVW $SYS_thr_kill, R7 SWI $0 RET TEXT runtime·setitimer(SB), NOSPLIT, $-8 MOVW 0(FP), R0 MOVW 4(FP), R1 MOVW 8(FP), R2 MOVW $SYS_setitimer, R7 SWI $0 RET // func now() (sec int64, nsec int32) TEXT time·now(SB), NOSPLIT, $32 MOVW $0, R0 // CLOCK_REALTIME MOVW $8(R13), R1 MOVW $SYS_clock_gettime, R7 SWI $0 MOVW 8(R13), R0 // sec.low MOVW 12(R13), R1 // sec.high MOVW 16(R13), R2 // nsec MOVW R0, 0(FP) MOVW R1, 4(FP) MOVW R2, 8(FP) RET // int64 nanotime(void) so really // void nanotime(int64 *nsec) TEXT runtime·nanotime(SB), NOSPLIT, $32 // We can use CLOCK_MONOTONIC_FAST here when we drop // support for FreeBSD 8-STABLE. MOVW $4, R0 // CLOCK_MONOTONIC MOVW $8(R13), R1 MOVW $SYS_clock_gettime, R7 SWI $0 MOVW 8(R13), R0 // sec.low MOVW 12(R13), R4 // sec.high MOVW 16(R13), R2 // nsec MOVW $1000000000, R3 MULLU R0, R3, (R1, R0) MUL R3, R4 ADD.S R2, R0 ADC R4, R1 MOVW R0, ret_lo+0(FP) MOVW R1, ret_hi+4(FP) RET TEXT runtime·sigaction(SB),NOSPLIT,$-8 MOVW 0(FP), R0 // arg 1 sig MOVW 4(FP), R1 // arg 2 act MOVW 8(FP), R2 // arg 3 oact MOVW $SYS_sigaction, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET TEXT runtime·sigtramp(SB),NOSPLIT,$24 // this might be called in external code context, // where g is not set. // first save R0, because runtime·load_g will clobber it MOVW R0, 4(R13) // signum MOVB runtime·iscgo(SB), R0 CMP $0, R0 BL.NE runtime·load_g(SB) CMP $0, g BNE 4(PC) // signal number is already prepared in 4(R13) MOVW $runtime·badsignal(SB), R11 BL (R11) RET // save g MOVW g, R4 MOVW g, 20(R13) // g = m->signal MOVW g_m(g), R8 MOVW m_gsignal(R8), g // R0 is already saved MOVW R1, 8(R13) // info MOVW R2, 12(R13) // context MOVW R4, 16(R13) // oldg BL runtime·sighandler(SB) // restore g MOVW 20(R13), g RET TEXT runtime·mmap(SB),NOSPLIT,$16 MOVW 0(FP), R0 // arg 1 addr MOVW 4(FP), R1 // arg 2 len MOVW 8(FP), R2 // arg 3 prot MOVW 12(FP), R3 // arg 4 flags // arg 5 (fid) and arg6 (offset_lo, offset_hi) are passed on stack // note the C runtime only passes the 32-bit offset_lo to us MOVW 16(FP), R4 // arg 5 MOVW R4, 4(R13) MOVW 20(FP), R5 // arg 6 lower 32-bit // the word at 8(R13) is skipped due to 64-bit argument alignment. MOVW R5, 12(R13) MOVW $0, R6 // higher 32-bit for arg 6 MOVW R6, 16(R13) ADD $4, R13 MOVW $SYS_mmap, R7 SWI $0 SUB $4, R13 // TODO(dfc) error checking ? MOVW R0, ret+24(FP) RET TEXT runtime·munmap(SB),NOSPLIT,$0 MOVW 0(FP), R0 // arg 1 addr MOVW 4(FP), R1 // arg 2 len MOVW $SYS_munmap, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET TEXT runtime·madvise(SB),NOSPLIT,$0 MOVW 0(FP), R0 // arg 1 addr MOVW 4(FP), R1 // arg 2 len MOVW 8(FP), R2 // arg 3 flags MOVW $SYS_madvise, R7 SWI $0 // ignore failure - maybe pages are locked RET TEXT runtime·sigaltstack(SB),NOSPLIT,$-8 MOVW new+0(FP), R0 MOVW old+4(FP), R1 MOVW $SYS_sigaltstack, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET TEXT runtime·usleep(SB),NOSPLIT,$16 MOVW usec+0(FP), R0 MOVW R0, R2 MOVW $1000000, R1 DIV R1, R0 // 0(R13) is the saved LR, don't use it MOVW R0, 4(R13) // tv_sec.low MOVW $0, R0 MOVW R0, 8(R13) // tv_sec.high MOD R1, R2 MOVW $1000, R1 MUL R1, R2 MOVW R2, 12(R13) // tv_nsec MOVW $4(R13), R0 // arg 1 - rqtp MOVW $0, R1 // arg 2 - rmtp MOVW $SYS_nanosleep, R7 SWI $0 RET TEXT runtime·sysctl(SB),NOSPLIT,$0 MOVW 0(FP), R0 // arg 1 - name MOVW 4(FP), R1 // arg 2 - namelen MOVW 8(FP), R2 // arg 3 - old MOVW 12(FP), R3 // arg 4 - oldlenp // arg 5 (newp) and arg 6 (newlen) are passed on stack ADD $20, R13 MOVW $SYS___sysctl, R7 SWI $0 SUB.CS $0, R0, R0 SUB $20, R13 MOVW R0, ret+24(FP) RET TEXT runtime·osyield(SB),NOSPLIT,$-4 MOVW $SYS_sched_yield, R7 SWI $0 RET TEXT runtime·sigprocmask(SB),NOSPLIT,$0 MOVW $3, R0 // arg 1 - how (SIG_SETMASK) MOVW 0(FP), R1 // arg 2 - set MOVW 4(FP), R2 // arg 3 - oset MOVW $SYS_sigprocmask, R7 SWI $0 MOVW.CS $0, R8 // crash on syscall failure MOVW.CS R8, (R8) RET // int32 runtime·kqueue(void) TEXT runtime·kqueue(SB),NOSPLIT,$0 MOVW $SYS_kqueue, R7 SWI $0 RSB.CS $0, R0 MOVW R0, ret+0(FP) RET // int32 runtime·kevent(int kq, Kevent *changelist, int nchanges, Kevent *eventlist, int nevents, Timespec *timeout) TEXT runtime·kevent(SB),NOSPLIT,$0 MOVW 0(FP), R0 // kq MOVW 4(FP), R1 // changelist MOVW 8(FP), R2 // nchanges MOVW 12(FP), R3 // eventlist ADD $20, R13 // pass arg 5 and 6 on stack MOVW $SYS_kevent, R7 SWI $0 RSB.CS $0, R0 SUB $20, R13 MOVW R0, ret+24(FP) RET // void runtime·closeonexec(int32 fd) TEXT runtime·closeonexec(SB),NOSPLIT,$0 MOVW 0(FP), R0 // fd MOVW $2, R1 // F_SETFD MOVW $1, R2 // FD_CLOEXEC MOVW $SYS_fcntl, R7 SWI $0 RET TEXT runtime·casp(SB),NOSPLIT,$0 B runtime·cas(SB) // TODO(minux): this is only valid for ARMv6+ // bool armcas(int32 *val, int32 old, int32 new) // Atomically: // if(*val == old){ // *val = new; // return 1; // }else // return 0; TEXT runtime·cas(SB),NOSPLIT,$0 B runtime·armcas(SB) // TODO(minux): this only supports ARMv6K+. TEXT runtime·read_tls_fallback(SB),NOSPLIT,$-4 WORD $0xee1d0f70 // mrc p15, 0, r0, c13, c0, 3 RET