/* * National Semiconductor LM8322/8323 GPIO keyboard & PWM chips. * * Copyright (C) 2008 Nokia Corporation * Written by Andrzej Zaborowski * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 or * (at your option) version 3 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, see . */ #include "hw.h" #include "i2c.h" #include "qemu-timer.h" #include "console.h" typedef struct { i2c_slave i2c; uint8_t i2c_dir; uint8_t i2c_cycle; uint8_t reg; qemu_irq nirq; uint16_t model; struct { qemu_irq out[2]; int in[2][2]; } mux; uint8_t config; uint8_t status; uint8_t acttime; uint8_t error; uint8_t clock; struct { uint16_t pull; uint16_t mask; uint16_t dir; uint16_t level; qemu_irq out[16]; } gpio; struct { uint8_t dbnctime; uint8_t size; uint8_t start; uint8_t len; uint8_t fifo[16]; } kbd; struct { uint16_t file[256]; uint8_t faddr; uint8_t addr[3]; QEMUTimer *tm[3]; } pwm; } LM823KbdState; #define INT_KEYPAD (1 << 0) #define INT_ERROR (1 << 3) #define INT_NOINIT (1 << 4) #define INT_PWMEND(n) (1 << (5 + n)) #define ERR_BADPAR (1 << 0) #define ERR_CMDUNK (1 << 1) #define ERR_KEYOVR (1 << 2) #define ERR_FIFOOVR (1 << 6) static void lm_kbd_irq_update(LM823KbdState *s) { qemu_set_irq(s->nirq, !s->status); } static void lm_kbd_gpio_update(LM823KbdState *s) { } static void lm_kbd_reset(LM823KbdState *s) { s->config = 0x80; s->status = INT_NOINIT; s->acttime = 125; s->kbd.dbnctime = 3; s->kbd.size = 0x33; s->clock = 0x08; lm_kbd_irq_update(s); lm_kbd_gpio_update(s); } static void lm_kbd_error(LM823KbdState *s, int err) { s->error |= err; s->status |= INT_ERROR; lm_kbd_irq_update(s); } static void lm_kbd_pwm_tick(LM823KbdState *s, int line) { } static void lm_kbd_pwm_start(LM823KbdState *s, int line) { lm_kbd_pwm_tick(s, line); } static void lm_kbd_pwm0_tick(void *opaque) { lm_kbd_pwm_tick(opaque, 0); } static void lm_kbd_pwm1_tick(void *opaque) { lm_kbd_pwm_tick(opaque, 1); } static void lm_kbd_pwm2_tick(void *opaque) { lm_kbd_pwm_tick(opaque, 2); } enum { LM832x_CMD_READ_ID = 0x80, /* Read chip ID. */ LM832x_CMD_WRITE_CFG = 0x81, /* Set configuration item. */ LM832x_CMD_READ_INT = 0x82, /* Get interrupt status. */ LM832x_CMD_RESET = 0x83, /* Reset, same as external one */ LM823x_CMD_WRITE_PULL_DOWN = 0x84, /* Select GPIO pull-up/down. */ LM832x_CMD_WRITE_PORT_SEL = 0x85, /* Select GPIO in/out. */ LM832x_CMD_WRITE_PORT_STATE = 0x86, /* Set GPIO pull-up/down. */ LM832x_CMD_READ_PORT_SEL = 0x87, /* Get GPIO in/out. */ LM832x_CMD_READ_PORT_STATE = 0x88, /* Get GPIO pull-up/down. */ LM832x_CMD_READ_FIFO = 0x89, /* Read byte from FIFO. */ LM832x_CMD_RPT_READ_FIFO = 0x8a, /* Read FIFO (no increment). */ LM832x_CMD_SET_ACTIVE = 0x8b, /* Set active time. */ LM832x_CMD_READ_ERROR = 0x8c, /* Get error status. */ LM832x_CMD_READ_ROTATOR = 0x8e, /* Read rotator status. */ LM832x_CMD_SET_DEBOUNCE = 0x8f, /* Set debouncing time. */ LM832x_CMD_SET_KEY_SIZE = 0x90, /* Set keypad size. */ LM832x_CMD_READ_KEY_SIZE = 0x91, /* Get keypad size. */ LM832x_CMD_READ_CFG = 0x92, /* Get configuration item. */ LM832x_CMD_WRITE_CLOCK = 0x93, /* Set clock config. */ LM832x_CMD_READ_CLOCK = 0x94, /* Get clock config. */ LM832x_CMD_PWM_WRITE = 0x95, /* Write PWM script. */ LM832x_CMD_PWM_START = 0x96, /* Start PWM engine. */ LM832x_CMD_PWM_STOP = 0x97, /* Stop PWM engine. */ LM832x_GENERAL_ERROR = 0xff, /* There was one error. Previously was represented by -1 This is not a command */ }; #define LM832x_MAX_KPX 8 #define LM832x_MAX_KPY 12 static uint8_t lm_kbd_read(LM823KbdState *s, int reg, int byte) { int ret; switch (reg) { case LM832x_CMD_READ_ID: ret = 0x0400; break; case LM832x_CMD_READ_INT: ret = s->status; if (!(s->status & INT_NOINIT)) { s->status = 0; lm_kbd_irq_update(s); } break; case LM832x_CMD_READ_PORT_SEL: ret = s->gpio.dir; break; case LM832x_CMD_READ_PORT_STATE: ret = s->gpio.mask; break; case LM832x_CMD_READ_FIFO: if (s->kbd.len <= 1) return 0x00; /* Example response from the two commands after a INT_KEYPAD * interrupt caused by the key 0x3c being pressed: * RPT_READ_FIFO: 55 bc 00 4e ff 0a 50 08 00 29 d9 08 01 c9 01 * READ_FIFO: bc 00 00 4e ff 0a 50 08 00 29 d9 08 01 c9 01 * RPT_READ_FIFO: bc 00 00 4e ff 0a 50 08 00 29 d9 08 01 c9 01 * * 55 is the code of the key release event serviced in the previous * interrupt handling. * * TODO: find out whether the FIFO is advanced a single character * before reading every byte or the whole size of the FIFO at the * last LM832x_CMD_READ_FIFO. This affects LM832x_CMD_RPT_READ_FIFO * output in cases where there are more than one event in the FIFO. * Assume 0xbc and 0x3c events are in the FIFO: * RPT_READ_FIFO: 55 bc 3c 00 4e ff 0a 50 08 00 29 d9 08 01 c9 * READ_FIFO: bc 3c 00 00 4e ff 0a 50 08 00 29 d9 08 01 c9 * Does RPT_READ_FIFO now return 0xbc and 0x3c or only 0x3c? */ s->kbd.start ++; s->kbd.start &= sizeof(s->kbd.fifo) - 1; s->kbd.len --; return s->kbd.fifo[s->kbd.start]; case LM832x_CMD_RPT_READ_FIFO: if (byte >= s->kbd.len) return 0x00; return s->kbd.fifo[(s->kbd.start + byte) & (sizeof(s->kbd.fifo) - 1)]; case LM832x_CMD_READ_ERROR: return s->error; case LM832x_CMD_READ_ROTATOR: return 0; case LM832x_CMD_READ_KEY_SIZE: return s->kbd.size; case LM832x_CMD_READ_CFG: return s->config & 0xf; case LM832x_CMD_READ_CLOCK: return (s->clock & 0xfc) | 2; default: lm_kbd_error(s, ERR_CMDUNK); fprintf(stderr, "%s: unknown command %02x\n", __FUNCTION__, reg); return 0x00; } return ret >> (byte << 3); } static void lm_kbd_write(LM823KbdState *s, int reg, int byte, uint8_t value) { switch (reg) { case LM832x_CMD_WRITE_CFG: s->config = value; /* This must be done whenever s->mux.in is updated (never). */ if ((s->config >> 1) & 1) /* MUX1EN */ qemu_set_irq(s->mux.out[0], s->mux.in[0][(s->config >> 0) & 1]); if ((s->config >> 3) & 1) /* MUX2EN */ qemu_set_irq(s->mux.out[0], s->mux.in[0][(s->config >> 2) & 1]); /* TODO: check that this is issued only following the chip reset * and not in the middle of operation and that it is followed by * the GPIO ports re-resablishing through WRITE_PORT_SEL and * WRITE_PORT_STATE (using a timer perhaps) and otherwise output * warnings. */ s->status = 0; lm_kbd_irq_update(s); s->kbd.len = 0; s->kbd.start = 0; s->reg = LM832x_GENERAL_ERROR; break; case LM832x_CMD_RESET: if (value == 0xaa) lm_kbd_reset(s); else lm_kbd_error(s, ERR_BADPAR); s->reg = LM832x_GENERAL_ERROR; break; case LM823x_CMD_WRITE_PULL_DOWN: if (!byte) s->gpio.pull = value; else { s->gpio.pull |= value << 8; lm_kbd_gpio_update(s); s->reg = LM832x_GENERAL_ERROR; } break; case LM832x_CMD_WRITE_PORT_SEL: if (!byte) s->gpio.dir = value; else { s->gpio.dir |= value << 8; lm_kbd_gpio_update(s); s->reg = LM832x_GENERAL_ERROR; } break; case LM832x_CMD_WRITE_PORT_STATE: if (!byte) s->gpio.mask = value; else { s->gpio.mask |= value << 8; lm_kbd_gpio_update(s); s->reg = LM832x_GENERAL_ERROR; } break; case LM832x_CMD_SET_ACTIVE: s->acttime = value; s->reg = LM832x_GENERAL_ERROR; break; case LM832x_CMD_SET_DEBOUNCE: s->kbd.dbnctime = value; s->reg = LM832x_GENERAL_ERROR; if (!value) lm_kbd_error(s, ERR_BADPAR); break; case LM832x_CMD_SET_KEY_SIZE: s->kbd.size = value; s->reg = LM832x_GENERAL_ERROR; if ( (value & 0xf) < 3 || (value & 0xf) > LM832x_MAX_KPY || (value >> 4) < 3 || (value >> 4) > LM832x_MAX_KPX) lm_kbd_error(s, ERR_BADPAR); break; case LM832x_CMD_WRITE_CLOCK: s->clock = value; s->reg = LM832x_GENERAL_ERROR; if ((value & 3) && (value & 3) != 3) { lm_kbd_error(s, ERR_BADPAR); fprintf(stderr, "%s: invalid clock setting in RCPWM\n", __FUNCTION__); } /* TODO: Validate that the command is only issued once */ break; case LM832x_CMD_PWM_WRITE: if (byte == 0) { if (!(value & 3) || (value >> 2) > 59) { lm_kbd_error(s, ERR_BADPAR); s->reg = LM832x_GENERAL_ERROR; break; } s->pwm.faddr = value; s->pwm.file[s->pwm.faddr] = 0; } else if (byte == 1) { s->pwm.file[s->pwm.faddr] |= value << 8; } else if (byte == 2) { s->pwm.file[s->pwm.faddr] |= value << 0; s->reg = LM832x_GENERAL_ERROR; } break; case LM832x_CMD_PWM_START: s->reg = LM832x_GENERAL_ERROR; if (!(value & 3) || (value >> 2) > 59) { lm_kbd_error(s, ERR_BADPAR); break; } s->pwm.addr[(value & 3) - 1] = value >> 2; lm_kbd_pwm_start(s, (value & 3) - 1); break; case LM832x_CMD_PWM_STOP: s->reg = LM832x_GENERAL_ERROR; if (!(value & 3)) { lm_kbd_error(s, ERR_BADPAR); break; } qemu_del_timer(s->pwm.tm[(value & 3) - 1]); break; case LM832x_GENERAL_ERROR: lm_kbd_error(s, ERR_BADPAR); break; default: lm_kbd_error(s, ERR_CMDUNK); fprintf(stderr, "%s: unknown command %02x\n", __FUNCTION__, reg); break; } } static void lm_i2c_event(i2c_slave *i2c, enum i2c_event event) { LM823KbdState *s = FROM_I2C_SLAVE(LM823KbdState, i2c); switch (event) { case I2C_START_RECV: case I2C_START_SEND: s->i2c_cycle = 0; s->i2c_dir = (event == I2C_START_SEND); break; default: break; } } static int lm_i2c_rx(i2c_slave *i2c) { LM823KbdState *s = FROM_I2C_SLAVE(LM823KbdState, i2c); return lm_kbd_read(s, s->reg, s->i2c_cycle ++); } static int lm_i2c_tx(i2c_slave *i2c, uint8_t data) { LM823KbdState *s = (LM823KbdState *) i2c; if (!s->i2c_cycle) s->reg = data; else lm_kbd_write(s, s->reg, s->i2c_cycle - 1, data); s->i2c_cycle ++; return 0; } static int lm_kbd_post_load(void *opaque, int version_id) { LM823KbdState *s = opaque; lm_kbd_irq_update(s); lm_kbd_gpio_update(s); return 0; } static const VMStateDescription vmstate_lm_kbd = { .name = "LM8323", .version_id = 0, .minimum_version_id = 0, .minimum_version_id_old = 0, .post_load = lm_kbd_post_load, .fields = (VMStateField []) { VMSTATE_I2C_SLAVE(i2c, LM823KbdState), VMSTATE_UINT8(i2c_dir, LM823KbdState), VMSTATE_UINT8(i2c_cycle, LM823KbdState), VMSTATE_UINT8(reg, LM823KbdState), VMSTATE_UINT8(config, LM823KbdState), VMSTATE_UINT8(status, LM823KbdState), VMSTATE_UINT8(acttime, LM823KbdState), VMSTATE_UINT8(error, LM823KbdState), VMSTATE_UINT8(clock, LM823KbdState), VMSTATE_UINT16(gpio.pull, LM823KbdState), VMSTATE_UINT16(gpio.mask, LM823KbdState), VMSTATE_UINT16(gpio.dir, LM823KbdState), VMSTATE_UINT16(gpio.level, LM823KbdState), VMSTATE_UINT8(kbd.dbnctime, LM823KbdState), VMSTATE_UINT8(kbd.size, LM823KbdState), VMSTATE_UINT8(kbd.start, LM823KbdState), VMSTATE_UINT8(kbd.len, LM823KbdState), VMSTATE_BUFFER(kbd.fifo, LM823KbdState), VMSTATE_UINT16_ARRAY(pwm.file, LM823KbdState, 256), VMSTATE_UINT8(pwm.faddr, LM823KbdState), VMSTATE_BUFFER(pwm.addr, LM823KbdState), VMSTATE_TIMER_ARRAY(pwm.tm, LM823KbdState, 3), VMSTATE_END_OF_LIST() } }; static int lm8323_init(i2c_slave *i2c) { LM823KbdState *s = FROM_I2C_SLAVE(LM823KbdState, i2c); s->model = 0x8323; s->pwm.tm[0] = qemu_new_timer_ns(vm_clock, lm_kbd_pwm0_tick, s); s->pwm.tm[1] = qemu_new_timer_ns(vm_clock, lm_kbd_pwm1_tick, s); s->pwm.tm[2] = qemu_new_timer_ns(vm_clock, lm_kbd_pwm2_tick, s); qdev_init_gpio_out(&i2c->qdev, &s->nirq, 1); lm_kbd_reset(s); qemu_register_reset((void *) lm_kbd_reset, s); return 0; } void lm832x_key_event(struct i2c_slave *i2c, int key, int state) { LM823KbdState *s = (LM823KbdState *) i2c; if ((s->status & INT_ERROR) && (s->error & ERR_FIFOOVR)) return; if (s->kbd.len >= sizeof(s->kbd.fifo)) { lm_kbd_error(s, ERR_FIFOOVR); return; } s->kbd.fifo[(s->kbd.start + s->kbd.len ++) & (sizeof(s->kbd.fifo) - 1)] = key | (state << 7); /* We never set ERR_KEYOVR because we support multiple keys fine. */ s->status |= INT_KEYPAD; lm_kbd_irq_update(s); } static I2CSlaveInfo lm8323_info = { .qdev.name = "lm8323", .qdev.size = sizeof(LM823KbdState), .qdev.vmsd = &vmstate_lm_kbd, .init = lm8323_init, .event = lm_i2c_event, .recv = lm_i2c_rx, .send = lm_i2c_tx }; static void lm832x_register_devices(void) { i2c_register_slave(&lm8323_info); } device_init(lm832x_register_devices)