/* * Copyright (c) 2021 BayLibre SAS * Written by: Nicolas Pitre * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include /* to be found in fpu.S */ extern void z_arm64_fpu_save(struct z_arm64_fp_context *saved_fp_context); extern void z_arm64_fpu_restore(struct z_arm64_fp_context *saved_fp_context); #define FPU_DEBUG 0 #if FPU_DEBUG /* * Debug traces have to be produced without printk() or any other functions * using a va_list as va_start() always copy the FPU registers that could be * used to pass float arguments, and that triggers an FPU access trap. */ #include static void DBG(char *msg, struct k_thread *th) { char buf[80], *p; unsigned int v; strcpy(buf, "CPU# exc# "); buf[3] = '0' + _current_cpu->id; buf[8] = '0' + arch_exception_depth(); strcat(buf, _current->name); strcat(buf, ": "); strcat(buf, msg); strcat(buf, " "); strcat(buf, th->name); v = *(unsigned char *)&th->arch.saved_fp_context; p = buf + strlen(buf); *p++ = ' '; *p++ = ((v >> 4) < 10) ? ((v >> 4) + '0') : ((v >> 4) - 10 + 'a'); *p++ = ((v & 15) < 10) ? ((v & 15) + '0') : ((v & 15) - 10 + 'a'); *p++ = '\n'; *p = 0; k_str_out(buf, p - buf); } #else static inline void DBG(char *msg, struct k_thread *t) { } #endif /* FPU_DEBUG */ /* * Flush FPU content and disable access. * This is called locally and also from flush_fpu_ipi_handler(). */ void z_arm64_flush_local_fpu(void) { __ASSERT(read_daif() & DAIF_IRQ_BIT, "must be called with IRQs disabled"); struct k_thread *owner = _current_cpu->arch.fpu_owner; if (owner != NULL) { uint64_t cpacr = read_cpacr_el1(); /* turn on FPU access */ write_cpacr_el1(cpacr | CPACR_EL1_FPEN_NOTRAP); isb(); /* save current owner's content */ z_arm64_fpu_save(&owner->arch.saved_fp_context); /* make sure content made it to memory before releasing */ dsb(); /* release ownership */ _current_cpu->arch.fpu_owner = NULL; DBG("disable", owner); /* disable FPU access */ write_cpacr_el1(cpacr & ~CPACR_EL1_FPEN_NOTRAP); } } #ifdef CONFIG_SMP static void flush_owned_fpu(struct k_thread *thread) { __ASSERT(read_daif() & DAIF_IRQ_BIT, "must be called with IRQs disabled"); int i; /* search all CPUs for the owner we want */ for (i = 0; i < CONFIG_MP_NUM_CPUS; i++) { if (_kernel.cpus[i].arch.fpu_owner != thread) { continue; } /* we found it live on CPU i */ if (i == _current_cpu->id) { z_arm64_flush_local_fpu(); } else { /* the FPU context is live on another CPU */ z_arm64_flush_fpu_ipi(i); /* * Wait for it only if this is about the thread * currently running on this CPU. Otherwise the * other CPU running some other thread could regain * ownership the moment it is removed from it and * we would be stuck here. * * Also, if this is for the thread running on this * CPU, then we preemptively flush any live context * on this CPU as well since we're likely to * replace it, and this avoids a deadlock where * two CPUs want to pull each other's FPU context. */ if (thread == _current) { z_arm64_flush_local_fpu(); while (_kernel.cpus[i].arch.fpu_owner == thread) { dsb(); } } } break; } } #endif void z_arm64_fpu_enter_exc(void) { __ASSERT(read_daif() & DAIF_IRQ_BIT, "must be called with IRQs disabled"); /* always deny FPU access whenever an exception is entered */ write_cpacr_el1(read_cpacr_el1() & ~CPACR_EL1_FPEN_NOTRAP); isb(); } /* * Simulate some FPU store instructions. * * In many cases, the FPU trap is triggered by va_start() that copies * the content of FP registers used for floating point argument passing * into the va_list object in case there were actual float arguments from * the caller. In practice this is almost never the case, especially if * FPU access is disabled and we're trapped while in exception context. * Rather than flushing the FPU context to its owner and enabling access * just to let the corresponding STR instructions execute, we simply * simulate them and leave the FPU access disabled. This also avoids the * need for disabling interrupts in syscalls and IRQ handlers as well. */ static bool simulate_str_q_insn(z_arch_esf_t *esf) { /* * Support only the "FP in exception" cases for now. * We know there is no saved FPU context to check nor any * userspace stack memory to validate in that case. */ if (arch_exception_depth() <= 1) { return false; } uint32_t *pc = (uint32_t *)esf->elr; /* The original (interrupted) sp is the top of the esf structure */ uintptr_t sp = (uintptr_t)esf + sizeof(*esf); for (;;) { uint32_t insn = *pc; /* * We're looking for STR (immediate, SIMD&FP) of the form: * * STR Q, [SP, #] * * where 0 <= <= 7 and is a 12-bits multiple of 16. */ if ((insn & 0xffc003f8) != 0x3d8003e0) break; uint32_t pimm = (insn >> 10) & 0xfff; /* Zero the location as the above STR would have done */ *(__int128 *)(sp + pimm * 16) = 0; /* move to the next instruction */ pc++; } /* did we do something? */ if (pc != (uint32_t *)esf->elr) { /* resume execution past the simulated instructions */ esf->elr = (uintptr_t)pc; return true; } return false; } /* * Process the FPU trap. * * This usually means that FP regs belong to another thread. Save them * to that thread's save area and restore the current thread's content. * * We also get here when FP regs are used while in exception as FP access * is always disabled by default in that case. If so we save the FPU content * to the owning thread and simply enable FPU access. Exceptions should be * short and don't have persistent register contexts when they're done so * there is nothing to save/restore for that context... as long as we * don't get interrupted that is. To ensure that we mask interrupts to * the triggering exception context. */ void z_arm64_fpu_trap(z_arch_esf_t *esf) { __ASSERT(read_daif() & DAIF_IRQ_BIT, "must be called with IRQs disabled"); /* check if a quick simulation can do it */ if (simulate_str_q_insn(esf)) { return; } /* turn on FPU access */ write_cpacr_el1(read_cpacr_el1() | CPACR_EL1_FPEN_NOTRAP); isb(); /* save current owner's content if any */ struct k_thread *owner = _current_cpu->arch.fpu_owner; if (owner) { z_arm64_fpu_save(&owner->arch.saved_fp_context); dsb(); _current_cpu->arch.fpu_owner = NULL; DBG("save", owner); } if (arch_exception_depth() > 1) { /* * We were already in exception when the FPU access trap. * We give it access and prevent any further IRQ recursion * by disabling IRQs as we wouldn't be able to preserve the * interrupted exception's FPU context. */ esf->spsr |= DAIF_IRQ_BIT; return; } #ifdef CONFIG_SMP /* * Make sure the FPU context we need isn't live on another CPU. * The current CPU's FPU context is NULL at this point. */ flush_owned_fpu(_current); #endif /* become new owner */ _current_cpu->arch.fpu_owner = _current; /* restore our content */ z_arm64_fpu_restore(&_current->arch.saved_fp_context); DBG("restore", _current); } /* * Perform lazy FPU context switching by simply granting or denying * access to FP regs based on FPU ownership before leaving the last * exception level. If current thread doesn't own the FP regs then * it will trap on its first access and then the actual FPU context * switching will occur. * * This is called on every exception exit except for z_arm64_fpu_trap(). */ void z_arm64_fpu_exit_exc(void) { __ASSERT(read_daif() & DAIF_IRQ_BIT, "must be called with IRQs disabled"); uint64_t cpacr = read_cpacr_el1(); if (arch_exception_depth() == 1) { /* We're about to leave exception mode */ if (_current_cpu->arch.fpu_owner == _current) { /* turn on FPU access */ write_cpacr_el1(cpacr | CPACR_EL1_FPEN_NOTRAP); } else { /* deny FPU access */ write_cpacr_el1(cpacr & ~CPACR_EL1_FPEN_NOTRAP); } } else { /* * Shallower exception levels should always trap on FPU * access as we want to make sure IRQs are disabled before * granting them access. */ write_cpacr_el1(cpacr & ~CPACR_EL1_FPEN_NOTRAP); } } int arch_float_disable(struct k_thread *thread) { if (thread != NULL) { unsigned int key = arch_irq_lock(); #ifdef CONFIG_SMP flush_owned_fpu(thread); #else if (thread == _current_cpu->arch.fpu_owner) { z_arm64_flush_local_fpu(); } #endif arch_irq_unlock(key); } return 0; } int arch_float_enable(struct k_thread *thread, unsigned int options) { /* floats always gets enabled automatically at the moment */ return 0; }