/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 by Linus Nielsen Feltzing * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #include "cpu.h" #include "system.h" #include "kernel.h" #include "thread.h" #include "string.h" #include "adc.h" #include "pcf50605.h" #include "pcf50606.h" #if CONFIG_CPU == SH7034 /************************************************************************** ** The A/D conversion is done every tick, in three steps: ** ** 1) On the tick interrupt, the conversion of channels 0-3 is started, and ** the A/D interrupt is enabled. ** ** 2) After the conversion is done (approx. 256*4 cycles later), an interrupt ** is generated at level 1, which is the same level as the tick interrupt ** itself. This interrupt will be pending until the tick interrupt is ** finished. ** When the A/D interrupt is finally served, it will read the results ** from the first conversion and start the conversion of channels 4-7. ** ** 3) When the conversion of channels 4-7 is finished, the interrupt is ** triggered again, and the results are read. This time, no new ** conversion is started, it will be done in the next tick interrupt. ** ** Thus, each channel will be updated HZ times per second. ** *************************************************************************/ static int current_channel; static unsigned short adcdata[NUM_ADC_CHANNELS]; static void adc_tick(void) { /* Start a conversion of channel group 0. This will trigger an interrupt, and the interrupt handler will take care of group 1. */ current_channel = 0; ADCSR = ADCSR_ADST | ADCSR_ADIE | ADCSR_SCAN | 3; } #pragma interrupt void ADITI(void) { if(ADCSR & ADCSR_ADF) { ADCSR = 0; if(current_channel == 0) { adcdata[0] = ADDRA >> 6; adcdata[1] = ADDRB >> 6; adcdata[2] = ADDRC >> 6; adcdata[3] = ADDRD >> 6; current_channel = 4; /* Convert the next group */ ADCSR = ADCSR_ADST | ADCSR_ADIE | ADCSR_SCAN | 7; } else { adcdata[4] = ADDRA >> 6; adcdata[5] = ADDRB >> 6; adcdata[6] = ADDRC >> 6; adcdata[7] = ADDRD >> 6; } } } unsigned short adc_read(int channel) { return adcdata[channel]; } void adc_init(void) { ADCR = 0x7f; /* No external trigger; other bits should be 1 according to the manual... */ ADCSR = 0; current_channel = 0; /* Enable the A/D IRQ on level 1 */ IPRE = (IPRE & 0xf0ff) | 0x0100; tick_add_task(adc_tick); sleep(2); /* Ensure valid readings when adc_init returns */ } #elif CONFIG_CPU == MCF5249 static unsigned char adcdata[NUM_ADC_CHANNELS]; #ifdef IRIVER_H300_SERIES static int channelnum[] = { 5, /* ADC_BUTTONS (ADCIN2) */ 6, /* ADC_REMOTE (ADCIN3) */ 0, /* ADC_BATTERY (BATVOLT, resistive divider) */ 2, /* ADC_REMOTEDETECT (ADCIN1, resistive divider) */ }; unsigned short adc_scan(int channel) { unsigned char data; pcf50606_write(0x2f, 0x80 | (channelnum[channel] << 1) | 1); data = pcf50606_read(0x30); adcdata[channel] = data; return data; } #else #define CS_LO and_l(~0x80, &GPIO_OUT) #define CS_HI or_l(0x80, &GPIO_OUT) #define CLK_LO and_l(~0x00400000, &GPIO_OUT) #define CLK_HI or_l(0x00400000, &GPIO_OUT) #define DO (GPIO_READ & 0x80000000) #define DI_LO and_l(~0x00200000, &GPIO_OUT) #define DI_HI or_l(0x00200000, &GPIO_OUT) /* delay loop */ #define DELAY do { int _x; for(_x=0;_x<10;_x++);} while (0) unsigned short adc_scan(int channel) { unsigned char data = 0; int i; CS_LO; DI_HI; /* Start bit */ DELAY; CLK_HI; DELAY; CLK_LO; DI_HI; /* Single channel */ DELAY; CLK_HI; DELAY; CLK_LO; if(channel & 1) /* LSB of channel number */ DI_HI; else DI_LO; DELAY; CLK_HI; DELAY; CLK_LO; if(channel & 2) /* MSB of channel number */ DI_HI; else DI_LO; DELAY; CLK_HI; DELAY; CLK_LO; DELAY; for(i = 0;i < 8;i++) /* 8 bits of data */ { CLK_HI; DELAY; CLK_LO; DELAY; data <<= 1; data |= DO?1:0; } CS_HI; adcdata[channel] = data; return data; } #endif unsigned short adc_read(int channel) { return adcdata[channel]; } static int adc_counter; static void adc_tick(void) { if(++adc_counter == HZ) { adc_counter = 0; adc_scan(ADC_BATTERY); adc_scan(ADC_REMOTEDETECT); /* Temporary. Remove when the remote detection feels stable. */ } } void adc_init(void) { #ifndef IRIVER_H300_SERIES or_l(0x80600080, &GPIO_FUNCTION); /* GPIO7: CS GPIO21: Data In (to the ADC) GPIO22: CLK GPIO31: Data Out (from the ADC) */ or_l(0x00600080, &GPIO_ENABLE); or_l(0x80, &GPIO_OUT); /* CS high */ and_l(~0x00400000, &GPIO_OUT); /* CLK low */ #endif adc_scan(ADC_BATTERY); tick_add_task(adc_tick); } #elif CONFIG_CPU == TCC730 /************************************************************************** ** ** Each channel will be updated HZ/CHANNEL_ORDER_SIZE times per second. ** *************************************************************************/ static int current_channel; static int current_channel_idx; static unsigned short adcdata[NUM_ADC_CHANNELS]; #define CHANNEL_ORDER_SIZE 2 static int channel_order[CHANNEL_ORDER_SIZE] = {6,7}; static void adc_tick(void) { if (ADCON & (1 << 3)) { /* previous conversion finished? */ adcdata[current_channel] = ADDATA >> 6; if (++current_channel_idx >= CHANNEL_ORDER_SIZE) current_channel_idx = 0; current_channel = channel_order[current_channel_idx]; int adcon = (current_channel << 4) | 1; ADCON = adcon; } } unsigned short adc_read(int channel) { return adcdata[channel]; } void adc_init(void) { current_channel_idx = 0; current_channel = channel_order[current_channel_idx]; ADCON = (current_channel << 4) | 1; tick_add_task(adc_tick); sleep(2); /* Ensure valid readings when adc_init returns */ } #elif CONFIG_CPU == PP5020 || (CONFIG_CPU == PP5002) struct adc_struct { long last_read; unsigned short (*conversion)(unsigned short data); short channelnum; unsigned short data; }; static struct adc_struct adcdata[NUM_ADC_CHANNELS] IDATA_ATTR; /* This takes 10 bit ADC data from the subtractor circuit and scales it to * a 13 bit value corresponding to 0-5.4v, the resulting range is 13FB-17FA, * representing 3.1-5.4v */ static unsigned short ten_bit_subtractor(unsigned short data) { return (data<<2)+0x13FB; } static unsigned short _adc_scan(struct adc_struct *adc) { unsigned short data = pcf50605_a2d_read(adc->channelnum); if (adc->conversion) { data = adc->conversion(data); } adc->data = data; return data; } /* Force an ADC scan _now_ */ unsigned short adc_scan(int channel) { return _adc_scan(&adcdata[channel]); } /* Retrieve the ADC value, only does a scan once per second or less */ unsigned short adc_read(int channel) { struct adc_struct *adc = &adcdata[channel]; if (adc->last_read + HZ < current_tick) { adc->last_read = current_tick; return _adc_scan(adc); } else { return adc->data; } } void adc_init(void) { struct adc_struct *adc_battery = &adcdata[ADC_BATTERY]; adc_battery->channelnum = 0x3; /* ADCVIN1, subtractor */ adc_battery->conversion = ten_bit_subtractor; adc_battery->last_read = current_tick; _adc_scan(adc_battery); } #elif CONFIG_CPU == PNX0101 static unsigned short adcdata[NUM_ADC_CHANNELS]; unsigned short adc_read(int channel) { return adcdata[channel]; } static void adc_tick(void) { if (ADCST & 0x10) { adcdata[0] = ADCCH0 & 0x3ff; adcdata[1] = ADCCH1 & 0x3ff; adcdata[2] = ADCCH2 & 0x3ff; adcdata[3] = ADCCH3 & 0x3ff; adcdata[4] = ADCCH4 & 0x3ff; ADCST = 0xa; } } void adc_init(void) { ADCR24 = 0xaaaaa; ADCR28 = 0; ADCST = 2; ADCST = 0xa; while (!(ADCST & 0x10)); adc_tick(); tick_add_task(adc_tick); } #endif