/* Copyright (c) 2012 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* 1-wire interface module for Chrome EC */ #include "common.h" #include "gpio.h" #include "task.h" #include "timer.h" /* * Standard speed; all timings padded by 2 usec for safety. * * Note that these timing are actually _longer_ than legacy 1-wire standard * speed because we're running the 1-wire bus at 3.3V instead of 5V. */ #define T_RSTL 602 /* Reset low pulse; 600-960 us */ #define T_MSP 72 /* Presence detect sample time; 70-75 us */ #define T_RSTH (68 + 260 + 5 + 2) /* Reset high; tPDHmax + tPDLmax + tRECmin */ #define T_SLOT 70 /* Timeslot; >67 us */ #define T_W0L 63 /* Write 0 low; 62-120 us */ #define T_W1L 7 /* Write 1 low; 5-15 us */ #define T_RL 7 /* Read low; 5-15 us */ #define T_MSR 9 /* Read sample time; <15 us. Must be at least 200 ns after * T_RL since that's how long the signal takes to be pulled * up on our board. */ /** * Output low on the bus for us, then switch back to open-drain input. */ static void output0(int usec) { gpio_set_flags(GPIO_ONEWIRE, GPIO_OPEN_DRAIN | GPIO_OUTPUT | GPIO_OUT_LOW); udelay(usec); gpio_set_flags(GPIO_ONEWIRE, GPIO_INPUT); } /** * Read a bit. */ static int readbit(void) { int bit; /* * The delay between sending the output pulse and reading the bit is * extremely timing sensitive, so disable interrupts. */ interrupt_disable(); /* Output low */ output0(T_RL); /* Delay to let slave release the line if it wants to send a 1-bit */ udelay(T_MSR - T_RL); /* Read bit */ bit = gpio_get_level(GPIO_ONEWIRE); /* * Enable interrupt as soon as we've read the bit. The delay to the * end of the timeslot is a lower bound, so additional latency here is * harmless. */ interrupt_enable(); /* Delay to end of timeslot */ udelay(T_SLOT - T_MSR); return bit; } /** * Write a bit. */ static void writebit(int bit) { /* * The delays in the output-low signal for sending 0 and 1 bits are * extremely timing sensitive, so disable interrupts during that time. * Interrupts can be enabled again as soon as the output is switched * back to open-drain, since the delay for the rest of the timeslot is * a lower bound. */ if (bit) { interrupt_disable(); output0(T_W1L); interrupt_enable(); udelay(T_SLOT - T_W1L); } else { interrupt_disable(); output0(T_W0L); interrupt_enable(); udelay(T_SLOT - T_W0L); } } int onewire_reset(void) { /* Start transaction with master reset pulse */ output0(T_RSTL); /* Wait for presence detect sample time. * * (Alternately, we could poll waiting for a 1-bit indicating our pulse * has let go, then poll up to max time waiting for a 0-bit indicating * the slave has responded.) */ udelay(T_MSP); if (gpio_get_level(GPIO_ONEWIRE)) return EC_ERROR_UNKNOWN; /* * Wait for end of presence pulse. * * (Alternately, we could poll waiting for a 1-bit.) */ udelay(T_RSTH - T_MSP); return EC_SUCCESS; } int onewire_read(void) { int data = 0; int i; for (i = 0; i < 8; i++) data |= readbit() << i; /* LSB first */ return data; } void onewire_write(int data) { int i; for (i = 0; i < 8; i++) writebit((data >> i) & 0x01); /* LSB first */ }