// SPDX-License-Identifier: GPL-2.0-only /* * IOSF-SB MailBox Interface Driver * Copyright (c) 2013, Intel Corporation. * * The IOSF-SB is a fabric bus available on Atom based SOC's that uses a * mailbox interface (MBI) to communicate with multiple devices. This * driver implements access to this interface for those platforms that can * enumerate the device using PCI. */ #include #include #include #include #include #include #include #include #include #include #define PCI_DEVICE_ID_INTEL_BAYTRAIL 0x0F00 #define PCI_DEVICE_ID_INTEL_BRASWELL 0x2280 #define PCI_DEVICE_ID_INTEL_QUARK_X1000 0x0958 #define PCI_DEVICE_ID_INTEL_TANGIER 0x1170 static struct pci_dev *mbi_pdev; static DEFINE_SPINLOCK(iosf_mbi_lock); /**************** Generic iosf_mbi access helpers ****************/ static inline u32 iosf_mbi_form_mcr(u8 op, u8 port, u8 offset) { return (op << 24) | (port << 16) | (offset << 8) | MBI_ENABLE; } static int iosf_mbi_pci_read_mdr(u32 mcrx, u32 mcr, u32 *mdr) { int result; if (!mbi_pdev) return -ENODEV; if (mcrx) { result = pci_write_config_dword(mbi_pdev, MBI_MCRX_OFFSET, mcrx); if (result < 0) goto fail_read; } result = pci_write_config_dword(mbi_pdev, MBI_MCR_OFFSET, mcr); if (result < 0) goto fail_read; result = pci_read_config_dword(mbi_pdev, MBI_MDR_OFFSET, mdr); if (result < 0) goto fail_read; return 0; fail_read: dev_err(&mbi_pdev->dev, "PCI config access failed with %d\n", result); return result; } static int iosf_mbi_pci_write_mdr(u32 mcrx, u32 mcr, u32 mdr) { int result; if (!mbi_pdev) return -ENODEV; result = pci_write_config_dword(mbi_pdev, MBI_MDR_OFFSET, mdr); if (result < 0) goto fail_write; if (mcrx) { result = pci_write_config_dword(mbi_pdev, MBI_MCRX_OFFSET, mcrx); if (result < 0) goto fail_write; } result = pci_write_config_dword(mbi_pdev, MBI_MCR_OFFSET, mcr); if (result < 0) goto fail_write; return 0; fail_write: dev_err(&mbi_pdev->dev, "PCI config access failed with %d\n", result); return result; } int iosf_mbi_read(u8 port, u8 opcode, u32 offset, u32 *mdr) { u32 mcr, mcrx; unsigned long flags; int ret; /* Access to the GFX unit is handled by GPU code */ if (port == BT_MBI_UNIT_GFX) { WARN_ON(1); return -EPERM; } mcr = iosf_mbi_form_mcr(opcode, port, offset & MBI_MASK_LO); mcrx = offset & MBI_MASK_HI; spin_lock_irqsave(&iosf_mbi_lock, flags); ret = iosf_mbi_pci_read_mdr(mcrx, mcr, mdr); spin_unlock_irqrestore(&iosf_mbi_lock, flags); return ret; } EXPORT_SYMBOL(iosf_mbi_read); int iosf_mbi_write(u8 port, u8 opcode, u32 offset, u32 mdr) { u32 mcr, mcrx; unsigned long flags; int ret; /* Access to the GFX unit is handled by GPU code */ if (port == BT_MBI_UNIT_GFX) { WARN_ON(1); return -EPERM; } mcr = iosf_mbi_form_mcr(opcode, port, offset & MBI_MASK_LO); mcrx = offset & MBI_MASK_HI; spin_lock_irqsave(&iosf_mbi_lock, flags); ret = iosf_mbi_pci_write_mdr(mcrx, mcr, mdr); spin_unlock_irqrestore(&iosf_mbi_lock, flags); return ret; } EXPORT_SYMBOL(iosf_mbi_write); int iosf_mbi_modify(u8 port, u8 opcode, u32 offset, u32 mdr, u32 mask) { u32 mcr, mcrx; u32 value; unsigned long flags; int ret; /* Access to the GFX unit is handled by GPU code */ if (port == BT_MBI_UNIT_GFX) { WARN_ON(1); return -EPERM; } mcr = iosf_mbi_form_mcr(opcode, port, offset & MBI_MASK_LO); mcrx = offset & MBI_MASK_HI; spin_lock_irqsave(&iosf_mbi_lock, flags); /* Read current mdr value */ ret = iosf_mbi_pci_read_mdr(mcrx, mcr & MBI_RD_MASK, &value); if (ret < 0) { spin_unlock_irqrestore(&iosf_mbi_lock, flags); return ret; } /* Apply mask */ value &= ~mask; mdr &= mask; value |= mdr; /* Write back */ ret = iosf_mbi_pci_write_mdr(mcrx, mcr | MBI_WR_MASK, value); spin_unlock_irqrestore(&iosf_mbi_lock, flags); return ret; } EXPORT_SYMBOL(iosf_mbi_modify); bool iosf_mbi_available(void) { /* Mbi isn't hot-pluggable. No remove routine is provided */ return mbi_pdev; } EXPORT_SYMBOL(iosf_mbi_available); /* **************** P-Unit/kernel shared I2C bus arbitration **************** * * Some Bay Trail and Cherry Trail devices have the P-Unit and us (the kernel) * share a single I2C bus to the PMIC. Below are helpers to arbitrate the * accesses between the kernel and the P-Unit. * * See arch/x86/include/asm/iosf_mbi.h for kernel-doc text for each function. */ #define SEMAPHORE_TIMEOUT 500 #define PUNIT_SEMAPHORE_BYT 0x7 #define PUNIT_SEMAPHORE_CHT 0x10e #define PUNIT_SEMAPHORE_BIT BIT(0) #define PUNIT_SEMAPHORE_ACQUIRE BIT(1) static DEFINE_MUTEX(iosf_mbi_pmic_access_mutex); static BLOCKING_NOTIFIER_HEAD(iosf_mbi_pmic_bus_access_notifier); static DECLARE_WAIT_QUEUE_HEAD(iosf_mbi_pmic_access_waitq); static u32 iosf_mbi_pmic_punit_access_count; static u32 iosf_mbi_pmic_i2c_access_count; static u32 iosf_mbi_sem_address; static unsigned long iosf_mbi_sem_acquired; static struct pm_qos_request iosf_mbi_pm_qos; void iosf_mbi_punit_acquire(void) { /* Wait for any I2C PMIC accesses from in kernel drivers to finish. */ mutex_lock(&iosf_mbi_pmic_access_mutex); while (iosf_mbi_pmic_i2c_access_count != 0) { mutex_unlock(&iosf_mbi_pmic_access_mutex); wait_event(iosf_mbi_pmic_access_waitq, iosf_mbi_pmic_i2c_access_count == 0); mutex_lock(&iosf_mbi_pmic_access_mutex); } /* * We do not need to do anything to allow the PUNIT to safely access * the PMIC, other then block in kernel accesses to the PMIC. */ iosf_mbi_pmic_punit_access_count++; mutex_unlock(&iosf_mbi_pmic_access_mutex); } EXPORT_SYMBOL(iosf_mbi_punit_acquire); void iosf_mbi_punit_release(void) { bool do_wakeup; mutex_lock(&iosf_mbi_pmic_access_mutex); iosf_mbi_pmic_punit_access_count--; do_wakeup = iosf_mbi_pmic_punit_access_count == 0; mutex_unlock(&iosf_mbi_pmic_access_mutex); if (do_wakeup) wake_up(&iosf_mbi_pmic_access_waitq); } EXPORT_SYMBOL(iosf_mbi_punit_release); static int iosf_mbi_get_sem(u32 *sem) { int ret; ret = iosf_mbi_read(BT_MBI_UNIT_PMC, MBI_REG_READ, iosf_mbi_sem_address, sem); if (ret) { dev_err(&mbi_pdev->dev, "Error P-Unit semaphore read failed\n"); return ret; } *sem &= PUNIT_SEMAPHORE_BIT; return 0; } static void iosf_mbi_reset_semaphore(void) { if (iosf_mbi_modify(BT_MBI_UNIT_PMC, MBI_REG_READ, iosf_mbi_sem_address, 0, PUNIT_SEMAPHORE_BIT)) dev_err(&mbi_pdev->dev, "Error P-Unit semaphore reset failed\n"); cpu_latency_qos_update_request(&iosf_mbi_pm_qos, PM_QOS_DEFAULT_VALUE); blocking_notifier_call_chain(&iosf_mbi_pmic_bus_access_notifier, MBI_PMIC_BUS_ACCESS_END, NULL); } /* * This function blocks P-Unit accesses to the PMIC I2C bus, so that kernel * I2C code, such as e.g. a fuel-gauge driver, can access it safely. * * This function may be called by I2C controller code while an I2C driver has * already blocked P-Unit accesses because it wants them blocked over multiple * i2c-transfers, for e.g. read-modify-write of an I2C client register. * * To allow safe PMIC i2c bus accesses this function takes the following steps: * * 1) Some code sends request to the P-Unit which make it access the PMIC * I2C bus. Testing has shown that the P-Unit does not check its internal * PMIC bus semaphore for these requests. Callers of these requests call * iosf_mbi_punit_acquire()/_release() around their P-Unit accesses, these * functions increase/decrease iosf_mbi_pmic_punit_access_count, so first * we wait for iosf_mbi_pmic_punit_access_count to become 0. * * 2) Check iosf_mbi_pmic_i2c_access_count, if access has already * been blocked by another caller, we only need to increment * iosf_mbi_pmic_i2c_access_count and we can skip the other steps. * * 3) Some code makes such P-Unit requests from atomic contexts where it * cannot call iosf_mbi_punit_acquire() as that may sleep. * As the second step we call a notifier chain which allows any code * needing P-Unit resources from atomic context to acquire them before * we take control over the PMIC I2C bus. * * 4) When CPU cores enter C6 or C7 the P-Unit needs to talk to the PMIC * if this happens while the kernel itself is accessing the PMIC I2C bus * the SoC hangs. * As the third step we call cpu_latency_qos_update_request() to disallow the * CPU to enter C6 or C7. * * 5) The P-Unit has a PMIC bus semaphore which we can request to stop * autonomous P-Unit tasks from accessing the PMIC I2C bus while we hold it. * As the fourth and final step we request this semaphore and wait for our * request to be acknowledged. */ int iosf_mbi_block_punit_i2c_access(void) { unsigned long start, end; int ret = 0; u32 sem; if (WARN_ON(!mbi_pdev || !iosf_mbi_sem_address)) return -ENXIO; mutex_lock(&iosf_mbi_pmic_access_mutex); while (iosf_mbi_pmic_punit_access_count != 0) { mutex_unlock(&iosf_mbi_pmic_access_mutex); wait_event(iosf_mbi_pmic_access_waitq, iosf_mbi_pmic_punit_access_count == 0); mutex_lock(&iosf_mbi_pmic_access_mutex); } if (iosf_mbi_pmic_i2c_access_count > 0) goto success; blocking_notifier_call_chain(&iosf_mbi_pmic_bus_access_notifier, MBI_PMIC_BUS_ACCESS_BEGIN, NULL); /* * Disallow the CPU to enter C6 or C7 state, entering these states * requires the P-Unit to talk to the PMIC and if this happens while * we're holding the semaphore, the SoC hangs. */ cpu_latency_qos_update_request(&iosf_mbi_pm_qos, 0); /* host driver writes to side band semaphore register */ ret = iosf_mbi_write(BT_MBI_UNIT_PMC, MBI_REG_WRITE, iosf_mbi_sem_address, PUNIT_SEMAPHORE_ACQUIRE); if (ret) { dev_err(&mbi_pdev->dev, "Error P-Unit semaphore request failed\n"); goto error; } /* host driver waits for bit 0 to be set in semaphore register */ start = jiffies; end = start + msecs_to_jiffies(SEMAPHORE_TIMEOUT); do { ret = iosf_mbi_get_sem(&sem); if (!ret && sem) { iosf_mbi_sem_acquired = jiffies; dev_dbg(&mbi_pdev->dev, "P-Unit semaphore acquired after %ums\n", jiffies_to_msecs(jiffies - start)); goto success; } usleep_range(1000, 2000); } while (time_before(jiffies, end)); ret = -ETIMEDOUT; dev_err(&mbi_pdev->dev, "Error P-Unit semaphore timed out, resetting\n"); error: iosf_mbi_reset_semaphore(); if (!iosf_mbi_get_sem(&sem)) dev_err(&mbi_pdev->dev, "P-Unit semaphore: %d\n", sem); success: if (!WARN_ON(ret)) iosf_mbi_pmic_i2c_access_count++; mutex_unlock(&iosf_mbi_pmic_access_mutex); return ret; } EXPORT_SYMBOL(iosf_mbi_block_punit_i2c_access); void iosf_mbi_unblock_punit_i2c_access(void) { bool do_wakeup = false; mutex_lock(&iosf_mbi_pmic_access_mutex); iosf_mbi_pmic_i2c_access_count--; if (iosf_mbi_pmic_i2c_access_count == 0) { iosf_mbi_reset_semaphore(); dev_dbg(&mbi_pdev->dev, "punit semaphore held for %ums\n", jiffies_to_msecs(jiffies - iosf_mbi_sem_acquired)); do_wakeup = true; } mutex_unlock(&iosf_mbi_pmic_access_mutex); if (do_wakeup) wake_up(&iosf_mbi_pmic_access_waitq); } EXPORT_SYMBOL(iosf_mbi_unblock_punit_i2c_access); int iosf_mbi_register_pmic_bus_access_notifier(struct notifier_block *nb) { int ret; /* Wait for the bus to go inactive before registering */ iosf_mbi_punit_acquire(); ret = blocking_notifier_chain_register( &iosf_mbi_pmic_bus_access_notifier, nb); iosf_mbi_punit_release(); return ret; } EXPORT_SYMBOL(iosf_mbi_register_pmic_bus_access_notifier); int iosf_mbi_unregister_pmic_bus_access_notifier_unlocked( struct notifier_block *nb) { iosf_mbi_assert_punit_acquired(); return blocking_notifier_chain_unregister( &iosf_mbi_pmic_bus_access_notifier, nb); } EXPORT_SYMBOL(iosf_mbi_unregister_pmic_bus_access_notifier_unlocked); int iosf_mbi_unregister_pmic_bus_access_notifier(struct notifier_block *nb) { int ret; /* Wait for the bus to go inactive before unregistering */ iosf_mbi_punit_acquire(); ret = iosf_mbi_unregister_pmic_bus_access_notifier_unlocked(nb); iosf_mbi_punit_release(); return ret; } EXPORT_SYMBOL(iosf_mbi_unregister_pmic_bus_access_notifier); void iosf_mbi_assert_punit_acquired(void) { WARN_ON(iosf_mbi_pmic_punit_access_count == 0); } EXPORT_SYMBOL(iosf_mbi_assert_punit_acquired); /**************** iosf_mbi debug code ****************/ #ifdef CONFIG_IOSF_MBI_DEBUG static u32 dbg_mdr; static u32 dbg_mcr; static u32 dbg_mcrx; static int mcr_get(void *data, u64 *val) { *val = *(u32 *)data; return 0; } static int mcr_set(void *data, u64 val) { u8 command = ((u32)val & 0xFF000000) >> 24, port = ((u32)val & 0x00FF0000) >> 16, offset = ((u32)val & 0x0000FF00) >> 8; int err; *(u32 *)data = val; if (!capable(CAP_SYS_RAWIO)) return -EACCES; if (command & 1u) err = iosf_mbi_write(port, command, dbg_mcrx | offset, dbg_mdr); else err = iosf_mbi_read(port, command, dbg_mcrx | offset, &dbg_mdr); return err; } DEFINE_SIMPLE_ATTRIBUTE(iosf_mcr_fops, mcr_get, mcr_set , "%llx\n"); static struct dentry *iosf_dbg; static void iosf_sideband_debug_init(void) { iosf_dbg = debugfs_create_dir("iosf_sb", NULL); /* mdr */ debugfs_create_x32("mdr", 0660, iosf_dbg, &dbg_mdr); /* mcrx */ debugfs_create_x32("mcrx", 0660, iosf_dbg, &dbg_mcrx); /* mcr - initiates mailbox transaction */ debugfs_create_file("mcr", 0660, iosf_dbg, &dbg_mcr, &iosf_mcr_fops); } static void iosf_debugfs_init(void) { iosf_sideband_debug_init(); } static void iosf_debugfs_remove(void) { debugfs_remove_recursive(iosf_dbg); } #else static inline void iosf_debugfs_init(void) { } static inline void iosf_debugfs_remove(void) { } #endif /* CONFIG_IOSF_MBI_DEBUG */ static int iosf_mbi_probe(struct pci_dev *pdev, const struct pci_device_id *dev_id) { int ret; ret = pci_enable_device(pdev); if (ret < 0) { dev_err(&pdev->dev, "error: could not enable device\n"); return ret; } mbi_pdev = pci_dev_get(pdev); iosf_mbi_sem_address = dev_id->driver_data; return 0; } static const struct pci_device_id iosf_mbi_pci_ids[] = { { PCI_DEVICE_DATA(INTEL, BAYTRAIL, PUNIT_SEMAPHORE_BYT) }, { PCI_DEVICE_DATA(INTEL, BRASWELL, PUNIT_SEMAPHORE_CHT) }, { PCI_DEVICE_DATA(INTEL, QUARK_X1000, 0) }, { PCI_DEVICE_DATA(INTEL, TANGIER, 0) }, { 0, }, }; MODULE_DEVICE_TABLE(pci, iosf_mbi_pci_ids); static struct pci_driver iosf_mbi_pci_driver = { .name = "iosf_mbi_pci", .probe = iosf_mbi_probe, .id_table = iosf_mbi_pci_ids, }; static int __init iosf_mbi_init(void) { iosf_debugfs_init(); cpu_latency_qos_add_request(&iosf_mbi_pm_qos, PM_QOS_DEFAULT_VALUE); return pci_register_driver(&iosf_mbi_pci_driver); } static void __exit iosf_mbi_exit(void) { iosf_debugfs_remove(); pci_unregister_driver(&iosf_mbi_pci_driver); pci_dev_put(mbi_pdev); mbi_pdev = NULL; cpu_latency_qos_remove_request(&iosf_mbi_pm_qos); } module_init(iosf_mbi_init); module_exit(iosf_mbi_exit); MODULE_AUTHOR("David E. Box "); MODULE_DESCRIPTION("IOSF Mailbox Interface accessor"); MODULE_LICENSE("GPL v2");