/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright © 2008 Rafaël Carré * * 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 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include "system.h" #include "kernel.h" #include "action.h" #include "lcd.h" #include "font.h" #include "cpu.h" #include "pl180.h" #include "ascodec.h" #include "adc.h" #include "storage.h" #define DEBUG_CANCEL ACTION_STD_CANCEL #define DEBUG_NEXT ACTION_STD_NEXT #define DEBUG_LEFT_JUSTIFY ACTION_STD_OK #define DEBUG_LEFT_SCROLL ACTION_STD_MENU /* if the possiblity exists to divide by zero protect with this macro */ #define DIV_FINITE(dividend, divisor) ((divisor == 0)? divisor : dividend/divisor) #define ON "Enabled" #define OFF "Disabled" #define CP15_MMU (1<<0) /* mmu off/on */ #define CP15_DC (1<<2) /* dcache off/on */ #define CP15_IC (1<<12) /* icache off/on */ #define CLK_MAIN 24000000 /* 24 MHz */ #define D_MHZ 1000000 #define D_KHZ 1000 enum dbg_clocks { CLK_PLLA = 0x0, CLK_PLLB, CLK_PROC, CLK_FCLK, CLK_EXTMEM, CLK_PCLK, CLK_IDE, CLK_I2C, CLK_I2SI, CLK_I2SO, CLK_DBOP, CLK_SD_MCLK_NAND, CLK_SD_MCLK_MSD, CLK_SD_SLOT, CLK_USB, CLK_SSP, }; #define MCI_NAND *((volatile unsigned long *)(NAND_FLASH_BASE + 0x04)) #define MCI_SD *((volatile unsigned long *)(SD_MCI_BASE + 0x04)) #if defined(SANSA_FUZE) || defined(SANSA_E200V2) || defined(SANSA_C200V2) #define DEBUG_DBOP #include "dbop-as3525.h" #endif static inline unsigned read_cp15 (void) { unsigned cp15_value; asm volatile ( "mrc p15, 0, %0, c1, c0, 0 @ read control reg\n" : "=r"(cp15_value)); return (cp15_value); } static int calc_freq(int clk) { unsigned int prediv = ((unsigned int)CGU_PROC>>2) & 0x3; unsigned int postdiv = ((unsigned int)CGU_PROC>>4) & 0xf; unsigned int u_out_div; #if CONFIG_CPU == AS3525 switch(clk) { /* clk_main = clk_int = 24MHz oscillator */ case CLK_PLLA: if(CGU_PLLASUP & (1<<3)) return 0; /*assume 24MHz oscillator only input available */ u_out_div = ((CGU_PLLA>>13) & 0x3); /* bits 13:14 */ if (u_out_div == 3) /* for 11 NO=4 */ u_out_div=4; /* NO = 0 not allowed */ return DIV_FINITE(((2 * (CGU_PLLA & 0xff))*CLK_MAIN), (((CGU_PLLA>>8) & 0x1f)*u_out_div)); case CLK_PLLB: if(CGU_PLLBSUP & (1<<3)) return 0; /*assume 24MHz oscillator only input available */ u_out_div = ((CGU_PLLB>>13) & 0x3); /* bits 13:14 */ if (u_out_div == 3) /* for 11 NO=4 */ u_out_div=4; /* NO = 0 not allowed */ return DIV_FINITE(((2 * (CGU_PLLB & 0xff))*CLK_MAIN), (((CGU_PLLB>>8) & 0x1f)*u_out_div)); #else /* AS3525v2 */ int od, f, r; /* AS3525v2 */ switch(clk) { case CLK_PLLA: if(CGU_PLLASUP & (1<<3)) return 0; f = (CGU_PLLA & 0x7F) + 1; r = ((CGU_PLLA >> 7) & 0x7) + 1; od = (CGU_PLLA >> 10) & 1 ? 2 : 1; return (CLK_MAIN / 2) * f / (r * od); case CLK_PLLB: if(CGU_PLLBSUP & (1<<3)) return 0; f = (CGU_PLLB & 0x7F) + 1; r = ((CGU_PLLB >> 7) & 0x7) + 1; od = (CGU_PLLB >> 10) & 1 ? 2 : 1; return (CLK_MAIN / 2) * f / (r * od); case CLK_SD_SLOT: switch(CGU_SDSLOT & 3) { case 0: return CLK_MAIN/(((CGU_SDSLOT>>2)& 0xf)+1); case 1: return calc_freq(CLK_PLLA)/(((CGU_SDSLOT>>2)& 0xf)+1); case 2: return calc_freq(CLK_PLLB)/(((CGU_SDSLOT>>2)& 0xf)+1); default: return 0; } #endif /* CONFIG_CPU == AS3525 */ case CLK_PROC: #if CONFIG_CPU == AS3525 /* not in arm926-ejs */ if (!(read_cp15()>>30)) /* fastbus */ return calc_freq(CLK_PCLK); else /* Synch or Asynch bus*/ #endif /* CONFIG_CPU == AS3525 */ return calc_freq(CLK_FCLK); case CLK_FCLK: switch(CGU_PROC & 3) { case 0: return (CLK_MAIN * (8 - prediv)) / (8 * (postdiv + 1)); case 1: return (calc_freq(CLK_PLLA) * (8 - prediv)) / (8 * (postdiv + 1)); case 2: return (calc_freq(CLK_PLLB) * (8 - prediv)) / (8 * (postdiv + 1)); default: return 0; } case CLK_EXTMEM: #if CONFIG_CPU == AS3525 switch(CGU_PERI & 3) { #else /* as3525v2 */ /* bits 1:0 of CGU_PERI always read as 0 and source = FCLK */ switch(3) { #endif /* CONFIG_CPU == AS3525 */ case 0: return CLK_MAIN/(((CGU_PERI>>2)& 0xf)+1); case 1: return calc_freq(CLK_PLLA)/(((CGU_PERI>>2)& 0xf)+1); case 2: return calc_freq(CLK_PLLB)/(((CGU_PERI>>2)& 0xf)+1); case 3: default: return calc_freq(CLK_FCLK)/(((CGU_PERI>>2)& 0xf)+1); } case CLK_PCLK: return calc_freq(CLK_EXTMEM)/(((CGU_PERI>>6)& 0x1)+1); case CLK_IDE: switch(CGU_IDE & 3) { case 0: return CLK_MAIN/(((CGU_IDE>>2)& 0xf)+1); case 1: return calc_freq(CLK_PLLA)/(((CGU_IDE>>2)& 0xf)+1); case 2: return calc_freq(CLK_PLLB)/(((CGU_IDE>>2)& 0xf)+1); default: return 0; } case CLK_I2C: ams_i2c_get_debug_cpsr(&u_out_div); /* NO = 0 not allowed */ return DIV_FINITE(calc_freq(CLK_PCLK), (u_out_div)); case CLK_I2SI: switch((CGU_AUDIO>>12) & 3) { case 0: return CLK_MAIN/(((CGU_AUDIO>>14) & 0x1ff)+1); case 1: return calc_freq(CLK_PLLA)/(((CGU_AUDIO>>14) & 0x1ff)+1); case 2: return calc_freq(CLK_PLLB)/(((CGU_AUDIO>>14) & 0x1ff)+1); default: return 0; } case CLK_I2SO: switch(CGU_AUDIO & 3) { case 0: return CLK_MAIN/(((CGU_AUDIO>>2) & 0x1ff)+1); case 1: return calc_freq(CLK_PLLA)/(((CGU_AUDIO>>2) & 0x1ff)+1); case 2: return calc_freq(CLK_PLLB)/(((CGU_AUDIO>>2) & 0x1ff)+1); default: return 0; } case CLK_DBOP: return calc_freq(CLK_PCLK)/((CGU_DBOP & 7)+1); #if CONFIG_CPU == AS3525 case CLK_SD_MCLK_NAND: if(!(MCI_NAND & (1<<8))) return 0; else if(MCI_NAND & (1<<10)) return calc_freq(CLK_IDE); else return calc_freq(CLK_IDE)/(((MCI_NAND & 0xff)+1)*2); case CLK_SD_MCLK_MSD: if(!(MCI_SD & (1<<8))) return 0; else if(MCI_SD & (1<<10)) return calc_freq(CLK_PCLK); else return calc_freq(CLK_PCLK)/(((MCI_SD & 0xff)+1)*2); #else /* as3525v2 */ case CLK_SSP: /* NO = 0 not allowed */ return DIV_FINITE(calc_freq(CLK_PCLK), SSP_CPSR); #endif /* CONFIG_CPU == AS3525 */ case CLK_USB: switch(CGU_USB & 3) { /* 0-> div=1 other->div=1/(2*n) */ case 0: if (!((CGU_USB>>2) & 0x7)) return CLK_MAIN; else return CLK_MAIN/(2*((CGU_USB>>2) & 0x7)); case 1: if (!((CGU_USB>>2) & 0x7)) return calc_freq(CLK_PLLA); else return calc_freq(CLK_PLLA)/(2*((CGU_USB>>2) & 0x7)); case 2: if (!((CGU_USB>>2) & 0x7)) return calc_freq(CLK_PLLB); else return calc_freq(CLK_PLLB)/(2*((CGU_USB>>2) & 0x7)); default: return 0; } default: return 0; } } static bool dbg_btn(bool *done, int *x) { bool cont = !*done; if (cont) { lcd_update(); int button = get_action(CONTEXT_STD,HZ/10); switch(button) { case DEBUG_CANCEL: *done = true; /*fallthrough*/ case DEBUG_NEXT: cont = false; /*fallthrough*/ case DEBUG_LEFT_JUSTIFY: (*x) = 0; sleep(HZ/5); break; case DEBUG_LEFT_SCROLL: (*x)--; break; default: break; } } lcd_clear_display(); return cont; } bool dbg_hw_info(void) { int line; int x = 0; bool done = false; lcd_clear_display(); lcd_setfont(FONT_SYSFIXED); while(!done) { while(dbg_btn(&done, &x)) { #if defined(SANSA_C200V2) || defined(SANSA_FUZEV2) || \ defined(SANSA_CLIPPLUS) || defined(SANSA_CLIPZIP) line = 0; lcd_puts(x, line++, "[Submodel:]"); #if defined(SANSA_C200V2) lcd_putsf(x, line++, "C200v2 variant %d", c200v2_variant); #elif defined(SANSA_FUZEV2) || defined(SANSA_CLIPPLUS) || \ defined(SANSA_CLIPZIP) lcd_putsf(x, line++, "AMSv2 variant %d", amsv2_variant); #endif } while(dbg_btn(&done, &x)) { #endif line = 0; lcd_puts(x, line++, "[Clock Frequencies:]"); lcd_puts(x, line++, " SET ACTUAL"); #if CONFIG_CPU == AS3525 lcd_putsf(x, line++, "922T:%s %3dMHz", (!(read_cp15()>>30)) ? "FAST " : (read_cp15()>>31) ? "ASYNC" : "SYNC ", #else /* as3525v2 */ lcd_putsf(x, line++, "926ejs: %3dMHz", #endif calc_freq(CLK_PROC)/D_MHZ); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "PLLA", AS3525_PLLA_FREQ/D_MHZ, calc_freq(CLK_PLLA)/D_MHZ); lcd_putsf(x, line++, "PLLB: %3dMHz", calc_freq(CLK_PLLB)/D_MHZ); lcd_putsf(x, line++, "FCLK: %3dMHz", calc_freq(CLK_FCLK)/D_MHZ); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "DRAM", AS3525_PCLK_FREQ/D_MHZ, calc_freq(CLK_EXTMEM)/D_MHZ); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "PCLK", AS3525_PCLK_FREQ/D_MHZ, calc_freq(CLK_PCLK)/D_MHZ); #if LCD_HEIGHT < 176 /* clip */ } while(dbg_btn(&done, &x)) { line = 0; #endif /* LCD_HEIGHT < 176 */ lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "IDE ", AS3525_IDE_FREQ/D_MHZ, calc_freq(CLK_IDE)/D_MHZ); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "DBOP", AS3525_DBOP_FREQ/D_MHZ, calc_freq(CLK_DBOP)/D_MHZ); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "I2C ", AS3525_I2C_FREQ/D_KHZ, calc_freq(CLK_I2C)/D_KHZ); lcd_putsf(x, line++, "I2SI: %s %3dMHz", (CGU_AUDIO & (1<<23)) ? "on " : "off" , calc_freq(CLK_I2SI)/D_MHZ); lcd_putsf(x, line++, "I2SO: %s %3dMHz", (CGU_AUDIO & (1<<11)) ? "on " : "off", calc_freq(CLK_I2SO)/D_MHZ); #if CONFIG_CPU == AS3525 struct ams_sd_debug_info dbg; ams_sd_get_debug_info(&dbg); lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "SD ", ((AS3525_IDE_FREQ/ D_MHZ) / ((dbg.mci_nand & MCI_CLOCK_BYPASS)? 1:(((dbg.mci_nand & 0xff)+1) * 2))), calc_freq(CLK_SD_MCLK_NAND)/D_MHZ); #ifdef HAVE_MULTIDRIVE lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "uSD ", ((AS3525_PCLK_FREQ/ D_MHZ) / ((dbg.mci_sd & MCI_CLOCK_BYPASS) ? 1: (((dbg.mci_sd & 0xff) + 1) * 2))), calc_freq(CLK_SD_MCLK_MSD)/D_MHZ); #endif #else /*AS3525v2*/ lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "SD ", AS3525_SDSLOT_FREQ/D_MHZ, calc_freq(CLK_SD_SLOT)/D_MHZ); long freq_ssp = calc_freq(CLK_SSP); if (freq_ssp >= D_MHZ) lcd_putsf(x, line++, "%s:%3dMHz %3dMHz", "SSP ", AS3525_SSP_FREQ/D_MHZ, calc_freq(CLK_SSP)/D_MHZ); else lcd_putsf(x, line++, "SSP :%3dMHz %3dKHz", AS3525_SSP_FREQ/D_MHZ, calc_freq(CLK_SSP)/D_KHZ); #endif /* CONFIG_CPU == AS3525 */ lcd_putsf(x, line++, "USB : %3dMHz", calc_freq(CLK_USB)/D_MHZ); #if LCD_HEIGHT < 176 /* clip */ } while(dbg_btn(&done, &x)) { lcd_clear_display(); line = 0; #endif /* LCD_HEIGHT < 176 */ lcd_putsf(x, line++, "MMU : %s CVDDP:%4d", (read_cp15() & CP15_MMU) ? " on" : "off", adc_read(ADC_CVDD) * 25); lcd_putsf(x, line++, "Icache:%s Dcache:%s", (read_cp15() & CP15_IC) ? " on" : "off", (read_cp15() & CP15_DC) ? " on" : "off"); } while(dbg_btn(&done, &x)) { line = 0; lcd_putsf(x, line++, "CGU_PLLA :%8x", (unsigned int)(CGU_PLLA)); lcd_putsf(x, line++, "CGU_PLLB :%8x", (unsigned int)(CGU_PLLB)); lcd_putsf(x, line++, "CGU_PROC :%8x", (unsigned int)(CGU_PROC)); lcd_putsf(x, line++, "CGU_PERI :%8x", (unsigned int)(CGU_PERI)); lcd_putsf(x, line++, "CGU_IDE :%8x", (unsigned int)(CGU_IDE)); lcd_putsf(x, line++, "CGU_DBOP :%8x", (unsigned int)(CGU_DBOP)); lcd_putsf(x, line++, "CGU_AUDIO :%8x", (unsigned int)(CGU_AUDIO)); lcd_putsf(x, line++, "CGU_USB :%8x", (unsigned int)(CGU_USB)); #if LCD_HEIGHT < 176 /* clip */ } while(dbg_btn(&done, &x)) { line = 0; #endif /* LCD_HEIGHT < 176 */ unsigned int i2c_cpsr; ams_i2c_get_debug_cpsr(&i2c_cpsr); lcd_putsf(x, line++, "I2C2_CPSR :%8x", i2c_cpsr); #if CONFIG_CPU == AS3525 lcd_putsf(x, line++, "MCI_NAND :%8x", (unsigned int)(MCI_NAND)); lcd_putsf(x, line++, "MCI_SD :%8x", (unsigned int)(MCI_SD)); #else /* as3525v2 */ lcd_putsf(x, line++, "CGU_MEMSTK:%8x", (unsigned int)(CGU_MEMSTICK)); lcd_putsf(x, line++, "CGU_SDSLOT:%8x", (unsigned int)(CGU_SDSLOT)); #endif lcd_putsf(x, line++, "SSP_CPSR :%8x", (unsigned int)(SSP_CPSR)); } } lcd_setfont(FONT_UI); return false; } #if CONFIG_CPU == AS3525v2 void adc_set_voltage_mux(int channel) { ascodec_lock(); /*this register also controls which subregister is subsequently written, so be careful*/ ascodec_write(AS3543_PMU_ENABLE, 8 | channel << 4 ); ascodec_unlock(); } #endif bool dbg_ports(void) { int line, i; int x = 0; bool done = false; lcd_clear_display(); lcd_setfont(FONT_SYSFIXED); while(!done) { while(dbg_btn(&done, &x)) { line = 0; lcd_puts(x, line++, "[GPIO Vals and Dirs]"); lcd_putsf(x, line++, "%s: %2x DIR: %2x", "GPIOA", GPIOA_DATA, GPIOA_DIR); lcd_putsf(x, line++, "%s: %2x DIR: %2x", "GPIOB", GPIOB_DATA, GPIOB_DIR); lcd_putsf(x, line++, "%s: %2x DIR: %2x", "GPIOC", GPIOC_DATA, GPIOC_DIR); lcd_putsf(x, line++, "%s: %2x DIR: %2x", "GPIOD", GPIOD_DATA, GPIOD_DIR); lcd_putsf(x, line++, "CCU_IO:%8x", CCU_IO); #ifdef DEBUG_DBOP lcd_puts(x, line++, "[DBOP_DIN]"); lcd_putsf(x, line++, "DBOP_DIN: %4x", dbop_debug()); #endif lcd_puts(x, line++, "[CP15]"); lcd_putsf(x, line++, "CP15: 0x%8x", read_cp15()); } #if CONFIG_CPU == AS3525 /* as3525v2 channels are different */ #define BATTEMP_UNIT 5/2 /* 2.5mV */ static const char *adc_name[13] = { "CHG_OUT ", "RTCSUP ", "VBUS ", "CHG_IN ", "CVDD ", "BatTemp ", "MicSup1 ", "MicSup2 ", "VBE1 ", "VBE2 ", "I_MicSup1", "I_MicSup2", "VBAT ", }; #elif CONFIG_CPU == AS3525v2 #define BATTEMP_UNIT 2 /* 2mV */ static const char *adc_name[16] = { "BVDD ", "BVDDR ", "CHGIN ", "CHGOUT ", "VBUS ", NULL, "BatTemp ", NULL, "MicSup ", NULL, "I_MiSsup", NULL, "VBE_1uA ", "VBE_2uA ", "I_CHGact", "I_CHGref", }; static const char *adc_mux_name[10] = { NULL, "AVDD27 ", "AVDD17 ", "PVDD1 ", "PVDD2 ", "CVDD1 ", "CVDD2 ", "RVDD ", "FVDD ", "PWGD ", }; #endif lcd_clear_display(); while(dbg_btn(&done, &x)) { line = 0; for(i=0; i<5; i++) lcd_putsf(x, line++, "%s: %d mV", adc_name[i], adc_read(i) * 5); for(; i<8; i++) if(adc_name[i]) lcd_putsf(x, line++, "%s: %d mV", adc_name[i], adc_read(i) * BATTEMP_UNIT); #if LCD_HEIGHT < 176 /* clip */ } while(dbg_btn(&done, &x)) { line = 0; #endif /* LCD_HEIGHT < 176 */ for(i=8; i<10; i++) if(adc_name[i]) lcd_putsf(x, line++, "%s: %d mV", adc_name[i], adc_read(i)); for(; i<12; i++) if(adc_name[i]) lcd_putsf(x, line++, "%s: %d uA", adc_name[i], adc_read(i)); #if CONFIG_CPU == AS3525 /* different units */ lcd_putsf(x, line++, "%s: %d mV", adc_name[i], adc_read(i)*5/2); #elif CONFIG_CPU == AS3525v2 for(; i<16; i++) lcd_putsf(x, line++, "%s: %d mV", adc_name[i], adc_read(i)); #endif } #if CONFIG_CPU == AS3525v2 /*extend AS3543 voltage registers*/ while(dbg_btn(&done, &x)) { line = 0; for(i=1; i<9; i++){ adc_set_voltage_mux(i); /*change the voltage mux to a new channel*/ lcd_putsf(x, line++, "%s: %d mV", adc_mux_name[i], adc_read(5) * 5); } } #endif } lcd_setfont(FONT_UI); return false; } #ifdef HAVE_ADJUSTABLE_CPU_VOLTAGE /* Return CPU voltage setting in millivolts */ int get_cpu_voltage_setting(void) { int value; #if CONFIG_CPU == AS3525 value = ascodec_read(AS3514_CVDD_DCDC3) & 0x3; value = 1200 - value * 50; #else /* as3525v2 */ value = ascodec_read_pmu(0x17, 1) & 0x7f; /* Calculate in 0.1mV steps */ if (value == 0) /* 0 volts */; else if (value <= 0x40) value = 6000 + value * 125; else if (value <= 0x70) value = 14000 + (value - 0x40) * 250; else if (value <= 0x7f) value = 26000 + (value - 0x70) * 500; /* Return voltage setting in millivolts */ value = (value + 5) / 10; #endif /* CONFIG_CPU */ return value; } #endif /* HAVE_ADJUSTABLE_CPU_VOLTAGE */