// SPDX-License-Identifier: GPL-2.0-only /* * * FIXME: Properly make this race free with refcounting etc... * * FIXME: LOCKING !!! */ #include <linux/delay.h> #include <linux/kernel.h> #include <linux/spinlock.h> #include <linux/slab.h> #include <linux/module.h> #include <linux/mutex.h> #include <linux/of.h> #include <asm/pmac_pfunc.h> /* Debug */ #define LOG_PARSE(fmt...) #define LOG_ERROR(fmt...) printk(fmt) #define LOG_BLOB(t,b,c) #undef DEBUG #ifdef DEBUG #define DBG(fmt...) printk(fmt) #else #define DBG(fmt...) #endif /* Command numbers */ #define PMF_CMD_LIST 0 #define PMF_CMD_WRITE_GPIO 1 #define PMF_CMD_READ_GPIO 2 #define PMF_CMD_WRITE_REG32 3 #define PMF_CMD_READ_REG32 4 #define PMF_CMD_WRITE_REG16 5 #define PMF_CMD_READ_REG16 6 #define PMF_CMD_WRITE_REG8 7 #define PMF_CMD_READ_REG8 8 #define PMF_CMD_DELAY 9 #define PMF_CMD_WAIT_REG32 10 #define PMF_CMD_WAIT_REG16 11 #define PMF_CMD_WAIT_REG8 12 #define PMF_CMD_READ_I2C 13 #define PMF_CMD_WRITE_I2C 14 #define PMF_CMD_RMW_I2C 15 #define PMF_CMD_GEN_I2C 16 #define PMF_CMD_SHIFT_BYTES_RIGHT 17 #define PMF_CMD_SHIFT_BYTES_LEFT 18 #define PMF_CMD_READ_CFG 19 #define PMF_CMD_WRITE_CFG 20 #define PMF_CMD_RMW_CFG 21 #define PMF_CMD_READ_I2C_SUBADDR 22 #define PMF_CMD_WRITE_I2C_SUBADDR 23 #define PMF_CMD_SET_I2C_MODE 24 #define PMF_CMD_RMW_I2C_SUBADDR 25 #define PMF_CMD_READ_REG32_MASK_SHR_XOR 26 #define PMF_CMD_READ_REG16_MASK_SHR_XOR 27 #define PMF_CMD_READ_REG8_MASK_SHR_XOR 28 #define PMF_CMD_WRITE_REG32_SHL_MASK 29 #define PMF_CMD_WRITE_REG16_SHL_MASK 30 #define PMF_CMD_WRITE_REG8_SHL_MASK 31 #define PMF_CMD_MASK_AND_COMPARE 32 #define PMF_CMD_COUNT 33 /* This structure holds the state of the parser while walking through * a function definition */ struct pmf_cmd { const void *cmdptr; const void *cmdend; struct pmf_function *func; void *instdata; struct pmf_args *args; int error; }; #if 0 /* Debug output */ static void print_blob(const char *title, const void *blob, int bytes) { printk("%s", title); while(bytes--) { printk("%02x ", *((u8 *)blob)); blob += 1; } printk("\n"); } #endif /* * Parser helpers */ static u32 pmf_next32(struct pmf_cmd *cmd) { u32 value; if ((cmd->cmdend - cmd->cmdptr) < 4) { cmd->error = 1; return 0; } value = *((u32 *)cmd->cmdptr); cmd->cmdptr += 4; return value; } static const void* pmf_next_blob(struct pmf_cmd *cmd, int count) { const void *value; if ((cmd->cmdend - cmd->cmdptr) < count) { cmd->error = 1; return NULL; } value = cmd->cmdptr; cmd->cmdptr += count; return value; } /* * Individual command parsers */ #define PMF_PARSE_CALL(name, cmd, handlers, p...) \ do { \ if (cmd->error) \ return -ENXIO; \ if (handlers == NULL) \ return 0; \ if (handlers->name) \ return handlers->name(cmd->func, cmd->instdata, \ cmd->args, p); \ return -1; \ } while(0) \ static int pmf_parser_write_gpio(struct pmf_cmd *cmd, struct pmf_handlers *h) { u8 value = (u8)pmf_next32(cmd); u8 mask = (u8)pmf_next32(cmd); LOG_PARSE("pmf: write_gpio(value: %02x, mask: %02x)\n", value, mask); PMF_PARSE_CALL(write_gpio, cmd, h, value, mask); } static int pmf_parser_read_gpio(struct pmf_cmd *cmd, struct pmf_handlers *h) { u8 mask = (u8)pmf_next32(cmd); int rshift = (int)pmf_next32(cmd); u8 xor = (u8)pmf_next32(cmd); LOG_PARSE("pmf: read_gpio(mask: %02x, rshift: %d, xor: %02x)\n", mask, rshift, xor); PMF_PARSE_CALL(read_gpio, cmd, h, mask, rshift, xor); } static int pmf_parser_write_reg32(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 value = pmf_next32(cmd); u32 mask = pmf_next32(cmd); LOG_PARSE("pmf: write_reg32(offset: %08x, value: %08x, mask: %08x)\n", offset, value, mask); PMF_PARSE_CALL(write_reg32, cmd, h, offset, value, mask); } static int pmf_parser_read_reg32(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); LOG_PARSE("pmf: read_reg32(offset: %08x)\n", offset); PMF_PARSE_CALL(read_reg32, cmd, h, offset); } static int pmf_parser_write_reg16(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u16 value = (u16)pmf_next32(cmd); u16 mask = (u16)pmf_next32(cmd); LOG_PARSE("pmf: write_reg16(offset: %08x, value: %04x, mask: %04x)\n", offset, value, mask); PMF_PARSE_CALL(write_reg16, cmd, h, offset, value, mask); } static int pmf_parser_read_reg16(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); LOG_PARSE("pmf: read_reg16(offset: %08x)\n", offset); PMF_PARSE_CALL(read_reg16, cmd, h, offset); } static int pmf_parser_write_reg8(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u8 value = (u16)pmf_next32(cmd); u8 mask = (u16)pmf_next32(cmd); LOG_PARSE("pmf: write_reg8(offset: %08x, value: %02x, mask: %02x)\n", offset, value, mask); PMF_PARSE_CALL(write_reg8, cmd, h, offset, value, mask); } static int pmf_parser_read_reg8(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); LOG_PARSE("pmf: read_reg8(offset: %08x)\n", offset); PMF_PARSE_CALL(read_reg8, cmd, h, offset); } static int pmf_parser_delay(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 duration = pmf_next32(cmd); LOG_PARSE("pmf: delay(duration: %d us)\n", duration); PMF_PARSE_CALL(delay, cmd, h, duration); } static int pmf_parser_wait_reg32(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 value = pmf_next32(cmd); u32 mask = pmf_next32(cmd); LOG_PARSE("pmf: wait_reg32(offset: %08x, comp_value: %08x,mask: %08x)\n", offset, value, mask); PMF_PARSE_CALL(wait_reg32, cmd, h, offset, value, mask); } static int pmf_parser_wait_reg16(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u16 value = (u16)pmf_next32(cmd); u16 mask = (u16)pmf_next32(cmd); LOG_PARSE("pmf: wait_reg16(offset: %08x, comp_value: %04x,mask: %04x)\n", offset, value, mask); PMF_PARSE_CALL(wait_reg16, cmd, h, offset, value, mask); } static int pmf_parser_wait_reg8(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u8 value = (u8)pmf_next32(cmd); u8 mask = (u8)pmf_next32(cmd); LOG_PARSE("pmf: wait_reg8(offset: %08x, comp_value: %02x,mask: %02x)\n", offset, value, mask); PMF_PARSE_CALL(wait_reg8, cmd, h, offset, value, mask); } static int pmf_parser_read_i2c(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 bytes = pmf_next32(cmd); LOG_PARSE("pmf: read_i2c(bytes: %ud)\n", bytes); PMF_PARSE_CALL(read_i2c, cmd, h, bytes); } static int pmf_parser_write_i2c(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 bytes = pmf_next32(cmd); const void *blob = pmf_next_blob(cmd, bytes); LOG_PARSE("pmf: write_i2c(bytes: %ud) ...\n", bytes); LOG_BLOB("pmf: data: \n", blob, bytes); PMF_PARSE_CALL(write_i2c, cmd, h, bytes, blob); } static int pmf_parser_rmw_i2c(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 maskbytes = pmf_next32(cmd); u32 valuesbytes = pmf_next32(cmd); u32 totalbytes = pmf_next32(cmd); const void *maskblob = pmf_next_blob(cmd, maskbytes); const void *valuesblob = pmf_next_blob(cmd, valuesbytes); LOG_PARSE("pmf: rmw_i2c(maskbytes: %ud, valuebytes: %ud, " "totalbytes: %d) ...\n", maskbytes, valuesbytes, totalbytes); LOG_BLOB("pmf: mask data: \n", maskblob, maskbytes); LOG_BLOB("pmf: values data: \n", valuesblob, valuesbytes); PMF_PARSE_CALL(rmw_i2c, cmd, h, maskbytes, valuesbytes, totalbytes, maskblob, valuesblob); } static int pmf_parser_read_cfg(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 bytes = pmf_next32(cmd); LOG_PARSE("pmf: read_cfg(offset: %x, bytes: %ud)\n", offset, bytes); PMF_PARSE_CALL(read_cfg, cmd, h, offset, bytes); } static int pmf_parser_write_cfg(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 bytes = pmf_next32(cmd); const void *blob = pmf_next_blob(cmd, bytes); LOG_PARSE("pmf: write_cfg(offset: %x, bytes: %ud)\n", offset, bytes); LOG_BLOB("pmf: data: \n", blob, bytes); PMF_PARSE_CALL(write_cfg, cmd, h, offset, bytes, blob); } static int pmf_parser_rmw_cfg(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 maskbytes = pmf_next32(cmd); u32 valuesbytes = pmf_next32(cmd); u32 totalbytes = pmf_next32(cmd); const void *maskblob = pmf_next_blob(cmd, maskbytes); const void *valuesblob = pmf_next_blob(cmd, valuesbytes); LOG_PARSE("pmf: rmw_cfg(maskbytes: %ud, valuebytes: %ud," " totalbytes: %d) ...\n", maskbytes, valuesbytes, totalbytes); LOG_BLOB("pmf: mask data: \n", maskblob, maskbytes); LOG_BLOB("pmf: values data: \n", valuesblob, valuesbytes); PMF_PARSE_CALL(rmw_cfg, cmd, h, offset, maskbytes, valuesbytes, totalbytes, maskblob, valuesblob); } static int pmf_parser_read_i2c_sub(struct pmf_cmd *cmd, struct pmf_handlers *h) { u8 subaddr = (u8)pmf_next32(cmd); u32 bytes = pmf_next32(cmd); LOG_PARSE("pmf: read_i2c_sub(subaddr: %x, bytes: %ud)\n", subaddr, bytes); PMF_PARSE_CALL(read_i2c_sub, cmd, h, subaddr, bytes); } static int pmf_parser_write_i2c_sub(struct pmf_cmd *cmd, struct pmf_handlers *h) { u8 subaddr = (u8)pmf_next32(cmd); u32 bytes = pmf_next32(cmd); const void *blob = pmf_next_blob(cmd, bytes); LOG_PARSE("pmf: write_i2c_sub(subaddr: %x, bytes: %ud) ...\n", subaddr, bytes); LOG_BLOB("pmf: data: \n", blob, bytes); PMF_PARSE_CALL(write_i2c_sub, cmd, h, subaddr, bytes, blob); } static int pmf_parser_set_i2c_mode(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 mode = pmf_next32(cmd); LOG_PARSE("pmf: set_i2c_mode(mode: %d)\n", mode); PMF_PARSE_CALL(set_i2c_mode, cmd, h, mode); } static int pmf_parser_rmw_i2c_sub(struct pmf_cmd *cmd, struct pmf_handlers *h) { u8 subaddr = (u8)pmf_next32(cmd); u32 maskbytes = pmf_next32(cmd); u32 valuesbytes = pmf_next32(cmd); u32 totalbytes = pmf_next32(cmd); const void *maskblob = pmf_next_blob(cmd, maskbytes); const void *valuesblob = pmf_next_blob(cmd, valuesbytes); LOG_PARSE("pmf: rmw_i2c_sub(subaddr: %x, maskbytes: %ud, valuebytes: %ud" ", totalbytes: %d) ...\n", subaddr, maskbytes, valuesbytes, totalbytes); LOG_BLOB("pmf: mask data: \n", maskblob, maskbytes); LOG_BLOB("pmf: values data: \n", valuesblob, valuesbytes); PMF_PARSE_CALL(rmw_i2c_sub, cmd, h, subaddr, maskbytes, valuesbytes, totalbytes, maskblob, valuesblob); } static int pmf_parser_read_reg32_msrx(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 mask = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 xor = pmf_next32(cmd); LOG_PARSE("pmf: read_reg32_msrx(offset: %x, mask: %x, shift: %x," " xor: %x\n", offset, mask, shift, xor); PMF_PARSE_CALL(read_reg32_msrx, cmd, h, offset, mask, shift, xor); } static int pmf_parser_read_reg16_msrx(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 mask = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 xor = pmf_next32(cmd); LOG_PARSE("pmf: read_reg16_msrx(offset: %x, mask: %x, shift: %x," " xor: %x\n", offset, mask, shift, xor); PMF_PARSE_CALL(read_reg16_msrx, cmd, h, offset, mask, shift, xor); } static int pmf_parser_read_reg8_msrx(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 mask = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 xor = pmf_next32(cmd); LOG_PARSE("pmf: read_reg8_msrx(offset: %x, mask: %x, shift: %x," " xor: %x\n", offset, mask, shift, xor); PMF_PARSE_CALL(read_reg8_msrx, cmd, h, offset, mask, shift, xor); } static int pmf_parser_write_reg32_slm(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 mask = pmf_next32(cmd); LOG_PARSE("pmf: write_reg32_slm(offset: %x, shift: %x, mask: %x\n", offset, shift, mask); PMF_PARSE_CALL(write_reg32_slm, cmd, h, offset, shift, mask); } static int pmf_parser_write_reg16_slm(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 mask = pmf_next32(cmd); LOG_PARSE("pmf: write_reg16_slm(offset: %x, shift: %x, mask: %x\n", offset, shift, mask); PMF_PARSE_CALL(write_reg16_slm, cmd, h, offset, shift, mask); } static int pmf_parser_write_reg8_slm(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 offset = pmf_next32(cmd); u32 shift = pmf_next32(cmd); u32 mask = pmf_next32(cmd); LOG_PARSE("pmf: write_reg8_slm(offset: %x, shift: %x, mask: %x\n", offset, shift, mask); PMF_PARSE_CALL(write_reg8_slm, cmd, h, offset, shift, mask); } static int pmf_parser_mask_and_compare(struct pmf_cmd *cmd, struct pmf_handlers *h) { u32 bytes = pmf_next32(cmd); const void *maskblob = pmf_next_blob(cmd, bytes); const void *valuesblob = pmf_next_blob(cmd, bytes); LOG_PARSE("pmf: mask_and_compare(length: %ud ...\n", bytes); LOG_BLOB("pmf: mask data: \n", maskblob, bytes); LOG_BLOB("pmf: values data: \n", valuesblob, bytes); PMF_PARSE_CALL(mask_and_compare, cmd, h, bytes, maskblob, valuesblob); } typedef int (*pmf_cmd_parser_t)(struct pmf_cmd *cmd, struct pmf_handlers *h); static pmf_cmd_parser_t pmf_parsers[PMF_CMD_COUNT] = { NULL, pmf_parser_write_gpio, pmf_parser_read_gpio, pmf_parser_write_reg32, pmf_parser_read_reg32, pmf_parser_write_reg16, pmf_parser_read_reg16, pmf_parser_write_reg8, pmf_parser_read_reg8, pmf_parser_delay, pmf_parser_wait_reg32, pmf_parser_wait_reg16, pmf_parser_wait_reg8, pmf_parser_read_i2c, pmf_parser_write_i2c, pmf_parser_rmw_i2c, NULL, /* Bogus command */ NULL, /* Shift bytes right: NYI */ NULL, /* Shift bytes left: NYI */ pmf_parser_read_cfg, pmf_parser_write_cfg, pmf_parser_rmw_cfg, pmf_parser_read_i2c_sub, pmf_parser_write_i2c_sub, pmf_parser_set_i2c_mode, pmf_parser_rmw_i2c_sub, pmf_parser_read_reg32_msrx, pmf_parser_read_reg16_msrx, pmf_parser_read_reg8_msrx, pmf_parser_write_reg32_slm, pmf_parser_write_reg16_slm, pmf_parser_write_reg8_slm, pmf_parser_mask_and_compare, }; struct pmf_device { struct list_head link; struct device_node *node; struct pmf_handlers *handlers; struct list_head functions; struct kref ref; }; static LIST_HEAD(pmf_devices); static DEFINE_SPINLOCK(pmf_lock); static DEFINE_MUTEX(pmf_irq_mutex); static void pmf_release_device(struct kref *kref) { struct pmf_device *dev = container_of(kref, struct pmf_device, ref); kfree(dev); } static inline void pmf_put_device(struct pmf_device *dev) { kref_put(&dev->ref, pmf_release_device); } static inline struct pmf_device *pmf_get_device(struct pmf_device *dev) { kref_get(&dev->ref); return dev; } static inline struct pmf_device *pmf_find_device(struct device_node *np) { struct pmf_device *dev; list_for_each_entry(dev, &pmf_devices, link) { if (dev->node == np) return pmf_get_device(dev); } return NULL; } static int pmf_parse_one(struct pmf_function *func, struct pmf_handlers *handlers, void *instdata, struct pmf_args *args) { struct pmf_cmd cmd; u32 ccode; int count, rc; cmd.cmdptr = func->data; cmd.cmdend = func->data + func->length; cmd.func = func; cmd.instdata = instdata; cmd.args = args; cmd.error = 0; LOG_PARSE("pmf: func %s, %d bytes, %s...\n", func->name, func->length, handlers ? "executing" : "parsing"); /* One subcommand to parse for now */ count = 1; while(count-- && cmd.cmdptr < cmd.cmdend) { /* Get opcode */ ccode = pmf_next32(&cmd); /* Check if we are hitting a command list, fetch new count */ if (ccode == 0) { count = pmf_next32(&cmd) - 1; ccode = pmf_next32(&cmd); } if (cmd.error) { LOG_ERROR("pmf: parse error, not enough data\n"); return -ENXIO; } if (ccode >= PMF_CMD_COUNT) { LOG_ERROR("pmf: command code %d unknown !\n", ccode); return -ENXIO; } if (pmf_parsers[ccode] == NULL) { LOG_ERROR("pmf: no parser for command %d !\n", ccode); return -ENXIO; } rc = pmf_parsers[ccode](&cmd, handlers); if (rc != 0) { LOG_ERROR("pmf: parser for command %d returned" " error %d\n", ccode, rc); return rc; } } /* We are doing an initial parse pass, we need to adjust the size */ if (handlers == NULL) func->length = cmd.cmdptr - func->data; return 0; } static int pmf_add_function_prop(struct pmf_device *dev, void *driverdata, const char *name, u32 *data, unsigned int length) { int count = 0; struct pmf_function *func = NULL; DBG("pmf: Adding functions for platform-do-%s\n", name); while (length >= 12) { /* Allocate a structure */ func = kzalloc(sizeof(*func), GFP_KERNEL); if (func == NULL) goto bail; kref_init(&func->ref); INIT_LIST_HEAD(&func->irq_clients); func->node = dev->node; func->driver_data = driverdata; func->name = name; func->phandle = data[0]; func->flags = data[1]; data += 2; length -= 8; func->data = data; func->length = length; func->dev = dev; DBG("pmf: idx %d: flags=%08x, phandle=%08x " " %d bytes remaining, parsing...\n", count+1, func->flags, func->phandle, length); if (pmf_parse_one(func, NULL, NULL, NULL)) { kfree(func); goto bail; } length -= func->length; data = (u32 *)(((u8 *)data) + func->length); list_add(&func->link, &dev->functions); pmf_get_device(dev); count++; } bail: DBG("pmf: Added %d functions\n", count); return count; } static int pmf_add_functions(struct pmf_device *dev, void *driverdata) { struct property *pp; #define PP_PREFIX "platform-do-" const int plen = strlen(PP_PREFIX); int count = 0; for_each_property_of_node(dev->node, pp) { const char *name; if (strncmp(pp->name, PP_PREFIX, plen) != 0) continue; name = pp->name + plen; if (strlen(name) && pp->length >= 12) count += pmf_add_function_prop(dev, driverdata, name, pp->value, pp->length); } return count; } int pmf_register_driver(struct device_node *np, struct pmf_handlers *handlers, void *driverdata) { struct pmf_device *dev; unsigned long flags; int rc = 0; if (handlers == NULL) return -EINVAL; DBG("pmf: registering driver for node %pOF\n", np); spin_lock_irqsave(&pmf_lock, flags); dev = pmf_find_device(np); spin_unlock_irqrestore(&pmf_lock, flags); if (dev != NULL) { DBG("pmf: already there !\n"); pmf_put_device(dev); return -EBUSY; } dev = kzalloc(sizeof(*dev), GFP_KERNEL); if (dev == NULL) { DBG("pmf: no memory !\n"); return -ENOMEM; } kref_init(&dev->ref); dev->node = of_node_get(np); dev->handlers = handlers; INIT_LIST_HEAD(&dev->functions); rc = pmf_add_functions(dev, driverdata); if (rc == 0) { DBG("pmf: no functions, disposing.. \n"); of_node_put(np); kfree(dev); return -ENODEV; } spin_lock_irqsave(&pmf_lock, flags); list_add(&dev->link, &pmf_devices); spin_unlock_irqrestore(&pmf_lock, flags); return 0; } EXPORT_SYMBOL_GPL(pmf_register_driver); struct pmf_function *pmf_get_function(struct pmf_function *func) { if (!try_module_get(func->dev->handlers->owner)) return NULL; kref_get(&func->ref); return func; } EXPORT_SYMBOL_GPL(pmf_get_function); static void pmf_release_function(struct kref *kref) { struct pmf_function *func = container_of(kref, struct pmf_function, ref); pmf_put_device(func->dev); kfree(func); } static inline void __pmf_put_function(struct pmf_function *func) { kref_put(&func->ref, pmf_release_function); } void pmf_put_function(struct pmf_function *func) { if (func == NULL) return; module_put(func->dev->handlers->owner); __pmf_put_function(func); } EXPORT_SYMBOL_GPL(pmf_put_function); void pmf_unregister_driver(struct device_node *np) { struct pmf_device *dev; unsigned long flags; DBG("pmf: unregistering driver for node %pOF\n", np); spin_lock_irqsave(&pmf_lock, flags); dev = pmf_find_device(np); if (dev == NULL) { DBG("pmf: not such driver !\n"); spin_unlock_irqrestore(&pmf_lock, flags); return; } list_del(&dev->link); while(!list_empty(&dev->functions)) { struct pmf_function *func = list_entry(dev->functions.next, typeof(*func), link); list_del(&func->link); __pmf_put_function(func); } pmf_put_device(dev); spin_unlock_irqrestore(&pmf_lock, flags); } EXPORT_SYMBOL_GPL(pmf_unregister_driver); static struct pmf_function *__pmf_find_function(struct device_node *target, const char *name, u32 flags) { struct device_node *actor = of_node_get(target); struct pmf_device *dev; struct pmf_function *func, *result = NULL; char fname[64]; const u32 *prop; u32 ph; /* * Look for a "platform-*" function reference. If we can't find * one, then we fallback to a direct call attempt */ snprintf(fname, 63, "platform-%s", name); prop = of_get_property(target, fname, NULL); if (prop == NULL) goto find_it; ph = *prop; if (ph == 0) goto find_it; /* * Ok, now try to find the actor. If we can't find it, we fail, * there is no point in falling back there */ of_node_put(actor); actor = of_find_node_by_phandle(ph); if (actor == NULL) return NULL; find_it: dev = pmf_find_device(actor); if (dev == NULL) { result = NULL; goto out; } list_for_each_entry(func, &dev->functions, link) { if (name && strcmp(name, func->name)) continue; if (func->phandle && target->phandle != func->phandle) continue; if ((func->flags & flags) == 0) continue; result = func; break; } pmf_put_device(dev); out: of_node_put(actor); return result; } int pmf_register_irq_client(struct device_node *target, const char *name, struct pmf_irq_client *client) { struct pmf_function *func; unsigned long flags; spin_lock_irqsave(&pmf_lock, flags); func = __pmf_find_function(target, name, PMF_FLAGS_INT_GEN); if (func) func = pmf_get_function(func); spin_unlock_irqrestore(&pmf_lock, flags); if (func == NULL) return -ENODEV; /* guard against manipulations of list */ mutex_lock(&pmf_irq_mutex); if (list_empty(&func->irq_clients)) func->dev->handlers->irq_enable(func); /* guard against pmf_do_irq while changing list */ spin_lock_irqsave(&pmf_lock, flags); list_add(&client->link, &func->irq_clients); spin_unlock_irqrestore(&pmf_lock, flags); client->func = func; mutex_unlock(&pmf_irq_mutex); return 0; } EXPORT_SYMBOL_GPL(pmf_register_irq_client); void pmf_unregister_irq_client(struct pmf_irq_client *client) { struct pmf_function *func = client->func; unsigned long flags; BUG_ON(func == NULL); /* guard against manipulations of list */ mutex_lock(&pmf_irq_mutex); client->func = NULL; /* guard against pmf_do_irq while changing list */ spin_lock_irqsave(&pmf_lock, flags); list_del(&client->link); spin_unlock_irqrestore(&pmf_lock, flags); if (list_empty(&func->irq_clients)) func->dev->handlers->irq_disable(func); mutex_unlock(&pmf_irq_mutex); pmf_put_function(func); } EXPORT_SYMBOL_GPL(pmf_unregister_irq_client); void pmf_do_irq(struct pmf_function *func) { unsigned long flags; struct pmf_irq_client *client; /* For now, using a spinlock over the whole function. Can be made * to drop the lock using 2 lists if necessary */ spin_lock_irqsave(&pmf_lock, flags); list_for_each_entry(client, &func->irq_clients, link) { if (!try_module_get(client->owner)) continue; client->handler(client->data); module_put(client->owner); } spin_unlock_irqrestore(&pmf_lock, flags); } EXPORT_SYMBOL_GPL(pmf_do_irq); int pmf_call_one(struct pmf_function *func, struct pmf_args *args) { struct pmf_device *dev = func->dev; void *instdata = NULL; int rc = 0; DBG(" ** pmf_call_one(%pOF/%s) **\n", dev->node, func->name); if (dev->handlers->begin) instdata = dev->handlers->begin(func, args); rc = pmf_parse_one(func, dev->handlers, instdata, args); if (dev->handlers->end) dev->handlers->end(func, instdata); return rc; } EXPORT_SYMBOL_GPL(pmf_call_one); int pmf_do_functions(struct device_node *np, const char *name, u32 phandle, u32 fflags, struct pmf_args *args) { struct pmf_device *dev; struct pmf_function *func, *tmp; unsigned long flags; int rc = -ENODEV; spin_lock_irqsave(&pmf_lock, flags); dev = pmf_find_device(np); if (dev == NULL) { spin_unlock_irqrestore(&pmf_lock, flags); return -ENODEV; } list_for_each_entry_safe(func, tmp, &dev->functions, link) { if (name && strcmp(name, func->name)) continue; if (phandle && func->phandle && phandle != func->phandle) continue; if ((func->flags & fflags) == 0) continue; if (pmf_get_function(func) == NULL) continue; spin_unlock_irqrestore(&pmf_lock, flags); rc = pmf_call_one(func, args); pmf_put_function(func); spin_lock_irqsave(&pmf_lock, flags); } pmf_put_device(dev); spin_unlock_irqrestore(&pmf_lock, flags); return rc; } EXPORT_SYMBOL_GPL(pmf_do_functions); struct pmf_function *pmf_find_function(struct device_node *target, const char *name) { struct pmf_function *func; unsigned long flags; spin_lock_irqsave(&pmf_lock, flags); func = __pmf_find_function(target, name, PMF_FLAGS_ON_DEMAND); if (func) func = pmf_get_function(func); spin_unlock_irqrestore(&pmf_lock, flags); return func; } EXPORT_SYMBOL_GPL(pmf_find_function); int pmf_call_function(struct device_node *target, const char *name, struct pmf_args *args) { struct pmf_function *func = pmf_find_function(target, name); int rc; if (func == NULL) return -ENODEV; rc = pmf_call_one(func, args); pmf_put_function(func); return rc; } EXPORT_SYMBOL_GPL(pmf_call_function);