Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Chen-Yu Tsai | 3294 | 90.59% | 6 | 42.86% |
Mylène Josserand | 304 | 8.36% | 4 | 28.57% |
Ondrej Jirman | 18 | 0.50% | 1 | 7.14% |
Stefan Wahren | 13 | 0.36% | 2 | 14.29% |
Wen Yang | 7 | 0.19% | 1 | 7.14% |
Total | 3636 | 14 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (c) 2018 Chen-Yu Tsai * * Chen-Yu Tsai <wens@csie.org> * * arch/arm/mach-sunxi/mc_smp.c * * Based on Allwinner code, arch/arm/mach-exynos/mcpm-exynos.c, and * arch/arm/mach-hisi/platmcpm.c * Cluster cache enable trampoline code adapted from MCPM framework */ #include <linux/arm-cci.h> #include <linux/cpu_pm.h> #include <linux/delay.h> #include <linux/io.h> #include <linux/iopoll.h> #include <linux/irqchip/arm-gic.h> #include <linux/of.h> #include <linux/of_address.h> #include <linux/smp.h> #include <asm/cacheflush.h> #include <asm/cp15.h> #include <asm/cputype.h> #include <asm/idmap.h> #include <asm/smp_plat.h> #include <asm/suspend.h> #define SUNXI_CPUS_PER_CLUSTER 4 #define SUNXI_NR_CLUSTERS 2 #define POLL_USEC 100 #define TIMEOUT_USEC 100000 #define CPUCFG_CX_CTRL_REG0(c) (0x10 * (c)) #define CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE(n) BIT(n) #define CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE_ALL 0xf #define CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A7 BIT(4) #define CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A15 BIT(0) #define CPUCFG_CX_CTRL_REG1(c) (0x10 * (c) + 0x4) #define CPUCFG_CX_CTRL_REG1_ACINACTM BIT(0) #define CPUCFG_CX_STATUS(c) (0x30 + 0x4 * (c)) #define CPUCFG_CX_STATUS_STANDBYWFI(n) BIT(16 + (n)) #define CPUCFG_CX_STATUS_STANDBYWFIL2 BIT(0) #define CPUCFG_CX_RST_CTRL(c) (0x80 + 0x4 * (c)) #define CPUCFG_CX_RST_CTRL_DBG_SOC_RST BIT(24) #define CPUCFG_CX_RST_CTRL_ETM_RST(n) BIT(20 + (n)) #define CPUCFG_CX_RST_CTRL_ETM_RST_ALL (0xf << 20) #define CPUCFG_CX_RST_CTRL_DBG_RST(n) BIT(16 + (n)) #define CPUCFG_CX_RST_CTRL_DBG_RST_ALL (0xf << 16) #define CPUCFG_CX_RST_CTRL_H_RST BIT(12) #define CPUCFG_CX_RST_CTRL_L2_RST BIT(8) #define CPUCFG_CX_RST_CTRL_CX_RST(n) BIT(4 + (n)) #define CPUCFG_CX_RST_CTRL_CORE_RST(n) BIT(n) #define CPUCFG_CX_RST_CTRL_CORE_RST_ALL (0xf << 0) #define PRCM_CPU_PO_RST_CTRL(c) (0x4 + 0x4 * (c)) #define PRCM_CPU_PO_RST_CTRL_CORE(n) BIT(n) #define PRCM_CPU_PO_RST_CTRL_CORE_ALL 0xf #define PRCM_PWROFF_GATING_REG(c) (0x100 + 0x4 * (c)) /* The power off register for clusters are different from a80 and a83t */ #define PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I BIT(0) #define PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I BIT(4) #define PRCM_PWROFF_GATING_REG_CORE(n) BIT(n) #define PRCM_PWR_SWITCH_REG(c, cpu) (0x140 + 0x10 * (c) + 0x4 * (cpu)) #define PRCM_CPU_SOFT_ENTRY_REG 0x164 /* R_CPUCFG registers, specific to sun8i-a83t */ #define R_CPUCFG_CLUSTER_PO_RST_CTRL(c) (0x30 + (c) * 0x4) #define R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(n) BIT(n) #define R_CPUCFG_CPU_SOFT_ENTRY_REG 0x01a4 #define CPU0_SUPPORT_HOTPLUG_MAGIC0 0xFA50392F #define CPU0_SUPPORT_HOTPLUG_MAGIC1 0x790DCA3A static void __iomem *cpucfg_base; static void __iomem *prcm_base; static void __iomem *sram_b_smp_base; static void __iomem *r_cpucfg_base; extern void sunxi_mc_smp_secondary_startup(void); extern void sunxi_mc_smp_resume(void); static bool is_a83t; static bool sunxi_core_is_cortex_a15(unsigned int core, unsigned int cluster) { struct device_node *node; int cpu = cluster * SUNXI_CPUS_PER_CLUSTER + core; bool is_compatible; node = of_cpu_device_node_get(cpu); /* In case of_cpu_device_node_get fails */ if (!node) node = of_get_cpu_node(cpu, NULL); if (!node) { /* * There's no point in returning an error, since we * would be mid way in a core or cluster power sequence. */ pr_err("%s: Couldn't get CPU cluster %u core %u device node\n", __func__, cluster, core); return false; } is_compatible = of_device_is_compatible(node, "arm,cortex-a15"); of_node_put(node); return is_compatible; } static int sunxi_cpu_power_switch_set(unsigned int cpu, unsigned int cluster, bool enable) { u32 reg; /* control sequence from Allwinner A80 user manual v1.2 PRCM section */ reg = readl(prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); if (enable) { if (reg == 0x00) { pr_debug("power clamp for cluster %u cpu %u already open\n", cluster, cpu); return 0; } writel(0xff, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); writel(0xfe, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); writel(0xf8, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); writel(0xf0, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); writel(0x00, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); } else { writel(0xff, prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu)); udelay(10); } return 0; } static void sunxi_cpu0_hotplug_support_set(bool enable) { if (enable) { writel(CPU0_SUPPORT_HOTPLUG_MAGIC0, sram_b_smp_base); writel(CPU0_SUPPORT_HOTPLUG_MAGIC1, sram_b_smp_base + 0x4); } else { writel(0x0, sram_b_smp_base); writel(0x0, sram_b_smp_base + 0x4); } } static int sunxi_cpu_powerup(unsigned int cpu, unsigned int cluster) { u32 reg; pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu); if (cpu >= SUNXI_CPUS_PER_CLUSTER || cluster >= SUNXI_NR_CLUSTERS) return -EINVAL; /* Set hotplug support magic flags for cpu0 */ if (cluster == 0 && cpu == 0) sunxi_cpu0_hotplug_support_set(true); /* assert processor power-on reset */ reg = readl(prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); reg &= ~PRCM_CPU_PO_RST_CTRL_CORE(cpu); writel(reg, prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); if (is_a83t) { /* assert cpu power-on reset */ reg = readl(r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); reg &= ~(R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(cpu)); writel(reg, r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); udelay(10); } /* Cortex-A7: hold L1 reset disable signal low */ if (!sunxi_core_is_cortex_a15(cpu, cluster)) { reg = readl(cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster)); reg &= ~CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE(cpu); writel(reg, cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster)); } /* assert processor related resets */ reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg &= ~CPUCFG_CX_RST_CTRL_DBG_RST(cpu); /* * Allwinner code also asserts resets for NEON on A15. According * to ARM manuals, asserting power-on reset is sufficient. */ if (!sunxi_core_is_cortex_a15(cpu, cluster)) reg &= ~CPUCFG_CX_RST_CTRL_ETM_RST(cpu); writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); /* open power switch */ sunxi_cpu_power_switch_set(cpu, cluster, true); /* Handle A83T bit swap */ if (is_a83t) { if (cpu == 0) cpu = 4; } /* clear processor power gate */ reg = readl(prcm_base + PRCM_PWROFF_GATING_REG(cluster)); reg &= ~PRCM_PWROFF_GATING_REG_CORE(cpu); writel(reg, prcm_base + PRCM_PWROFF_GATING_REG(cluster)); udelay(20); /* Handle A83T bit swap */ if (is_a83t) { if (cpu == 4) cpu = 0; } /* de-assert processor power-on reset */ reg = readl(prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); reg |= PRCM_CPU_PO_RST_CTRL_CORE(cpu); writel(reg, prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); if (is_a83t) { reg = readl(r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); reg |= R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(cpu); writel(reg, r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); udelay(10); } /* de-assert all processor resets */ reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg |= CPUCFG_CX_RST_CTRL_DBG_RST(cpu); reg |= CPUCFG_CX_RST_CTRL_CORE_RST(cpu); if (!sunxi_core_is_cortex_a15(cpu, cluster)) reg |= CPUCFG_CX_RST_CTRL_ETM_RST(cpu); else reg |= CPUCFG_CX_RST_CTRL_CX_RST(cpu); /* NEON */ writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); return 0; } static int sunxi_cluster_powerup(unsigned int cluster) { u32 reg; pr_debug("%s: cluster %u\n", __func__, cluster); if (cluster >= SUNXI_NR_CLUSTERS) return -EINVAL; /* For A83T, assert cluster cores resets */ if (is_a83t) { reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg &= ~CPUCFG_CX_RST_CTRL_CORE_RST_ALL; /* Core Reset */ writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); udelay(10); } /* assert ACINACTM */ reg = readl(cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); reg |= CPUCFG_CX_CTRL_REG1_ACINACTM; writel(reg, cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); /* assert cluster processor power-on resets */ reg = readl(prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); reg &= ~PRCM_CPU_PO_RST_CTRL_CORE_ALL; writel(reg, prcm_base + PRCM_CPU_PO_RST_CTRL(cluster)); /* assert cluster cores resets */ if (is_a83t) { reg = readl(r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); reg &= ~CPUCFG_CX_RST_CTRL_CORE_RST_ALL; writel(reg, r_cpucfg_base + R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster)); udelay(10); } /* assert cluster resets */ reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg &= ~CPUCFG_CX_RST_CTRL_DBG_SOC_RST; reg &= ~CPUCFG_CX_RST_CTRL_DBG_RST_ALL; reg &= ~CPUCFG_CX_RST_CTRL_H_RST; reg &= ~CPUCFG_CX_RST_CTRL_L2_RST; /* * Allwinner code also asserts resets for NEON on A15. According * to ARM manuals, asserting power-on reset is sufficient. */ if (!sunxi_core_is_cortex_a15(0, cluster)) reg &= ~CPUCFG_CX_RST_CTRL_ETM_RST_ALL; writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); /* hold L1/L2 reset disable signals low */ reg = readl(cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster)); if (sunxi_core_is_cortex_a15(0, cluster)) { /* Cortex-A15: hold L2RSTDISABLE low */ reg &= ~CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A15; } else { /* Cortex-A7: hold L1RSTDISABLE and L2RSTDISABLE low */ reg &= ~CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE_ALL; reg &= ~CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A7; } writel(reg, cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster)); /* clear cluster power gate */ reg = readl(prcm_base + PRCM_PWROFF_GATING_REG(cluster)); if (is_a83t) reg &= ~PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I; else reg &= ~PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I; writel(reg, prcm_base + PRCM_PWROFF_GATING_REG(cluster)); udelay(20); /* de-assert cluster resets */ reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg |= CPUCFG_CX_RST_CTRL_DBG_SOC_RST; reg |= CPUCFG_CX_RST_CTRL_H_RST; reg |= CPUCFG_CX_RST_CTRL_L2_RST; writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); /* de-assert ACINACTM */ reg = readl(cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); reg &= ~CPUCFG_CX_CTRL_REG1_ACINACTM; writel(reg, cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); return 0; } /* * This bit is shared between the initial nocache_trampoline call to * enable CCI-400 and proper cluster cache disable before power down. */ static void sunxi_cluster_cache_disable_without_axi(void) { if (read_cpuid_part() == ARM_CPU_PART_CORTEX_A15) { /* * On the Cortex-A15 we need to disable * L2 prefetching before flushing the cache. */ asm volatile( "mcr p15, 1, %0, c15, c0, 3\n" "isb\n" "dsb" : : "r" (0x400)); } /* Flush all cache levels for this cluster. */ v7_exit_coherency_flush(all); /* * Disable cluster-level coherency by masking * incoming snoops and DVM messages: */ cci_disable_port_by_cpu(read_cpuid_mpidr()); } static int sunxi_mc_smp_cpu_table[SUNXI_NR_CLUSTERS][SUNXI_CPUS_PER_CLUSTER]; int sunxi_mc_smp_first_comer; static DEFINE_SPINLOCK(boot_lock); static bool sunxi_mc_smp_cluster_is_down(unsigned int cluster) { int i; for (i = 0; i < SUNXI_CPUS_PER_CLUSTER; i++) if (sunxi_mc_smp_cpu_table[cluster][i]) return false; return true; } static void sunxi_mc_smp_secondary_init(unsigned int cpu) { /* Clear hotplug support magic flags for cpu0 */ if (cpu == 0) sunxi_cpu0_hotplug_support_set(false); } static int sunxi_mc_smp_boot_secondary(unsigned int l_cpu, struct task_struct *idle) { unsigned int mpidr, cpu, cluster; mpidr = cpu_logical_map(l_cpu); cpu = MPIDR_AFFINITY_LEVEL(mpidr, 0); cluster = MPIDR_AFFINITY_LEVEL(mpidr, 1); if (!cpucfg_base) return -ENODEV; if (cluster >= SUNXI_NR_CLUSTERS || cpu >= SUNXI_CPUS_PER_CLUSTER) return -EINVAL; spin_lock_irq(&boot_lock); if (sunxi_mc_smp_cpu_table[cluster][cpu]) goto out; if (sunxi_mc_smp_cluster_is_down(cluster)) { sunxi_mc_smp_first_comer = true; sunxi_cluster_powerup(cluster); } else { sunxi_mc_smp_first_comer = false; } /* This is read by incoming CPUs with their cache and MMU disabled */ sync_cache_w(&sunxi_mc_smp_first_comer); sunxi_cpu_powerup(cpu, cluster); out: sunxi_mc_smp_cpu_table[cluster][cpu]++; spin_unlock_irq(&boot_lock); return 0; } #ifdef CONFIG_HOTPLUG_CPU static void sunxi_cluster_cache_disable(void) { unsigned int cluster = MPIDR_AFFINITY_LEVEL(read_cpuid_mpidr(), 1); u32 reg; pr_debug("%s: cluster %u\n", __func__, cluster); sunxi_cluster_cache_disable_without_axi(); /* last man standing, assert ACINACTM */ reg = readl(cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); reg |= CPUCFG_CX_CTRL_REG1_ACINACTM; writel(reg, cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster)); } static void sunxi_mc_smp_cpu_die(unsigned int l_cpu) { unsigned int mpidr, cpu, cluster; bool last_man; mpidr = cpu_logical_map(l_cpu); cpu = MPIDR_AFFINITY_LEVEL(mpidr, 0); cluster = MPIDR_AFFINITY_LEVEL(mpidr, 1); pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu); spin_lock(&boot_lock); sunxi_mc_smp_cpu_table[cluster][cpu]--; if (sunxi_mc_smp_cpu_table[cluster][cpu] == 1) { /* A power_up request went ahead of us. */ pr_debug("%s: aborting due to a power up request\n", __func__); spin_unlock(&boot_lock); return; } else if (sunxi_mc_smp_cpu_table[cluster][cpu] > 1) { pr_err("Cluster %d CPU%d boots multiple times\n", cluster, cpu); BUG(); } last_man = sunxi_mc_smp_cluster_is_down(cluster); spin_unlock(&boot_lock); gic_cpu_if_down(0); if (last_man) sunxi_cluster_cache_disable(); else v7_exit_coherency_flush(louis); for (;;) wfi(); } static int sunxi_cpu_powerdown(unsigned int cpu, unsigned int cluster) { u32 reg; int gating_bit = cpu; pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu); if (cpu >= SUNXI_CPUS_PER_CLUSTER || cluster >= SUNXI_NR_CLUSTERS) return -EINVAL; if (is_a83t && cpu == 0) gating_bit = 4; /* gate processor power */ reg = readl(prcm_base + PRCM_PWROFF_GATING_REG(cluster)); reg |= PRCM_PWROFF_GATING_REG_CORE(gating_bit); writel(reg, prcm_base + PRCM_PWROFF_GATING_REG(cluster)); udelay(20); /* close power switch */ sunxi_cpu_power_switch_set(cpu, cluster, false); return 0; } static int sunxi_cluster_powerdown(unsigned int cluster) { u32 reg; pr_debug("%s: cluster %u\n", __func__, cluster); if (cluster >= SUNXI_NR_CLUSTERS) return -EINVAL; /* assert cluster resets or system will hang */ pr_debug("%s: assert cluster reset\n", __func__); reg = readl(cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); reg &= ~CPUCFG_CX_RST_CTRL_DBG_SOC_RST; reg &= ~CPUCFG_CX_RST_CTRL_H_RST; reg &= ~CPUCFG_CX_RST_CTRL_L2_RST; writel(reg, cpucfg_base + CPUCFG_CX_RST_CTRL(cluster)); /* gate cluster power */ pr_debug("%s: gate cluster power\n", __func__); reg = readl(prcm_base + PRCM_PWROFF_GATING_REG(cluster)); if (is_a83t) reg |= PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I; else reg |= PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I; writel(reg, prcm_base + PRCM_PWROFF_GATING_REG(cluster)); udelay(20); return 0; } static int sunxi_mc_smp_cpu_kill(unsigned int l_cpu) { unsigned int mpidr, cpu, cluster; unsigned int tries, count; int ret = 0; u32 reg; mpidr = cpu_logical_map(l_cpu); cpu = MPIDR_AFFINITY_LEVEL(mpidr, 0); cluster = MPIDR_AFFINITY_LEVEL(mpidr, 1); /* This should never happen */ if (WARN_ON(cluster >= SUNXI_NR_CLUSTERS || cpu >= SUNXI_CPUS_PER_CLUSTER)) return 0; /* wait for CPU core to die and enter WFI */ count = TIMEOUT_USEC / POLL_USEC; spin_lock_irq(&boot_lock); for (tries = 0; tries < count; tries++) { spin_unlock_irq(&boot_lock); usleep_range(POLL_USEC / 2, POLL_USEC); spin_lock_irq(&boot_lock); /* * If the user turns off a bunch of cores at the same * time, the kernel might call cpu_kill before some of * them are ready. This is because boot_lock serializes * both cpu_die and cpu_kill callbacks. Either one could * run first. We should wait for cpu_die to complete. */ if (sunxi_mc_smp_cpu_table[cluster][cpu]) continue; reg = readl(cpucfg_base + CPUCFG_CX_STATUS(cluster)); if (reg & CPUCFG_CX_STATUS_STANDBYWFI(cpu)) break; } if (tries >= count) { ret = ETIMEDOUT; goto out; } /* power down CPU core */ sunxi_cpu_powerdown(cpu, cluster); if (!sunxi_mc_smp_cluster_is_down(cluster)) goto out; /* wait for cluster L2 WFI */ ret = readl_poll_timeout(cpucfg_base + CPUCFG_CX_STATUS(cluster), reg, reg & CPUCFG_CX_STATUS_STANDBYWFIL2, POLL_USEC, TIMEOUT_USEC); if (ret) { /* * Ignore timeout on the cluster. Leaving the cluster on * will not affect system execution, just use a bit more * power. But returning an error here will only confuse * the user as the CPU has already been shutdown. */ ret = 0; goto out; } /* Power down cluster */ sunxi_cluster_powerdown(cluster); out: spin_unlock_irq(&boot_lock); pr_debug("%s: cluster %u cpu %u powerdown: %d\n", __func__, cluster, cpu, ret); return !ret; } static bool sunxi_mc_smp_cpu_can_disable(unsigned int cpu) { /* CPU0 hotplug not handled for sun8i-a83t */ if (is_a83t) if (cpu == 0) return false; return true; } #endif static const struct smp_operations sunxi_mc_smp_smp_ops __initconst = { .smp_secondary_init = sunxi_mc_smp_secondary_init, .smp_boot_secondary = sunxi_mc_smp_boot_secondary, #ifdef CONFIG_HOTPLUG_CPU .cpu_die = sunxi_mc_smp_cpu_die, .cpu_kill = sunxi_mc_smp_cpu_kill, .cpu_can_disable = sunxi_mc_smp_cpu_can_disable, #endif }; static bool __init sunxi_mc_smp_cpu_table_init(void) { unsigned int mpidr, cpu, cluster; mpidr = read_cpuid_mpidr(); cpu = MPIDR_AFFINITY_LEVEL(mpidr, 0); cluster = MPIDR_AFFINITY_LEVEL(mpidr, 1); if (cluster >= SUNXI_NR_CLUSTERS || cpu >= SUNXI_CPUS_PER_CLUSTER) { pr_err("%s: boot CPU is out of bounds!\n", __func__); return false; } sunxi_mc_smp_cpu_table[cluster][cpu] = 1; return true; } /* * Adapted from arch/arm/common/mc_smp_entry.c * * We need the trampoline code to enable CCI-400 on the first cluster */ typedef typeof(cpu_reset) phys_reset_t; static int __init nocache_trampoline(unsigned long __unused) { phys_reset_t phys_reset; setup_mm_for_reboot(); sunxi_cluster_cache_disable_without_axi(); phys_reset = (phys_reset_t)(unsigned long)__pa_symbol(cpu_reset); phys_reset(__pa_symbol(sunxi_mc_smp_resume), false); BUG(); } static int __init sunxi_mc_smp_loopback(void) { int ret; /* * We're going to soft-restart the current CPU through the * low-level MCPM code by leveraging the suspend/resume * infrastructure. Let's play it safe by using cpu_pm_enter() * in case the CPU init code path resets the VFP or similar. */ sunxi_mc_smp_first_comer = true; local_irq_disable(); local_fiq_disable(); ret = cpu_pm_enter(); if (!ret) { ret = cpu_suspend(0, nocache_trampoline); cpu_pm_exit(); } local_fiq_enable(); local_irq_enable(); sunxi_mc_smp_first_comer = false; return ret; } /* * This holds any device nodes that we requested resources for, * so that we may easily release resources in the error path. */ struct sunxi_mc_smp_nodes { struct device_node *prcm_node; struct device_node *cpucfg_node; struct device_node *sram_node; struct device_node *r_cpucfg_node; }; /* This structure holds SoC-specific bits tied to an enable-method string. */ struct sunxi_mc_smp_data { const char *enable_method; int (*get_smp_nodes)(struct sunxi_mc_smp_nodes *nodes); bool is_a83t; }; static void __init sunxi_mc_smp_put_nodes(struct sunxi_mc_smp_nodes *nodes) { of_node_put(nodes->prcm_node); of_node_put(nodes->cpucfg_node); of_node_put(nodes->sram_node); of_node_put(nodes->r_cpucfg_node); memset(nodes, 0, sizeof(*nodes)); } static int __init sun9i_a80_get_smp_nodes(struct sunxi_mc_smp_nodes *nodes) { nodes->prcm_node = of_find_compatible_node(NULL, NULL, "allwinner,sun9i-a80-prcm"); if (!nodes->prcm_node) { pr_err("%s: PRCM not available\n", __func__); return -ENODEV; } nodes->cpucfg_node = of_find_compatible_node(NULL, NULL, "allwinner,sun9i-a80-cpucfg"); if (!nodes->cpucfg_node) { pr_err("%s: CPUCFG not available\n", __func__); return -ENODEV; } nodes->sram_node = of_find_compatible_node(NULL, NULL, "allwinner,sun9i-a80-smp-sram"); if (!nodes->sram_node) { pr_err("%s: Secure SRAM not available\n", __func__); return -ENODEV; } return 0; } static int __init sun8i_a83t_get_smp_nodes(struct sunxi_mc_smp_nodes *nodes) { nodes->prcm_node = of_find_compatible_node(NULL, NULL, "allwinner,sun8i-a83t-r-ccu"); if (!nodes->prcm_node) { pr_err("%s: PRCM not available\n", __func__); return -ENODEV; } nodes->cpucfg_node = of_find_compatible_node(NULL, NULL, "allwinner,sun8i-a83t-cpucfg"); if (!nodes->cpucfg_node) { pr_err("%s: CPUCFG not available\n", __func__); return -ENODEV; } nodes->r_cpucfg_node = of_find_compatible_node(NULL, NULL, "allwinner,sun8i-a83t-r-cpucfg"); if (!nodes->r_cpucfg_node) { pr_err("%s: RCPUCFG not available\n", __func__); return -ENODEV; } return 0; } static const struct sunxi_mc_smp_data sunxi_mc_smp_data[] __initconst = { { .enable_method = "allwinner,sun9i-a80-smp", .get_smp_nodes = sun9i_a80_get_smp_nodes, }, { .enable_method = "allwinner,sun8i-a83t-smp", .get_smp_nodes = sun8i_a83t_get_smp_nodes, .is_a83t = true, }, }; static int __init sunxi_mc_smp_init(void) { struct sunxi_mc_smp_nodes nodes = { 0 }; struct device_node *node; struct resource res; void __iomem *addr; int i, ret; /* * Don't bother checking the "cpus" node, as an enable-method * property in that node is undocumented. */ node = of_cpu_device_node_get(0); if (!node) return -ENODEV; /* * We can't actually use the enable-method magic in the kernel. * Our loopback / trampoline code uses the CPU suspend framework, * which requires the identity mapping be available. It would not * yet be available if we used the .init_cpus or .prepare_cpus * callbacks in smp_operations, which we would use if we were to * use CPU_METHOD_OF_DECLARE */ for (i = 0; i < ARRAY_SIZE(sunxi_mc_smp_data); i++) { ret = of_property_match_string(node, "enable-method", sunxi_mc_smp_data[i].enable_method); if (ret >= 0) break; } of_node_put(node); if (ret < 0) return -ENODEV; is_a83t = sunxi_mc_smp_data[i].is_a83t; if (!sunxi_mc_smp_cpu_table_init()) return -EINVAL; if (!cci_probed()) { pr_err("%s: CCI-400 not available\n", __func__); return -ENODEV; } /* Get needed device tree nodes */ ret = sunxi_mc_smp_data[i].get_smp_nodes(&nodes); if (ret) goto err_put_nodes; /* * Unfortunately we can not request the I/O region for the PRCM. * It is shared with the PRCM clock. */ prcm_base = of_iomap(nodes.prcm_node, 0); if (!prcm_base) { pr_err("%s: failed to map PRCM registers\n", __func__); ret = -ENOMEM; goto err_put_nodes; } cpucfg_base = of_io_request_and_map(nodes.cpucfg_node, 0, "sunxi-mc-smp"); if (IS_ERR(cpucfg_base)) { ret = PTR_ERR(cpucfg_base); pr_err("%s: failed to map CPUCFG registers: %d\n", __func__, ret); goto err_unmap_prcm; } if (is_a83t) { r_cpucfg_base = of_io_request_and_map(nodes.r_cpucfg_node, 0, "sunxi-mc-smp"); if (IS_ERR(r_cpucfg_base)) { ret = PTR_ERR(r_cpucfg_base); pr_err("%s: failed to map R-CPUCFG registers\n", __func__); goto err_unmap_release_cpucfg; } } else { sram_b_smp_base = of_io_request_and_map(nodes.sram_node, 0, "sunxi-mc-smp"); if (IS_ERR(sram_b_smp_base)) { ret = PTR_ERR(sram_b_smp_base); pr_err("%s: failed to map secure SRAM\n", __func__); goto err_unmap_release_cpucfg; } } /* Configure CCI-400 for boot cluster */ ret = sunxi_mc_smp_loopback(); if (ret) { pr_err("%s: failed to configure boot cluster: %d\n", __func__, ret); goto err_unmap_release_sram_rcpucfg; } /* We don't need the device nodes anymore */ sunxi_mc_smp_put_nodes(&nodes); /* Set the hardware entry point address */ if (is_a83t) addr = r_cpucfg_base + R_CPUCFG_CPU_SOFT_ENTRY_REG; else addr = prcm_base + PRCM_CPU_SOFT_ENTRY_REG; writel(__pa_symbol(sunxi_mc_smp_secondary_startup), addr); /* Actually enable multi cluster SMP */ smp_set_ops(&sunxi_mc_smp_smp_ops); pr_info("sunxi multi cluster SMP support installed\n"); return 0; err_unmap_release_sram_rcpucfg: if (is_a83t) { iounmap(r_cpucfg_base); of_address_to_resource(nodes.r_cpucfg_node, 0, &res); } else { iounmap(sram_b_smp_base); of_address_to_resource(nodes.sram_node, 0, &res); } release_mem_region(res.start, resource_size(&res)); err_unmap_release_cpucfg: iounmap(cpucfg_base); of_address_to_resource(nodes.cpucfg_node, 0, &res); release_mem_region(res.start, resource_size(&res)); err_unmap_prcm: iounmap(prcm_base); err_put_nodes: sunxi_mc_smp_put_nodes(&nodes); return ret; } early_initcall(sunxi_mc_smp_init);
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