Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Todd Android Poynor | 1292 | 54.19% | 13 | 56.52% |
Simon Que | 1028 | 43.12% | 1 | 4.35% |
Sandro Volery | 41 | 1.72% | 1 | 4.35% |
Sanjana Sanikommu | 9 | 0.38% | 1 | 4.35% |
Nick Ewalt | 5 | 0.21% | 1 | 4.35% |
Felix Siegel | 4 | 0.17% | 1 | 4.35% |
Greg Kroah-Hartman | 2 | 0.08% | 2 | 8.70% |
Nishka Dasgupta | 2 | 0.08% | 2 | 8.70% |
Ivan Bornyakov | 1 | 0.04% | 1 | 4.35% |
Total | 2384 | 23 |
// SPDX-License-Identifier: GPL-2.0 /* * Driver for the Apex chip. * * Copyright (C) 2018 Google, Inc. */ #include <linux/compiler.h> #include <linux/delay.h> #include <linux/device.h> #include <linux/fs.h> #include <linux/init.h> #include <linux/mm.h> #include <linux/module.h> #include <linux/moduleparam.h> #include <linux/pci.h> #include <linux/printk.h> #include <linux/sched.h> #include <linux/uaccess.h> #include "apex.h" #include "gasket_core.h" #include "gasket_interrupt.h" #include "gasket_page_table.h" #include "gasket_sysfs.h" /* Constants */ #define APEX_DEVICE_NAME "Apex" #define APEX_DRIVER_VERSION "1.0" /* CSRs are in BAR 2. */ #define APEX_BAR_INDEX 2 #define APEX_PCI_VENDOR_ID 0x1ac1 #define APEX_PCI_DEVICE_ID 0x089a /* Bar Offsets. */ #define APEX_BAR_OFFSET 0 #define APEX_CM_OFFSET 0x1000000 /* The sizes of each Apex BAR 2. */ #define APEX_BAR_BYTES 0x100000 #define APEX_CH_MEM_BYTES (PAGE_SIZE * MAX_NUM_COHERENT_PAGES) /* The number of user-mappable memory ranges in BAR2 of a Apex chip. */ #define NUM_REGIONS 3 /* The number of nodes in a Apex chip. */ #define NUM_NODES 1 /* * The total number of entries in the page table. Should match the value read * from the register APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE_SIZE. */ #define APEX_PAGE_TABLE_TOTAL_ENTRIES 8192 #define APEX_EXTENDED_SHIFT 63 /* Extended address bit position. */ /* Check reset 120 times */ #define APEX_RESET_RETRY 120 /* Wait 100 ms between checks. Total 12 sec wait maximum. */ #define APEX_RESET_DELAY 100 /* Enumeration of the supported sysfs entries. */ enum sysfs_attribute_type { ATTR_KERNEL_HIB_PAGE_TABLE_SIZE, ATTR_KERNEL_HIB_SIMPLE_PAGE_TABLE_SIZE, ATTR_KERNEL_HIB_NUM_ACTIVE_PAGES, }; /* * Register offsets into BAR2 memory. * Only values necessary for driver implementation are defined. */ enum apex_bar2_regs { APEX_BAR2_REG_SCU_BASE = 0x1A300, APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE_SIZE = 0x46000, APEX_BAR2_REG_KERNEL_HIB_EXTENDED_TABLE = 0x46008, APEX_BAR2_REG_KERNEL_HIB_TRANSLATION_ENABLE = 0x46010, APEX_BAR2_REG_KERNEL_HIB_INSTR_QUEUE_INTVECCTL = 0x46018, APEX_BAR2_REG_KERNEL_HIB_INPUT_ACTV_QUEUE_INTVECCTL = 0x46020, APEX_BAR2_REG_KERNEL_HIB_PARAM_QUEUE_INTVECCTL = 0x46028, APEX_BAR2_REG_KERNEL_HIB_OUTPUT_ACTV_QUEUE_INTVECCTL = 0x46030, APEX_BAR2_REG_KERNEL_HIB_SC_HOST_INTVECCTL = 0x46038, APEX_BAR2_REG_KERNEL_HIB_TOP_LEVEL_INTVECCTL = 0x46040, APEX_BAR2_REG_KERNEL_HIB_FATAL_ERR_INTVECCTL = 0x46048, APEX_BAR2_REG_KERNEL_HIB_DMA_PAUSE = 0x46050, APEX_BAR2_REG_KERNEL_HIB_DMA_PAUSE_MASK = 0x46058, APEX_BAR2_REG_KERNEL_HIB_STATUS_BLOCK_DELAY = 0x46060, APEX_BAR2_REG_KERNEL_HIB_MSIX_PENDING_BIT_ARRAY0 = 0x46068, APEX_BAR2_REG_KERNEL_HIB_MSIX_PENDING_BIT_ARRAY1 = 0x46070, APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE_INIT = 0x46078, APEX_BAR2_REG_KERNEL_HIB_MSIX_TABLE_INIT = 0x46080, APEX_BAR2_REG_KERNEL_WIRE_INT_PENDING_BIT_ARRAY = 0x48778, APEX_BAR2_REG_KERNEL_WIRE_INT_MASK_ARRAY = 0x48780, APEX_BAR2_REG_USER_HIB_DMA_PAUSE = 0x486D8, APEX_BAR2_REG_USER_HIB_DMA_PAUSED = 0x486E0, APEX_BAR2_REG_IDLEGENERATOR_IDLEGEN_IDLEREGISTER = 0x4A000, APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE = 0x50000, /* Error registers - Used mostly for debug */ APEX_BAR2_REG_USER_HIB_ERROR_STATUS = 0x86f0, APEX_BAR2_REG_SCALAR_CORE_ERROR_STATUS = 0x41a0, }; /* Addresses for packed registers. */ #define APEX_BAR2_REG_AXI_QUIESCE (APEX_BAR2_REG_SCU_BASE + 0x2C) #define APEX_BAR2_REG_GCB_CLOCK_GATE (APEX_BAR2_REG_SCU_BASE + 0x14) #define APEX_BAR2_REG_SCU_0 (APEX_BAR2_REG_SCU_BASE + 0xc) #define APEX_BAR2_REG_SCU_1 (APEX_BAR2_REG_SCU_BASE + 0x10) #define APEX_BAR2_REG_SCU_2 (APEX_BAR2_REG_SCU_BASE + 0x14) #define APEX_BAR2_REG_SCU_3 (APEX_BAR2_REG_SCU_BASE + 0x18) #define APEX_BAR2_REG_SCU_4 (APEX_BAR2_REG_SCU_BASE + 0x1c) #define APEX_BAR2_REG_SCU_5 (APEX_BAR2_REG_SCU_BASE + 0x20) #define SCU3_RG_PWR_STATE_OVR_BIT_OFFSET 26 #define SCU3_RG_PWR_STATE_OVR_MASK_WIDTH 2 #define SCU3_CUR_RST_GCB_BIT_MASK 0x10 #define SCU2_RG_RST_GCB_BIT_MASK 0xc /* Configuration for page table. */ static struct gasket_page_table_config apex_page_table_configs[NUM_NODES] = { { .id = 0, .mode = GASKET_PAGE_TABLE_MODE_NORMAL, .total_entries = APEX_PAGE_TABLE_TOTAL_ENTRIES, .base_reg = APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE, .extended_reg = APEX_BAR2_REG_KERNEL_HIB_EXTENDED_TABLE, .extended_bit = APEX_EXTENDED_SHIFT, }, }; /* The regions in the BAR2 space that can be mapped into user space. */ static const struct gasket_mappable_region mappable_regions[NUM_REGIONS] = { { 0x40000, 0x1000 }, { 0x44000, 0x1000 }, { 0x48000, 0x1000 }, }; /* Gasket device interrupts enums must be dense (i.e., no empty slots). */ enum apex_interrupt { APEX_INTERRUPT_INSTR_QUEUE = 0, APEX_INTERRUPT_INPUT_ACTV_QUEUE = 1, APEX_INTERRUPT_PARAM_QUEUE = 2, APEX_INTERRUPT_OUTPUT_ACTV_QUEUE = 3, APEX_INTERRUPT_SC_HOST_0 = 4, APEX_INTERRUPT_SC_HOST_1 = 5, APEX_INTERRUPT_SC_HOST_2 = 6, APEX_INTERRUPT_SC_HOST_3 = 7, APEX_INTERRUPT_TOP_LEVEL_0 = 8, APEX_INTERRUPT_TOP_LEVEL_1 = 9, APEX_INTERRUPT_TOP_LEVEL_2 = 10, APEX_INTERRUPT_TOP_LEVEL_3 = 11, APEX_INTERRUPT_FATAL_ERR = 12, APEX_INTERRUPT_COUNT = 13, }; /* Interrupt descriptors for Apex */ static struct gasket_interrupt_desc apex_interrupts[] = { { APEX_INTERRUPT_INSTR_QUEUE, APEX_BAR2_REG_KERNEL_HIB_INSTR_QUEUE_INTVECCTL, UNPACKED, }, { APEX_INTERRUPT_INPUT_ACTV_QUEUE, APEX_BAR2_REG_KERNEL_HIB_INPUT_ACTV_QUEUE_INTVECCTL, UNPACKED }, { APEX_INTERRUPT_PARAM_QUEUE, APEX_BAR2_REG_KERNEL_HIB_PARAM_QUEUE_INTVECCTL, UNPACKED }, { APEX_INTERRUPT_OUTPUT_ACTV_QUEUE, APEX_BAR2_REG_KERNEL_HIB_OUTPUT_ACTV_QUEUE_INTVECCTL, UNPACKED }, { APEX_INTERRUPT_SC_HOST_0, APEX_BAR2_REG_KERNEL_HIB_SC_HOST_INTVECCTL, PACK_0 }, { APEX_INTERRUPT_SC_HOST_1, APEX_BAR2_REG_KERNEL_HIB_SC_HOST_INTVECCTL, PACK_1 }, { APEX_INTERRUPT_SC_HOST_2, APEX_BAR2_REG_KERNEL_HIB_SC_HOST_INTVECCTL, PACK_2 }, { APEX_INTERRUPT_SC_HOST_3, APEX_BAR2_REG_KERNEL_HIB_SC_HOST_INTVECCTL, PACK_3 }, { APEX_INTERRUPT_TOP_LEVEL_0, APEX_BAR2_REG_KERNEL_HIB_TOP_LEVEL_INTVECCTL, PACK_0 }, { APEX_INTERRUPT_TOP_LEVEL_1, APEX_BAR2_REG_KERNEL_HIB_TOP_LEVEL_INTVECCTL, PACK_1 }, { APEX_INTERRUPT_TOP_LEVEL_2, APEX_BAR2_REG_KERNEL_HIB_TOP_LEVEL_INTVECCTL, PACK_2 }, { APEX_INTERRUPT_TOP_LEVEL_3, APEX_BAR2_REG_KERNEL_HIB_TOP_LEVEL_INTVECCTL, PACK_3 }, { APEX_INTERRUPT_FATAL_ERR, APEX_BAR2_REG_KERNEL_HIB_FATAL_ERR_INTVECCTL, UNPACKED }, }; /* Allows device to enter power save upon driver close(). */ static int allow_power_save = 1; /* Allows SW based clock gating. */ static int allow_sw_clock_gating; /* Allows HW based clock gating. */ /* Note: this is not mutual exclusive with SW clock gating. */ static int allow_hw_clock_gating = 1; /* Act as if only GCB is instantiated. */ static int bypass_top_level; module_param(allow_power_save, int, 0644); module_param(allow_sw_clock_gating, int, 0644); module_param(allow_hw_clock_gating, int, 0644); module_param(bypass_top_level, int, 0644); /* Check the device status registers and return device status ALIVE or DEAD. */ static int apex_get_status(struct gasket_dev *gasket_dev) { /* TODO: Check device status. */ return GASKET_STATUS_ALIVE; } /* Enter GCB reset state. */ static int apex_enter_reset(struct gasket_dev *gasket_dev) { if (bypass_top_level) return 0; /* * Software reset: * Enable sleep mode * - Software force GCB idle * - Enable GCB idle */ gasket_read_modify_write_64(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_IDLEGENERATOR_IDLEGEN_IDLEREGISTER, 0x0, 1, 32); /* - Initiate DMA pause */ gasket_dev_write_64(gasket_dev, 1, APEX_BAR_INDEX, APEX_BAR2_REG_USER_HIB_DMA_PAUSE); /* - Wait for DMA pause complete. */ if (gasket_wait_with_reschedule(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_USER_HIB_DMA_PAUSED, 1, 1, APEX_RESET_DELAY, APEX_RESET_RETRY)) { dev_err(gasket_dev->dev, "DMAs did not quiesce within timeout (%d ms)\n", APEX_RESET_RETRY * APEX_RESET_DELAY); return -ETIMEDOUT; } /* - Enable GCB reset (0x1 to rg_rst_gcb) */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_2, 0x1, 2, 2); /* - Enable GCB clock Gate (0x1 to rg_gated_gcb) */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_2, 0x1, 2, 18); /* - Enable GCB memory shut down (0x3 to rg_force_ram_sd) */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, 0x3, 2, 14); /* - Wait for RAM shutdown. */ if (gasket_wait_with_reschedule(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, BIT(6), BIT(6), APEX_RESET_DELAY, APEX_RESET_RETRY)) { dev_err(gasket_dev->dev, "RAM did not shut down within timeout (%d ms)\n", APEX_RESET_RETRY * APEX_RESET_DELAY); return -ETIMEDOUT; } return 0; } /* Quit GCB reset state. */ static int apex_quit_reset(struct gasket_dev *gasket_dev) { u32 val0, val1; if (bypass_top_level) return 0; /* * Disable sleep mode: * - Disable GCB memory shut down: * - b00: Not forced (HW controlled) * - b1x: Force disable */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, 0x0, 2, 14); /* * - Disable software clock gate: * - b00: Not forced (HW controlled) * - b1x: Force disable */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_2, 0x0, 2, 18); /* * - Disable GCB reset (rg_rst_gcb): * - b00: Not forced (HW controlled) * - b1x: Force disable = Force not Reset */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_2, 0x2, 2, 2); /* - Wait for RAM enable. */ if (gasket_wait_with_reschedule(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, BIT(6), 0, APEX_RESET_DELAY, APEX_RESET_RETRY)) { dev_err(gasket_dev->dev, "RAM did not enable within timeout (%d ms)\n", APEX_RESET_RETRY * APEX_RESET_DELAY); return -ETIMEDOUT; } /* - Wait for Reset complete. */ if (gasket_wait_with_reschedule(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, SCU3_CUR_RST_GCB_BIT_MASK, 0, APEX_RESET_DELAY, APEX_RESET_RETRY)) { dev_err(gasket_dev->dev, "GCB did not leave reset within timeout (%d ms)\n", APEX_RESET_RETRY * APEX_RESET_DELAY); return -ETIMEDOUT; } if (!allow_hw_clock_gating) { val0 = gasket_dev_read_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3); /* Inactive and Sleep mode are disabled. */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, 0x3, SCU3_RG_PWR_STATE_OVR_MASK_WIDTH, SCU3_RG_PWR_STATE_OVR_BIT_OFFSET); val1 = gasket_dev_read_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3); dev_dbg(gasket_dev->dev, "Disallow HW clock gating 0x%x -> 0x%x\n", val0, val1); } else { val0 = gasket_dev_read_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3); /* Inactive mode enabled - Sleep mode disabled. */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3, 2, SCU3_RG_PWR_STATE_OVR_MASK_WIDTH, SCU3_RG_PWR_STATE_OVR_BIT_OFFSET); val1 = gasket_dev_read_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3); dev_dbg(gasket_dev->dev, "Allow HW clock gating 0x%x -> 0x%x\n", val0, val1); } return 0; } /* Reset the Apex hardware. Called on final close via device_close_cb. */ static int apex_device_cleanup(struct gasket_dev *gasket_dev) { u64 scalar_error; u64 hib_error; int ret = 0; hib_error = gasket_dev_read_64(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_USER_HIB_ERROR_STATUS); scalar_error = gasket_dev_read_64(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCALAR_CORE_ERROR_STATUS); dev_dbg(gasket_dev->dev, "%s 0x%p hib_error 0x%llx scalar_error 0x%llx\n", __func__, gasket_dev, hib_error, scalar_error); if (allow_power_save) ret = apex_enter_reset(gasket_dev); return ret; } /* Determine if GCB is in reset state. */ static bool is_gcb_in_reset(struct gasket_dev *gasket_dev) { u32 val = gasket_dev_read_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_SCU_3); /* Masks rg_rst_gcb bit of SCU_CTRL_2 */ return (val & SCU3_CUR_RST_GCB_BIT_MASK); } /* Reset the hardware, then quit reset. Called on device open. */ static int apex_reset(struct gasket_dev *gasket_dev) { int ret; if (bypass_top_level) return 0; if (!is_gcb_in_reset(gasket_dev)) { /* We are not in reset - toggle the reset bit so as to force * re-init of custom block */ dev_dbg(gasket_dev->dev, "%s: toggle reset\n", __func__); ret = apex_enter_reset(gasket_dev); if (ret) return ret; } return apex_quit_reset(gasket_dev); } /* * Check permissions for Apex ioctls. * Returns true if the current user may execute this ioctl, and false otherwise. */ static bool apex_ioctl_check_permissions(struct file *filp, uint cmd) { return !!(filp->f_mode & FMODE_WRITE); } /* Gates or un-gates Apex clock. */ static long apex_clock_gating(struct gasket_dev *gasket_dev, struct apex_gate_clock_ioctl __user *argp) { struct apex_gate_clock_ioctl ibuf; if (bypass_top_level || !allow_sw_clock_gating) return 0; if (copy_from_user(&ibuf, argp, sizeof(ibuf))) return -EFAULT; dev_dbg(gasket_dev->dev, "%s %llu\n", __func__, ibuf.enable); if (ibuf.enable) { /* Quiesce AXI, gate GCB clock. */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_AXI_QUIESCE, 0x1, 1, 16); gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_GCB_CLOCK_GATE, 0x1, 2, 18); } else { /* Un-gate GCB clock, un-quiesce AXI. */ gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_GCB_CLOCK_GATE, 0x0, 2, 18); gasket_read_modify_write_32(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_AXI_QUIESCE, 0x0, 1, 16); } return 0; } /* Apex-specific ioctl handler. */ static long apex_ioctl(struct file *filp, uint cmd, void __user *argp) { struct gasket_dev *gasket_dev = filp->private_data; if (!apex_ioctl_check_permissions(filp, cmd)) return -EPERM; switch (cmd) { case APEX_IOCTL_GATE_CLOCK: return apex_clock_gating(gasket_dev, argp); default: return -ENOTTY; /* unknown command */ } } /* Display driver sysfs entries. */ static ssize_t sysfs_show(struct device *device, struct device_attribute *attr, char *buf) { int ret; struct gasket_dev *gasket_dev; struct gasket_sysfs_attribute *gasket_attr; enum sysfs_attribute_type type; struct gasket_page_table *gpt; uint val; gasket_dev = gasket_sysfs_get_device_data(device); if (!gasket_dev) { dev_err(device, "No Apex device sysfs mapping found\n"); return -ENODEV; } gasket_attr = gasket_sysfs_get_attr(device, attr); if (!gasket_attr) { dev_err(device, "No Apex device sysfs attr data found\n"); gasket_sysfs_put_device_data(device, gasket_dev); return -ENODEV; } type = (enum sysfs_attribute_type)gasket_attr->data.attr_type; gpt = gasket_dev->page_table[0]; switch (type) { case ATTR_KERNEL_HIB_PAGE_TABLE_SIZE: val = gasket_page_table_num_entries(gpt); break; case ATTR_KERNEL_HIB_SIMPLE_PAGE_TABLE_SIZE: val = gasket_page_table_num_simple_entries(gpt); break; case ATTR_KERNEL_HIB_NUM_ACTIVE_PAGES: val = gasket_page_table_num_active_pages(gpt); break; default: dev_dbg(gasket_dev->dev, "Unknown attribute: %s\n", attr->attr.name); ret = 0; goto exit; } ret = scnprintf(buf, PAGE_SIZE, "%u\n", val); exit: gasket_sysfs_put_attr(device, gasket_attr); gasket_sysfs_put_device_data(device, gasket_dev); return ret; } static struct gasket_sysfs_attribute apex_sysfs_attrs[] = { GASKET_SYSFS_RO(node_0_page_table_entries, sysfs_show, ATTR_KERNEL_HIB_PAGE_TABLE_SIZE), GASKET_SYSFS_RO(node_0_simple_page_table_entries, sysfs_show, ATTR_KERNEL_HIB_SIMPLE_PAGE_TABLE_SIZE), GASKET_SYSFS_RO(node_0_num_mapped_pages, sysfs_show, ATTR_KERNEL_HIB_NUM_ACTIVE_PAGES), GASKET_END_OF_ATTR_ARRAY }; /* On device open, perform a core reinit reset. */ static int apex_device_open_cb(struct gasket_dev *gasket_dev) { return gasket_reset_nolock(gasket_dev); } static const struct pci_device_id apex_pci_ids[] = { { PCI_DEVICE(APEX_PCI_VENDOR_ID, APEX_PCI_DEVICE_ID) }, { 0 } }; static int apex_pci_probe(struct pci_dev *pci_dev, const struct pci_device_id *id) { int ret; ulong page_table_ready, msix_table_ready; int retries = 0; struct gasket_dev *gasket_dev; ret = pci_enable_device(pci_dev); if (ret) { dev_err(&pci_dev->dev, "error enabling PCI device\n"); return ret; } pci_set_master(pci_dev); ret = gasket_pci_add_device(pci_dev, &gasket_dev); if (ret) { dev_err(&pci_dev->dev, "error adding gasket device\n"); pci_disable_device(pci_dev); return ret; } pci_set_drvdata(pci_dev, gasket_dev); apex_reset(gasket_dev); while (retries < APEX_RESET_RETRY) { page_table_ready = gasket_dev_read_64(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_KERNEL_HIB_PAGE_TABLE_INIT); msix_table_ready = gasket_dev_read_64(gasket_dev, APEX_BAR_INDEX, APEX_BAR2_REG_KERNEL_HIB_MSIX_TABLE_INIT); if (page_table_ready && msix_table_ready) break; schedule_timeout(msecs_to_jiffies(APEX_RESET_DELAY)); retries++; } if (retries == APEX_RESET_RETRY) { if (!page_table_ready) dev_err(gasket_dev->dev, "Page table init timed out\n"); if (!msix_table_ready) dev_err(gasket_dev->dev, "MSI-X table init timed out\n"); ret = -ETIMEDOUT; goto remove_device; } ret = gasket_sysfs_create_entries(gasket_dev->dev_info.device, apex_sysfs_attrs); if (ret) dev_err(&pci_dev->dev, "error creating device sysfs entries\n"); ret = gasket_enable_device(gasket_dev); if (ret) { dev_err(&pci_dev->dev, "error enabling gasket device\n"); goto remove_device; } /* Place device in low power mode until opened */ if (allow_power_save) apex_enter_reset(gasket_dev); return 0; remove_device: gasket_pci_remove_device(pci_dev); pci_disable_device(pci_dev); return ret; } static void apex_pci_remove(struct pci_dev *pci_dev) { struct gasket_dev *gasket_dev = pci_get_drvdata(pci_dev); gasket_disable_device(gasket_dev); gasket_pci_remove_device(pci_dev); pci_disable_device(pci_dev); } static const struct gasket_driver_desc apex_desc = { .name = "apex", .driver_version = APEX_DRIVER_VERSION, .major = 120, .minor = 0, .module = THIS_MODULE, .pci_id_table = apex_pci_ids, .num_page_tables = NUM_NODES, .page_table_bar_index = APEX_BAR_INDEX, .page_table_configs = apex_page_table_configs, .page_table_extended_bit = APEX_EXTENDED_SHIFT, .bar_descriptions = { GASKET_UNUSED_BAR, GASKET_UNUSED_BAR, { APEX_BAR_BYTES, (VM_WRITE | VM_READ), APEX_BAR_OFFSET, NUM_REGIONS, mappable_regions, PCI_BAR }, GASKET_UNUSED_BAR, GASKET_UNUSED_BAR, GASKET_UNUSED_BAR, }, .coherent_buffer_description = { APEX_CH_MEM_BYTES, (VM_WRITE | VM_READ), APEX_CM_OFFSET, }, .interrupt_type = PCI_MSIX, .interrupt_bar_index = APEX_BAR_INDEX, .num_interrupts = APEX_INTERRUPT_COUNT, .interrupts = apex_interrupts, .interrupt_pack_width = 7, .device_open_cb = apex_device_open_cb, .device_close_cb = apex_device_cleanup, .ioctl_handler_cb = apex_ioctl, .device_status_cb = apex_get_status, .hardware_revision_cb = NULL, .device_reset_cb = apex_reset, }; static struct pci_driver apex_pci_driver = { .name = "apex", .probe = apex_pci_probe, .remove = apex_pci_remove, .id_table = apex_pci_ids, }; static int __init apex_init(void) { int ret; ret = gasket_register_device(&apex_desc); if (ret) return ret; ret = pci_register_driver(&apex_pci_driver); if (ret) gasket_unregister_device(&apex_desc); return ret; } static void apex_exit(void) { pci_unregister_driver(&apex_pci_driver); gasket_unregister_device(&apex_desc); } MODULE_DESCRIPTION("Google Apex driver"); MODULE_VERSION(APEX_DRIVER_VERSION); MODULE_LICENSE("GPL v2"); MODULE_AUTHOR("John Joseph <jnjoseph@google.com>"); MODULE_DEVICE_TABLE(pci, apex_pci_ids); module_init(apex_init); module_exit(apex_exit);
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