qemu/linux-user/ppc/signal.c

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/*
* Emulation of Linux signals
*
* Copyright (c) 2003 Fabrice Bellard
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "qemu.h"
#include "signal-common.h"
#include "linux-user/trace.h"
/* Size of dummy stack frame allocated when calling signal handler.
See arch/powerpc/include/asm/ptrace.h. */
#if defined(TARGET_PPC64)
#define SIGNAL_FRAMESIZE 128
#else
#define SIGNAL_FRAMESIZE 64
#endif
/* See arch/powerpc/include/asm/ucontext.h. Only used for 32-bit PPC;
on 64-bit PPC, sigcontext and mcontext are one and the same. */
struct target_mcontext {
target_ulong mc_gregs[48];
/* Includes fpscr. */
uint64_t mc_fregs[33];
#if defined(TARGET_PPC64)
/* Pointer to the vector regs */
target_ulong v_regs;
/*
* On ppc64, this mcontext structure is naturally *unaligned*,
* or rather it is aligned on a 8 bytes boundary but not on
* a 16 byte boundary. This pad fixes it up. This is why we
* cannot use ppc_avr_t, which would force alignment. This is
* also why the vector regs are referenced in the ABI by the
* v_regs pointer above so any amount of padding can be added here.
*/
target_ulong pad;
/* VSCR and VRSAVE are saved separately. Also reserve space for VSX. */
struct {
uint64_t altivec[34 + 16][2];
} mc_vregs;
#else
target_ulong mc_pad[2];
/* We need to handle Altivec and SPE at the same time, which no
kernel needs to do. Fortunately, the kernel defines this bit to
be Altivec-register-large all the time, rather than trying to
twiddle it based on the specific platform. */
union {
/* SPE vector registers. One extra for SPEFSCR. */
uint32_t spe[33];
/*
* Altivec vector registers. One extra for VRSAVE.
* On ppc32, we are already aligned to 16 bytes. We could
* use ppc_avr_t, but choose to share the same type as ppc64.
*/
uint64_t altivec[33][2];
} mc_vregs;
#endif
};
/* See arch/powerpc/include/asm/sigcontext.h. */
struct target_sigcontext {
target_ulong _unused[4];
int32_t signal;
#if defined(TARGET_PPC64)
int32_t pad0;
#endif
target_ulong handler;
target_ulong oldmask;
target_ulong regs; /* struct pt_regs __user * */
#if defined(TARGET_PPC64)
struct target_mcontext mcontext;
#endif
};
/* Indices for target_mcontext.mc_gregs, below.
See arch/powerpc/include/asm/ptrace.h for details. */
enum {
TARGET_PT_R0 = 0,
TARGET_PT_R1 = 1,
TARGET_PT_R2 = 2,
TARGET_PT_R3 = 3,
TARGET_PT_R4 = 4,
TARGET_PT_R5 = 5,
TARGET_PT_R6 = 6,
TARGET_PT_R7 = 7,
TARGET_PT_R8 = 8,
TARGET_PT_R9 = 9,
TARGET_PT_R10 = 10,
TARGET_PT_R11 = 11,
TARGET_PT_R12 = 12,
TARGET_PT_R13 = 13,
TARGET_PT_R14 = 14,
TARGET_PT_R15 = 15,
TARGET_PT_R16 = 16,
TARGET_PT_R17 = 17,
TARGET_PT_R18 = 18,
TARGET_PT_R19 = 19,
TARGET_PT_R20 = 20,
TARGET_PT_R21 = 21,
TARGET_PT_R22 = 22,
TARGET_PT_R23 = 23,
TARGET_PT_R24 = 24,
TARGET_PT_R25 = 25,
TARGET_PT_R26 = 26,
TARGET_PT_R27 = 27,
TARGET_PT_R28 = 28,
TARGET_PT_R29 = 29,
TARGET_PT_R30 = 30,
TARGET_PT_R31 = 31,
TARGET_PT_NIP = 32,
TARGET_PT_MSR = 33,
TARGET_PT_ORIG_R3 = 34,
TARGET_PT_CTR = 35,
TARGET_PT_LNK = 36,
TARGET_PT_XER = 37,
TARGET_PT_CCR = 38,
/* Yes, there are two registers with #39. One is 64-bit only. */
TARGET_PT_MQ = 39,
TARGET_PT_SOFTE = 39,
TARGET_PT_TRAP = 40,
TARGET_PT_DAR = 41,
TARGET_PT_DSISR = 42,
TARGET_PT_RESULT = 43,
TARGET_PT_REGS_COUNT = 44
};
struct target_ucontext {
target_ulong tuc_flags;
target_ulong tuc_link; /* ucontext_t __user * */
struct target_sigaltstack tuc_stack;
#if !defined(TARGET_PPC64)
int32_t tuc_pad[7];
target_ulong tuc_regs; /* struct mcontext __user *
points to uc_mcontext field */
#endif
target_sigset_t tuc_sigmask;
#if defined(TARGET_PPC64)
target_sigset_t unused[15]; /* Allow for uc_sigmask growth */
struct target_sigcontext tuc_sigcontext;
#else
int32_t tuc_maskext[30];
int32_t tuc_pad2[3];
struct target_mcontext tuc_mcontext;
#endif
};
/* See arch/powerpc/kernel/signal_32.c. */
struct target_sigframe {
struct target_sigcontext sctx;
struct target_mcontext mctx;
int32_t abigap[56];
};
#if defined(TARGET_PPC64)
#define TARGET_TRAMP_SIZE 6
struct target_rt_sigframe {
/* sys_rt_sigreturn requires the ucontext be the first field */
struct target_ucontext uc;
target_ulong _unused[2];
uint32_t trampoline[TARGET_TRAMP_SIZE];
target_ulong pinfo; /* struct siginfo __user * */
target_ulong puc; /* void __user * */
struct target_siginfo info;
/* 64 bit ABI allows for 288 bytes below sp before decrementing it. */
char abigap[288];
} __attribute__((aligned(16)));
#else
struct target_rt_sigframe {
struct target_siginfo info;
struct target_ucontext uc;
int32_t abigap[56];
};
#endif
#if defined(TARGET_PPC64)
struct target_func_ptr {
target_ulong entry;
target_ulong toc;
};
#endif
/* We use the mc_pad field for the signal return trampoline. */
#define tramp mc_pad
/* See arch/powerpc/kernel/signal.c. */
static target_ulong get_sigframe(struct target_sigaction *ka,
CPUPPCState *env,
int frame_size)
{
target_ulong oldsp;
oldsp = target_sigsp(get_sp_from_cpustate(env), ka);
return (oldsp - frame_size) & ~0xFUL;
}
#if ((defined(TARGET_WORDS_BIGENDIAN) && defined(HOST_WORDS_BIGENDIAN)) || \
(!defined(HOST_WORDS_BIGENDIAN) && !defined(TARGET_WORDS_BIGENDIAN)))
#define PPC_VEC_HI 0
#define PPC_VEC_LO 1
#else
#define PPC_VEC_HI 1
#define PPC_VEC_LO 0
#endif
static void save_user_regs(CPUPPCState *env, struct target_mcontext *frame)
{
target_ulong msr = env->msr;
int i;
target_ulong ccr = 0;
/* In general, the kernel attempts to be intelligent about what it
needs to save for Altivec/FP/SPE registers. We don't care that
much, so we just go ahead and save everything. */
/* Save general registers. */
for (i = 0; i < ARRAY_SIZE(env->gpr); i++) {
__put_user(env->gpr[i], &frame->mc_gregs[i]);
}
__put_user(env->nip, &frame->mc_gregs[TARGET_PT_NIP]);
__put_user(env->ctr, &frame->mc_gregs[TARGET_PT_CTR]);
__put_user(env->lr, &frame->mc_gregs[TARGET_PT_LNK]);
__put_user(env->xer, &frame->mc_gregs[TARGET_PT_XER]);
for (i = 0; i < ARRAY_SIZE(env->crf); i++) {
ccr |= env->crf[i] << (32 - ((i + 1) * 4));
}
__put_user(ccr, &frame->mc_gregs[TARGET_PT_CCR]);
/* Save Altivec registers if necessary. */
if (env->insns_flags & PPC_ALTIVEC) {
uint32_t *vrsave;
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
ppc_avr_t *avr = cpu_avr_ptr(env, i);
ppc_avr_t *vreg = (ppc_avr_t *)&frame->mc_vregs.altivec[i];
__put_user(avr->u64[PPC_VEC_HI], &vreg->u64[0]);
__put_user(avr->u64[PPC_VEC_LO], &vreg->u64[1]);
}
#if defined(TARGET_PPC64)
vrsave = (uint32_t *)&frame->mc_vregs.altivec[33];
/* 64-bit needs to put a pointer to the vectors in the frame */
__put_user(h2g(frame->mc_vregs.altivec), &frame->v_regs);
#else
vrsave = (uint32_t *)&frame->mc_vregs.altivec[32];
#endif
__put_user((uint32_t)env->spr[SPR_VRSAVE], vrsave);
}
#if defined(TARGET_PPC64)
/* Save VSX second halves */
if (env->insns_flags2 & PPC2_VSX) {
uint64_t *vsregs = (uint64_t *)&frame->mc_vregs.altivec[34];
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
uint64_t *vsrl = cpu_vsrl_ptr(env, i);
__put_user(*vsrl, &vsregs[i]);
}
}
#endif
/* Save floating point registers. */
if (env->insns_flags & PPC_FLOAT) {
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
uint64_t *fpr = cpu_fpr_ptr(env, i);
__put_user(*fpr, &frame->mc_fregs[i]);
}
__put_user((uint64_t) env->fpscr, &frame->mc_fregs[32]);
}
#if !defined(TARGET_PPC64)
/* Save SPE registers. The kernel only saves the high half. */
if (env->insns_flags & PPC_SPE) {
for (i = 0; i < ARRAY_SIZE(env->gprh); i++) {
__put_user(env->gprh[i], &frame->mc_vregs.spe[i]);
}
__put_user(env->spe_fscr, &frame->mc_vregs.spe[32]);
}
#endif
/* Store MSR. */
__put_user(msr, &frame->mc_gregs[TARGET_PT_MSR]);
}
static void encode_trampoline(int sigret, uint32_t *tramp)
{
/* Set up the sigreturn trampoline: li r0,sigret; sc. */
if (sigret) {
__put_user(0x38000000 | sigret, &tramp[0]);
__put_user(0x44000002, &tramp[1]);
}
}
static void restore_user_regs(CPUPPCState *env,
struct target_mcontext *frame, int sig)
{
target_ulong save_r2 = 0;
target_ulong msr;
target_ulong ccr;
int i;
if (!sig) {
save_r2 = env->gpr[2];
}
/* Restore general registers. */
for (i = 0; i < ARRAY_SIZE(env->gpr); i++) {
__get_user(env->gpr[i], &frame->mc_gregs[i]);
}
__get_user(env->nip, &frame->mc_gregs[TARGET_PT_NIP]);
__get_user(env->ctr, &frame->mc_gregs[TARGET_PT_CTR]);
__get_user(env->lr, &frame->mc_gregs[TARGET_PT_LNK]);
__get_user(env->xer, &frame->mc_gregs[TARGET_PT_XER]);
__get_user(ccr, &frame->mc_gregs[TARGET_PT_CCR]);
for (i = 0; i < ARRAY_SIZE(env->crf); i++) {
env->crf[i] = (ccr >> (32 - ((i + 1) * 4))) & 0xf;
}
if (!sig) {
env->gpr[2] = save_r2;
}
/* Restore MSR. */
__get_user(msr, &frame->mc_gregs[TARGET_PT_MSR]);
/* If doing signal return, restore the previous little-endian mode. */
if (sig) {
ppc_store_msr(env, ((env->msr & ~(1ull << MSR_LE)) |
(msr & (1ull << MSR_LE))));
}
/* Restore Altivec registers if necessary. */
if (env->insns_flags & PPC_ALTIVEC) {
ppc_avr_t *v_regs;
uint32_t *vrsave;
#if defined(TARGET_PPC64)
uint64_t v_addr;
/* 64-bit needs to recover the pointer to the vectors from the frame */
__get_user(v_addr, &frame->v_regs);
v_regs = g2h(env_cpu(env), v_addr);
#else
v_regs = (ppc_avr_t *)frame->mc_vregs.altivec;
#endif
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
ppc_avr_t *avr = cpu_avr_ptr(env, i);
ppc_avr_t *vreg = &v_regs[i];
__get_user(avr->u64[PPC_VEC_HI], &vreg->u64[0]);
__get_user(avr->u64[PPC_VEC_LO], &vreg->u64[1]);
}
#if defined(TARGET_PPC64)
vrsave = (uint32_t *)&v_regs[33];
#else
vrsave = (uint32_t *)&v_regs[32];
#endif
__get_user(env->spr[SPR_VRSAVE], vrsave);
}
#if defined(TARGET_PPC64)
/* Restore VSX second halves */
if (env->insns_flags2 & PPC2_VSX) {
uint64_t *vsregs = (uint64_t *)&frame->mc_vregs.altivec[34];
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
uint64_t *vsrl = cpu_vsrl_ptr(env, i);
__get_user(*vsrl, &vsregs[i]);
}
}
#endif
/* Restore floating point registers. */
if (env->insns_flags & PPC_FLOAT) {
uint64_t fpscr;
target/ppc: move FP and VMX registers into aligned vsr register array The VSX register array is a block of 64 128-bit registers where the first 32 registers consist of the existing 64-bit FP registers extended to 128-bit using new VSR registers, and the last 32 registers are the VMX 128-bit registers as show below: 64-bit 64-bit +--------------------+--------------------+ | FP0 | | VSR0 +--------------------+--------------------+ | FP1 | | VSR1 +--------------------+--------------------+ | ... | ... | ... +--------------------+--------------------+ | FP30 | | VSR30 +--------------------+--------------------+ | FP31 | | VSR31 +--------------------+--------------------+ | VMX0 | VSR32 +-----------------------------------------+ | VMX1 | VSR33 +-----------------------------------------+ | ... | ... +-----------------------------------------+ | VMX30 | VSR62 +-----------------------------------------+ | VMX31 | VSR63 +-----------------------------------------+ In order to allow for future conversion of VSX instructions to use TCG vector operations, recreate the same layout using an aligned version of the existing vsr register array. Since the old fpr and avr register arrays are removed, the existing callers must also be updated to use the correct offset in the vsr register array. This also includes switching the relevant VMState fields over to using subarrays to make sure that migration is preserved. Signed-off-by: Mark Cave-Ayland <mark.cave-ayland@ilande.co.uk> Reviewed-by: Richard Henderson <richard.henderson@linaro.org> Acked-by: David Gibson <david@gibson.dropbear.id.au> Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
2019-01-02 12:14:22 +03:00
for (i = 0; i < 32; i++) {
uint64_t *fpr = cpu_fpr_ptr(env, i);
__get_user(*fpr, &frame->mc_fregs[i]);
}
__get_user(fpscr, &frame->mc_fregs[32]);
env->fpscr = (uint32_t) fpscr;
}
#if !defined(TARGET_PPC64)
/* Save SPE registers. The kernel only saves the high half. */
if (env->insns_flags & PPC_SPE) {
for (i = 0; i < ARRAY_SIZE(env->gprh); i++) {
__get_user(env->gprh[i], &frame->mc_vregs.spe[i]);
}
__get_user(env->spe_fscr, &frame->mc_vregs.spe[32]);
}
#endif
}
#if !defined(TARGET_PPC64)
void setup_frame(int sig, struct target_sigaction *ka,
target_sigset_t *set, CPUPPCState *env)
{
struct target_sigframe *frame;
struct target_sigcontext *sc;
target_ulong frame_addr, newsp;
int err = 0;
frame_addr = get_sigframe(ka, env, sizeof(*frame));
trace_user_setup_frame(env, frame_addr);
if (!lock_user_struct(VERIFY_WRITE, frame, frame_addr, 1))
goto sigsegv;
sc = &frame->sctx;
__put_user(ka->_sa_handler, &sc->handler);
__put_user(set->sig[0], &sc->oldmask);
__put_user(set->sig[1], &sc->_unused[3]);
__put_user(h2g(&frame->mctx), &sc->regs);
__put_user(sig, &sc->signal);
/* Save user regs. */
save_user_regs(env, &frame->mctx);
/* Construct the trampoline code on the stack. */
encode_trampoline(TARGET_NR_sigreturn, (uint32_t *)&frame->mctx.tramp);
/* The kernel checks for the presence of a VDSO here. We don't
emulate a vdso, so use a sigreturn system call. */
env->lr = (target_ulong) h2g(frame->mctx.tramp);
/* Turn off all fp exceptions. */
env->fpscr = 0;
/* Create a stack frame for the caller of the handler. */
newsp = frame_addr - SIGNAL_FRAMESIZE;
err |= put_user(env->gpr[1], newsp, target_ulong);
if (err)
goto sigsegv;
/* Set up registers for signal handler. */
env->gpr[1] = newsp;
env->gpr[3] = sig;
env->gpr[4] = frame_addr + offsetof(struct target_sigframe, sctx);
env->nip = (target_ulong) ka->_sa_handler;
/* Signal handlers are entered in big-endian mode. */
ppc_store_msr(env, env->msr & ~(1ull << MSR_LE));
unlock_user_struct(frame, frame_addr, 1);
return;
sigsegv:
unlock_user_struct(frame, frame_addr, 1);
force_sigsegv(sig);
}
#endif /* !defined(TARGET_PPC64) */
void setup_rt_frame(int sig, struct target_sigaction *ka,
target_siginfo_t *info,
target_sigset_t *set, CPUPPCState *env)
{
struct target_rt_sigframe *rt_sf;
uint32_t *trampptr = 0;
struct target_mcontext *mctx = 0;
target_ulong rt_sf_addr, newsp = 0;
int i, err = 0;
#if defined(TARGET_PPC64)
struct target_sigcontext *sc = 0;
#if !defined(TARGET_ABI32)
struct image_info *image = ((TaskState *)thread_cpu->opaque)->info;
#endif
#endif
rt_sf_addr = get_sigframe(ka, env, sizeof(*rt_sf));
if (!lock_user_struct(VERIFY_WRITE, rt_sf, rt_sf_addr, 1))
goto sigsegv;
tswap_siginfo(&rt_sf->info, info);
__put_user(0, &rt_sf->uc.tuc_flags);
__put_user(0, &rt_sf->uc.tuc_link);
target_save_altstack(&rt_sf->uc.tuc_stack, env);
#if !defined(TARGET_PPC64)
__put_user(h2g (&rt_sf->uc.tuc_mcontext),
&rt_sf->uc.tuc_regs);
#endif
for(i = 0; i < TARGET_NSIG_WORDS; i++) {
__put_user(set->sig[i], &rt_sf->uc.tuc_sigmask.sig[i]);
}
#if defined(TARGET_PPC64)
mctx = &rt_sf->uc.tuc_sigcontext.mcontext;
trampptr = &rt_sf->trampoline[0];
sc = &rt_sf->uc.tuc_sigcontext;
__put_user(h2g(mctx), &sc->regs);
__put_user(sig, &sc->signal);
#else
mctx = &rt_sf->uc.tuc_mcontext;
trampptr = (uint32_t *)&rt_sf->uc.tuc_mcontext.tramp;
#endif
save_user_regs(env, mctx);
encode_trampoline(TARGET_NR_rt_sigreturn, trampptr);
/* The kernel checks for the presence of a VDSO here. We don't
emulate a vdso, so use a sigreturn system call. */
env->lr = (target_ulong) h2g(trampptr);
/* Turn off all fp exceptions. */
env->fpscr = 0;
/* Create a stack frame for the caller of the handler. */
newsp = rt_sf_addr - (SIGNAL_FRAMESIZE + 16);
err |= put_user(env->gpr[1], newsp, target_ulong);
if (err)
goto sigsegv;
/* Set up registers for signal handler. */
env->gpr[1] = newsp;
env->gpr[3] = (target_ulong) sig;
env->gpr[4] = (target_ulong) h2g(&rt_sf->info);
env->gpr[5] = (target_ulong) h2g(&rt_sf->uc);
env->gpr[6] = (target_ulong) h2g(rt_sf);
#if defined(TARGET_PPC64) && !defined(TARGET_ABI32)
if (get_ppc64_abi(image) < 2) {
/* ELFv1 PPC64 function pointers are pointers to OPD entries. */
struct target_func_ptr *handler =
(struct target_func_ptr *)g2h(env_cpu(env), ka->_sa_handler);
env->nip = tswapl(handler->entry);
env->gpr[2] = tswapl(handler->toc);
} else {
/* ELFv2 PPC64 function pointers are entry points. R12 must also be set. */
env->gpr[12] = env->nip = ka->_sa_handler;
}
#else
env->nip = (target_ulong) ka->_sa_handler;
#endif
#ifdef TARGET_WORDS_BIGENDIAN
/* Signal handlers are entered in big-endian mode. */
ppc_store_msr(env, env->msr & ~(1ull << MSR_LE));
#else
/* Signal handlers are entered in little-endian mode. */
ppc_store_msr(env, env->msr | (1ull << MSR_LE));
#endif
unlock_user_struct(rt_sf, rt_sf_addr, 1);
return;
sigsegv:
unlock_user_struct(rt_sf, rt_sf_addr, 1);
force_sigsegv(sig);
}
#if !defined(TARGET_PPC64) || defined(TARGET_ABI32)
long do_sigreturn(CPUPPCState *env)
{
struct target_sigcontext *sc = NULL;
struct target_mcontext *sr = NULL;
target_ulong sr_addr = 0, sc_addr;
sigset_t blocked;
target_sigset_t set;
sc_addr = env->gpr[1] + SIGNAL_FRAMESIZE;
if (!lock_user_struct(VERIFY_READ, sc, sc_addr, 1))
goto sigsegv;
#if defined(TARGET_PPC64)
set.sig[0] = sc->oldmask + ((uint64_t)(sc->_unused[3]) << 32);
#else
__get_user(set.sig[0], &sc->oldmask);
__get_user(set.sig[1], &sc->_unused[3]);
#endif
target_to_host_sigset_internal(&blocked, &set);
set_sigmask(&blocked);
__get_user(sr_addr, &sc->regs);
if (!lock_user_struct(VERIFY_READ, sr, sr_addr, 1))
goto sigsegv;
restore_user_regs(env, sr, 1);
unlock_user_struct(sr, sr_addr, 1);
unlock_user_struct(sc, sc_addr, 1);
return -TARGET_QEMU_ESIGRETURN;
sigsegv:
unlock_user_struct(sr, sr_addr, 1);
unlock_user_struct(sc, sc_addr, 1);
force_sig(TARGET_SIGSEGV);
return -TARGET_QEMU_ESIGRETURN;
}
#endif /* !defined(TARGET_PPC64) */
/* See arch/powerpc/kernel/signal_32.c. */
static int do_setcontext(struct target_ucontext *ucp, CPUPPCState *env, int sig)
{
struct target_mcontext *mcp;
target_ulong mcp_addr;
sigset_t blocked;
target_sigset_t set;
if (copy_from_user(&set, h2g(ucp) + offsetof(struct target_ucontext, tuc_sigmask),
sizeof (set)))
return 1;
#if defined(TARGET_PPC64)
mcp_addr = h2g(ucp) +
offsetof(struct target_ucontext, tuc_sigcontext.mcontext);
#else
__get_user(mcp_addr, &ucp->tuc_regs);
#endif
if (!lock_user_struct(VERIFY_READ, mcp, mcp_addr, 1))
return 1;
target_to_host_sigset_internal(&blocked, &set);
set_sigmask(&blocked);
restore_user_regs(env, mcp, sig);
unlock_user_struct(mcp, mcp_addr, 1);
return 0;
}
long do_rt_sigreturn(CPUPPCState *env)
{
struct target_rt_sigframe *rt_sf = NULL;
target_ulong rt_sf_addr;
rt_sf_addr = env->gpr[1] + SIGNAL_FRAMESIZE + 16;
if (!lock_user_struct(VERIFY_READ, rt_sf, rt_sf_addr, 1))
goto sigsegv;
if (do_setcontext(&rt_sf->uc, env, 1))
goto sigsegv;
target_restore_altstack(&rt_sf->uc.tuc_stack, env);
unlock_user_struct(rt_sf, rt_sf_addr, 1);
return -TARGET_QEMU_ESIGRETURN;
sigsegv:
unlock_user_struct(rt_sf, rt_sf_addr, 1);
force_sig(TARGET_SIGSEGV);
return -TARGET_QEMU_ESIGRETURN;
}
/* This syscall implements {get,set,swap}context for userland. */
abi_long do_swapcontext(CPUArchState *env, abi_ulong uold_ctx,
abi_ulong unew_ctx, abi_long ctx_size)
{
struct target_ucontext *uctx;
struct target_mcontext *mctx;
/* For ppc32, ctx_size is "reserved for future use".
* For ppc64, we do not yet support the VSX extension.
*/
if (ctx_size < sizeof(struct target_ucontext)) {
return -TARGET_EINVAL;
}
if (uold_ctx) {
TaskState *ts = (TaskState *)thread_cpu->opaque;
if (!lock_user_struct(VERIFY_WRITE, uctx, uold_ctx, 1)) {
return -TARGET_EFAULT;
}
#ifdef TARGET_PPC64
mctx = &uctx->tuc_sigcontext.mcontext;
#else
/* ??? The kernel aligns the pointer down here into padding, but
* in setup_rt_frame we don't. Be self-compatible for now.
*/
mctx = &uctx->tuc_mcontext;
__put_user(h2g(mctx), &uctx->tuc_regs);
#endif
save_user_regs(env, mctx);
host_to_target_sigset(&uctx->tuc_sigmask, &ts->signal_mask);
unlock_user_struct(uctx, uold_ctx, 1);
}
if (unew_ctx) {
int err;
if (!lock_user_struct(VERIFY_READ, uctx, unew_ctx, 1)) {
return -TARGET_EFAULT;
}
err = do_setcontext(uctx, env, 0);
unlock_user_struct(uctx, unew_ctx, 1);
if (err) {
/* We cannot return to a partially updated context. */
force_sig(TARGET_SIGSEGV);
}
return -TARGET_QEMU_ESIGRETURN;
}
return 0;
}