/* * Copyright (c) 2022 Intel Corporation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define CORE_POWER_CHECK_NUM 128 #define CPU_POWERUP_TIMEOUT_USEC 10000 #define ACE_INTC_IRQ DT_IRQN(DT_NODELABEL(ace_intc)) #if CONFIG_SOC_INTEL_ACE15_MTPM /* .bss is uncached, we further check it below */ uint32_t g_key_read_holder; #endif /* CONFIG_SOC_INTEL_ACE15_MTPM */ static void ipc_isr(void *arg) { uint32_t cpu_id = arch_proc_id(); /* * Clearing the BUSY bits in both TDR and TDA are needed to * complete an IDC message. If we do only one (and not both), * the other side will not be able to send another IDC * message as the hardware still thinks you are processing * the IDC message (and thus will not send another one). * On TDR, it is to write one to clear, while on TDA, it is * to write zero to clear. */ IDC[cpu_id].agents[0].ipc.tdr = BIT(31); IDC[cpu_id].agents[0].ipc.tda = 0; #ifdef CONFIG_SMP void z_sched_ipi(void); z_sched_ipi(); #endif } #define DFIDCCP 0x2020 #define CAP_INST_SHIFT 24 #define CAP_INST_MASK BIT_MASK(4) unsigned int soc_num_cpus; static __imr int soc_num_cpus_init(void) { /* Need to set soc_num_cpus early to arch_num_cpus() works properly */ soc_num_cpus = ((sys_read32(DFIDCCP) >> CAP_INST_SHIFT) & CAP_INST_MASK) + 1; soc_num_cpus = MIN(CONFIG_MP_MAX_NUM_CPUS, soc_num_cpus); return 0; } SYS_INIT(soc_num_cpus_init, EARLY, 1); void soc_mp_init(void) { IRQ_CONNECT(ACE_IRQ_TO_ZEPHYR(ACE_INTL_IDCA), 0, ipc_isr, 0, 0); irq_enable(ACE_IRQ_TO_ZEPHYR(ACE_INTL_IDCA)); unsigned int num_cpus = arch_num_cpus(); for (int i = 0; i < num_cpus; i++) { /* DINT has one bit per IPC, unmask only IPC "Ax" on core "x" */ ACE_DINT[i].ie[ACE_INTL_IDCA] = BIT(i); /* Agent A should signal only BUSY interrupts */ IDC[i].agents[0].ipc.ctl = BIT(0); /* IPCTBIE */ } /* Set the core 0 active */ soc_cpus_active[0] = true; #if CONFIG_SOC_INTEL_ACE15_MTPM #if defined(CONFIG_SMP) && (CONFIG_MP_MAX_NUM_CPUS > 1) /* * Only when more than 1 CPUs is enabled, then this is in uncached area. * Otherwise, this is in cached area and will fail this test. */ __ASSERT(!sys_cache_is_ptr_cached(&g_key_read_holder), "g_key_read_holder must be uncached"); #endif /* defined(CONFIG_SMP) && (CONFIG_MP_MAX_NUM_CPUS > 1) */ g_key_read_holder = INTEL_ADSP_ACE15_MAGIC_KEY; #endif /* CONFIG_SOC_INTEL_ACE15_MTPM */ } static int host_runtime_get(void) { return pm_device_runtime_get(INTEL_ADSP_HST_DOMAIN_DEV); } SYS_INIT(host_runtime_get, POST_KERNEL, 99); #ifdef CONFIG_ADSP_IMR_CONTEXT_SAVE /* * Called after exiting D3 state when context restore is enabled. * Re-enables IDC interrupt again for all cores. Called once from core 0. */ void soc_mp_on_d3_exit(void) { soc_mp_init(); } #endif void soc_start_core(int cpu_num) { int retry = CORE_POWER_CHECK_NUM; if (cpu_num > 0) { /* Initialize the ROM jump address */ uint32_t *rom_jump_vector = (uint32_t *) ROM_JUMP_ADDR; #if CONFIG_PM extern void dsp_restore_vector(void); /* We need to find out what type of booting is taking place here. Secondary cores * can be disabled and enabled multiple times during runtime. During kernel * initialization, the next pm state is set to ACTIVE. This way we can determine * whether the core is being turned on again or for the first time. */ if (pm_state_next_get(cpu_num)->state == PM_STATE_ACTIVE) { *rom_jump_vector = (uint32_t) z_soc_mp_asm_entry; } else { *rom_jump_vector = (uint32_t) dsp_restore_vector; } #else *rom_jump_vector = (uint32_t) z_soc_mp_asm_entry; #endif sys_cache_data_flush_range(rom_jump_vector, sizeof(*rom_jump_vector)); soc_cpu_power_up(cpu_num); if (!WAIT_FOR(soc_cpu_is_powered(cpu_num), CPU_POWERUP_TIMEOUT_USEC, k_busy_wait(HW_STATE_CHECK_DELAY))) { k_panic(); } /* Tell the ACE ROM that it should use secondary core flow */ DSPCS.bootctl[cpu_num].battr |= DSPBR_BATTR_LPSCTL_BATTR_SLAVE_CORE; } /* Setting the Power Active bit to the off state before powering up the core. This step is * required by the HW if we are starting core for a second time. Without this sequence, the * core will not power on properly when doing transition D0->D3->D0. */ DSPCS.capctl[cpu_num].ctl &= ~DSPCS_CTL_SPA; /* Checking current power status of the core. */ if (!WAIT_FOR((DSPCS.capctl[cpu_num].ctl & DSPCS_CTL_CPA) != DSPCS_CTL_CPA, CPU_POWERUP_TIMEOUT_USEC, k_busy_wait(HW_STATE_CHECK_DELAY))) { k_panic(); } DSPCS.capctl[cpu_num].ctl |= DSPCS_CTL_SPA; /* Waiting for power up */ while (((DSPCS.capctl[cpu_num].ctl & DSPCS_CTL_CPA) != DSPCS_CTL_CPA) && (retry > 0)) { k_busy_wait(HW_STATE_CHECK_DELAY); retry--; } if (retry == 0) { __ASSERT(false, "%s secondary core has not powered up", __func__); } } void soc_mp_startup(uint32_t cpu) { /* Must have this enabled always */ xtensa_irq_enable(ACE_INTC_IRQ); #if CONFIG_ADSP_IDLE_CLOCK_GATING /* Disable idle power gating */ DSPCS.bootctl[cpu].bctl |= DSPBR_BCTL_WAITIPPG; #else /* Disable idle power and clock gating */ DSPCS.bootctl[cpu].bctl |= DSPBR_BCTL_WAITIPCG | DSPBR_BCTL_WAITIPPG; #endif /* CONFIG_ADSP_IDLE_CLOCK_GATING */ } void arch_sched_ipi(void) { uint32_t curr = arch_proc_id(); /* Signal agent B[n] to cause an interrupt from agent A[n] */ unsigned int num_cpus = arch_num_cpus(); for (int core = 0; core < num_cpus; core++) { if (core != curr && soc_cpus_active[core]) { IDC[core].agents[1].ipc.idr = INTEL_ADSP_IPC_BUSY; } } } #if CONFIG_MP_MAX_NUM_CPUS > 1 int soc_adsp_halt_cpu(int id) { int retry = CORE_POWER_CHECK_NUM; CHECKIF(arch_proc_id() != 0) { return -EINVAL; } CHECKIF(id <= 0 || id >= arch_num_cpus()) { return -EINVAL; } CHECKIF(soc_cpus_active[id]) { return -EINVAL; } DSPCS.capctl[id].ctl &= ~DSPCS_CTL_SPA; /* Waiting for power off */ while (((DSPCS.capctl[id].ctl & DSPCS_CTL_CPA) == DSPCS_CTL_CPA) && (retry > 0)) { k_busy_wait(HW_STATE_CHECK_DELAY); retry--; } if (retry == 0) { __ASSERT(false, "%s secondary core has not powered down", __func__); return -EINVAL; } soc_cpu_power_down(id); return 0; } #endif