/* Copyright Statement: * * This software/firmware and related documentation ("MediaTek Software") are * protected under relevant copyright laws. The information contained herein * is confidential and proprietary to MediaTek Inc. and/or its licensors. * Without the prior written permission of MediaTek inc. and/or its licensors, * any reproduction, modification, use or disclosure of MediaTek Software, * and information contained herein, in whole or in part, shall be strictly prohibited. * * MediaTek Inc. (C) 2012. All rights reserved. * * BY OPENING THIS FILE, RECEIVER HEREBY UNEQUIVOCALLY ACKNOWLEDGES AND AGREES * THAT THE SOFTWARE/FIRMWARE AND ITS DOCUMENTATIONS ("MEDIATEK SOFTWARE") * RECEIVED FROM MEDIATEK AND/OR ITS REPRESENTATIVES ARE PROVIDED TO RECEIVER ON * AN "AS-IS" BASIS ONLY. MEDIATEK EXPRESSLY DISCLAIMS ANY AND ALL WARRANTIES, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT. * NEITHER DOES MEDIATEK PROVIDE ANY WARRANTY WHATSOEVER WITH RESPECT TO THE * SOFTWARE OF ANY THIRD PARTY WHICH MAY BE USED BY, INCORPORATED IN, OR * SUPPLIED WITH THE MEDIATEK SOFTWARE, AND RECEIVER AGREES TO LOOK ONLY TO SUCH * THIRD PARTY FOR ANY WARRANTY CLAIM RELATING THERETO. RECEIVER EXPRESSLY ACKNOWLEDGES * THAT IT IS RECEIVER'S SOLE RESPONSIBILITY TO OBTAIN FROM ANY THIRD PARTY ALL PROPER LICENSES * CONTAINED IN MEDIATEK SOFTWARE. MEDIATEK SHALL ALSO NOT BE RESPONSIBLE FOR ANY MEDIATEK * SOFTWARE RELEASES MADE TO RECEIVER'S SPECIFICATION OR TO CONFORM TO A PARTICULAR * STANDARD OR OPEN FORUM. RECEIVER'S SOLE AND EXCLUSIVE REMEDY AND MEDIATEK'S ENTIRE AND * CUMULATIVE LIABILITY WITH RESPECT TO THE MEDIATEK SOFTWARE RELEASED HEREUNDER WILL BE, * AT MEDIATEK'S OPTION, TO REVISE OR REPLACE THE MEDIATEK SOFTWARE AT ISSUE, * OR REFUND ANY SOFTWARE LICENSE FEES OR SERVICE CHARGE PAID BY RECEIVER TO * MEDIATEK FOR SUCH MEDIATEK SOFTWARE AT ISSUE. * * The following software/firmware and/or related documentation ("MediaTek Software") * have been modified by MediaTek Inc. All revisions are subject to any receiver's * applicable license agreements with MediaTek Inc. */ /* * Version: V2.0 * Release Date: 2013/08/28 * Contact: andrew@goodix.com, meta@goodix.com * Revision Record: * V1.4: * 1. New Heartbeat/ESD-protect Mechanism(external watchdog) * 2. doze mode, sliding wakeup * 3. config length verification & 3 more config groups(GT9 Sensor_ID: 0 ~ 5) * 4. charger status switch * By Meta, 2013/03/11 * V1.6: * 1. pen/stylus support * 2. slide wakeup, new esd optimization * By Meta, 2013/04/18 * V1.8: * 1. read double check & fixed config support * 2. other optimizations * By Meta, 2013/06/08 * V2.0: * 1. compatible with GT9XXF * 2. I2C DMA support * By Meta, 2013/08/28 * V2.2: * 1. update gt9xx_config to compatible with Linux 3.10 * 2. gesture wakeup * 3. pen separate input device, active-pen button support * 4. coordinates & keys optimization * 5. no longer support GT915S * By Meta, 2014/01/14 */ #include "tpd.h" #include "tpd_custom_gt9xx.h" #include #ifndef TPD_NO_GPIO #include "cust_gpio_usage.h" #endif #ifdef TPD_PROXIMITY #include #include #include #endif #if GTP_SUPPORT_I2C_DMA #include #endif #define TYPE_B_PROTOCOL #ifdef TYPE_B_PROTOCOL #include #endif #include extern struct tpd_device *tpd; #define MZ_SELF_TEST #ifdef MZ_SELF_TEST extern s32 gtp_test_sysfs_init(struct kobject *); extern void gtp_test_sysfs_deinit(void); #endif static int tpd_flag = 0; static unsigned long gt9xx_finger_status = 0; static unsigned long gt9xx_finger_status_pre = 0; int tpd_halt = 0; static struct task_struct *thread = NULL; static DECLARE_WAIT_QUEUE_HEAD(waiter); static u8 gt9xx_tp_state = MZ_GESTURE_PART; static u8 gt9xx_tp_state_pre = MZ_GESTURE_PART; #ifdef TPD_HAVE_BUTTON static int tpd_keys_local[TPD_KEY_COUNT] = TPD_KEYS; static int tpd_keys_dim_local[TPD_KEY_COUNT][4] = TPD_KEYS_DIM; #endif #if GTP_GESTURE_WAKEUP typedef enum { DOZE_DISABLED = 0, DOZE_ENABLED = 1, DOZE_WAKEUP = 2, }DOZE_T; static DOZE_T doze_status = DOZE_DISABLED; static s8 gtp_enter_doze(struct i2c_client *client); #endif #if GTP_CHARGER_SWITCH #ifdef MT6573 #define CHR_CON0 (0xF7000000+0x2FA00) #else extern kal_bool upmu_is_chr_det(void); #endif static void gtp_charger_switch(s32 dir_update); #endif #if GTP_HAVE_TOUCH_KEY const u16 touch_key_array[] = GTP_KEY_TAB; #define GTP_MAX_KEY_NUM ( sizeof( touch_key_array )/sizeof( touch_key_array[0] ) ) #endif #if (defined(TPD_WARP_START) && defined(TPD_WARP_END)) static int tpd_wb_start_local[TPD_WARP_CNT] = TPD_WARP_START; static int tpd_wb_end_local[TPD_WARP_CNT] = TPD_WARP_END; #endif #if (defined(TPD_HAVE_CALIBRATION) && !defined(TPD_CUSTOM_CALIBRATION)) //static int tpd_calmat_local[8] = TPD_CALIBRATION_MATRIX; static int tpd_def_calmat_local[8] = TPD_CALIBRATION_MATRIX; #endif #if GTP_SUPPORT_I2C_DMA s32 i2c_dma_write(struct i2c_client *client, u16 addr, u8 *txbuf, s32 len); s32 i2c_dma_read(struct i2c_client *client, u16 addr, u8 *rxbuf, s32 len); static u8 *gpDMABuf_va = NULL; static u64 gpDMABuf_pa = 0; #endif s32 gtp_send_cfg(struct i2c_client *client); void gtp_reset_guitar(struct i2c_client *client, s32 ms); static void tpd_eint_interrupt_handler(void); static int touch_event_handler(void *unused); static int tpd_i2c_probe(struct i2c_client *client, const struct i2c_device_id *id); static int tpd_i2c_detect(struct i2c_client *client, struct i2c_board_info *info); static int tpd_i2c_remove(struct i2c_client *client); s32 gtp_i2c_read_dbl_check(struct i2c_client *client, u16 addr, u8 *rxbuf, int len); extern void mt_eint_unmask(unsigned int line); extern void mt_eint_mask(unsigned int line); #ifndef MT6572 extern void mt65xx_eint_set_hw_debounce(kal_uint8 eintno, kal_uint32 ms); extern kal_uint32 mt65xx_eint_set_sens(kal_uint8 eintno, kal_bool sens); extern void mt65xx_eint_registration(kal_uint8 eintno, kal_bool Dbounce_En, kal_bool ACT_Polarity, void (EINT_FUNC_PTR)(void), kal_bool auto_umask); #endif #if GTP_CREATE_WR_NODE extern s32 init_wr_node(struct i2c_client *); extern void uninit_wr_node(void); #endif #if (GTP_ESD_PROTECT || GTP_COMPATIBLE_MODE) static void force_reset_guitar(void); #endif #if GTP_ESD_PROTECT static int clk_tick_cnt = 200; static struct delayed_work gtp_esd_check_work; static struct workqueue_struct *gtp_esd_check_workqueue = NULL; static s32 gtp_init_ext_watchdog(struct i2c_client *client); static void gtp_esd_check_func(struct work_struct *); void gtp_esd_switch(struct i2c_client *client, s32 on); u8 esd_running = 0; spinlock_t esd_lock; #endif #ifdef TPD_PROXIMITY #define TPD_PROXIMITY_VALID_REG 0x814E #define TPD_PROXIMITY_ENABLE_REG 0x8042 static u8 tpd_proximity_flag = 0; static u8 tpd_proximity_detect = 1;//0-->close ; 1--> far away #endif struct i2c_client *i2c_client_point = NULL; static const struct i2c_device_id tpd_i2c_id[] = {{"gt9xx", 0}, {}}; static unsigned short force[] = {0, 0xBA, I2C_CLIENT_END, I2C_CLIENT_END}; static const unsigned short *const forces[] = { force, NULL }; //static struct i2c_client_address_data addr_data = { .forces = forces,}; static struct i2c_board_info __initdata i2c_tpd = { I2C_BOARD_INFO("gt9xx", (0xBA >> 1))}; static struct i2c_driver tpd_i2c_driver = { .probe = tpd_i2c_probe, .remove = tpd_i2c_remove, .detect = tpd_i2c_detect, .driver.name = "gt9xx", .id_table = tpd_i2c_id, .address_list = (const unsigned short *) forces, }; static u8 config[GTP_CONFIG_MAX_LENGTH + GTP_ADDR_LENGTH] = {GTP_REG_CONFIG_DATA >> 8, GTP_REG_CONFIG_DATA & 0xff}; #ifdef MZ_HALL_MODE static u8 config_hall_mode[GTP_CONFIG_MAX_LENGTH + GTP_ADDR_LENGTH] = {GTP_REG_CONFIG_DATA >> 8, GTP_REG_CONFIG_DATA & 0xff}; #endif #pragma pack(1) typedef struct { u16 pid; //product id // u16 vid; //version id // } st_tpd_info; #pragma pack() st_tpd_info tpd_info; u8 int_type = 0; u32 abs_x_max = 0; u32 abs_y_max = 0; u8 gtp_rawdiff_mode = 0; u8 cfg_len = 0; u8 grp_cfg_version = 0; u8 fixed_config = 0; u8 pnl_init_error = 0; #if GTP_WITH_PEN struct input_dev *pen_dev; #endif #if GTP_COMPATIBLE_MODE u8 driver_num = 0; u8 sensor_num = 0; u8 gtp_ref_retries = 0; u8 gtp_clk_retries = 0; CHIP_TYPE_T gtp_chip_type = CHIP_TYPE_GT9; u8 rqst_processing = 0; u8 is_950 = 0; extern u8 gup_check_fs_mounted(char *path_name); extern u8 gup_clk_calibration(void); extern s32 gup_fw_download_proc(void *dir, u8 dwn_mode); void gtp_get_chip_type(struct i2c_client *client); u8 gtp_fw_startup(struct i2c_client *client); static u8 gtp_bak_ref_proc(struct i2c_client *client, u8 mode); static u8 gtp_main_clk_proc(struct i2c_client *client); static void gtp_recovery_reset(struct i2c_client *client); #endif /* proc file system */ s32 i2c_read_bytes(struct i2c_client *client, u16 addr, u8 *rxbuf, int len); s32 i2c_write_bytes(struct i2c_client *client, u16 addr, u8 *txbuf, int len); static ssize_t gt91xx_config_read_proc(struct file *, char __user *, size_t, loff_t *); static ssize_t gt91xx_config_write_proc(struct file *, const char __user *, size_t, loff_t *); static struct proc_dir_entry *gt91xx_config_proc = NULL; static const struct file_operations config_proc_ops = { .owner = THIS_MODULE, .read = gt91xx_config_read_proc, .write = gt91xx_config_write_proc, }; #define VELOCITY_CUSTOM #ifdef VELOCITY_CUSTOM #include #include #include #ifndef TPD_VELOCITY_CUSTOM_X #define TPD_VELOCITY_CUSTOM_X 10 #endif #ifndef TPD_VELOCITY_CUSTOM_Y #define TPD_VELOCITY_CUSTOM_Y 10 #endif // for magnify velocity******************************************** #define TOUCH_IOC_MAGIC 'A' #define TPD_GET_VELOCITY_CUSTOM_X _IO(TOUCH_IOC_MAGIC,0) #define TPD_GET_VELOCITY_CUSTOM_Y _IO(TOUCH_IOC_MAGIC,1) int g_v_magnify_x = TPD_VELOCITY_CUSTOM_X; int g_v_magnify_y = TPD_VELOCITY_CUSTOM_Y; static int tpd_misc_open(struct inode *inode, struct file *file) { return nonseekable_open(inode, file); } static int tpd_misc_release(struct inode *inode, struct file *file) { return 0; } static long tpd_unlocked_ioctl(struct file *file, unsigned int cmd, unsigned long arg) { //char strbuf[256]; void __user *data; long err = 0; if (_IOC_DIR(cmd) & _IOC_READ) { err = !access_ok(VERIFY_WRITE, (void __user *)arg, _IOC_SIZE(cmd)); } else if (_IOC_DIR(cmd) & _IOC_WRITE) { err = !access_ok(VERIFY_READ, (void __user *)arg, _IOC_SIZE(cmd)); } if (err) { GTP_ERROR("tpd: access error: %08X, (%2d, %2d)\n", cmd, _IOC_DIR(cmd), _IOC_SIZE(cmd)); return -EFAULT; } switch (cmd) { case TPD_GET_VELOCITY_CUSTOM_X: data = (void __user *) arg; if (data == NULL) { err = -EINVAL; break; } if (copy_to_user(data, &g_v_magnify_x, sizeof(g_v_magnify_x))) { err = -EFAULT; break; } break; case TPD_GET_VELOCITY_CUSTOM_Y: data = (void __user *) arg; if (data == NULL) { err = -EINVAL; break; } if (copy_to_user(data, &g_v_magnify_y, sizeof(g_v_magnify_y))) { err = -EFAULT; break; } break; default: GTP_ERROR("tpd: unknown IOCTL: 0x%08x\n", cmd); err = -ENOIOCTLCMD; break; } return err; } static struct file_operations tpd_fops = { // .owner = THIS_MODULE, .open = tpd_misc_open, .release = tpd_misc_release, .unlocked_ioctl = tpd_unlocked_ioctl, }; /*----------------------------------------------------------------------------*/ static struct miscdevice tpd_misc_device = { .minor = MISC_DYNAMIC_MINOR, .name = "touch", .fops = &tpd_fops, }; //********************************************** #endif void gt9xx_gesture_handler(u8 state) { gt9xx_tp_state = state; } static int tpd_i2c_detect(struct i2c_client *client, struct i2c_board_info *info) { strcpy(info->type, "mtk-tpd"); return 0; } #ifdef TPD_PROXIMITY static s32 tpd_get_ps_value(void) { return tpd_proximity_detect; } static s32 tpd_enable_ps(s32 enable) { u8 state; s32 ret = -1; if (enable) { state = 1; tpd_proximity_flag = 1; GTP_INFO("TPD proximity function to be on."); } else { state = 0; tpd_proximity_flag = 0; GTP_INFO("TPD proximity function to be off."); } ret = i2c_write_bytes(i2c_client_point, TPD_PROXIMITY_ENABLE_REG, &state, 1); if (ret < 0) { GTP_ERROR("TPD %s proximity cmd failed.", state ? "enable" : "disable"); return ret; } GTP_INFO("TPD proximity function %s success.", state ? "enable" : "disable"); return 0; } s32 tpd_ps_operate(void *self, u32 command, void *buff_in, s32 size_in, void *buff_out, s32 size_out, s32 *actualout) { s32 err = 0; s32 value; hwm_sensor_data *sensor_data; switch (command) { case SENSOR_DELAY: if ((buff_in == NULL) || (size_in < sizeof(int))) { GTP_ERROR("Set delay parameter error!"); err = -EINVAL; } // Do nothing break; case SENSOR_ENABLE: if ((buff_in == NULL) || (size_in < sizeof(int))) { GTP_ERROR("Enable sensor parameter error!"); err = -EINVAL; } else { value = *(int *)buff_in; err = tpd_enable_ps(value); } break; case SENSOR_GET_DATA: if ((buff_out == NULL) || (size_out < sizeof(hwm_sensor_data))) { GTP_ERROR("Get sensor data parameter error!"); err = -EINVAL; } else { sensor_data = (hwm_sensor_data *)buff_out; sensor_data->values[0] = tpd_get_ps_value(); sensor_data->value_divide = 1; sensor_data->status = SENSOR_STATUS_ACCURACY_MEDIUM; } break; default: GTP_ERROR("proxmy sensor operate function no this parameter %d!\n", command); err = -1; break; } return err; } #endif static ssize_t gt91xx_config_read_proc(struct file *file, char __user *page, size_t size, loff_t *ppos) { char *ptr = page; char temp_data[GTP_CONFIG_MAX_LENGTH + 2] = {0}; int i; if (*ppos) // CMD call again { return 0; } ptr += sprintf(ptr, "==== GT9XX config init value====\n"); for (i = 0 ; i < GTP_CONFIG_MAX_LENGTH ; i++) { ptr += sprintf(ptr, "0x%02X ", config[i + 2]); if (i % 8 == 7) ptr += sprintf(ptr, "\n"); } ptr += sprintf(ptr, "\n"); ptr += sprintf(ptr, "==== GT9XX config real value====\n"); i2c_read_bytes(i2c_client_point, GTP_REG_CONFIG_DATA, temp_data, GTP_CONFIG_MAX_LENGTH); for (i = 0 ; i < GTP_CONFIG_MAX_LENGTH ; i++) { ptr += sprintf(ptr, "0x%02X ", temp_data[i]); if (i % 8 == 7) ptr += sprintf(ptr, "\n"); } *ppos += ptr - page; return (ptr - page); } static ssize_t gt91xx_config_write_proc(struct file *filp, const char __user *buffer, size_t count, loff_t *off) { s32 ret = 0; GTP_DEBUG("write count %ld\n", count); if (count > GTP_CONFIG_MAX_LENGTH) { GTP_ERROR("size not match [%d:%ld]\n", GTP_CONFIG_MAX_LENGTH, count); return -EFAULT; } if (copy_from_user(&config[2], buffer, count)) { GTP_ERROR("copy from user fail\n"); return -EFAULT; } ret = gtp_send_cfg(i2c_client_point); abs_x_max = (config[RESOLUTION_LOC + 1] << 8) + config[RESOLUTION_LOC]; abs_y_max = (config[RESOLUTION_LOC + 3] << 8) + config[RESOLUTION_LOC + 2]; int_type = (config[TRIGGER_LOC]) & 0x03; if (ret < 0) { GTP_ERROR("send config failed."); } return count; } #if GTP_SUPPORT_I2C_DMA s32 i2c_dma_read(struct i2c_client *client, u16 addr, u8 *rxbuf, s32 len) { int ret; s32 retry = 0; u8 buffer[2]; struct i2c_msg msg[2] = { { .addr = (client->addr & I2C_MASK_FLAG), .flags = 0, .buf = buffer, .len = 2, .timing = I2C_MASTER_CLOCK }, { .addr = (client->addr & I2C_MASK_FLAG), .ext_flag = (client->ext_flag | I2C_ENEXT_FLAG | I2C_DMA_FLAG), .flags = I2C_M_RD, .buf = gpDMABuf_pa, .len = len, .timing = I2C_MASTER_CLOCK }, }; buffer[0] = (addr >> 8) & 0xFF; buffer[1] = addr & 0xFF; if (rxbuf == NULL) return -1; //GTP_DEBUG("dma i2c read: 0x%04X, %d bytes(s)", addr, len); for (retry = 0; retry < 5; ++retry) { ret = i2c_transfer(client->adapter, &msg[0], 2); if (ret < 0) { continue; } memcpy(rxbuf, gpDMABuf_va, len); return 0; } GTP_ERROR("Dma I2C Read Error: 0x%04X, %d byte(s), err-code: %d", addr, len, ret); return ret; } s32 i2c_dma_write(struct i2c_client *client, u16 addr, u8 *txbuf, s32 len) { int ret; s32 retry = 0; u8 *wr_buf = gpDMABuf_va; struct i2c_msg msg = { .addr = (client->addr & I2C_MASK_FLAG), .ext_flag = (client->ext_flag | I2C_ENEXT_FLAG | I2C_DMA_FLAG), .flags = 0, .buf = gpDMABuf_pa, .len = 2 + len, .timing = I2C_MASTER_CLOCK }; wr_buf[0] = (u8)((addr >> 8) & 0xFF); wr_buf[1] = (u8)(addr & 0xFF); if (txbuf == NULL) return -1; //GTP_DEBUG("dma i2c write: 0x%04X, %d bytes(s)", addr, len); memcpy(wr_buf+2, txbuf, len); for (retry = 0; retry < 5; ++retry) { ret = i2c_transfer(client->adapter, &msg, 1); if (ret < 0) { continue; } return 0; } GTP_ERROR("Dma I2C Write Error: 0x%04X, %d byte(s), err-code: %d", addr, len, ret); return ret; } s32 i2c_read_bytes_dma(struct i2c_client *client, u16 addr, u8 *rxbuf, s32 len) { s32 left = len; s32 read_len = 0; u8 *rd_buf = rxbuf; s32 ret = 0; //GTP_DEBUG("Read bytes dma: 0x%04X, %d byte(s)", addr, len); while (left > 0) { if (left > GTP_DMA_MAX_TRANSACTION_LENGTH) { read_len = GTP_DMA_MAX_TRANSACTION_LENGTH; } else { read_len = left; } ret = i2c_dma_read(client, addr, rd_buf, read_len); if (ret < 0) { GTP_ERROR("dma read failed"); return -1; } left -= read_len; addr += read_len; rd_buf += read_len; } return 0; } s32 i2c_write_bytes_dma(struct i2c_client *client, u16 addr, u8 *txbuf, s32 len) { s32 ret = 0; s32 write_len = 0; s32 left = len; u8 *wr_buf = txbuf; //GTP_DEBUG("Write bytes dma: 0x%04X, %d byte(s)", addr, len); while (left > 0) { if (left > GTP_DMA_MAX_I2C_TRANSFER_SIZE) { write_len = GTP_DMA_MAX_I2C_TRANSFER_SIZE; } else { write_len = left; } ret = i2c_dma_write(client, addr, wr_buf, write_len); if (ret < 0) { GTP_ERROR("dma i2c write failed!"); return -1; } left -= write_len; addr += write_len; wr_buf += write_len; } return 0; } #endif int i2c_read_bytes_non_dma(struct i2c_client *client, u16 addr, u8 *rxbuf, int len) { u8 buffer[GTP_ADDR_LENGTH]; u8 retry; u16 left = len; u16 offset = 0; struct i2c_msg msg[2] = { { .addr = ((client->addr &I2C_MASK_FLAG) | (I2C_ENEXT_FLAG)), //.addr = ((client->addr &I2C_MASK_FLAG) | (I2C_PUSHPULL_FLAG)), .flags = 0, .buf = buffer, .len = GTP_ADDR_LENGTH, .timing = I2C_MASTER_CLOCK }, { .addr = ((client->addr &I2C_MASK_FLAG) | (I2C_ENEXT_FLAG)), //.addr = ((client->addr &I2C_MASK_FLAG) | (I2C_PUSHPULL_FLAG)), .flags = I2C_M_RD, .timing = I2C_MASTER_CLOCK }, }; if (rxbuf == NULL) return -1; //GTP_DEBUG("i2c_read_bytes to device %02X address %04X len %d\n", client->addr, addr, len); while (left > 0) { buffer[0] = ((addr + offset) >> 8) & 0xFF; buffer[1] = (addr + offset) & 0xFF; msg[1].buf = &rxbuf[offset]; if (left > MAX_TRANSACTION_LENGTH) { msg[1].len = MAX_TRANSACTION_LENGTH; left -= MAX_TRANSACTION_LENGTH; offset += MAX_TRANSACTION_LENGTH; } else { msg[1].len = left; left = 0; } retry = 0; while (i2c_transfer(client->adapter, &msg[0], 2) != 2) { retry++; //if (retry == 20) if (retry == 5) { GTP_ERROR("I2C read 0x%X length=%d failed\n", addr + offset, len); return -1; } } } return 0; } int i2c_read_bytes(struct i2c_client *client, u16 addr, u8 *rxbuf, int len) { #if GTP_SUPPORT_I2C_DMA return i2c_read_bytes_dma(client, addr, rxbuf, len); #else return i2c_read_bytes_non_dma(client, addr, rxbuf, len); #endif } s32 gtp_i2c_read(struct i2c_client *client, u8 *buf, s32 len) { s32 ret = -1; u16 addr = (buf[0] << 8) + buf[1]; ret = i2c_read_bytes_non_dma(client, addr, &buf[2], len - 2); if (!ret) { return 2; } else { #if GTP_GESTURE_WAKEUP if (DOZE_ENABLED == doze_status) { return ret; } #endif #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { gtp_recovery_reset(client); } else #endif { gtp_reset_guitar(client, 20); } return ret; } } s32 gtp_i2c_read_dbl_check(struct i2c_client *client, u16 addr, u8 *rxbuf, int len) { u8 buf[16] = {0}; u8 confirm_buf[16] = {0}; u8 retry = 0; while (retry++ < 3) { memset(buf, 0xAA, 16); buf[0] = (u8)(addr >> 8); buf[1] = (u8)(addr & 0xFF); gtp_i2c_read(client, buf, len + 2); memset(confirm_buf, 0xAB, 16); confirm_buf[0] = (u8)(addr >> 8); confirm_buf[1] = (u8)(addr & 0xFF); gtp_i2c_read(client, confirm_buf, len + 2); if (!memcmp(buf, confirm_buf, len+2)) { memcpy(rxbuf, confirm_buf+2, len); return SUCCESS; } } GTP_ERROR("i2c read 0x%04X, %d bytes, double check failed!", addr, len); return FAIL; } int i2c_write_bytes_non_dma(struct i2c_client *client, u16 addr, u8 *txbuf, int len) { u8 buffer[MAX_TRANSACTION_LENGTH]; u16 left = len; u16 offset = 0; u8 retry = 0; struct i2c_msg msg = { .addr = ((client->addr &I2C_MASK_FLAG) | (I2C_ENEXT_FLAG)), //.addr = ((client->addr &I2C_MASK_FLAG) | (I2C_PUSHPULL_FLAG)), .flags = 0, .buf = buffer, .timing = I2C_MASTER_CLOCK, }; if (txbuf == NULL) return -1; //GTP_DEBUG("i2c_write_bytes to device %02X address %04X len %d\n", client->addr, addr, len); while (left > 0) { retry = 0; buffer[0] = ((addr + offset) >> 8) & 0xFF; buffer[1] = (addr + offset) & 0xFF; if (left > MAX_I2C_TRANSFER_SIZE) { memcpy(&buffer[GTP_ADDR_LENGTH], &txbuf[offset], MAX_I2C_TRANSFER_SIZE); msg.len = MAX_TRANSACTION_LENGTH; left -= MAX_I2C_TRANSFER_SIZE; offset += MAX_I2C_TRANSFER_SIZE; } else { memcpy(&buffer[GTP_ADDR_LENGTH], &txbuf[offset], left); msg.len = left + GTP_ADDR_LENGTH; left = 0; } //GTP_DEBUG("byte left %d offset %d\n", left, offset); while (i2c_transfer(client->adapter, &msg, 1) != 1) { retry++; //if (retry == 20) if (retry == 5) { GTP_ERROR("I2C write 0x%X%X length=%d failed\n", buffer[0], buffer[1], len); return -1; } } } return 0; } int i2c_write_bytes(struct i2c_client *client, u16 addr, u8 *txbuf, int len) { #if GTP_SUPPORT_I2C_DMA return i2c_write_bytes_dma(client, addr, txbuf, len); #else return i2c_write_bytes_non_dma(client, addr, txbuf, len); #endif } s32 gtp_i2c_write(struct i2c_client *client, u8 *buf, s32 len) { s32 ret = -1; u16 addr = (buf[0] << 8) + buf[1]; ret = i2c_write_bytes_non_dma(client, addr, &buf[2], len - 2); if (!ret) { return 1; } else { #if GTP_GESTURE_WAKEUP if (DOZE_ENABLED == doze_status) { return ret; } #endif #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { gtp_recovery_reset(client); } else #endif { gtp_reset_guitar(client, 20); } return ret; } } /******************************************************* Function: Send config Function. Input: client: i2c client. Output: Executive outcomes.0--success,non-0--fail. *******************************************************/ s32 gtp_send_cfg(struct i2c_client *client) { s32 ret = 1; #if GTP_DRIVER_SEND_CFG s32 retry = 0; if (fixed_config) { GTP_INFO("Ic fixed config, no config sent!"); return 0; } else if (pnl_init_error) { GTP_INFO("Error occurred in init_panel, no config sent!"); return 0; } GTP_ERROR("Driver Send Config version %02x\n", config[2]); for (retry = 0; retry < 5; retry++) { ret = gtp_i2c_write(client, config, GTP_CONFIG_MAX_LENGTH + GTP_ADDR_LENGTH); if (ret > 0) { break; } } #endif // delay 50ms, to make sure cfg switch successfully msleep(50); return ret; } /******************************************************* Function: Read goodix touchscreen version function. Input: client: i2c client struct. version:address to store version info Output: Executive outcomes.0---succeed. *******************************************************/ s32 gtp_read_version(struct i2c_client *client, u16 *version) { s32 ret = -1; s32 i; u8 buf[8] = {GTP_REG_VERSION >> 8, GTP_REG_VERSION & 0xff}; GTP_DEBUG_FUNC(); ret = gtp_i2c_read(client, buf, sizeof(buf)); if (ret < 0) { GTP_ERROR("GTP read version failed"); return ret; } if (version) { *version = (buf[7] << 8) | buf[6]; } tpd_info.vid = *version; tpd_info.pid = 0x00; for (i = 0; i < 4; i++) { if (buf[i + 2] < 0x30)break; tpd_info.pid |= ((buf[i + 2] - 0x30) << ((3 - i) * 4)); } if (buf[5] == 0x00) { GTP_INFO("IC VERSION: %c%c%c_%02x%02x", buf[2], buf[3], buf[4], buf[7], buf[6]); } else { GTP_INFO("IC VERSION:%c%c%c%c_%02x%02x", buf[2], buf[3], buf[4], buf[5], buf[7], buf[6]); } return ret; } #if GTP_DRIVER_SEND_CFG /******************************************************* Function: Get information from ic, such as resolution and int trigger type Input: client: i2c client private struct. Output: FAIL: i2c failed, SUCCESS: i2c ok *******************************************************/ static s32 gtp_get_info(struct i2c_client *client) { u8 opr_buf[6] = {0}; s32 ret = 0; opr_buf[0] = (u8)((GTP_REG_CONFIG_DATA+1) >> 8); opr_buf[1] = (u8)((GTP_REG_CONFIG_DATA+1) & 0xFF); ret = gtp_i2c_read(client, opr_buf, 6); if (ret < 0) { return FAIL; } abs_x_max = (opr_buf[3] << 8) + opr_buf[2]; abs_y_max = (opr_buf[5] << 8) + opr_buf[4]; opr_buf[0] = (u8)((GTP_REG_CONFIG_DATA+6) >> 8); opr_buf[1] = (u8)((GTP_REG_CONFIG_DATA+6) & 0xFF); ret = gtp_i2c_read(client, opr_buf, 3); if (ret < 0) { return FAIL; } int_type = opr_buf[2] & 0x03; GTP_INFO("X_MAX = %d, Y_MAX = %d, TRIGGER = 0x%02x", abs_x_max,abs_y_max, int_type); return SUCCESS; } #endif /******************************************************* Function: GTP initialize function. Input: client: i2c client private struct. Output: Executive outcomes.0---succeed. *******************************************************/ static s32 gtp_init_panel(struct i2c_client *client) { s32 ret = 0; #if GTP_DRIVER_SEND_CFG s32 i; u8 check_sum = 0; u8 opr_buf[16]; u8 sensor_id = 0; u8 retry = 0; #ifdef MZ_HALL_MODE u8 cfg_info_hall_mode[] = CTP_CFG_HALL_MODE; #endif u8 cfg_info_group1[] = CTP_CFG_GROUP1; u8 cfg_info_group2[] = CTP_CFG_GROUP2; u8 cfg_info_group3[] = CTP_CFG_GROUP3; u8 cfg_info_group4[] = CTP_CFG_GROUP4; u8 cfg_info_group5[] = CTP_CFG_GROUP5; u8 cfg_info_group6[] = CTP_CFG_GROUP6; u8 *send_cfg_buf[] = {cfg_info_group1, cfg_info_group2, cfg_info_group3, cfg_info_group4, cfg_info_group5, cfg_info_group6}; u8 cfg_info_len[] = { CFG_GROUP_LEN(cfg_info_group1), CFG_GROUP_LEN(cfg_info_group2), CFG_GROUP_LEN(cfg_info_group3), CFG_GROUP_LEN(cfg_info_group4), CFG_GROUP_LEN(cfg_info_group5), CFG_GROUP_LEN(cfg_info_group6)}; GTP_DEBUG("Config Groups\' Lengths: %d, %d, %d, %d, %d, %d", cfg_info_len[0], cfg_info_len[1], cfg_info_len[2], cfg_info_len[3], cfg_info_len[4], cfg_info_len[5]); if ((!cfg_info_len[1]) && (!cfg_info_len[2]) && (!cfg_info_len[3]) && (!cfg_info_len[4]) && (!cfg_info_len[5])) { sensor_id = 0; } else { #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { msleep(50); } #endif ret = gtp_i2c_read_dbl_check(client, GTP_REG_SENSOR_ID, &sensor_id, 1); if (SUCCESS == ret) { while((sensor_id == 0xff)&&(retry++ < 3)) { msleep(100); ret = gtp_i2c_read_dbl_check(client, GTP_REG_SENSOR_ID, &sensor_id, 1); GTP_ERROR("GTP sensor_ID read failed time %d.",retry); } /*******************/ if (sensor_id >= 0x06) { GTP_ERROR("Invalid sensor_id(0x%02X), No Config Sent!", sensor_id); pnl_init_error = 1; return -1; } } else { GTP_ERROR("Failed to get sensor_id, No config sent!"); pnl_init_error = 1; return -1; } GTP_INFO("Sensor_ID: %d", sensor_id); } cfg_len = cfg_info_len[sensor_id]; GTP_INFO("CTP_CONFIG_GROUP%d used, config length: %d", sensor_id + 1, cfg_len); if (cfg_len < GTP_CONFIG_MIN_LENGTH) { GTP_ERROR("CTP_CONFIG_GROUP%d is INVALID CONFIG GROUP! NO Config Sent! You need to check you header file CFG_GROUP section!", sensor_id+1); pnl_init_error = 1; return -1; } #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { fixed_config = 0; } else #endif { ret = gtp_i2c_read_dbl_check(client, GTP_REG_CONFIG_DATA, &opr_buf[0], 1); if (ret == SUCCESS) { GTP_DEBUG("CFG_CONFIG_GROUP%d Config Version: %d, 0x%02X; IC Config Version: %d, 0x%02X", sensor_id+1, send_cfg_buf[sensor_id][0], send_cfg_buf[sensor_id][0], opr_buf[0], opr_buf[0]); //if (opr_buf[0] < 90) { grp_cfg_version = send_cfg_buf[sensor_id][0]; // backup group config version send_cfg_buf[sensor_id][0] = 0x00; fixed_config = 0; } #if 0 else // treated as fixed config, not send config { GTP_INFO("Ic fixed config with config version(%d)", opr_buf[0]); fixed_config = 1; gtp_get_info(client); return 0; } #endif } else { GTP_ERROR("Failed to get ic config version!No config sent!"); return -1; } } #ifdef MZ_HALL_MODE memset(&config_hall_mode[GTP_ADDR_LENGTH], 0, GTP_CONFIG_MAX_LENGTH); memcpy(&config_hall_mode[GTP_ADDR_LENGTH], cfg_info_hall_mode, CFG_GROUP_LEN(cfg_info_hall_mode)); #endif memset(&config[GTP_ADDR_LENGTH], 0, GTP_CONFIG_MAX_LENGTH); memcpy(&config[GTP_ADDR_LENGTH], send_cfg_buf[sensor_id], cfg_len); #if GTP_CUSTOM_CFG config[RESOLUTION_LOC] = (u8)GTP_MAX_WIDTH; config[RESOLUTION_LOC + 1] = (u8)(GTP_MAX_WIDTH>>8); config[RESOLUTION_LOC + 2] = (u8)GTP_MAX_HEIGHT; config[RESOLUTION_LOC + 3] = (u8)(GTP_MAX_HEIGHT>>8); if (GTP_INT_TRIGGER == 0) //RISING { config[TRIGGER_LOC] &= 0xfe; } else if (GTP_INT_TRIGGER == 1) //FALLING { config[TRIGGER_LOC] |= 0x01; } #endif // GTP_CUSTOM_CFG check_sum = 0; for (i = GTP_ADDR_LENGTH; i < cfg_len; i++) { check_sum += config[i]; } config[cfg_len] = (~check_sum) + 1; #else // DRIVER NOT SEND CONFIG cfg_len = GTP_CONFIG_MAX_LENGTH; ret = gtp_i2c_read(client, config, cfg_len + GTP_ADDR_LENGTH); if (ret < 0) { GTP_ERROR("Read Config Failed, Using DEFAULT Resolution & INT Trigger!"); abs_x_max = GTP_MAX_WIDTH; abs_y_max = GTP_MAX_HEIGHT; int_type = GTP_INT_TRIGGER; } #endif // GTP_DRIVER_SEND_CFG GTP_DEBUG_FUNC(); if ((abs_x_max == 0) && (abs_y_max == 0)) { abs_x_max = (config[RESOLUTION_LOC + 1] << 8) + config[RESOLUTION_LOC]; abs_y_max = (config[RESOLUTION_LOC + 3] << 8) + config[RESOLUTION_LOC + 2]; int_type = (config[TRIGGER_LOC]) & 0x03; } #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { u8 have_key = 0; if (is_950) { driver_num = config[GTP_REG_MATRIX_DRVNUM - GTP_REG_CONFIG_DATA + 2]; sensor_num = config[GTP_REG_MATRIX_SENNUM - GTP_REG_CONFIG_DATA + 2]; } else { driver_num = (config[CFG_LOC_DRVA_NUM]&0x1F) + (config[CFG_LOC_DRVB_NUM]&0x1F); sensor_num = (config[CFG_LOC_SENS_NUM]&0x0F) + ((config[CFG_LOC_SENS_NUM]>>4)&0x0F); } have_key = config[GTP_REG_HAVE_KEY - GTP_REG_CONFIG_DATA + 2] & 0x01; // have key or not if (1 == have_key) { driver_num--; } GTP_INFO("Driver * Sensor: %d * %d(Key: %d), X_MAX = %d, Y_MAX = %d, TRIGGER = 0x%02x", driver_num, sensor_num, have_key, abs_x_max,abs_y_max,int_type); } else #endif { #if GTP_DRIVER_SEND_CFG ret = gtp_send_cfg(client); if (ret < 0) { GTP_ERROR("Send config error."); } // set config version to CTP_CFG_GROUP // for resume to send config /* config[GTP_ADDR_LENGTH] = grp_cfg_version; check_sum = 0; for (i = GTP_ADDR_LENGTH; i < cfg_len; i++) { check_sum += config[i]; } config[cfg_len] = (~check_sum) + 1; */ #endif GTP_INFO("X_MAX = %d, Y_MAX = %d, TRIGGER = 0x%02x", abs_x_max,abs_y_max,int_type); } msleep(10); return 0; } static s8 gtp_i2c_test(struct i2c_client *client) { u8 retry = 0; s8 ret = -1; u32 hw_info = 0; GTP_DEBUG_FUNC(); while (retry++ < 3) { ret = i2c_read_bytes(client, GTP_REG_HW_INFO, (u8 *)&hw_info, sizeof(hw_info)); if ((!ret) && (hw_info == 0x00900600)) //20121212 { return ret; } GTP_ERROR("GTP_REG_HW_INFO : %08X", hw_info); GTP_ERROR("GTP i2c test failed time %d.", retry); msleep(10); } return -1; } /******************************************************* Function: Set INT pin as input for FW sync. Note: If the INT is high, It means there is pull up resistor attached on the INT pin. Pull low the INT pin manaully for FW sync. *******************************************************/ void gtp_int_sync(s32 ms) { GTP_GPIO_OUTPUT(GTP_INT_PORT, 0); msleep(ms); GTP_GPIO_AS_INT(GTP_INT_PORT); } void gtp_reset_guitar(struct i2c_client *client, s32 ms) { GTP_INFO("GTP RESET!\n"); GTP_GPIO_OUTPUT(GTP_RST_PORT, 0); msleep(ms); GTP_GPIO_OUTPUT(GTP_INT_PORT, client->addr == 0x14); msleep(2); GTP_GPIO_OUTPUT(GTP_RST_PORT, 1); msleep(6); //must >= 6ms #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { return; } #endif gtp_int_sync(50); #if GTP_ESD_PROTECT gtp_init_ext_watchdog(i2c_client_point); #endif } static int tpd_power_on(struct i2c_client *client) { int ret = 0; int reset_count = 0; reset_proc: GTP_GPIO_OUTPUT(GTP_RST_PORT, 0); GTP_GPIO_OUTPUT(GTP_INT_PORT, 0); msleep(10); #ifdef MT6573 // power on CTP mt_set_gpio_mode(GPIO_CTP_EN_PIN, GPIO_CTP_EN_PIN_M_GPIO); mt_set_gpio_dir(GPIO_CTP_EN_PIN, GPIO_DIR_OUT); mt_set_gpio_out(GPIO_CTP_EN_PIN, GPIO_OUT_ONE); #else // ( defined(MT6575) || defined(MT6577) || defined(MT6589) ) #ifdef TPD_POWER_SOURCE_CUSTOM hwPowerOn(TPD_POWER_SOURCE_CUSTOM, VOL_2800, "TP"); #else hwPowerOn(MT65XX_POWER_LDO_VGP2, VOL_2800, "TP"); #endif #ifdef TPD_POWER_SOURCE_1800 hwPowerOn(TPD_POWER_SOURCE_1800, VOL_1800, "TP"); #endif #endif gtp_reset_guitar(client, 20); #if GTP_COMPATIBLE_MODE gtp_get_chip_type(client); if (CHIP_TYPE_GT9F == gtp_chip_type) { ret = gup_fw_download_proc(NULL, GTP_FL_FW_BURN); if(FAIL == ret) { GTP_ERROR("[tpd_power_on]Download fw failed."); if(reset_count++ < TPD_MAX_RESET_COUNT) { goto reset_proc; } else { return -1; } } ret = gtp_fw_startup(client); if(FAIL == ret) { GTP_ERROR("[tpd_power_on]Startup fw failed."); if(reset_count++ < TPD_MAX_RESET_COUNT) { goto reset_proc; } else { return -1; } } } else #endif { ret = gtp_i2c_test(client); if (ret < 0) { GTP_ERROR("I2C communication ERROR!"); if (reset_count < TPD_MAX_RESET_COUNT) { reset_count++; goto reset_proc; } } } return ret; } //**************** For GT9XXF Start ********************// #if GTP_COMPATIBLE_MODE void gtp_get_chip_type(struct i2c_client *client) { u8 opr_buf[10] = {0x00}; s32 ret = 0; msleep(10); ret = gtp_i2c_read_dbl_check(client, GTP_REG_CHIP_TYPE, opr_buf, 10); if (FAIL == ret) { GTP_ERROR("Failed to get chip-type, set chip type default: GOODIX_GT9"); gtp_chip_type = CHIP_TYPE_GT9; return; } if (!memcmp(opr_buf, "GOODIX_GT9", 10)) { gtp_chip_type = CHIP_TYPE_GT9; } else // GT9XXF { gtp_chip_type = CHIP_TYPE_GT9F; } GTP_INFO("Chip Type: %s", (gtp_chip_type == CHIP_TYPE_GT9) ? "GOODIX_GT9" : "GOODIX_GT9F"); } static u8 gtp_bak_ref_proc(struct i2c_client *client, u8 mode) { s32 i = 0; s32 j = 0; s32 ret = 0; struct file *flp = NULL; u8 *refp = NULL; u32 ref_len = 0; u32 ref_seg_len = 0; s32 ref_grps = 0; s32 ref_chksum = 0; u16 tmp = 0; GTP_DEBUG("[gtp_bak_ref_proc]Driver:%d,Sensor:%d.", driver_num, sensor_num); //check file-system mounted GTP_DEBUG("[gtp_bak_ref_proc]Waiting for FS %d", gtp_ref_retries); if (gup_check_fs_mounted("/data") == FAIL) { GTP_DEBUG("[gtp_bak_ref_proc]/data not mounted"); if(gtp_ref_retries++ < GTP_CHK_FS_MNT_MAX) { return FAIL; } } else { GTP_DEBUG("[gtp_bak_ref_proc]/data mounted !!!!"); } if (is_950) { ref_seg_len = (driver_num * (sensor_num - 1) + 2) * 2; ref_grps = 6; ref_len = ref_seg_len * 6; // for GT950, backup-reference for six segments } else { ref_len = driver_num*(sensor_num-2)*2 + 4; ref_seg_len = ref_len; ref_grps = 1; } refp = (u8 *)kzalloc(ref_len, GFP_KERNEL); if(refp == NULL) { GTP_ERROR("Failed to allocate memory for reference buffer!"); return FAIL; } memset(refp, 0, ref_len); //get ref file data flp = filp_open(GTP_BAK_REF_PATH, O_RDWR | O_CREAT, 0666); if (IS_ERR(flp)) { GTP_ERROR("Failed to open/create %s.", GTP_BAK_REF_PATH); if (GTP_BAK_REF_SEND == mode) { goto default_bak_ref; } else { goto exit_ref_proc; } } switch (mode) { case GTP_BAK_REF_SEND: { flp->f_op->llseek(flp, 0, SEEK_SET); ret = flp->f_op->read(flp, (char *)refp, ref_len, &flp->f_pos); if(ret < 0) { GTP_ERROR("Read ref file failed, send default bak ref."); goto default_bak_ref; } //checksum ref file for (j = 0; j < ref_grps; ++j) { ref_chksum = 0; for(i=0; if_op->llseek(flp, 0, SEEK_SET); flp->f_op->write(flp, (char *)refp, ref_len, &flp->f_pos); } break; default: GTP_ERROR("Invalid Argument(%d) for backup reference", mode); ret = FAIL; goto exit_ref_proc; } ret = SUCCESS; goto exit_ref_proc; default_bak_ref: for (j = 0; j < ref_grps; ++j) { memset(&refp[j * ref_seg_len], 0, ref_seg_len); refp[j * ref_seg_len + ref_seg_len - 1] = 0x01; // checksum = 1 } ret = i2c_write_bytes(client, GTP_REG_BAK_REF, refp, ref_len); if (flp && !IS_ERR(flp)) { GTP_INFO("Write backup-reference data into %s", GTP_BAK_REF_PATH); flp->f_op->llseek(flp, 0, SEEK_SET); flp->f_op->write(flp, (char*)refp, ref_len, &flp->f_pos); } if (ret < 0) { GTP_ERROR("Failed to load the default backup reference"); ret = FAIL; } else { ret = SUCCESS; } exit_ref_proc: if (refp) { kfree(refp); } if (flp && !IS_ERR(flp)) { filp_close(flp, NULL); } return ret; } u8 gtp_fw_startup(struct i2c_client *client) { u8 wr_buf[4]; s32 ret = 0; //init sw WDT wr_buf[0] = 0xAA; ret = i2c_write_bytes(client, 0x8041, wr_buf, 1); if (ret < 0) { GTP_ERROR("I2C error to firmware startup."); return FAIL; } //release SS51 & DSP wr_buf[0] = 0x00; i2c_write_bytes(client, 0x4180, wr_buf, 1); //int sync gtp_int_sync(25); //check fw run status i2c_read_bytes(client, 0x8041, wr_buf, 1); if(0xAA == wr_buf[0]) { GTP_ERROR("IC works abnormally,startup failed."); return FAIL; } else { GTP_DEBUG("IC works normally,Startup success."); wr_buf[0] = 0xAA; i2c_write_bytes(client, 0x8041, wr_buf, 1); return SUCCESS; } } static void gtp_recovery_reset(struct i2c_client *client) { #if GTP_ESD_PROTECT gtp_esd_switch(client, SWITCH_OFF); #endif force_reset_guitar(); #if GTP_ESD_PROTECT gtp_esd_switch(client, SWITCH_ON); #endif } static u8 gtp_check_clk_legality(u8 *p_clk_buf) { u8 i = 0; u8 clk_chksum = p_clk_buf[5]; for(i = 0; i < 5; i++) { if((p_clk_buf[i] < 50) || (p_clk_buf[i] > 120) || (p_clk_buf[i] != p_clk_buf[0])) { break; } clk_chksum += p_clk_buf[i]; } if((i == 5) && (clk_chksum == 0)) { GTP_DEBUG("Valid main clock data."); return SUCCESS; } GTP_ERROR("Invalid main clock data."); return FAIL; } static u8 gtp_main_clk_proc(struct i2c_client *client) { s32 ret = 0; u8 i = 0; u8 clk_cal_result = 0; u8 clk_chksum = 0; u8 gtp_clk_buf[6] = {0}; struct file *flp = NULL; GTP_DEBUG("[gtp_main_clk_proc]Waiting for FS %d", gtp_ref_retries); if (gup_check_fs_mounted("/data") == FAIL) { GTP_DEBUG("[gtp_main_clk_proc]/data not mounted"); if(gtp_clk_retries++ < GTP_CHK_FS_MNT_MAX) { return FAIL; } else { GTP_ERROR("[gtp_main_clk_proc]Wait for file system timeout,need cal clk"); } } else { GTP_DEBUG("[gtp_main_clk_proc]/data mounted !!!!"); flp = filp_open(GTP_MAIN_CLK_PATH, O_RDWR | O_CREAT, 0666); if (!IS_ERR(flp)) { flp->f_op->llseek(flp, 0, SEEK_SET); ret = flp->f_op->read(flp, (char *)gtp_clk_buf, 6, &flp->f_pos); if(ret > 0) { ret = gtp_check_clk_legality(gtp_clk_buf); if(SUCCESS == ret) { GTP_DEBUG("[gtp_main_clk_proc]Open & read & check clk file success."); goto send_main_clk; } } } GTP_ERROR("[gtp_main_clk_proc]Check clk file failed,need cal clk"); } //cal clk #if GTP_ESD_PROTECT gtp_esd_switch(client, SWITCH_OFF); #endif clk_cal_result = gup_clk_calibration(); force_reset_guitar(); GTP_DEBUG("&&&&&&&&&&clk cal result:%d", clk_cal_result); #if GTP_ESD_PROTECT gtp_esd_switch(client, SWITCH_ON); #endif if(clk_cal_result < 50 || clk_cal_result > 120) { GTP_ERROR("Invalid main clock: %d", clk_cal_result); ret = FAIL; goto exit_clk_proc; } for(i = 0;i < 5; i++) { gtp_clk_buf[i] = clk_cal_result; clk_chksum += gtp_clk_buf[i]; } gtp_clk_buf[5] = 0 - clk_chksum; send_main_clk: ret = i2c_write_bytes(client, 0x8020, gtp_clk_buf, 6); if (flp && !IS_ERR(flp)) { flp->f_op->llseek(flp, 0, SEEK_SET); flp->f_op->write(flp, (char *)gtp_clk_buf, 6, &flp->f_pos); } if(-1 == ret) { GTP_ERROR("[gtp_main_clk_proc]send main clk i2c error!"); ret = FAIL; } else { ret = SUCCESS; } exit_clk_proc: if (flp && !IS_ERR(flp)) { filp_close(flp, NULL); } return ret; } #endif //************* For GT9XXF End **********************// #if GTP_WITH_PEN static void gtp_pen_init(void) { s32 ret = 0; pen_dev = input_allocate_device(); if (pen_dev == NULL) { GTP_ERROR("Failed to allocate input device for pen/stylus."); return; } pen_dev->evbit[0] = BIT_MASK(EV_SYN) | BIT_MASK(EV_KEY) | BIT_MASK(EV_ABS) ; pen_dev->keybit[BIT_WORD(BTN_TOUCH)] = BIT_MASK(BTN_TOUCH); set_bit(BTN_TOOL_PEN, pen_dev->keybit); set_bit(INPUT_PROP_DIRECT, pen_dev->propbit); //set_bit(INPUT_PROP_POINTER, pen_dev->propbit); #if GTP_PEN_HAVE_BUTTON input_set_capability(pen_dev, EV_KEY, BTN_STYLUS); input_set_capability(pen_dev, EV_KEY, BTN_STYLUS2); #endif input_set_abs_params(pen_dev, ABS_MT_POSITION_X, 0, TPD_RES_X, 0, 0); input_set_abs_params(pen_dev, ABS_MT_POSITION_Y, 0, TPD_RES_Y, 0, 0); input_set_abs_params(pen_dev, ABS_MT_PRESSURE, 0, 255, 0, 0); input_set_abs_params(pen_dev, ABS_MT_TOUCH_MAJOR, 0, 255, 0, 0); input_set_abs_params(pen_dev, ABS_MT_TRACKING_ID, 0, 255, 0, 0); pen_dev->name = "mtk-pen"; pen_dev->phys = "input/ts"; pen_dev->id.bustype = BUS_I2C; ret = input_register_device(pen_dev); if (ret) { GTP_ERROR("Register %s input device failed", pen_dev->name); return; } } static void gtp_pen_down(s32 x, s32 y, s32 size, s32 id) { input_report_key(pen_dev, BTN_TOOL_PEN, 1); input_report_key(pen_dev, BTN_TOUCH, 1); input_report_abs(pen_dev, ABS_MT_POSITION_X, x); input_report_abs(pen_dev, ABS_MT_POSITION_Y, y); if ((!size) && (!id)) { input_report_abs(pen_dev, ABS_MT_PRESSURE, 100); input_report_abs(pen_dev, ABS_MT_TOUCH_MAJOR, 100); } else { input_report_abs(pen_dev, ABS_MT_PRESSURE, size); input_report_abs(pen_dev, ABS_MT_TOUCH_MAJOR, size); input_report_abs(pen_dev, ABS_MT_TRACKING_ID, id); } input_mt_sync(pen_dev); } static void gtp_pen_up(void) { input_report_key(pen_dev, BTN_TOOL_PEN, 0); input_report_key(pen_dev, BTN_TOUCH, 0); } #endif /* Get /dev/devices sysfs kobject struct */ static struct kobject * sysfs_get_devices_parent(void) { struct device *tmp = NULL; struct kset *pdevices_kset; tmp = kzalloc(sizeof(*tmp), GFP_KERNEL); if (!tmp){ return NULL; } device_initialize(tmp); pdevices_kset = tmp->kobj.kset; kfree(tmp); return &pdevices_kset->kobj; } #ifdef MZ_HALL_MODE static int gt9xx_hall_mode = 0; static s32 gtp_send_cfg_hall_mode(struct i2c_client *client) { s32 ret = 1; #if GTP_DRIVER_SEND_CFG s32 retry = 0; if (fixed_config) { GTP_INFO("Ic fixed config, no config sent!"); return 0; } else if (pnl_init_error) { GTP_INFO("Error occurred in init_panel, no config sent!"); return 0; } GTP_ERROR("Driver Send Hall Mode Config version %02x\n", config[0]); for (retry = 0; retry < 5; retry++) { ret = gtp_i2c_write(client, config_hall_mode, GTP_CONFIG_MAX_LENGTH + GTP_ADDR_LENGTH); if (ret > 0) { break; } } #endif // delay 50ms, to make sure cfg switch successfully msleep(50); return ret; } static ssize_t gtp_sysfs_hall_mode_show(struct device *dev, struct device_attribute *attr, char *buf) { return sprintf(buf, "%d\n", gt9xx_hall_mode); } static ssize_t gtp_sysfs_hall_mode_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { int state = simple_strtol(buf, NULL, 10); gt9xx_hall_mode = !!state; if(gt9xx_hall_mode) gtp_send_cfg_hall_mode(i2c_client_point); else gtp_send_cfg(i2c_client_point); return count; } static DEVICE_ATTR(hall_mode, S_IRUGO|S_IWUSR, gtp_sysfs_hall_mode_show, gtp_sysfs_hall_mode_store); #endif static s32 tpd_i2c_probe(struct i2c_client *client, const struct i2c_device_id *id) { s32 err = 0; s32 ret = 0; u16 version_info; #if GTP_HAVE_TOUCH_KEY s32 idx = 0; #endif #ifdef TPD_PROXIMITY struct hwmsen_object obj_ps; #endif i2c_client_point = client; ret = tpd_power_on(client); if (ret < 0) { GTP_ERROR("I2C communication ERROR!"); return -1; } #ifdef VELOCITY_CUSTOM if ((err = misc_register(&tpd_misc_device))) { GTP_ERROR("mtk_tpd: tpd_misc_device register failed\n"); } #endif ret = gtp_read_version(client, &version_info); if (ret < 0) { GTP_ERROR("Read version failed."); } ret = gtp_init_panel(client); if (ret < 0) { GTP_ERROR("GTP init panel failed."); } // Create proc file system gt91xx_config_proc = proc_create(GT91XX_CONFIG_PROC_FILE, 0666, NULL, &config_proc_ops); if (gt91xx_config_proc == NULL) { GTP_ERROR("create_proc_entry %s failed\n", GT91XX_CONFIG_PROC_FILE); } else { GTP_INFO("create proc entry %s success", GT91XX_CONFIG_PROC_FILE); } #if GTP_CREATE_WR_NODE init_wr_node(client); #endif #ifdef MZ_SELF_TEST gtp_test_sysfs_init(&client->dev.kobj); #endif #ifdef MZ_HALL_MODE sysfs_create_file(&client->dev.kobj, &dev_attr_hall_mode.attr); #endif // keep this to make kernel compatible with old flyme sysfs_create_link(sysfs_get_devices_parent(), &client->dev.kobj, "mx_tsp"); meizu_sysfslink_register_name(&client->dev, "tp"); thread = kthread_run(touch_event_handler, 0, TPD_DEVICE); if (IS_ERR(thread)) { err = PTR_ERR(thread); GTP_INFO(TPD_DEVICE " failed to create kernel thread: %d\n", err); } mz_gesture_handle_register(gt9xx_gesture_handler); #if GTP_HAVE_TOUCH_KEY for (idx = 0; idx < GTP_MAX_KEY_NUM; idx++) { input_set_capability(tpd->dev, EV_KEY, touch_key_array[idx]); } #endif #ifdef TYPE_B_PROTOCOL input_mt_init_slots(tpd->dev, GTP_MAX_TOUCH, INPUT_MT_DIRECT); #endif #if GTP_WITH_PEN gtp_pen_init(); #endif // set INT mode mt_set_gpio_mode(GPIO_CTP_EINT_PIN, GPIO_CTP_EINT_PIN_M_EINT); mt_set_gpio_dir(GPIO_CTP_EINT_PIN, GPIO_DIR_IN); mt_set_gpio_pull_enable(GPIO_CTP_EINT_PIN, GPIO_PULL_DISABLE); msleep(50); //#ifdef MT6572 if (!int_type) //EINTF_TRIGGER { mt_eint_registration(CUST_EINT_TOUCH_PANEL_NUM, EINTF_TRIGGER_RISING, tpd_eint_interrupt_handler, 1); } else { mt_eint_registration(CUST_EINT_TOUCH_PANEL_NUM, EINTF_TRIGGER_FALLING, tpd_eint_interrupt_handler, 1); } #if 0 mt65xx_eint_set_sens(CUST_EINT_TOUCH_PANEL_NUM, CUST_EINT_TOUCH_PANEL_SENSITIVE); mt65xx_eint_set_hw_debounce(CUST_EINT_TOUCH_PANEL_NUM, CUST_EINT_TOUCH_PANEL_DEBOUNCE_CN); if (!int_type) { mt65xx_eint_registration(CUST_EINT_TOUCH_PANEL_NUM, CUST_EINT_TOUCH_PANEL_DEBOUNCE_EN, CUST_EINT_POLARITY_HIGH, tpd_eint_interrupt_handler, 1); } else { mt65xx_eint_registration(CUST_EINT_TOUCH_PANEL_NUM, CUST_EINT_TOUCH_PANEL_DEBOUNCE_EN, CUST_EINT_POLARITY_LOW, tpd_eint_interrupt_handler, 1); } #endif mt_eint_unmask(CUST_EINT_TOUCH_PANEL_NUM); #if GTP_AUTO_UPDATE ret = gup_init_update_proc(client); if (ret < 0) { GTP_ERROR("Create update thread error."); } #endif #ifdef TPD_PROXIMITY //obj_ps.self = cm3623_obj; obj_ps.polling = 0; //0--interrupt mode;1--polling mode; obj_ps.sensor_operate = tpd_ps_operate; if ((err = hwmsen_attach(ID_PROXIMITY, &obj_ps))) { GTP_ERROR("hwmsen attach fail, return:%d.", err); } #endif #if GTP_ESD_PROTECT gtp_esd_switch(client, SWITCH_ON); #endif tpd_load_status = 1; return 0; } static void tpd_eint_interrupt_handler(void) { TPD_DEBUG_PRINT_INT; tpd_flag = 1; wake_up_interruptible(&waiter); } static int tpd_i2c_remove(struct i2c_client *client) { #if GTP_CREATE_WR_NODE uninit_wr_node(); #endif #ifdef MZ_SELF_TEST gtp_test_sysfs_deinit(); #endif #if GTP_ESD_PROTECT destroy_workqueue(gtp_esd_check_workqueue); #endif return 0; } #if (GTP_ESD_PROTECT || GTP_COMPATIBLE_MODE) static void force_reset_guitar(void) { s32 i = 0; s32 ret = 0; GTP_INFO("force_reset_guitar"); mt_eint_mask(CUST_EINT_TOUCH_PANEL_NUM); GTP_GPIO_OUTPUT(GTP_RST_PORT, 0); GTP_GPIO_OUTPUT(GTP_INT_PORT, 0); #ifdef MT6573 //Power off TP mt_set_gpio_mode(GPIO_CTP_EN_PIN, GPIO_CTP_EN_PIN_M_GPIO); mt_set_gpio_dir(GPIO_CTP_EN_PIN, GPIO_DIR_OUT); mt_set_gpio_out(GPIO_CTP_EN_PIN, GPIO_OUT_ZERO); msleep(30); //Power on TP mt_set_gpio_out(GPIO_CTP_EN_PIN, GPIO_OUT_ONE); msleep(30); #else // ( defined(MT6575) || defined(MT6577) || defined(MT6589) ) // Power off TP #ifdef TPD_POWER_SOURCE_CUSTOM hwPowerDown(TPD_POWER_SOURCE_CUSTOM, "TP"); #else hwPowerDown(MT65XX_POWER_LDO_VGP2, "TP"); #endif msleep(30); // Power on TP #ifdef TPD_POWER_SOURCE_CUSTOM hwPowerOn(TPD_POWER_SOURCE_CUSTOM, VOL_2800, "TP"); #else hwPowerOn(MT65XX_POWER_LDO_VGP2, VOL_2800, "TP"); #endif msleep(30); #endif for (i = 0; i < 5; i++) { #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { ret = gup_fw_download_proc(NULL, GTP_FL_ESD_RECOVERY); if(FAIL == ret) { GTP_ERROR("[force_reset_guitar]Check & repair fw failed."); continue; } //startup fw ret = gtp_fw_startup(i2c_client_point); if(FAIL == ret) { GTP_ERROR("[force_reset_guitar]Startup fw failed."); continue; } break; } else #endif { //Reset Guitar gtp_reset_guitar(i2c_client_point, 20); msleep(50); //Send config ret = gtp_send_cfg(i2c_client_point); if (ret < 0) { continue; } } break; } mt_eint_unmask(CUST_EINT_TOUCH_PANEL_NUM); if (i >= 5) { GTP_ERROR("Failed to reset guitar."); return; } GTP_INFO("Esd recovery successful"); return; } #endif #if GTP_ESD_PROTECT static s32 gtp_init_ext_watchdog(struct i2c_client *client) { u8 opr_buffer[2] = {0xAA}; GTP_DEBUG("Init external watchdog."); return i2c_write_bytes(client, 0x8041, opr_buffer, 1); } void gtp_esd_switch(struct i2c_client *client, s32 on) { spin_lock(&esd_lock); if (SWITCH_ON == on) // switch on esd { if (!esd_running) { esd_running = 1; spin_unlock(&esd_lock); GTP_INFO("Esd started"); queue_delayed_work(gtp_esd_check_workqueue, >p_esd_check_work, clk_tick_cnt); } else { spin_unlock(&esd_lock); } } else // switch off esd { if (esd_running) { esd_running = 0; spin_unlock(&esd_lock); GTP_INFO("Esd cancelled"); cancel_delayed_work_sync(>p_esd_check_work); } else { spin_unlock(&esd_lock); } } } static void gtp_esd_check_func(struct work_struct *work) { s32 i = 0; s32 ret = -1; u8 esd_buf[3] = {0x00}; if (tpd_halt) { GTP_ERROR("Esd suspended!"); return; } for (i = 0; i < 3; i++) { ret = i2c_read_bytes_non_dma(i2c_client_point, 0x8040, esd_buf, 2); GTP_ERROR("[Esd]0x8040 = 0x%02X, 0x8041 = 0x%02X", esd_buf[0], esd_buf[1]); if (ret < 0) { // IIC communication problem continue; } else { if ((esd_buf[0] == 0xAA) || (esd_buf[1] != 0xAA)) { u8 chk_buf[2] = {0x00}; i2c_read_bytes_non_dma(i2c_client_point, 0x8040, chk_buf, 2); GTP_ERROR("[Check]0x8040 = 0x%02X, 0x8041 = 0x%02X", chk_buf[0], chk_buf[1]); if ( (chk_buf[0] == 0xAA) || (chk_buf[1] != 0xAA) ) { i = 3; // jump to reset guitar break; } else { continue; } } else { // IC works normally, Write 0x8040 0xAA, feed the watchdog esd_buf[0] = 0xAA; i2c_write_bytes_non_dma(i2c_client_point, 0x8040, esd_buf, 1); break; } } } if (i >= 3) { #if GTP_COMPATIBLE_MODE if ((CHIP_TYPE_GT9F == gtp_chip_type) && (1 == rqst_processing)) { GTP_INFO("Request Processing, no reset guitar."); } else #endif { GTP_ERROR("IC works abnormally! Process reset guitar."); esd_buf[0] = 0x01; esd_buf[1] = 0x01; esd_buf[2] = 0x01; i2c_write_bytes(i2c_client_point, 0x4226, esd_buf, 3); msleep(50); force_reset_guitar(); } } if (!tpd_halt) { queue_delayed_work(gtp_esd_check_workqueue, >p_esd_check_work, clk_tick_cnt); } else { GTP_ERROR("Esd suspended!"); } return; } #endif static void tpd_down(s32 x, s32 y, s32 size, s32 id) { #ifdef TYPE_B_PROTOCOL input_mt_slot(tpd->dev, id); input_mt_report_slot_state(tpd->dev, MT_TOOL_FINGER, 1); #endif if ((!size) && (!id)) { input_report_abs(tpd->dev, ABS_MT_PRESSURE, 100); input_report_abs(tpd->dev, ABS_MT_TOUCH_MAJOR, 100); } else { input_report_abs(tpd->dev, ABS_MT_PRESSURE, size); input_report_abs(tpd->dev, ABS_MT_TOUCH_MAJOR, size); } set_bit(id, >9xx_finger_status); input_report_abs(tpd->dev, ABS_MT_POSITION_X, x); input_report_abs(tpd->dev, ABS_MT_POSITION_Y, y); #ifndef TYPE_B_PROTOCOL input_mt_sync(tpd->dev); #endif TPD_EM_PRINT(x, y, x, y, id, 1); #if (defined(MT6575)||defined(MT6577)) if (FACTORY_BOOT == get_boot_mode() || RECOVERY_BOOT == get_boot_mode()) { tpd_button(x, y, 1); } #endif } static void tpd_up(s32 x, s32 y, s32 id) { #ifdef TYPE_B_PROTOCOL input_mt_slot(tpd->dev, id); input_mt_report_slot_state(tpd->dev, MT_TOOL_FINGER, 0); #endif clear_bit(id, >9xx_finger_status); #ifndef TYPE_B_PROTOCOL input_mt_sync(tpd->dev); #endif TPD_EM_PRINT(x, y, x, y, id, 0); #if (defined(MT6575) || defined(MT6577)) if (FACTORY_BOOT == get_boot_mode() || RECOVERY_BOOT == get_boot_mode()) { tpd_button(x, y, 0); } #endif } static void gt9xx_clear_all_touch(void) { int i = 0; gt9xx_finger_status = gt9xx_finger_status_pre; while(gt9xx_finger_status != 0) { tpd_up(0, 0, i); i++; if(i > GTP_MAX_TOUCH) break; } input_sync(tpd->dev); gt9xx_finger_status_pre = 0; } #if GTP_CHARGER_SWITCH static void gtp_charger_switch(s32 dir_update) { u32 chr_status = 0; u8 chr_cmd[3] = {0x80, 0x40}; static u8 chr_pluggedin = 0; int ret = 0; #ifdef MT6573 chr_status = *(volatile u32 *)CHR_CON0; chr_status &= (1 << 13); #else // ( defined(MT6575) || defined(MT6577) || defined(MT6589) ) chr_status = upmu_is_chr_det(); #endif if (chr_status) // charger plugged in { if (!chr_pluggedin || dir_update) { chr_cmd[2] = 6; ret = gtp_i2c_write(i2c_client_point, chr_cmd, 3); if (ret > 0) { GTP_INFO("Update status for Charger Plugin"); } chr_pluggedin = 1; } } else // charger plugged out { if (chr_pluggedin || dir_update) { chr_cmd[2] = 7; ret = gtp_i2c_write(i2c_client_point, chr_cmd, 3); if (ret > 0) { GTP_INFO("Update status for Charger Plugout"); } chr_pluggedin = 0; } } } #endif DEFINE_MUTEX(gtp_suspend_lock); static int touch_event_handler(void *unused) { struct sched_param param = { .sched_priority = RTPM_PRIO_TPD }; u8 end_cmd[3] = {GTP_READ_COOR_ADDR >> 8, GTP_READ_COOR_ADDR & 0xFF, 0}; u8 point_data[2 + 1 + 8 * GTP_MAX_TOUCH + 1] = {GTP_READ_COOR_ADDR >> 8, GTP_READ_COOR_ADDR & 0xFF}; u8 touch_num = 0; u8 finger = 0; static u8 pre_touch = 0; static u8 pre_key = 0; #if GTP_WITH_PEN u8 pen_active = 0; static u8 pre_pen = 0; #endif u8 key_value = 0; u8 *coor_data = NULL; s32 input_x = 0; s32 input_y = 0; s32 input_w = 0; s32 id = 0; s32 i = 0; s32 ret = -1; u8 gesture_code; #if GTP_COMPATIBLE_MODE u8 rqst_data[3] = {(u8)(GTP_REG_RQST >> 8), (u8)(GTP_REG_RQST & 0xFF), 0}; #endif #ifdef TPD_PROXIMITY s32 err = 0; hwm_sensor_data sensor_data; u8 proximity_status; #endif #if GTP_GESTURE_WAKEUP u8 doze_buf[3] = {0x81, 0x4B}; u8 gesture_data[6] = {0x81, 0x4D}; #endif sched_setscheduler(current, SCHED_RR, ¶m); do { set_current_state(TASK_INTERRUPTIBLE); while (tpd_halt) { #if GTP_GESTURE_WAKEUP if (DOZE_ENABLED == doze_status) { break; } #endif tpd_flag = 0; msleep(20); } wait_event_interruptible(waiter, tpd_flag != 0); tpd_flag = 0; TPD_DEBUG_SET_TIME; set_current_state(TASK_RUNNING); mutex_lock(>p_suspend_lock); #if GTP_CHARGER_SWITCH gtp_charger_switch(0); #endif #if GTP_GESTURE_WAKEUP if (DOZE_ENABLED == doze_status) { ret = gtp_i2c_read(i2c_client_point, doze_buf, 3); if (ret > 0) { if(doze_buf[2] == 0xcc) { gtp_i2c_read(i2c_client_point, gesture_data, 6); if (((gesture_data[2]==1) || (gesture_data[2]==2) || (gesture_data[2]==4)) && (gesture_data[3]==0) && (gesture_data[4]==0) && (gesture_data[5]==0)) { //ignore double tap on HOME_KEY gesture_code = GESTURE_ERROR; } else gesture_code = DOUBLE_TAP; } else if(doze_buf[2] == 0xaa) { gesture_code = SWIPE_X_RIGHT; } else if(doze_buf[2] == 0xbb) { gesture_code = SWIPE_X_LEFT; } else if(doze_buf[2] == 0xab) { gesture_code = SWIPE_Y_DOWN; } else if(doze_buf[2] == 0xba) { gesture_code = SWIPE_Y_UP; } else if(doze_buf[2] == 'e') { gesture_code = UNICODE_E; } else if(doze_buf[2] == 'c') { gesture_code = UNICODE_C; } else if(doze_buf[2] == 'w') { gesture_code = UNICODE_W; } else if(doze_buf[2] == 'm') { gesture_code = UNICODE_M; } else if(doze_buf[2] == 'o') { gesture_code = UNICODE_O; } else if(doze_buf[2] == 's') { gesture_code = UNICODE_S; } else if(doze_buf[2] == 'v') { gesture_code = UNICODE_V_DOWN; } else if(doze_buf[2] == 'z') { gesture_code = UNICODE_Z; } else { gesture_code = GESTURE_ERROR; } GTP_DEBUG("0x814B = 0x%02X, gesture_code 0x%02x\n", doze_buf[2], gesture_code); // clear 0x814B doze_buf[2] = 0x00; gtp_i2c_write(i2c_client_point, doze_buf, 3); if(gesture_code != GESTURE_ERROR) { if(mz_gesture_report(tpd->dev, gesture_code)) doze_status = DOZE_ENABLED; } else { gtp_enter_doze(i2c_client_point); } } goto exit_lock; } #endif ret = gtp_i2c_read(i2c_client_point, point_data, 12); if (ret < 0) { GTP_ERROR("I2C transfer error. errno:%d\n ", ret); goto exit_work_func; } finger = point_data[GTP_ADDR_LENGTH]; #if GTP_COMPATIBLE_MODE if ((finger == 0x00) && (CHIP_TYPE_GT9F == gtp_chip_type)) { ret = gtp_i2c_read(i2c_client_point, rqst_data, 3); if(ret < 0) { GTP_ERROR("I2C transfer error. errno:%d\n ", ret); goto exit_work_func; } switch (rqst_data[2]) { case GTP_RQST_BAK_REF: GTP_INFO("Request Ref."); rqst_processing = 1; ret = gtp_bak_ref_proc(i2c_client_point, GTP_BAK_REF_SEND); if(SUCCESS == ret) { GTP_INFO("Send ref success."); rqst_data[2] = GTP_RQST_RESPONDED; gtp_i2c_write(i2c_client_point, rqst_data, 3); rqst_processing = 0; } goto exit_work_func; case GTP_RQST_CONFIG: GTP_INFO("Request Config."); ret = gtp_send_cfg(i2c_client_point); if (ret < 0) { GTP_ERROR("Send config error."); } else { GTP_INFO("Send config success."); rqst_data[2] = GTP_RQST_RESPONDED; gtp_i2c_write(i2c_client_point, rqst_data, 3); } goto exit_work_func; case GTP_RQST_MAIN_CLOCK: GTP_INFO("Request main clock."); rqst_processing = 1; ret = gtp_main_clk_proc(i2c_client_point); if(SUCCESS == ret) { GTP_INFO("Send main clk success."); rqst_data[2] = GTP_RQST_RESPONDED; gtp_i2c_write(i2c_client_point, rqst_data, 3); rqst_processing = 0; } goto exit_work_func; case GTP_RQST_RESET: GTP_INFO("Request Reset."); gtp_recovery_reset(i2c_client_point); goto exit_work_func; default: GTP_INFO("Undefined request code: 0x%02X", rqst_data[2]); rqst_data[2] = GTP_RQST_RESPONDED; gtp_i2c_write(i2c_client_point, rqst_data, 3); break; } } #endif if (finger == 0x00) { goto exit_work_func; } // large point control bit if ((finger & 0x40) != 0) { gt9xx_clear_all_touch(); goto exit_work_func; } if ((finger & 0x80) == 0) { goto exit_work_func; } #ifdef TPD_PROXIMITY if (tpd_proximity_flag == 1) { proximity_status = point_data[GTP_ADDR_LENGTH]; GTP_DEBUG("REG INDEX[0x814E]:0x%02X\n", proximity_status); if (proximity_status & 0x60) //proximity or large touch detect,enable hwm_sensor. { tpd_proximity_detect = 0; //sensor_data.values[0] = 0; } else { tpd_proximity_detect = 1; //sensor_data.values[0] = 1; } //get raw data GTP_DEBUG(" ps change\n"); GTP_DEBUG("PROXIMITY STATUS:0x%02X\n", tpd_proximity_detect); //map and store data to hwm_sensor_data sensor_data.values[0] = tpd_get_ps_value(); sensor_data.value_divide = 1; sensor_data.status = SENSOR_STATUS_ACCURACY_MEDIUM; //report to the up-layer ret = hwmsen_get_interrupt_data(ID_PROXIMITY, &sensor_data); if (ret) { GTP_ERROR("Call hwmsen_get_interrupt_data fail = %d\n", err); } } #endif touch_num = finger & 0x0f; if (touch_num > GTP_MAX_TOUCH) { goto exit_work_func; } if (touch_num > 1) { u8 buf[8 * GTP_MAX_TOUCH] = {(GTP_READ_COOR_ADDR + 10) >> 8, (GTP_READ_COOR_ADDR + 10) & 0xff}; ret = gtp_i2c_read(i2c_client_point, buf, 2 + 8 * (touch_num - 1)); memcpy(&point_data[12], &buf[2], 8 * (touch_num - 1)); } #if (GTP_HAVE_TOUCH_KEY || GTP_PEN_HAVE_BUTTON) key_value = point_data[3 + 8 * touch_num]; if (key_value || pre_key) { #if GTP_PEN_HAVE_BUTTON if (key_value == 0x40) { GTP_DEBUG("BTN_STYLUS & BTN_STYLUS2 Down."); input_report_key(pen_dev, BTN_STYLUS, 1); input_report_key(pen_dev, BTN_STYLUS2, 1); pen_active = 1; } else if (key_value == 0x10) { GTP_DEBUG("BTN_STYLUS Down, BTN_STYLUS2 Up."); input_report_key(pen_dev, BTN_STYLUS, 1); input_report_key(pen_dev, BTN_STYLUS2, 0); pen_active = 1; } else if (key_value == 0x20) { GTP_DEBUG("BTN_STYLUS Up, BTN_STYLUS2 Down."); input_report_key(pen_dev, BTN_STYLUS, 0); input_report_key(pen_dev, BTN_STYLUS2, 1); pen_active = 1; } else { GTP_DEBUG("BTN_STYLUS & BTN_STYLUS2 Up."); input_report_key(pen_dev, BTN_STYLUS, 0); input_report_key(pen_dev, BTN_STYLUS2, 0); if ( (pre_key == 0x40) || (pre_key == 0x20) || (pre_key == 0x10) ) { pen_active = 1; } } if (pen_active) { touch_num = 0; // shield pen point //pre_touch = 0; // clear last pen status } #endif #if GTP_HAVE_TOUCH_KEY if (!pre_touch) { for (i = 0; i < GTP_MAX_KEY_NUM; i++) { GTP_ERROR("report touch key %d, val %d\n", touch_key_array[i], key_value & (0x01 << i)); // record we have key pressed if(key_value & (0x01 << i)) { set_bit(16 + i, >9xx_finger_status); continue; } else if(test_bit(16 + i, >9xx_finger_status_pre)) { GTP_ERROR("start report touch key, i %d", i); input_report_key(tpd->dev, touch_key_array[i], 1); input_report_key(tpd->dev, touch_key_array[i], 0); //clear_bit(16 + i, >9xx_finger_status); } else GTP_ERROR("ignore invalid key %d, val %d\n", touch_key_array[i], key_value & (0x01 << i)); } //touch_num = 0; // shiled fingers } #endif } #endif pre_key = key_value; GTP_DEBUG("pre_touch:%02x, finger:%02x.", pre_touch, finger); if (touch_num) { input_report_key(tpd->dev, BTN_TOUCH, 1); for (i = 0; i < touch_num; i++) { coor_data = &point_data[i * 8 + 3]; id = coor_data[0] & 0x0F; input_x = coor_data[1] | coor_data[2] << 8; input_y = coor_data[3] | coor_data[4] << 8; input_w = coor_data[5] | coor_data[6] << 8; input_x = TPD_WARP_X(abs_x_max, input_x); input_y = TPD_WARP_Y(abs_y_max, input_y); #if GTP_WITH_PEN id = coor_data[0]; if ((id & 0x80)) // pen/stylus is activated { GTP_DEBUG("Pen touch DOWN!"); pre_pen = 1; //id &= 0x7F; id = 0; GTP_DEBUG("(%d)(%d, %d)[%d]", id, input_x, input_y, input_w); gtp_pen_down(input_x, input_y, input_w, id); pen_active = 1; } else #endif { GTP_DEBUG(" (%d)(%d, %d)[%d]\n", id, input_x, input_y, input_w); tpd_down(input_x, input_y, input_w, id); } } if(gt9xx_finger_status != gt9xx_finger_status_pre) { // up non-contact finger for(i = 0; i < GTP_MAX_TOUCH; i++) if(!test_bit(i, >9xx_finger_status) && test_bit(i, >9xx_finger_status_pre)) tpd_up(0, 0, i); } } else { if (pre_touch) { #if GTP_WITH_PEN if (pre_pen) { GTP_DEBUG("Pen touch UP!"); gtp_pen_up(); pre_pen = 0; pen_active = 1; } else #endif { #ifdef TYPE_B_PROTOCOL gt9xx_clear_all_touch(); #else tpd_up(0, 0, 0); #endif GTP_DEBUG("Touch Release: %d, finger_status: %lx\n", pre_touch, gt9xx_finger_status_pre); input_report_key(tpd->dev, BTN_TOUCH, 0); } } } pre_touch = touch_num; gt9xx_finger_status_pre = gt9xx_finger_status; gt9xx_finger_status = 0; #if GTP_WITH_PEN if (pen_active) { pen_active = 0; input_sync(pen_dev); } else #endif { input_sync(tpd->dev); } exit_work_func: if (!gtp_rawdiff_mode) { ret = gtp_i2c_write(i2c_client_point, end_cmd, 3); if (ret < 0) { GTP_INFO("I2C write end_cmd error!"); } } exit_lock: mutex_unlock(>p_suspend_lock); } while (!kthread_should_stop()); return 0; } static int tpd_local_init(void) { #if GTP_ESD_PROTECT clk_tick_cnt = 2 * HZ; // HZ: clock ticks in 1 second generated by system GTP_DEBUG("Clock ticks for an esd cycle: %d", clk_tick_cnt); INIT_DELAYED_WORK(>p_esd_check_work, gtp_esd_check_func); gtp_esd_check_workqueue = create_workqueue("gtp_esd_check"); spin_lock_init(&esd_lock); // 2.6.39 & later // esd_lock = SPIN_LOCK_UNLOCKED; // 2.6.39 & before #endif #if GTP_SUPPORT_I2C_DMA gpDMABuf_va = (u8 *)dma_alloc_coherent(&tpd->dev->dev, GTP_DMA_MAX_TRANSACTION_LENGTH, &gpDMABuf_pa, GFP_KERNEL); if(!gpDMABuf_va){ GTP_INFO("[Error] Allocate DMA I2C Buffer failed!\n"); } memset(gpDMABuf_va, 0, GTP_DMA_MAX_TRANSACTION_LENGTH); #endif if (i2c_add_driver(&tpd_i2c_driver) != 0) { GTP_INFO("unable to add i2c driver.\n"); goto exit_free_dma_buffer; } if (tpd_load_status == 0) //if(tpd_load_status == 0) // disable auto load touch driver for linux3.0 porting { GTP_INFO("add error touch panel driver.\n"); i2c_del_driver(&tpd_i2c_driver); goto exit_free_dma_buffer; } #ifdef TPD_HAVE_BUTTON tpd_button_setting(TPD_KEY_COUNT, tpd_keys_local, tpd_keys_dim_local);// initialize tpd button data #endif #if (defined(TPD_WARP_START) && defined(TPD_WARP_END)) TPD_DO_WARP = 1; memcpy(tpd_wb_start, tpd_wb_start_local, TPD_WARP_CNT * 4); memcpy(tpd_wb_end, tpd_wb_start_local, TPD_WARP_CNT * 4); #endif #if (defined(TPD_HAVE_CALIBRATION) && !defined(TPD_CUSTOM_CALIBRATION)) memcpy(tpd_calmat, tpd_def_calmat_local, 8 * 4); memcpy(tpd_def_calmat, tpd_def_calmat_local, 8 * 4); #endif // set vendor string tpd->dev->id.vendor = 0x00; tpd->dev->id.product = tpd_info.pid; tpd->dev->id.version = tpd_info.vid; GTP_INFO("end %s, %d\n", __func__, __LINE__); tpd_type_cap = 1; return 0; exit_free_dma_buffer: if (gpDMABuf_va) { dma_free_coherent(&tpd->dev->dev, GTP_DMA_MAX_TRANSACTION_LENGTH, gpDMABuf_va, gpDMABuf_pa); gpDMABuf_va = NULL; gpDMABuf_pa = 0; GTP_INFO("free DMA I2C buffer\n"); } return -1; } #if GTP_GESTURE_WAKEUP static s8 gtp_enter_doze(struct i2c_client *client) { s8 ret = -1; s8 retry = 0; u8 i2c_control_buf[3] = {(u8)(GTP_REG_SLEEP >> 8), (u8)GTP_REG_SLEEP, 8}; GTP_DEBUG_FUNC(); GTP_DEBUG("Entering gesture mode..."); while(retry++ < 5) { i2c_control_buf[0] = 0x80; i2c_control_buf[1] = 0x46; ret = gtp_i2c_write(client, i2c_control_buf, 3); if (ret < 0) { GTP_DEBUG("Failed to set gesture flag into 0x8046, %d", retry); continue; } i2c_control_buf[0] = 0x80; i2c_control_buf[1] = 0x40; ret = gtp_i2c_write(client, i2c_control_buf, 3); if (ret > 0) { doze_status = DOZE_ENABLED; GTP_INFO("Gesture mode enabled."); return ret; } msleep(10); } GTP_ERROR("GTP send gesture cmd failed."); return ret; } /******************************************************* Function: Eter sleep function. Input: client:i2c_client. Output: Executive outcomes.0--success,non-0--fail. *******************************************************/ static s8 gtp_enter_sleep(struct i2c_client *client) { #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { u8 i2c_status_buf[3] = {0x80, 0x44, 0x00}; s32 ret = 0; ret = gtp_i2c_read(client, i2c_status_buf, 3); if(ret <= 0) { GTP_ERROR("[gtp_enter_sleep]Read ref status reg error."); } if (i2c_status_buf[2] & 0x80) { //Store bak ref ret = gtp_bak_ref_proc(client, GTP_BAK_REF_STORE); if(FAIL == ret) { GTP_ERROR("[gtp_enter_sleep]Store bak ref failed."); } } } #endif #if GTP_POWER_CTRL_SLEEP GTP_GPIO_OUTPUT(GTP_RST_PORT, 0); GTP_GPIO_OUTPUT(GTP_INT_PORT, 0); msleep(10); #ifdef MT6573 mt_set_gpio_mode(GPIO_CTP_EN_PIN, GPIO_CTP_EN_PIN_M_GPIO); mt_set_gpio_dir(GPIO_CTP_EN_PIN, GPIO_DIR_OUT); mt_set_gpio_out(GPIO_CTP_EN_PIN, GPIO_OUT_ZERO); msleep(30); #else // ( defined(MT6575) || defined(MT6577) || defined(MT6589) ) #ifdef TPD_POWER_SOURCE_1800 hwPowerDown(TPD_POWER_SOURCE_1800, "TP"); #endif #ifdef TPD_POWER_SOURCE_CUSTOM hwPowerDown(TPD_POWER_SOURCE_CUSTOM, "TP"); #else hwPowerDown(MT65XX_POWER_LDO_VGP2, "TP"); #endif #endif GTP_INFO("GTP enter sleep by poweroff!"); return 0; #else { s8 ret = -1; s8 retry = 0; u8 i2c_control_buf[3] = {(u8)(GTP_REG_SLEEP >> 8), (u8)GTP_REG_SLEEP, 5}; GTP_GPIO_OUTPUT(GTP_INT_PORT, 0); msleep(5); while (retry++ < 5) { ret = gtp_i2c_write(client, i2c_control_buf, 3); if (ret > 0) { GTP_INFO("GTP enter sleep!"); return ret; } msleep(10); } GTP_ERROR("GTP send sleep cmd failed."); return ret; } #endif } #endif /******************************************************* Function: Wakeup from sleep mode Function. Input: client:i2c_client. Output: Executive outcomes.0--success,non-0--fail. *******************************************************/ static s8 gtp_wakeup_sleep(struct i2c_client *client) { u8 retry = 0; s8 ret = -1; GTP_DEBUG("GTP wakeup begin."); #if (GTP_POWER_CTRL_SLEEP) #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { force_reset_guitar(); GTP_INFO("Esd recovery wakeup."); return 0; } #endif while (retry++ < 5) { ret = tpd_power_on(client); if (ret < 0) { GTP_ERROR("I2C Power on ERROR!"); continue; } GTP_INFO("Ic wakeup by poweron"); return 0; } #else #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { u8 opr_buf[2] = {0}; while (retry++ < 10) { GTP_GPIO_OUTPUT(GTP_INT_PORT, 1); msleep(5); ret = gtp_i2c_test(client); if (ret >= 0) { // Hold ss51 & dsp opr_buf[0] = 0x0C; ret = i2c_write_bytes(client, 0x4180, opr_buf, 1); if (ret < 0) { GTP_DEBUG("Hold ss51 & dsp I2C error,retry:%d", retry); continue; } // Confirm hold opr_buf[0] = 0x00; ret = i2c_read_bytes(client, 0x4180, opr_buf, 1); if (ret < 0) { GTP_DEBUG("confirm ss51 & dsp hold, I2C error,retry:%d", retry); continue; } if (0x0C != opr_buf[0]) { GTP_DEBUG("ss51 & dsp not hold, val: %d, retry: %d", opr_buf[0], retry); continue; } GTP_DEBUG("ss51 & dsp has been hold"); ret = gtp_fw_startup(client); if (FAIL == ret) { GTP_ERROR("[gtp_wakeup_sleep]Startup fw failed."); continue; } GTP_INFO("flashless wakeup sleep success"); return ret; } force_reset_guitar(); retry = 0; break; } if (retry >= 10) { GTP_ERROR("wakeup retry timeout, process esd reset"); force_reset_guitar(); } GTP_ERROR("GTP wakeup sleep failed."); return ret; } #endif while (retry++ < 10) { #if GTP_GESTURE_WAKEUP if (DOZE_WAKEUP != doze_status) { GTP_INFO("Powerkey wakeup."); } else { GTP_INFO("Gesture wakeup."); } doze_status = DOZE_DISABLED; mt_eint_mask(CUST_EINT_TOUCH_PANEL_NUM); gtp_reset_guitar(client, 20); mt_eint_unmask(CUST_EINT_TOUCH_PANEL_NUM); #else GTP_GPIO_OUTPUT(GTP_INT_PORT, 1); msleep(5); #endif ret = gtp_i2c_test(client); if (ret >= 0) { GTP_INFO("GTP wakeup sleep."); #if (!GTP_GESTURE_WAKEUP) { gtp_int_sync(25); #if GTP_ESD_PROTECT gtp_init_ext_watchdog(client); #endif } #endif return ret; } gtp_reset_guitar(client, 20); } #endif GTP_ERROR("GTP wakeup sleep failed."); return ret; } /* Function to manage low power suspend */ void mz_set_tp_mode(int mode); static void tpd_suspend(struct early_suspend *h) { s32 ret = -1; GTP_INFO("System suspend."); #ifdef TPD_PROXIMITY if (tpd_proximity_flag == 1) { return ; } #endif mutex_lock(>p_suspend_lock); // clear all touch #ifdef TYPE_B_PROTOCOL gt9xx_clear_all_touch(); #else tpd_up(0, 0, 0); input_sync(tpd->dev); #endif tpd_halt = 1; #if GTP_ESD_PROTECT gtp_esd_switch(i2c_client_point, SWITCH_OFF); #endif #if GTP_GESTURE_WAKEUP // prevent tp_state changed during suspend time gt9xx_tp_state_pre = gt9xx_tp_state; #ifdef MZ_HALL_MODE if ((gt9xx_tp_state_pre == MZ_GESTURE_DISABLE) || gt9xx_hall_mode) { #else if (gt9xx_tp_state_pre == MZ_GESTURE_DISABLE) { #endif pr_debug("gtp enter sleep mode\n"); mz_set_tp_mode(MZ_SLEEP_MODE); mt_eint_mask(CUST_EINT_TOUCH_PANEL_NUM); ret = gtp_enter_sleep(i2c_client_point); } else { pr_debug("gtp enter gesture mode\n"); mz_set_tp_mode(MZ_GESTURE_MODE); ret = gtp_enter_doze(i2c_client_point); } #else mt_eint_mask(CUST_EINT_TOUCH_PANEL_NUM); ret = gtp_enter_sleep(i2c_client_point); #endif if (ret < 0) { GTP_ERROR("GTP early suspend failed."); } // to avoid waking up while not sleeping, delay 48 + 10ms to ensure reliability msleep(58); mutex_unlock(>p_suspend_lock); } /* Function to manage power-on resume */ static void tpd_resume(struct early_suspend *h) { s32 ret = -1; GTP_INFO("System resume."); #ifdef TPD_PROXIMITY if (tpd_proximity_flag == 1) { return ; } #endif mutex_lock(>p_suspend_lock); ret = gtp_wakeup_sleep(i2c_client_point); if (ret < 0) { GTP_ERROR("GTP later resume failed."); } #if GTP_COMPATIBLE_MODE if (CHIP_TYPE_GT9F == gtp_chip_type) { // do nothing } else #endif { #ifdef MZ_HALL_MODE if(gt9xx_hall_mode) { mz_set_tp_mode(MZ_COVER_MODE); gtp_send_cfg_hall_mode(i2c_client_point); } else #endif { mz_set_tp_mode(MZ_HAND_MODE); gtp_send_cfg(i2c_client_point); } } #if GTP_CHARGER_SWITCH gtp_charger_switch(1); // force update #endif tpd_halt = 0; #if GTP_GESTURE_WAKEUP #ifdef MZ_HALL_MODE if ((gt9xx_tp_state_pre == MZ_GESTURE_DISABLE) || gt9xx_hall_mode) { #else if (gt9xx_tp_state_pre == MZ_GESTURE_DISABLE) { #endif mt_eint_unmask(CUST_EINT_TOUCH_PANEL_NUM); } else { doze_status = DOZE_DISABLED; } #else mt_eint_unmask(CUST_EINT_TOUCH_PANEL_NUM); #endif #if GTP_ESD_PROTECT gtp_esd_switch(i2c_client_point, SWITCH_ON); #endif mutex_unlock(>p_suspend_lock); } static struct tpd_driver_t tpd_device_driver = { .tpd_device_name = "gt9xx", .tpd_local_init = tpd_local_init, .suspend = tpd_suspend, .resume = tpd_resume, #ifdef TPD_HAVE_BUTTON .tpd_have_button = 1, #else .tpd_have_button = 0, #endif }; /* called when loaded into kernel */ static int __init tpd_driver_init(void) { GTP_INFO("MediaTek gt91xx touch panel driver init\n"); #ifdef MT6572 i2c_register_board_info(I2C_BUS_NUMBER, &i2c_tpd, 1); #else i2c_register_board_info(1, &i2c_tpd, 1); #endif if (tpd_driver_add(&tpd_device_driver) < 0) GTP_INFO("add generic driver failed\n"); return 0; } /* should never be called */ static void __exit tpd_driver_exit(void) { GTP_INFO("MediaTek gt91xx touch panel driver exit\n"); tpd_driver_remove(&tpd_device_driver); } module_init(tpd_driver_init); module_exit(tpd_driver_exit);