/* * Copyright (C) 2007-2009 ST-Ericsson * License terms: GNU General Public License (GPL) version 2 * Low-level core for exclusive access to the AB3100 IC on the I2C bus * and some basic chip-configuration. * Author: Linus Walleij */ #include #include #include #include #include #include #include #include #include #include #include #include /* These are the only registers inside AB3100 used in this main file */ /* Interrupt event registers */ #define AB3100_EVENTA1 0x21 #define AB3100_EVENTA2 0x22 #define AB3100_EVENTA3 0x23 /* AB3100 DAC converter registers */ #define AB3100_DIS 0x00 #define AB3100_D0C 0x01 #define AB3100_D1C 0x02 #define AB3100_D2C 0x03 #define AB3100_D3C 0x04 /* Chip ID register */ #define AB3100_CID 0x20 /* AB3100 interrupt registers */ #define AB3100_IMRA1 0x24 #define AB3100_IMRA2 0x25 #define AB3100_IMRA3 0x26 #define AB3100_IMRB1 0x2B #define AB3100_IMRB2 0x2C #define AB3100_IMRB3 0x2D /* System Power Monitoring and control registers */ #define AB3100_MCA 0x2E #define AB3100_MCB 0x2F /* SIM power up */ #define AB3100_SUP 0x50 /* * I2C communication * * The AB3100 is usually assigned address 0x48 (7-bit) * The chip is defined in the platform i2c_board_data section. */ u8 ab3100_get_chip_type(struct ab3100 *ab3100) { u8 chip = ABUNKNOWN; switch (ab3100->chip_id & 0xf0) { case 0xa0: chip = AB3000; break; case 0xc0: chip = AB3100; break; } return chip; } EXPORT_SYMBOL(ab3100_get_chip_type); int ab3100_set_register_interruptible(struct ab3100 *ab3100, u8 reg, u8 regval) { u8 regandval[2] = {reg, regval}; int err; err = mutex_lock_interruptible(&ab3100->access_mutex); if (err) return err; /* * A two-byte write message with the first byte containing the register * number and the second byte containing the value to be written * effectively sets a register in the AB3100. */ err = i2c_master_send(ab3100->i2c_client, regandval, 2); if (err < 0) { dev_err(ab3100->dev, "write error (write register): %d\n", err); } else if (err != 2) { dev_err(ab3100->dev, "write error (write register) " "%d bytes transferred (expected 2)\n", err); err = -EIO; } else { /* All is well */ err = 0; } mutex_unlock(&ab3100->access_mutex); return err; } EXPORT_SYMBOL(ab3100_set_register_interruptible); /* * The test registers exist at an I2C bus address up one * from the ordinary base. They are not supposed to be used * in production code, but sometimes you have to do that * anyway. It's currently only used from this file so declare * it static and do not export. */ static int ab3100_set_test_register_interruptible(struct ab3100 *ab3100, u8 reg, u8 regval) { u8 regandval[2] = {reg, regval}; int err; err = mutex_lock_interruptible(&ab3100->access_mutex); if (err) return err; err = i2c_master_send(ab3100->testreg_client, regandval, 2); if (err < 0) { dev_err(ab3100->dev, "write error (write test register): %d\n", err); } else if (err != 2) { dev_err(ab3100->dev, "write error (write test register) " "%d bytes transferred (expected 2)\n", err); err = -EIO; } else { /* All is well */ err = 0; } mutex_unlock(&ab3100->access_mutex); return err; } int ab3100_get_register_interruptible(struct ab3100 *ab3100, u8 reg, u8 *regval) { int err; err = mutex_lock_interruptible(&ab3100->access_mutex); if (err) return err; /* * AB3100 require an I2C "stop" command between each message, else * it will not work. The only way of achieveing this with the * message transport layer is to send the read and write messages * separately. */ err = i2c_master_send(ab3100->i2c_client, ®, 1); if (err < 0) { dev_err(ab3100->dev, "write error (send register address): %d\n", err); goto get_reg_out_unlock; } else if (err != 1) { dev_err(ab3100->dev, "write error (send register address) " "%d bytes transferred (expected 1)\n", err); err = -EIO; goto get_reg_out_unlock; } else { /* All is well */ err = 0; } err = i2c_master_recv(ab3100->i2c_client, regval, 1); if (err < 0) { dev_err(ab3100->dev, "write error (read register): %d\n", err); goto get_reg_out_unlock; } else if (err != 1) { dev_err(ab3100->dev, "write error (read register) " "%d bytes transferred (expected 1)\n", err); err = -EIO; goto get_reg_out_unlock; } else { /* All is well */ err = 0; } get_reg_out_unlock: mutex_unlock(&ab3100->access_mutex); return err; } EXPORT_SYMBOL(ab3100_get_register_interruptible); int ab3100_get_register_page_interruptible(struct ab3100 *ab3100, u8 first_reg, u8 *regvals, u8 numregs) { int err; if (ab3100->chip_id == 0xa0 || ab3100->chip_id == 0xa1) /* These don't support paged reads */ return -EIO; err = mutex_lock_interruptible(&ab3100->access_mutex); if (err) return err; /* * Paged read also require an I2C "stop" command. */ err = i2c_master_send(ab3100->i2c_client, &first_reg, 1); if (err < 0) { dev_err(ab3100->dev, "write error (send first register address): %d\n", err); goto get_reg_page_out_unlock; } else if (err != 1) { dev_err(ab3100->dev, "write error (send first register address) " "%d bytes transferred (expected 1)\n", err); err = -EIO; goto get_reg_page_out_unlock; } err = i2c_master_recv(ab3100->i2c_client, regvals, numregs); if (err < 0) { dev_err(ab3100->dev, "write error (read register page): %d\n", err); goto get_reg_page_out_unlock; } else if (err != numregs) { dev_err(ab3100->dev, "write error (read register page) " "%d bytes transferred (expected %d)\n", err, numregs); err = -EIO; goto get_reg_page_out_unlock; } /* All is well */ err = 0; get_reg_page_out_unlock: mutex_unlock(&ab3100->access_mutex); return err; } EXPORT_SYMBOL(ab3100_get_register_page_interruptible); int ab3100_mask_and_set_register_interruptible(struct ab3100 *ab3100, u8 reg, u8 andmask, u8 ormask) { u8 regandval[2] = {reg, 0}; int err; err = mutex_lock_interruptible(&ab3100->access_mutex); if (err) return err; /* First read out the target register */ err = i2c_master_send(ab3100->i2c_client, ®, 1); if (err < 0) { dev_err(ab3100->dev, "write error (maskset send address): %d\n", err); goto get_maskset_unlock; } else if (err != 1) { dev_err(ab3100->dev, "write error (maskset send address) " "%d bytes transferred (expected 1)\n", err); err = -EIO; goto get_maskset_unlock; } err = i2c_master_recv(ab3100->i2c_client, ®andval[1], 1); if (err < 0) { dev_err(ab3100->dev, "write error (maskset read register): %d\n", err); goto get_maskset_unlock; } else if (err != 1) { dev_err(ab3100->dev, "write error (maskset read register) " "%d bytes transferred (expected 1)\n", err); err = -EIO; goto get_maskset_unlock; } /* Modify the register */ regandval[1] &= andmask; regandval[1] |= ormask; /* Write the register */ err = i2c_master_send(ab3100->i2c_client, regandval, 2); if (err < 0) { dev_err(ab3100->dev, "write error (write register): %d\n", err); goto get_maskset_unlock; } else if (err != 2) { dev_err(ab3100->dev, "write error (write register) " "%d bytes transferred (expected 2)\n", err); err = -EIO; goto get_maskset_unlock; } /* All is well */ err = 0; get_maskset_unlock: mutex_unlock(&ab3100->access_mutex); return err; } EXPORT_SYMBOL(ab3100_mask_and_set_register_interruptible); /* * Register a simple callback for handling any AB3100 events. */ int ab3100_event_register(struct ab3100 *ab3100, struct notifier_block *nb) { return blocking_notifier_chain_register(&ab3100->event_subscribers, nb); } EXPORT_SYMBOL(ab3100_event_register); /* * Remove a previously registered callback. */ int ab3100_event_unregister(struct ab3100 *ab3100, struct notifier_block *nb) { return blocking_notifier_chain_unregister(&ab3100->event_subscribers, nb); } EXPORT_SYMBOL(ab3100_event_unregister); int ab3100_event_registers_startup_state_get(struct ab3100 *ab3100, u32 *fatevent) { if (!ab3100->startup_events_read) return -EAGAIN; /* Try again later */ *fatevent = ab3100->startup_events; return 0; } EXPORT_SYMBOL(ab3100_event_registers_startup_state_get); /* Interrupt handling worker */ static void ab3100_work(struct work_struct *work) { struct ab3100 *ab3100 = container_of(work, struct ab3100, work); u8 event_regs[3]; u32 fatevent; int err; err = ab3100_get_register_page_interruptible(ab3100, AB3100_EVENTA1, event_regs, 3); if (err) goto err_event_wq; fatevent = (event_regs[0] << 16) | (event_regs[1] << 8) | event_regs[2]; if (!ab3100->startup_events_read) { ab3100->startup_events = fatevent; ab3100->startup_events_read = true; } /* * The notified parties will have to mask out the events * they're interested in and react to them. They will be * notified on all events, then they use the fatevent value * to determine if they're interested. */ blocking_notifier_call_chain(&ab3100->event_subscribers, fatevent, NULL); dev_dbg(ab3100->dev, "IRQ Event: 0x%08x\n", fatevent); /* By now the IRQ should be acked and deasserted so enable it again */ enable_irq(ab3100->i2c_client->irq); return; err_event_wq: dev_dbg(ab3100->dev, "error in event workqueue\n"); /* Enable the IRQ anyway, what choice do we have? */ enable_irq(ab3100->i2c_client->irq); return; } static irqreturn_t ab3100_irq_handler(int irq, void *data) { struct ab3100 *ab3100 = data; /* * Disable the IRQ and dispatch a worker to handle the * event. Since the chip resides on I2C this is slow * stuff and we will re-enable the interrupts once th * worker has finished. */ disable_irq_nosync(irq); schedule_work(&ab3100->work); return IRQ_HANDLED; } #ifdef CONFIG_DEBUG_FS /* * Some debugfs entries only exposed if we're using debug */ static int ab3100_registers_print(struct seq_file *s, void *p) { struct ab3100 *ab3100 = s->private; u8 value; u8 reg; seq_printf(s, "AB3100 registers:\n"); for (reg = 0; reg < 0xff; reg++) { ab3100_get_register_interruptible(ab3100, reg, &value); seq_printf(s, "[0x%x]: 0x%x\n", reg, value); } return 0; } static int ab3100_registers_open(struct inode *inode, struct file *file) { return single_open(file, ab3100_registers_print, inode->i_private); } static const struct file_operations ab3100_registers_fops = { .open = ab3100_registers_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, .owner = THIS_MODULE, }; struct ab3100_get_set_reg_priv { struct ab3100 *ab3100; bool mode; }; static int ab3100_get_set_reg_open_file(struct inode *inode, struct file *file) { file->private_data = inode->i_private; return 0; } static ssize_t ab3100_get_set_reg(struct file *file, const char __user *user_buf, size_t count, loff_t *ppos) { struct ab3100_get_set_reg_priv *priv = file->private_data; struct ab3100 *ab3100 = priv->ab3100; char buf[32]; ssize_t buf_size; int regp; unsigned long user_reg; int err; int i = 0; /* Get userspace string and assure termination */ buf_size = min(count, (sizeof(buf)-1)); if (copy_from_user(buf, user_buf, buf_size)) return -EFAULT; buf[buf_size] = 0; /* * The idea is here to parse a string which is either * "0xnn" for reading a register, or "0xaa 0xbb" for * writing 0xbb to the register 0xaa. First move past * whitespace and then begin to parse the register. */ while ((i < buf_size) && (buf[i] == ' ')) i++; regp = i; /* * Advance pointer to end of string then terminate * the register string. This is needed to satisfy * the strict_strtoul() function. */ while ((i < buf_size) && (buf[i] != ' ')) i++; buf[i] = '\0'; err = strict_strtoul(&buf[regp], 16, &user_reg); if (err) return err; if (user_reg > 0xff) return -EINVAL; /* Either we read or we write a register here */ if (!priv->mode) { /* Reading */ u8 reg = (u8) user_reg; u8 regvalue; ab3100_get_register_interruptible(ab3100, reg, ®value); dev_info(ab3100->dev, "debug read AB3100 reg[0x%02x]: 0x%02x\n", reg, regvalue); } else { int valp; unsigned long user_value; u8 reg = (u8) user_reg; u8 value; u8 regvalue; /* * Writing, we need some value to write to * the register so keep parsing the string * from userspace. */ i++; while ((i < buf_size) && (buf[i] == ' ')) i++; valp = i; while ((i < buf_size) && (buf[i] != ' ')) i++; buf[i] = '\0'; err = strict_strtoul(&buf[valp], 16, &user_value); if (err) return err; if (user_reg > 0xff) return -EINVAL; value = (u8) user_value; ab3100_set_register_interruptible(ab3100, reg, value); ab3100_get_register_interruptible(ab3100, reg, ®value); dev_info(ab3100->dev, "debug write reg[0x%02x] with 0x%02x, " "after readback: 0x%02x\n", reg, value, regvalue); } return buf_size; } static const struct file_operations ab3100_get_set_reg_fops = { .open = ab3100_get_set_reg_open_file, .write = ab3100_get_set_reg, }; static struct dentry *ab3100_dir; static struct dentry *ab3100_reg_file; static struct ab3100_get_set_reg_priv ab3100_get_priv; static struct dentry *ab3100_get_reg_file; static struct ab3100_get_set_reg_priv ab3100_set_priv; static struct dentry *ab3100_set_reg_file; static void ab3100_setup_debugfs(struct ab3100 *ab3100) { int err; ab3100_dir = debugfs_create_dir("ab3100", NULL); if (!ab3100_dir) goto exit_no_debugfs; ab3100_reg_file = debugfs_create_file("registers", S_IRUGO, ab3100_dir, ab3100, &ab3100_registers_fops); if (!ab3100_reg_file) { err = -ENOMEM; goto exit_destroy_dir; } ab3100_get_priv.ab3100 = ab3100; ab3100_get_priv.mode = false; ab3100_get_reg_file = debugfs_create_file("get_reg", S_IWUGO, ab3100_dir, &ab3100_get_priv, &ab3100_get_set_reg_fops); if (!ab3100_get_reg_file) { err = -ENOMEM; goto exit_destroy_reg; } ab3100_set_priv.ab3100 = ab3100; ab3100_set_priv.mode = true; ab3100_set_reg_file = debugfs_create_file("set_reg", S_IWUGO, ab3100_dir, &ab3100_set_priv, &ab3100_get_set_reg_fops); if (!ab3100_set_reg_file) { err = -ENOMEM; goto exit_destroy_get_reg; } return; exit_destroy_get_reg: debugfs_remove(ab3100_get_reg_file); exit_destroy_reg: debugfs_remove(ab3100_reg_file); exit_destroy_dir: debugfs_remove(ab3100_dir); exit_no_debugfs: return; } static inline void ab3100_remove_debugfs(void) { debugfs_remove(ab3100_set_reg_file); debugfs_remove(ab3100_get_reg_file); debugfs_remove(ab3100_reg_file); debugfs_remove(ab3100_dir); } #else static inline void ab3100_setup_debugfs(struct ab3100 *ab3100) { } static inline void ab3100_remove_debugfs(void) { } #endif /* * Basic set-up, datastructure creation/destruction and I2C interface. * This sets up a default config in the AB3100 chip so that it * will work as expected. */ struct ab3100_init_setting { u8 abreg; u8 setting; }; static const struct ab3100_init_setting __initconst ab3100_init_settings[] = { { .abreg = AB3100_MCA, .setting = 0x01 }, { .abreg = AB3100_MCB, .setting = 0x30 }, { .abreg = AB3100_IMRA1, .setting = 0x00 }, { .abreg = AB3100_IMRA2, .setting = 0xFF }, { .abreg = AB3100_IMRA3, .setting = 0x01 }, { .abreg = AB3100_IMRB1, .setting = 0xBF }, { .abreg = AB3100_IMRB2, .setting = 0xFF }, { .abreg = AB3100_IMRB3, .setting = 0xFF }, { .abreg = AB3100_SUP, .setting = 0x00 }, { .abreg = AB3100_DIS, .setting = 0xF0 }, { .abreg = AB3100_D0C, .setting = 0x00 }, { .abreg = AB3100_D1C, .setting = 0x00 }, { .abreg = AB3100_D2C, .setting = 0x00 }, { .abreg = AB3100_D3C, .setting = 0x00 }, }; static int __init ab3100_setup(struct ab3100 *ab3100) { int err = 0; int i; for (i = 0; i < ARRAY_SIZE(ab3100_init_settings); i++) { err = ab3100_set_register_interruptible(ab3100, ab3100_init_settings[i].abreg, ab3100_init_settings[i].setting); if (err) goto exit_no_setup; } /* * Special trick to make the AB3100 use the 32kHz clock (RTC) * bit 3 in test register 0x02 is a special, undocumented test * register bit that only exist in AB3100 P1E */ if (ab3100->chip_id == 0xc4) { dev_warn(ab3100->dev, "AB3100 P1E variant detected, " "forcing chip to 32KHz\n"); err = ab3100_set_test_register_interruptible(ab3100, 0x02, 0x08); } exit_no_setup: return err; } /* * Here we define all the platform devices that appear * as children of the AB3100. These are regular platform * devices with the IORESOURCE_IO .start and .end set * to correspond to the internal AB3100 register range * mapping to the corresponding subdevice. */ #define AB3100_DEVICE(devname, devid) \ static struct platform_device ab3100_##devname##_device = { \ .name = devid, \ .id = -1, \ } /* * This lists all the subdevices and corresponding register * ranges. */ AB3100_DEVICE(dac, "ab3100-dac"); AB3100_DEVICE(leds, "ab3100-leds"); AB3100_DEVICE(power, "ab3100-power"); AB3100_DEVICE(regulators, "ab3100-regulators"); AB3100_DEVICE(sim, "ab3100-sim"); AB3100_DEVICE(uart, "ab3100-uart"); AB3100_DEVICE(rtc, "ab3100-rtc"); AB3100_DEVICE(charger, "ab3100-charger"); AB3100_DEVICE(boost, "ab3100-boost"); AB3100_DEVICE(adc, "ab3100-adc"); AB3100_DEVICE(fuelgauge, "ab3100-fuelgauge"); AB3100_DEVICE(vibrator, "ab3100-vibrator"); AB3100_DEVICE(otp, "ab3100-otp"); AB3100_DEVICE(codec, "ab3100-codec"); static struct platform_device * ab3100_platform_devs[] = { &ab3100_dac_device, &ab3100_leds_device, &ab3100_power_device, &ab3100_regulators_device, &ab3100_sim_device, &ab3100_uart_device, &ab3100_rtc_device, &ab3100_charger_device, &ab3100_boost_device, &ab3100_adc_device, &ab3100_fuelgauge_device, &ab3100_vibrator_device, &ab3100_otp_device, &ab3100_codec_device, }; struct ab_family_id { u8 id; char *name; }; static const struct ab_family_id ids[] __initdata = { /* AB3100 */ { .id = 0xc0, .name = "P1A" }, { .id = 0xc1, .name = "P1B" }, { .id = 0xc2, .name = "P1C" }, { .id = 0xc3, .name = "P1D" }, { .id = 0xc4, .name = "P1E" }, { .id = 0xc5, .name = "P1F/R1A" }, { .id = 0xc6, .name = "P1G/R1A" }, { .id = 0xc7, .name = "P2A/R2A" }, { .id = 0xc8, .name = "P2B/R2B" }, /* AB3000 variants, not supported */ { .id = 0xa0 }, { .id = 0xa1 }, { .id = 0xa2 }, { .id = 0xa3 }, { .id = 0xa4 }, { .id = 0xa5 }, { .id = 0xa6 }, { .id = 0xa7 }, /* Terminator */ { .id = 0x00, }, }; static int __init ab3100_probe(struct i2c_client *client, const struct i2c_device_id *id) { struct ab3100 *ab3100; struct ab3100_platform_data *ab3100_plf_data = client->dev.platform_data; int err; int i; ab3100 = kzalloc(sizeof(struct ab3100), GFP_KERNEL); if (!ab3100) { dev_err(&client->dev, "could not allocate AB3100 device\n"); return -ENOMEM; } /* Initialize data structure */ mutex_init(&ab3100->access_mutex); BLOCKING_INIT_NOTIFIER_HEAD(&ab3100->event_subscribers); ab3100->i2c_client = client; ab3100->dev = &ab3100->i2c_client->dev; i2c_set_clientdata(client, ab3100); /* Read chip ID register */ err = ab3100_get_register_interruptible(ab3100, AB3100_CID, &ab3100->chip_id); if (err) { dev_err(&client->dev, "could not communicate with the AB3100 analog " "baseband chip\n"); goto exit_no_detect; } for (i = 0; ids[i].id != 0x0; i++) { if (ids[i].id == ab3100->chip_id) { if (ids[i].name != NULL) { snprintf(&ab3100->chip_name[0], sizeof(ab3100->chip_name) - 1, "AB3100 %s", ids[i].name); break; } else { dev_err(&client->dev, "AB3000 is not supported\n"); goto exit_no_detect; } } } if (ids[i].id == 0x0) { dev_err(&client->dev, "unknown analog baseband chip id: 0x%x\n", ab3100->chip_id); dev_err(&client->dev, "accepting it anyway. Please update " "the driver.\n"); goto exit_no_detect; } dev_info(&client->dev, "Detected chip: %s\n", &ab3100->chip_name[0]); /* Attach a second dummy i2c_client to the test register address */ ab3100->testreg_client = i2c_new_dummy(client->adapter, client->addr + 1); if (!ab3100->testreg_client) { err = -ENOMEM; goto exit_no_testreg_client; } err = ab3100_setup(ab3100); if (err) goto exit_no_setup; INIT_WORK(&ab3100->work, ab3100_work); /* This real unpredictable IRQ is of course sampled for entropy */ err = request_irq(client->irq, ab3100_irq_handler, IRQF_DISABLED | IRQF_SAMPLE_RANDOM, "AB3100 IRQ", ab3100); if (err) goto exit_no_irq; /* Set parent and a pointer back to the container in device data */ for (i = 0; i < ARRAY_SIZE(ab3100_platform_devs); i++) { ab3100_platform_devs[i]->dev.parent = &client->dev; ab3100_platform_devs[i]->dev.platform_data = ab3100_plf_data; platform_set_drvdata(ab3100_platform_devs[i], ab3100); } /* Register the platform devices */ platform_add_devices(ab3100_platform_devs, ARRAY_SIZE(ab3100_platform_devs)); ab3100_setup_debugfs(ab3100); return 0; exit_no_irq: exit_no_setup: i2c_unregister_device(ab3100->testreg_client); exit_no_testreg_client: exit_no_detect: kfree(ab3100); return err; } static int __exit ab3100_remove(struct i2c_client *client) { struct ab3100 *ab3100 = i2c_get_clientdata(client); int i; /* Unregister subdevices */ for (i = 0; i < ARRAY_SIZE(ab3100_platform_devs); i++) platform_device_unregister(ab3100_platform_devs[i]); ab3100_remove_debugfs(); i2c_unregister_device(ab3100->testreg_client); /* * At this point, all subscribers should have unregistered * their notifiers so deactivate IRQ */ free_irq(client->irq, ab3100); kfree(ab3100); return 0; } static const struct i2c_device_id ab3100_id[] = { { "ab3100", 0 }, { } }; MODULE_DEVICE_TABLE(i2c, ab3100_id); static struct i2c_driver ab3100_driver = { .driver = { .name = "ab3100", .owner = THIS_MODULE, }, .id_table = ab3100_id, .probe = ab3100_probe, .remove = __exit_p(ab3100_remove), }; static int __init ab3100_i2c_init(void) { return i2c_add_driver(&ab3100_driver); } static void __exit ab3100_i2c_exit(void) { i2c_del_driver(&ab3100_driver); } subsys_initcall(ab3100_i2c_init); module_exit(ab3100_i2c_exit); MODULE_AUTHOR("Linus Walleij "); MODULE_DESCRIPTION("AB3100 core driver"); MODULE_LICENSE("GPL");