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1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 | // SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2011-2016 Synaptics Incorporated * Copyright (c) 2011 Unixphere * * This driver provides the core support for a single RMI4-based device. * * The RMI4 specification can be found here (URL split for line length): * * http://www.synaptics.com/sites/default/files/ * 511-000136-01-Rev-E-RMI4-Interfacing-Guide.pdf */ #include <linux/bitmap.h> #include <linux/delay.h> #include <linux/fs.h> #include <linux/irq.h> #include <linux/pm.h> #include <linux/slab.h> #include <linux/of.h> #include <linux/irqdomain.h> #include <uapi/linux/input.h> #include <linux/rmi.h> #include "rmi_bus.h" #include "rmi_driver.h" #define HAS_NONSTANDARD_PDT_MASK 0x40 #define RMI4_MAX_PAGE 0xff #define RMI4_PAGE_SIZE 0x100 #define RMI4_PAGE_MASK 0xFF00 #define RMI_DEVICE_RESET_CMD 0x01 #define DEFAULT_RESET_DELAY_MS 100 void rmi_free_function_list(struct rmi_device *rmi_dev) { struct rmi_function *fn, *tmp; struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); rmi_dbg(RMI_DEBUG_CORE, &rmi_dev->dev, "Freeing function list\n"); /* Doing it in the reverse order so F01 will be removed last */ list_for_each_entry_safe_reverse(fn, tmp, &data->function_list, node) { list_del(&fn->node); rmi_unregister_function(fn); } devm_kfree(&rmi_dev->dev, data->irq_memory); data->irq_memory = NULL; data->irq_status = NULL; data->fn_irq_bits = NULL; data->current_irq_mask = NULL; data->new_irq_mask = NULL; data->f01_container = NULL; data->f34_container = NULL; } static int reset_one_function(struct rmi_function *fn) { struct rmi_function_handler *fh; int retval = 0; if (!fn || !fn->dev.driver) return 0; fh = to_rmi_function_handler(fn->dev.driver); if (fh->reset) { retval = fh->reset(fn); if (retval < 0) dev_err(&fn->dev, "Reset failed with code %d.\n", retval); } return retval; } static int configure_one_function(struct rmi_function *fn) { struct rmi_function_handler *fh; int retval = 0; if (!fn || !fn->dev.driver) return 0; fh = to_rmi_function_handler(fn->dev.driver); if (fh->config) { retval = fh->config(fn); if (retval < 0) dev_err(&fn->dev, "Config failed with code %d.\n", retval); } return retval; } static int rmi_driver_process_reset_requests(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi_function *entry; int retval; list_for_each_entry(entry, &data->function_list, node) { retval = reset_one_function(entry); if (retval < 0) return retval; } return 0; } static int rmi_driver_process_config_requests(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi_function *entry; int retval; list_for_each_entry(entry, &data->function_list, node) { retval = configure_one_function(entry); if (retval < 0) return retval; } return 0; } static int rmi_process_interrupt_requests(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct device *dev = &rmi_dev->dev; int i; int error; if (!data) return 0; if (!data->attn_data.data) { error = rmi_read_block(rmi_dev, data->f01_container->fd.data_base_addr + 1, data->irq_status, data->num_of_irq_regs); if (error < 0) { dev_err(dev, "Failed to read irqs, code=%d\n", error); return error; } } mutex_lock(&data->irq_mutex); bitmap_and(data->irq_status, data->irq_status, data->fn_irq_bits, data->irq_count); /* * At this point, irq_status has all bits that are set in the * interrupt status register and are enabled. */ mutex_unlock(&data->irq_mutex); for_each_set_bit(i, data->irq_status, data->irq_count) handle_nested_irq(irq_find_mapping(data->irqdomain, i)); if (data->input) input_sync(data->input); return 0; } void rmi_set_attn_data(struct rmi_device *rmi_dev, unsigned long irq_status, void *data, size_t size) { struct rmi_driver_data *drvdata = dev_get_drvdata(&rmi_dev->dev); struct rmi4_attn_data attn_data; void *fifo_data; if (!drvdata->enabled) return; fifo_data = kmemdup(data, size, GFP_ATOMIC); if (!fifo_data) return; attn_data.irq_status = irq_status; attn_data.size = size; attn_data.data = fifo_data; kfifo_put(&drvdata->attn_fifo, attn_data); } EXPORT_SYMBOL_GPL(rmi_set_attn_data); static irqreturn_t rmi_irq_fn(int irq, void *dev_id) { struct rmi_device *rmi_dev = dev_id; struct rmi_driver_data *drvdata = dev_get_drvdata(&rmi_dev->dev); struct rmi4_attn_data attn_data = {0}; int ret, count; count = kfifo_get(&drvdata->attn_fifo, &attn_data); if (count) { *(drvdata->irq_status) = attn_data.irq_status; drvdata->attn_data = attn_data; } ret = rmi_process_interrupt_requests(rmi_dev); if (ret) rmi_dbg(RMI_DEBUG_CORE, &rmi_dev->dev, "Failed to process interrupt request: %d\n", ret); if (count) { kfree(attn_data.data); attn_data.data = NULL; } if (!kfifo_is_empty(&drvdata->attn_fifo)) return rmi_irq_fn(irq, dev_id); return IRQ_HANDLED; } static int rmi_irq_init(struct rmi_device *rmi_dev) { struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev); struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); int irq_flags = irq_get_trigger_type(pdata->irq); int ret; if (!irq_flags) irq_flags = IRQF_TRIGGER_LOW; ret = devm_request_threaded_irq(&rmi_dev->dev, pdata->irq, NULL, rmi_irq_fn, irq_flags | IRQF_ONESHOT, dev_driver_string(rmi_dev->xport->dev), rmi_dev); if (ret < 0) { dev_err(&rmi_dev->dev, "Failed to register interrupt %d\n", pdata->irq); return ret; } data->enabled = true; return 0; } struct rmi_function *rmi_find_function(struct rmi_device *rmi_dev, u8 number) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi_function *entry; list_for_each_entry(entry, &data->function_list, node) { if (entry->fd.function_number == number) return entry; } return NULL; } static int suspend_one_function(struct rmi_function *fn) { struct rmi_function_handler *fh; int retval = 0; if (!fn || !fn->dev.driver) return 0; fh = to_rmi_function_handler(fn->dev.driver); if (fh->suspend) { retval = fh->suspend(fn); if (retval < 0) dev_err(&fn->dev, "Suspend failed with code %d.\n", retval); } return retval; } static int rmi_suspend_functions(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi_function *entry; int retval; list_for_each_entry(entry, &data->function_list, node) { retval = suspend_one_function(entry); if (retval < 0) return retval; } return 0; } static int resume_one_function(struct rmi_function *fn) { struct rmi_function_handler *fh; int retval = 0; if (!fn || !fn->dev.driver) return 0; fh = to_rmi_function_handler(fn->dev.driver); if (fh->resume) { retval = fh->resume(fn); if (retval < 0) dev_err(&fn->dev, "Resume failed with code %d.\n", retval); } return retval; } static int rmi_resume_functions(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi_function *entry; int retval; list_for_each_entry(entry, &data->function_list, node) { retval = resume_one_function(entry); if (retval < 0) return retval; } return 0; } int rmi_enable_sensor(struct rmi_device *rmi_dev) { int retval = 0; retval = rmi_driver_process_config_requests(rmi_dev); if (retval < 0) return retval; return rmi_process_interrupt_requests(rmi_dev); } /** * rmi_driver_set_input_params - set input device id and other data. * * @rmi_dev: Pointer to an RMI device * @input: Pointer to input device * */ static int rmi_driver_set_input_params(struct rmi_device *rmi_dev, struct input_dev *input) { input->name = SYNAPTICS_INPUT_DEVICE_NAME; input->id.vendor = SYNAPTICS_VENDOR_ID; input->id.bustype = BUS_RMI; return 0; } static void rmi_driver_set_input_name(struct rmi_device *rmi_dev, struct input_dev *input) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); const char *device_name = rmi_f01_get_product_ID(data->f01_container); char *name; name = devm_kasprintf(&rmi_dev->dev, GFP_KERNEL, "Synaptics %s", device_name); if (!name) return; input->name = name; } static int rmi_driver_set_irq_bits(struct rmi_device *rmi_dev, unsigned long *mask) { int error = 0; struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct device *dev = &rmi_dev->dev; mutex_lock(&data->irq_mutex); bitmap_or(data->new_irq_mask, data->current_irq_mask, mask, data->irq_count); error = rmi_write_block(rmi_dev, data->f01_container->fd.control_base_addr + 1, data->new_irq_mask, data->num_of_irq_regs); if (error < 0) { dev_err(dev, "%s: Failed to change enabled interrupts!", __func__); goto error_unlock; } bitmap_copy(data->current_irq_mask, data->new_irq_mask, data->num_of_irq_regs); bitmap_or(data->fn_irq_bits, data->fn_irq_bits, mask, data->irq_count); error_unlock: mutex_unlock(&data->irq_mutex); return error; } static int rmi_driver_clear_irq_bits(struct rmi_device *rmi_dev, unsigned long *mask) { int error = 0; struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct device *dev = &rmi_dev->dev; mutex_lock(&data->irq_mutex); bitmap_andnot(data->fn_irq_bits, data->fn_irq_bits, mask, data->irq_count); bitmap_andnot(data->new_irq_mask, data->current_irq_mask, mask, data->irq_count); error = rmi_write_block(rmi_dev, data->f01_container->fd.control_base_addr + 1, data->new_irq_mask, data->num_of_irq_regs); if (error < 0) { dev_err(dev, "%s: Failed to change enabled interrupts!", __func__); goto error_unlock; } bitmap_copy(data->current_irq_mask, data->new_irq_mask, data->num_of_irq_regs); error_unlock: mutex_unlock(&data->irq_mutex); return error; } static int rmi_driver_reset_handler(struct rmi_device *rmi_dev) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); int error; /* * Can get called before the driver is fully ready to deal with * this situation. */ if (!data || !data->f01_container) { dev_warn(&rmi_dev->dev, "Not ready to handle reset yet!\n"); return 0; } error = rmi_read_block(rmi_dev, data->f01_container->fd.control_base_addr + 1, data->current_irq_mask, data->num_of_irq_regs); if (error < 0) { dev_err(&rmi_dev->dev, "%s: Failed to read current IRQ mask.\n", __func__); return error; } error = rmi_driver_process_reset_requests(rmi_dev); if (error < 0) return error; error = rmi_driver_process_config_requests(rmi_dev); if (error < 0) return error; return 0; } static int rmi_read_pdt_entry(struct rmi_device *rmi_dev, struct pdt_entry *entry, u16 pdt_address) { u8 buf[RMI_PDT_ENTRY_SIZE]; int error; error = rmi_read_block(rmi_dev, pdt_address, buf, RMI_PDT_ENTRY_SIZE); if (error) { dev_err(&rmi_dev->dev, "Read PDT entry at %#06x failed, code: %d.\n", pdt_address, error); return error; } entry->page_start = pdt_address & RMI4_PAGE_MASK; entry->query_base_addr = buf[0]; entry->command_base_addr = buf[1]; entry->control_base_addr = buf[2]; entry->data_base_addr = buf[3]; entry->interrupt_source_count = buf[4] & RMI_PDT_INT_SOURCE_COUNT_MASK; entry->function_version = (buf[4] & RMI_PDT_FUNCTION_VERSION_MASK) >> 5; entry->function_number = buf[5]; return 0; } static void rmi_driver_copy_pdt_to_fd(const struct pdt_entry *pdt, struct rmi_function_descriptor *fd) { fd->query_base_addr = pdt->query_base_addr + pdt->page_start; fd->command_base_addr = pdt->command_base_addr + pdt->page_start; fd->control_base_addr = pdt->control_base_addr + pdt->page_start; fd->data_base_addr = pdt->data_base_addr + pdt->page_start; fd->function_number = pdt->function_number; fd->interrupt_source_count = pdt->interrupt_source_count; fd->function_version = pdt->function_version; } #define RMI_SCAN_CONTINUE 0 #define RMI_SCAN_DONE 1 static int rmi_scan_pdt_page(struct rmi_device *rmi_dev, int page, int *empty_pages, void *ctx, int (*callback)(struct rmi_device *rmi_dev, void *ctx, const struct pdt_entry *entry)) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct pdt_entry pdt_entry; u16 page_start = RMI4_PAGE_SIZE * page; u16 pdt_start = page_start + PDT_START_SCAN_LOCATION; u16 pdt_end = page_start + PDT_END_SCAN_LOCATION; u16 addr; int error; int retval; for (addr = pdt_start; addr >= pdt_end; addr -= RMI_PDT_ENTRY_SIZE) { error = rmi_read_pdt_entry(rmi_dev, &pdt_entry, addr); if (error) return error; if (RMI4_END_OF_PDT(pdt_entry.function_number)) break; retval = callback(rmi_dev, ctx, &pdt_entry); if (retval != RMI_SCAN_CONTINUE) return retval; } /* * Count number of empty PDT pages. If a gap of two pages * or more is found, stop scanning. */ if (addr == pdt_start) ++*empty_pages; else *empty_pages = 0; return (data->bootloader_mode || *empty_pages >= 2) ? RMI_SCAN_DONE : RMI_SCAN_CONTINUE; } int rmi_scan_pdt(struct rmi_device *rmi_dev, void *ctx, int (*callback)(struct rmi_device *rmi_dev, void *ctx, const struct pdt_entry *entry)) { int page; int empty_pages = 0; int retval = RMI_SCAN_DONE; for (page = 0; page <= RMI4_MAX_PAGE; page++) { retval = rmi_scan_pdt_page(rmi_dev, page, &empty_pages, ctx, callback); if (retval != RMI_SCAN_CONTINUE) break; } return retval < 0 ? retval : 0; } int rmi_read_register_desc(struct rmi_device *d, u16 addr, struct rmi_register_descriptor *rdesc) { int ret; u8 size_presence_reg; u8 buf[35]; int presense_offset = 1; u8 *struct_buf; int reg; int offset = 0; int map_offset = 0; int i; int b; /* * The first register of the register descriptor is the size of * the register descriptor's presense register. */ ret = rmi_read(d, addr, &size_presence_reg); if (ret) return ret; ++addr; if (size_presence_reg < 0 || size_presence_reg > 35) return -EIO; memset(buf, 0, sizeof(buf)); /* * The presence register contains the size of the register structure * and a bitmap which identified which packet registers are present * for this particular register type (ie query, control, or data). */ ret = rmi_read_block(d, addr, buf, size_presence_reg); if (ret) return ret; ++addr; if (buf[0] == 0) { presense_offset = 3; rdesc->struct_size = buf[1] | (buf[2] << 8); } else { rdesc->struct_size = buf[0]; } for (i = presense_offset; i < size_presence_reg; i++) { for (b = 0; b < 8; b++) { if (buf[i] & (0x1 << b)) bitmap_set(rdesc->presense_map, map_offset, 1); ++map_offset; } } rdesc->num_registers = bitmap_weight(rdesc->presense_map, RMI_REG_DESC_PRESENSE_BITS); rdesc->registers = devm_kcalloc(&d->dev, rdesc->num_registers, sizeof(struct rmi_register_desc_item), GFP_KERNEL); if (!rdesc->registers) return -ENOMEM; /* * Allocate a temporary buffer to hold the register structure. * I'm not using devm_kzalloc here since it will not be retained * after exiting this function */ struct_buf = kzalloc(rdesc->struct_size, GFP_KERNEL); if (!struct_buf) return -ENOMEM; /* * The register structure contains information about every packet * register of this type. This includes the size of the packet * register and a bitmap of all subpackets contained in the packet * register. */ ret = rmi_read_block(d, addr, struct_buf, rdesc->struct_size); if (ret) goto free_struct_buff; reg = find_first_bit(rdesc->presense_map, RMI_REG_DESC_PRESENSE_BITS); for (i = 0; i < rdesc->num_registers; i++) { struct rmi_register_desc_item *item = &rdesc->registers[i]; int reg_size = struct_buf[offset]; ++offset; if (reg_size == 0) { reg_size = struct_buf[offset] | (struct_buf[offset + 1] << 8); offset += 2; } if (reg_size == 0) { reg_size = struct_buf[offset] | (struct_buf[offset + 1] << 8) | (struct_buf[offset + 2] << 16) | (struct_buf[offset + 3] << 24); offset += 4; } item->reg = reg; item->reg_size = reg_size; map_offset = 0; do { for (b = 0; b < 7; b++) { if (struct_buf[offset] & (0x1 << b)) bitmap_set(item->subpacket_map, map_offset, 1); ++map_offset; } } while (struct_buf[offset++] & 0x80); item->num_subpackets = bitmap_weight(item->subpacket_map, RMI_REG_DESC_SUBPACKET_BITS); rmi_dbg(RMI_DEBUG_CORE, &d->dev, "%s: reg: %d reg size: %ld subpackets: %d\n", __func__, item->reg, item->reg_size, item->num_subpackets); reg = find_next_bit(rdesc->presense_map, RMI_REG_DESC_PRESENSE_BITS, reg + 1); } free_struct_buff: kfree(struct_buf); return ret; } const struct rmi_register_desc_item *rmi_get_register_desc_item( struct rmi_register_descriptor *rdesc, u16 reg) { const struct rmi_register_desc_item *item; int i; for (i = 0; i < rdesc->num_registers; i++) { item = &rdesc->registers[i]; if (item->reg == reg) return item; } return NULL; } size_t rmi_register_desc_calc_size(struct rmi_register_descriptor *rdesc) { const struct rmi_register_desc_item *item; int i; size_t size = 0; for (i = 0; i < rdesc->num_registers; i++) { item = &rdesc->registers[i]; size += item->reg_size; } return size; } /* Compute the register offset relative to the base address */ int rmi_register_desc_calc_reg_offset( struct rmi_register_descriptor *rdesc, u16 reg) { const struct rmi_register_desc_item *item; int offset = 0; int i; for (i = 0; i < rdesc->num_registers; i++) { item = &rdesc->registers[i]; if (item->reg == reg) return offset; ++offset; } return -1; } bool rmi_register_desc_has_subpacket(const struct rmi_register_desc_item *item, u8 subpacket) { return find_next_bit(item->subpacket_map, RMI_REG_DESC_PRESENSE_BITS, subpacket) == subpacket; } static int rmi_check_bootloader_mode(struct rmi_device *rmi_dev, const struct pdt_entry *pdt) { struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); int ret; u8 status; if (pdt->function_number == 0x34 && pdt->function_version > 1) { ret = rmi_read(rmi_dev, pdt->data_base_addr, &status); if (ret) { dev_err(&rmi_dev->dev, "Failed to read F34 status: %d.\n", ret); return ret; } if (status & BIT(7)) data->bootloader_mode = true; } else if (pdt->function_number == 0x01) { ret = rmi_read(rmi_dev, pdt->data_base_addr, &status); if (ret) { dev_err(&rmi_dev->dev, "Failed to read F01 status: %d.\n", ret); return ret; } if (status & BIT(6)) data->bootloader_mode = true; } return 0; } static int rmi_count_irqs(struct rmi_device *rmi_dev, void *ctx, const struct pdt_entry *pdt) { int *irq_count = ctx; int ret; *irq_count += pdt->interrupt_source_count; ret = rmi_check_bootloader_mode(rmi_dev, pdt); if (ret < 0) return ret; return RMI_SCAN_CONTINUE; } int rmi_initial_reset(struct rmi_device *rmi_dev, void *ctx, const struct pdt_entry *pdt) { int error; if (pdt->function_number == 0x01) { u16 cmd_addr = pdt->page_start + pdt->command_base_addr; u8 cmd_buf = RMI_DEVICE_RESET_CMD; const struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev); if (rmi_dev->xport->ops->reset) { error = rmi_dev->xport->ops->reset(rmi_dev->xport, cmd_addr); if (error) return error; return RMI_SCAN_DONE; } rmi_dbg(RMI_DEBUG_CORE, &rmi_dev->dev, "Sending reset\n"); error = rmi_write_block(rmi_dev, cmd_addr, &cmd_buf, 1); if (error) { dev_err(&rmi_dev->dev, "Initial reset failed. Code = %d.\n", error); return error; } mdelay(pdata->reset_delay_ms ?: DEFAULT_RESET_DELAY_MS); return RMI_SCAN_DONE; } /* F01 should always be on page 0. If we don't find it there, fail. */ return pdt->page_start == 0 ? RMI_SCAN_CONTINUE : -ENODEV; } static int rmi_create_function(struct rmi_device *rmi_dev, void *ctx, const struct pdt_entry *pdt) { struct device *dev = &rmi_dev->dev; struct rmi_driver_data *data = dev_get_drvdata(dev); int *current_irq_count = ctx; struct rmi_function *fn; int i; int error; rmi_dbg(RMI_DEBUG_CORE, dev, "Initializing F%02X.\n", pdt->function_number); fn = kzalloc(sizeof(struct rmi_function) + BITS_TO_LONGS(data->irq_count) * sizeof(unsigned long), GFP_KERNEL); if (!fn) { dev_err(dev, "Failed to allocate memory for F%02X\n", pdt->function_number); return -ENOMEM; } INIT_LIST_HEAD(&fn->node); rmi_driver_copy_pdt_to_fd(pdt, &fn->fd); fn->rmi_dev = rmi_dev; fn->num_of_irqs = pdt->interrupt_source_count; fn->irq_pos = *current_irq_count; *current_irq_count += fn->num_of_irqs; for (i = 0; i < fn->num_of_irqs; i++) set_bit(fn->irq_pos + i, fn->irq_mask); error = rmi_register_function(fn); if (error) return error; if (pdt->function_number == 0x01) data->f01_container = fn; else if (pdt->function_number == 0x34) data->f34_container = fn; list_add_tail(&fn->node, &data->function_list); return RMI_SCAN_CONTINUE; } void rmi_enable_irq(struct rmi_device *rmi_dev, bool clear_wake) { struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev); struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); int irq = pdata->irq; int irq_flags; int retval; mutex_lock(&data->enabled_mutex); if (data->enabled) goto out; enable_irq(irq); data->enabled = true; if (clear_wake && device_may_wakeup(rmi_dev->xport->dev)) { retval = disable_irq_wake(irq); if (retval) dev_warn(&rmi_dev->dev, "Failed to disable irq for wake: %d\n", retval); } /* * Call rmi_process_interrupt_requests() after enabling irq, * otherwise we may lose interrupt on edge-triggered systems. */ irq_flags = irq_get_trigger_type(pdata->irq); if (irq_flags & IRQ_TYPE_EDGE_BOTH) rmi_process_interrupt_requests(rmi_dev); out: mutex_unlock(&data->enabled_mutex); } void rmi_disable_irq(struct rmi_device *rmi_dev, bool enable_wake) { struct rmi_device_platform_data *pdata = rmi_get_platform_data(rmi_dev); struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); struct rmi4_attn_data attn_data = {0}; int irq = pdata->irq; int retval, count; mutex_lock(&data->enabled_mutex); if (!data->enabled) goto out; data->enabled = false; disable_irq(irq); if (enable_wake && device_may_wakeup(rmi_dev->xport->dev)) { retval = enable_irq_wake(irq); if (retval) dev_warn(&rmi_dev->dev, "Failed to enable irq for wake: %d\n", retval); } /* make sure the fifo is clean */ while (!kfifo_is_empty(&data->attn_fifo)) { count = kfifo_get(&data->attn_fifo, &attn_data); if (count) kfree(attn_data.data); } out: mutex_unlock(&data->enabled_mutex); } int rmi_driver_suspend(struct rmi_device *rmi_dev, bool enable_wake) { int retval; retval = rmi_suspend_functions(rmi_dev); if (retval) dev_warn(&rmi_dev->dev, "Failed to suspend functions: %d\n", retval); rmi_disable_irq(rmi_dev, enable_wake); return retval; } EXPORT_SYMBOL_GPL(rmi_driver_suspend); int rmi_driver_resume(struct rmi_device *rmi_dev, bool clear_wake) { int retval; rmi_enable_irq(rmi_dev, clear_wake); retval = rmi_resume_functions(rmi_dev); if (retval) dev_warn(&rmi_dev->dev, "Failed to suspend functions: %d\n", retval); return retval; } EXPORT_SYMBOL_GPL(rmi_driver_resume); static int rmi_driver_remove(struct device *dev) { struct rmi_device *rmi_dev = to_rmi_device(dev); struct rmi_driver_data *data = dev_get_drvdata(&rmi_dev->dev); rmi_disable_irq(rmi_dev, false); irq_domain_remove(data->irqdomain); data->irqdomain = NULL; rmi_f34_remove_sysfs(rmi_dev); rmi_free_function_list(rmi_dev); return 0; } #ifdef CONFIG_OF static int rmi_driver_of_probe(struct device *dev, struct rmi_device_platform_data *pdata) { int retval; retval = rmi_of_property_read_u32(dev, &pdata->reset_delay_ms, "syna,reset-delay-ms", 1); if (retval) return retval; return 0; } #else static inline int rmi_driver_of_probe(struct device *dev, struct rmi_device_platform_data *pdata) { return -ENODEV; } #endif int rmi_probe_interrupts(struct rmi_driver_data *data) { struct rmi_device *rmi_dev = data->rmi_dev; struct device *dev = &rmi_dev->dev; struct fwnode_handle *fwnode = rmi_dev->xport->dev->fwnode; int irq_count = 0; size_t size; int retval; /* * We need to count the IRQs and allocate their storage before scanning * the PDT and creating the function entries, because adding a new * function can trigger events that result in the IRQ related storage * being accessed. */ rmi_dbg(RMI_DEBUG_CORE, dev, "%s: Counting IRQs.\n", __func__); data->bootloader_mode = false; retval = rmi_scan_pdt(rmi_dev, &irq_count, rmi_count_irqs); if (retval < 0) { dev_err(dev, "IRQ counting failed with code %d.\n", retval); return retval; } if (data->bootloader_mode) dev_warn(dev, "Device in bootloader mode.\n"); /* Allocate and register a linear revmap irq_domain */ data->irqdomain = irq_domain_create_linear(fwnode, irq_count, &irq_domain_simple_ops, data); if (!data->irqdomain) { dev_err(&rmi_dev->dev, "Failed to create IRQ domain\n"); return -ENOMEM; } data->irq_count = irq_count; data->num_of_irq_regs = (data->irq_count + 7) / 8; size = BITS_TO_LONGS(data->irq_count) * sizeof(unsigned long); data->irq_memory = devm_kcalloc(dev, size, 4, GFP_KERNEL); if (!data->irq_memory) { dev_err(dev, "Failed to allocate memory for irq masks.\n"); return -ENOMEM; } data->irq_status = data->irq_memory + size * 0; data->fn_irq_bits = data->irq_memory + size * 1; data->current_irq_mask = data->irq_memory + size * 2; data->new_irq_mask = data->irq_memory + size * 3; return retval; } int rmi_init_functions(struct rmi_driver_data *data) { struct rmi_device *rmi_dev = data->rmi_dev; struct device *dev = &rmi_dev->dev; int irq_count = 0; int retval; rmi_dbg(RMI_DEBUG_CORE, dev, "%s: Creating functions.\n", __func__); retval = rmi_scan_pdt(rmi_dev, &irq_count, rmi_create_function); if (retval < 0) { dev_err(dev, "Function creation failed with code %d.\n", retval); goto err_destroy_functions; } if (!data->f01_container) { dev_err(dev, "Missing F01 container!\n"); retval = -EINVAL; goto err_destroy_functions; } retval = rmi_read_block(rmi_dev, data->f01_container->fd.control_base_addr + 1, data->current_irq_mask, data->num_of_irq_regs); if (retval < 0) { dev_err(dev, "%s: Failed to read current IRQ mask.\n", __func__); goto err_destroy_functions; } return 0; err_destroy_functions: rmi_free_function_list(rmi_dev); return retval; } static int rmi_driver_probe(struct device *dev) { struct rmi_driver *rmi_driver; struct rmi_driver_data *data; struct rmi_device_platform_data *pdata; struct rmi_device *rmi_dev; int retval; rmi_dbg(RMI_DEBUG_CORE, dev, "%s: Starting probe.\n", __func__); if (!rmi_is_physical_device(dev)) { rmi_dbg(RMI_DEBUG_CORE, dev, "Not a physical device.\n"); return -ENODEV; } rmi_dev = to_rmi_device(dev); rmi_driver = to_rmi_driver(dev->driver); rmi_dev->driver = rmi_driver; pdata = rmi_get_platform_data(rmi_dev); if (rmi_dev->xport->dev->of_node) { retval = rmi_driver_of_probe(rmi_dev->xport->dev, pdata); if (retval) return retval; } data = devm_kzalloc(dev, sizeof(struct rmi_driver_data), GFP_KERNEL); if (!data) return -ENOMEM; INIT_LIST_HEAD(&data->function_list); data->rmi_dev = rmi_dev; dev_set_drvdata(&rmi_dev->dev, data); /* * Right before a warm boot, the sensor might be in some unusual state, * such as F54 diagnostics, or F34 bootloader mode after a firmware * or configuration update. In order to clear the sensor to a known * state and/or apply any updates, we issue a initial reset to clear any * previous settings and force it into normal operation. * * We have to do this before actually building the PDT because * the reflash updates (if any) might cause various registers to move * around. * * For a number of reasons, this initial reset may fail to return * within the specified time, but we'll still be able to bring up the * driver normally after that failure. This occurs most commonly in * a cold boot situation (where then firmware takes longer to come up * than from a warm boot) and the reset_delay_ms in the platform data * has been set too short to accommodate that. Since the sensor will * eventually come up and be usable, we don't want to just fail here * and leave the customer's device unusable. So we warn them, and * continue processing. */ retval = rmi_scan_pdt(rmi_dev, NULL, rmi_initial_reset); if (retval < 0) dev_warn(dev, "RMI initial reset failed! Continuing in spite of this.\n"); retval = rmi_read(rmi_dev, PDT_PROPERTIES_LOCATION, &data->pdt_props); if (retval < 0) { /* * we'll print out a warning and continue since * failure to get the PDT properties is not a cause to fail */ dev_warn(dev, "Could not read PDT properties from %#06x (code %d). Assuming 0x00.\n", PDT_PROPERTIES_LOCATION, retval); } mutex_init(&data->irq_mutex); mutex_init(&data->enabled_mutex); retval = rmi_probe_interrupts(data); if (retval) goto err; if (rmi_dev->xport->input) { /* * The transport driver already has an input device. * In some cases it is preferable to reuse the transport * devices input device instead of creating a new one here. * One example is some HID touchpads report "pass-through" * button events are not reported by rmi registers. */ data->input = rmi_dev->xport->input; } else { data->input = devm_input_allocate_device(dev); if (!data->input) { dev_err(dev, "%s: Failed to allocate input device.\n", __func__); retval = -ENOMEM; goto err; } rmi_driver_set_input_params(rmi_dev, data->input); data->input->phys = devm_kasprintf(dev, GFP_KERNEL, "%s/input0", dev_name(dev)); } retval = rmi_init_functions(data); if (retval) goto err; retval = rmi_f34_create_sysfs(rmi_dev); if (retval) goto err; if (data->input) { rmi_driver_set_input_name(rmi_dev, data->input); if (!rmi_dev->xport->input) { if (input_register_device(data->input)) { dev_err(dev, "%s: Failed to register input device.\n", __func__); goto err_destroy_functions; } } } retval = rmi_irq_init(rmi_dev); if (retval < 0) goto err_destroy_functions; if (data->f01_container->dev.driver) { /* Driver already bound, so enable ATTN now. */ retval = rmi_enable_sensor(rmi_dev); if (retval) goto err_disable_irq; } return 0; err_disable_irq: rmi_disable_irq(rmi_dev, false); err_destroy_functions: rmi_free_function_list(rmi_dev); err: return retval; } static struct rmi_driver rmi_physical_driver = { .driver = { .owner = THIS_MODULE, .name = "rmi4_physical", .bus = &rmi_bus_type, .probe = rmi_driver_probe, .remove = rmi_driver_remove, }, .reset_handler = rmi_driver_reset_handler, .clear_irq_bits = rmi_driver_clear_irq_bits, .set_irq_bits = rmi_driver_set_irq_bits, .set_input_params = rmi_driver_set_input_params, }; bool rmi_is_physical_driver(struct device_driver *drv) { return drv == &rmi_physical_driver.driver; } int __init rmi_register_physical_driver(void) { int error; error = driver_register(&rmi_physical_driver.driver); if (error) { pr_err("%s: driver register failed, code=%d.\n", __func__, error); return error; } return 0; } void __exit rmi_unregister_physical_driver(void) { driver_unregister(&rmi_physical_driver.driver); } |