/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 Heikki Hannikainen * * 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 "config.h" #include #include #include #include #include "lcd.h" #include "lang.h" #include "menu.h" #include "debug_menu.h" #include "kernel.h" #include "structec.h" #include "action.h" #include "debug.h" #include "thread.h" #include "powermgmt.h" #include "system.h" #include "font.h" #include "audio.h" #include "settings.h" #include "list.h" #include "statusbar.h" #include "dir.h" #include "panic.h" #include "screens.h" #include "misc.h" #include "splash.h" #include "shortcuts.h" #include "dircache.h" #include "viewport.h" #ifdef HAVE_TAGCACHE #include "tagcache.h" #endif #ifdef HAVE_REMOTE_LCD #include "lcd-remote.h" #endif #include "crc32.h" #include "logf.h" #if (CONFIG_PLATFORM & PLATFORM_NATIVE) #include "disk.h" #include "adc.h" #include "usb.h" #include "rtc.h" #include "storage.h" #include "fs_defines.h" #include "eeprom_24cxx.h" #if (CONFIG_STORAGE & STORAGE_MMC) || (CONFIG_STORAGE & STORAGE_SD) #include "sdmmc.h" #endif #if (CONFIG_STORAGE & STORAGE_ATA) #include "ata.h" #endif #endif /* CONFIG_PLATFORM & PLATFORM_NATIVE */ #include "power.h" #if ((CONFIG_PLATFORM & PLATFORM_NATIVE) || defined(SAMSUNG_YPR0) || defined(SAMSUNG_YPR1) \ || defined(SONY_NWZ_LINUX)) \ && CONFIG_TUNER != 0 #include "tuner.h" #include "radio.h" #endif #include "scrollbar.h" #include "peakmeter.h" #include "skin_engine/skin_engine.h" #include "logfdisp.h" #include "core_alloc.h" #include "pcmbuf.h" #include "buffering.h" #include "playback.h" #if defined(HAVE_SPDIF_OUT) || defined(HAVE_SPDIF_IN) #include "spdif.h" #endif #ifdef IRIVER_H300_SERIES #include "pcf50606.h" /* for pcf50606_read */ #endif #ifdef IAUDIO_X5 #include "ds2411.h" #endif #include "hwcompat.h" #include "button.h" #if CONFIG_RTC == RTC_PCF50605 #include "pcf50605.h" #endif #include "appevents.h" #if defined(HAVE_AS3514) && CONFIG_CHARGING #include "ascodec.h" #endif #ifdef IPOD_NANO2G #include "pmu-target.h" #endif #ifdef SANSA_CONNECT #include "avr-sansaconnect.h" #endif #ifdef HAVE_USBSTACK #include "usb_core.h" #endif #if defined(IPOD_ACCESSORY_PROTOCOL) #include "iap.h" #endif #include "talk.h" #if defined(HAVE_BOOTDATA) && !defined(SIMULATOR) #include "bootdata.h" #endif static const char* threads_getname(int selected_item, void *data, char *buffer, size_t buffer_len) { (void)data; #if NUM_CORES > 1 if (selected_item < (int)NUM_CORES) { struct core_debug_info coreinfo; core_get_debug_info(selected_item, &coreinfo); snprintf(buffer, buffer_len, "Idle (%d): %2d%%", selected_item, coreinfo.idle_stack_usage); return buffer; } selected_item -= NUM_CORES; #endif const char *fmtstr = "%2d: ---"; struct thread_debug_info threadinfo; if (thread_get_debug_info(selected_item, &threadinfo) > 0) { fmtstr = "%2d:" IF_COP(" (%d)") " %s" IF_PRIO(" %d %d") IFN_SDL(" %2d%%") " %s"; } snprintf(buffer, buffer_len, fmtstr, selected_item, IF_COP(threadinfo.core,) threadinfo.statusstr, IF_PRIO(threadinfo.base_priority, threadinfo.current_priority,) IFN_SDL(threadinfo.stack_usage,) threadinfo.name); return buffer; } static int dbg_threads_action_callback(int action, struct gui_synclist *lists) { (void)lists; if (action == ACTION_NONE) action = ACTION_REDRAW; return action; } /* Test code!!! */ static bool dbg_os(void) { struct simplelist_info info; simplelist_info_init(&info, IF_COP("Core and ") "Stack usage:", MAXTHREADS IF_COP( + NUM_CORES ), NULL); info.hide_selection = true; info.scroll_all = true; info.action_callback = dbg_threads_action_callback; info.get_name = threads_getname; return simplelist_show_list(&info); } #ifdef __linux__ #include "cpuinfo-linux.h" #define MAX_STATES 16 static struct time_state states[MAX_STATES]; static const char* get_cpuinfo(int selected_item, void *data, char *buffer, size_t buffer_len) { (void)data;(void)buffer_len; const char* text; long time, diff; struct cpuusage us; static struct cpuusage last_us; int state_count = *(int*)data; if (cpuusage_linux(&us) != 0) return NULL; switch(selected_item) { case 0: diff = abs(last_us.usage - us.usage); sprintf(buffer, "Usage: %ld.%02ld%% (%c %ld.%02ld)", us.usage/100, us.usage%100, (us.usage >= last_us.usage) ? '+':'-', diff/100, diff%100); last_us.usage = us.usage; return buffer; case 1: text = "User"; time = us.utime; diff = us.utime - last_us.utime; last_us.utime = us.utime; break; case 2: text = "Sys"; time = us.stime; diff = us.stime - last_us.stime; last_us.stime = us.stime; break; case 3: text = "Real"; time = us.rtime; diff = us.rtime - last_us.rtime; last_us.rtime = us.rtime; break; case 4: return "*** Per CPU freq stats ***"; default: { int cpu = (selected_item - 5) / (state_count + 1); int cpu_line = (selected_item - 5) % (state_count + 1); /* scaling info */ int min_freq = min_scaling_frequency(cpu); int cur_freq = current_scaling_frequency(cpu); /* fallback if scaling frequency is not available */ if(cur_freq <= 0) cur_freq = frequency_linux(cpu); int max_freq = max_scaling_frequency(cpu); char governor[20]; bool have_governor = current_scaling_governor(cpu, governor, sizeof(governor)); if(cpu_line == 0) { sprintf(buffer, " CPU%d: %s: %d/%d/%d MHz", cpu, have_governor ? governor : "Min/Cur/Max freq", min_freq > 0 ? min_freq/1000 : -1, cur_freq > 0 ? cur_freq/1000 : -1, max_freq > 0 ? max_freq/1000 : -1); } else { cpustatetimes_linux(cpu, states, ARRAYLEN(states)); snprintf(buffer, buffer_len, " %ld %ld", states[cpu_line-1].frequency, states[cpu_line-1].time); } return buffer; } } sprintf(buffer, "%s: %ld.%02lds (+ %ld.%02ld)", text, time / us.hz, time % us.hz, diff / us.hz, diff % us.hz); return buffer; } static int cpuinfo_cb(int action, struct gui_synclist *lists) { (void)lists; if (action == ACTION_NONE) action = ACTION_REDRAW; return action; } static bool dbg_cpuinfo(void) { struct simplelist_info info; int cpu_count = MAX(cpucount_linux(), 1); int state_count = cpustatetimes_linux(0, states, ARRAYLEN(states)); printf("%s(): %d %d\n", __func__, cpu_count, state_count); simplelist_info_init(&info, "CPU info:", 5 + cpu_count*(state_count+1), &state_count); info.get_name = get_cpuinfo; info.action_callback = cpuinfo_cb; info.timeout = HZ; info.hide_selection = true; info.scroll_all = true; return simplelist_show_list(&info); } #endif static unsigned int ticks, freq_sum; #ifndef CPU_MULTI_FREQUENCY static unsigned int boost_ticks; #endif static void dbg_audio_task(void) { #ifdef CPUFREQ_NORMAL #ifndef CPU_MULTI_FREQUENCY if(FREQ > CPUFREQ_NORMAL) boost_ticks++; #endif freq_sum += FREQ/1000000; /* in MHz */ #endif ticks++; } static bool dbg_buffering_thread(void) { int button; int line; bool done = false; size_t bufused; size_t bufsize = pcmbuf_get_bufsize(); int pcmbufdescs = pcmbuf_descs(); struct buffering_debug d; size_t filebuflen = audio_get_filebuflen(); /* This is a size_t, but call it a long so it puts a - when it's bad. */ #ifndef CPU_MULTI_FREQUENCY boost_ticks = 0; #endif ticks = freq_sum = 0; tick_add_task(dbg_audio_task); FOR_NB_SCREENS(i) screens[i].setfont(FONT_SYSFIXED); while(!done) { button = get_action(CONTEXT_STD,HZ/5); switch(button) { case ACTION_STD_NEXT: audio_next(); break; case ACTION_STD_PREV: audio_prev(); break; case ACTION_STD_CANCEL: done = true; break; } buffering_get_debugdata(&d); bufused = bufsize - pcmbuf_free(); FOR_NB_SCREENS(i) { line = 0; screens[i].clear_display(); screens[i].putsf(0, line++, "pcm: %6ld/%ld", (long) bufused, (long) bufsize); gui_scrollbar_draw(&screens[i],0, line*8, screens[i].lcdwidth, 6, bufsize, 0, bufused, HORIZONTAL); line++; screens[i].putsf(0, line++, "alloc: %6ld/%ld", audio_filebufused(), (long) filebuflen); #if LCD_HEIGHT > 80 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_HEIGHT > 80) if (screens[i].lcdheight > 80) { gui_scrollbar_draw(&screens[i],0, line*8, screens[i].lcdwidth, 6, filebuflen, 0, audio_filebufused(), HORIZONTAL); line++; screens[i].putsf(0, line++, "real: %6ld/%ld", (long)d.buffered_data, (long)filebuflen); gui_scrollbar_draw(&screens[i],0, line*8, screens[i].lcdwidth, 6, filebuflen, 0, (long)d.buffered_data, HORIZONTAL); line++; } #endif screens[i].putsf(0, line++, "usefl: %6ld/%ld", (long)(d.useful_data), (long)filebuflen); #if LCD_HEIGHT > 80 || (defined(HAVE_REMOTE_LCD) && LCD_REMOTE_HEIGHT > 80) if (screens[i].lcdheight > 80) { gui_scrollbar_draw(&screens[i],0, line*8, screens[i].lcdwidth, 6, filebuflen, 0, d.useful_data, HORIZONTAL); line++; } #endif screens[i].putsf(0, line++, "data_rem: %ld", (long)d.data_rem); screens[i].putsf(0, line++, "track count: %2u", audio_track_count()); screens[i].putsf(0, line++, "handle count: %d", (int)d.num_handles); #if (CONFIG_PLATFORM & PLATFORM_NATIVE) screens[i].putsf(0, line++, "cpu freq: %3dMHz", (int)((FREQ + 500000) / 1000000)); #endif if (ticks > 0) { int avgclock = freq_sum * 10 / ticks; /* in 100 kHz */ #ifdef CPU_MULTI_FREQUENCY int boostquota = (avgclock * 100 - CPUFREQ_NORMAL/1000) / ((CPUFREQ_MAX - CPUFREQ_NORMAL) / 1000000); /* in 0.1 % */ #else int boostquota = boost_ticks * 1000 / ticks; /* in 0.1 % */ #endif screens[i].putsf(0, line++, "boost:%3d.%d%% (%d.%dMHz)", boostquota/10, boostquota%10, avgclock/10, avgclock%10); } screens[i].putsf(0, line++, "pcmbufdesc: %2d/%2d", pcmbuf_used_descs(), pcmbufdescs); screens[i].putsf(0, line++, "watermark: %6d", (int)(d.watermark)); screens[i].update(); } } tick_remove_task(dbg_audio_task); FOR_NB_SCREENS(i) screens[i].setfont(FONT_UI); return false; } static const char* bf_getname(int selected_item, void *data, char *buffer, size_t buffer_len) { (void)data; core_print_block_at(selected_item, buffer, buffer_len); return buffer; } static int bf_action_cb(int action, struct gui_synclist* list) { if (action == ACTION_STD_OK) { if (gui_synclist_get_sel_pos(list) == 0 && core_test_free()) { splash(HZ, "Freed test handle. New alloc should trigger compact"); } else { splash(HZ/1, "Attempting a 64k allocation"); int handle = core_alloc("test", 64<<10); splash(HZ/2, (handle > 0) ? "Success":"Fail"); /* for some reason simplelist doesn't allow adding items here if * info.get_name is given, so use normal list api */ gui_synclist_set_nb_items(list, core_get_num_blocks()); if (handle > 0) core_free(handle); } action = ACTION_REDRAW; } return action; } static bool dbg_buflib_allocs(void) { struct simplelist_info info; simplelist_info_init(&info, "mem allocs", core_get_num_blocks(), NULL); info.get_name = bf_getname; info.action_callback = bf_action_cb; info.timeout = HZ; return simplelist_show_list(&info); } #if (CONFIG_PLATFORM & PLATFORM_NATIVE) static const char* dbg_partitions_getname(int selected_item, void *data, char *buffer, size_t buffer_len) { (void)data; int partition = selected_item/2; struct partinfo p; if (!disk_partinfo(partition, &p)) return buffer; if (selected_item%2) { snprintf(buffer, buffer_len, " T:%x %ld MB", p.type, p.size / ( 2048 / ( SECTOR_SIZE / 512 ))); } else { snprintf(buffer, buffer_len, "P%d: S:%lx", partition, p.start); } return buffer; } static bool dbg_partitions(void) { struct simplelist_info info; simplelist_info_init(&info, "Partition Info", NUM_DRIVES * 4, NULL); info.selection_size = 2; info.hide_selection = true; info.scroll_all = true; info.get_name = dbg_partitions_getname; return simplelist_show_list(&info); } #endif /* PLATFORM_NATIVE */ #if defined(CPU_COLDFIRE) && defined(HAVE_SPDIF_OUT) static bool dbg_spdif(void) { int line; unsigned int control; int x; char *s; int category; int generation; unsigned int interruptstat; bool valnogood, symbolerr, parityerr; bool done = false; bool spdif_src_on; int spdif_source = spdif_get_output_source(&spdif_src_on); spdif_set_output_source(AUDIO_SRC_SPDIF IF_SPDIF_POWER_(, true)); lcd_clear_display(); lcd_setfont(FONT_SYSFIXED); #ifdef HAVE_SPDIF_POWER spdif_power_enable(true); /* We need SPDIF power for both sending & receiving */ #endif while (!done) { line = 0; control = EBU1RCVCCHANNEL1; interruptstat = INTERRUPTSTAT; INTERRUPTCLEAR = 0x03c00000; valnogood = (interruptstat & 0x01000000)?true:false; symbolerr = (interruptstat & 0x00800000)?true:false; parityerr = (interruptstat & 0x00400000)?true:false; lcd_putsf(0, line++, "Val: %s Sym: %s Par: %s", valnogood?"--":"OK", symbolerr?"--":"OK", parityerr?"--":"OK"); lcd_putsf(0, line++, "Status word: %08x", (int)control); line++; x = control >> 31; lcd_putsf(0, line++, "PRO: %d (%s)", x, x?"Professional":"Consumer"); x = (control >> 30) & 1; lcd_putsf(0, line++, "Audio: %d (%s)", x, x?"Non-PCM":"PCM"); x = (control >> 29) & 1; lcd_putsf(0, line++, "Copy: %d (%s)", x, x?"Permitted":"Inhibited"); x = (control >> 27) & 7; switch(x) { case 0: s = "None"; break; case 1: s = "50/15us"; break; default: s = "Reserved"; break; } lcd_putsf(0, line++, "Preemphasis: %d (%s)", x, s); x = (control >> 24) & 3; lcd_putsf(0, line++, "Mode: %d", x); category = (control >> 17) & 127; switch(category) { case 0x00: s = "General"; break; case 0x40: s = "Audio CD"; break; default: s = "Unknown"; } lcd_putsf(0, line++, "Category: 0x%02x (%s)", category, s); x = (control >> 16) & 1; generation = x; if(((category & 0x70) == 0x10) || ((category & 0x70) == 0x40) || ((category & 0x78) == 0x38)) { generation = !generation; } lcd_putsf(0, line++, "Generation: %d (%s)", x, generation?"Original":"No ind."); x = (control >> 12) & 15; lcd_putsf(0, line++, "Source: %d", x); x = (control >> 8) & 15; switch(x) { case 0: s = "Unspecified"; break; case 8: s = "A (Left)"; break; case 4: s = "B (Right)"; break; default: s = ""; break; } lcd_putsf(0, line++, "Channel: %d (%s)", x, s); x = (control >> 4) & 15; switch(x) { case 0: s = "44.1kHz"; break; case 0x4: s = "48kHz"; break; case 0xc: s = "32kHz"; break; } lcd_putsf(0, line++, "Frequency: %d (%s)", x, s); x = (control >> 2) & 3; lcd_putsf(0, line++, "Clock accuracy: %d", x); line++; #if (CONFIG_PLATFORM & PLATFORM_NATIVE) lcd_putsf(0, line++, "Measured freq: %ldHz", spdif_measure_frequency()); #endif lcd_update(); if (action_userabort(HZ/10)) break; } spdif_set_output_source(spdif_source IF_SPDIF_POWER_(, spdif_src_on)); #ifdef HAVE_SPDIF_POWER spdif_power_enable(global_settings.spdif_enable); #endif lcd_setfont(FONT_UI); return false; } #endif /* CPU_COLDFIRE */ #if (CONFIG_RTC == RTC_PCF50605) && (CONFIG_PLATFORM & PLATFORM_NATIVE) static bool dbg_pcf(void) { int line; lcd_setfont(FONT_SYSFIXED); lcd_clear_display(); while(1) { line = 0; lcd_putsf(0, line++, "DCDC1: %02x", pcf50605_read(0x1b)); lcd_putsf(0, line++, "DCDC2: %02x", pcf50605_read(0x1c)); lcd_putsf(0, line++, "DCDC3: %02x", pcf50605_read(0x1d)); lcd_putsf(0, line++, "DCDC4: %02x", pcf50605_read(0x1e)); lcd_putsf(0, line++, "DCDEC1: %02x", pcf50605_read(0x1f)); lcd_putsf(0, line++, "DCDEC2: %02x", pcf50605_read(0x20)); lcd_putsf(0, line++, "DCUDC1: %02x", pcf50605_read(0x21)); lcd_putsf(0, line++, "DCUDC2: %02x", pcf50605_read(0x22)); lcd_putsf(0, line++, "IOREGC: %02x", pcf50605_read(0x23)); lcd_putsf(0, line++, "D1REGC: %02x", pcf50605_read(0x24)); lcd_putsf(0, line++, "D2REGC: %02x", pcf50605_read(0x25)); lcd_putsf(0, line++, "D3REGC: %02x", pcf50605_read(0x26)); lcd_putsf(0, line++, "LPREG1: %02x", pcf50605_read(0x27)); lcd_update(); if (action_userabort(HZ/10)) { lcd_setfont(FONT_UI); return false; } } lcd_setfont(FONT_UI); return false; } #endif #ifdef HAVE_ADJUSTABLE_CPU_FREQ static bool dbg_cpufreq(void) { int line; int button; int x = 0; bool done = false; lcd_setfont(FONT_SYSFIXED); lcd_clear_display(); while(!done) { line = 0; int temp = FREQ / 1000; lcd_putsf(x, line++, "Frequency: %ld.%ld MHz", temp / 1000, temp % 1000); lcd_putsf(x, line++, "boost_counter: %d", get_cpu_boost_counter()); #ifdef HAVE_ADJUSTABLE_CPU_VOLTAGE extern int get_cpu_voltage_setting(void); temp = get_cpu_voltage_setting(); lcd_putsf(x, line++, "CPU voltage: %d.%03dV", temp / 1000, temp % 1000); #endif lcd_update(); button = get_action(CONTEXT_STD,HZ/10); switch(button) { case ACTION_STD_PREV: cpu_boost(true); break; case ACTION_STD_NEXT: cpu_boost(false); break; case ACTION_STD_MENU: x--; break; case ACTION_STD_OK: x = 0; while (get_cpu_boost_counter() > 0) cpu_boost(false); set_cpu_frequency(CPUFREQ_DEFAULT); break; case ACTION_STD_CANCEL: done = true;; } lcd_clear_display(); } lcd_setfont(FONT_UI); return false; } #endif /* HAVE_ADJUSTABLE_CPU_FREQ */ #if defined(HAVE_TSC2100) && (CONFIG_PLATFORM & PLATFORM_NATIVE) #include "tsc2100.h" static const char* tsc2100_debug_getname(int selected_item, void * data, char *buffer, size_t buffer_len) { int *page = (int*)data; bool reserved = false; switch (*page) { case 0: if ((selected_item > 0x0a) || (selected_item == 0x04) || (selected_item == 0x08)) reserved = true; break; case 1: if ((selected_item > 0x05) || (selected_item == 0x02)) reserved = true; break; case 2: if (selected_item > 0x1e) reserved = true; break; } if (reserved) snprintf(buffer, buffer_len, "%02x: RSVD", selected_item); else snprintf(buffer, buffer_len, "%02x: %04x", selected_item, tsc2100_readreg(*page, selected_item)&0xffff); return buffer; } static int tsc2100debug_action_callback(int action, struct gui_synclist *lists) { int *page = (int*)lists->data; if (action == ACTION_STD_OK) { *page = (*page+1)%3; snprintf(lists->title, 32, "tsc2100 registers - Page %d", *page); return ACTION_REDRAW; } return action; } static bool tsc2100_debug(void) { int page = 0; char title[32] = "tsc2100 registers - Page 0"; struct simplelist_info info; simplelist_info_init(&info, title, 32, &page); info.timeout = HZ/100; info.get_name = tsc2100_debug_getname; info.action_callback= tsc2100debug_action_callback; return simplelist_show_list(&info); } #endif #if (CONFIG_BATTERY_MEASURE != 0) && !defined(SIMULATOR) /* * view_battery() shows a automatically scaled graph of the battery voltage * over time. Usable for estimating battery life / charging rate. * The power_history array is updated in power_thread of powermgmt.c. */ #define BAT_LAST_VAL MIN(LCD_WIDTH, POWER_HISTORY_LEN) #define BAT_TSPACE 20 #define BAT_YSPACE (LCD_HEIGHT - BAT_TSPACE) static bool view_battery(void) { int view = 0; int i, x, y, z, y1, y2, grid, graph; unsigned short maxv, minv; lcd_setfont(FONT_SYSFIXED); while(1) { lcd_clear_display(); switch (view) { case 0: /* voltage history graph */ /* Find maximum and minimum voltage for scaling */ minv = power_history[0]; maxv = minv + 1; for (i = 1; i < BAT_LAST_VAL && power_history[i]; i++) { if (power_history[i] > maxv) maxv = power_history[i]; if (power_history[i] < minv) minv = power_history[i]; } /* print header */ #if (CONFIG_BATTERY_MEASURE & VOLTAGE_MEASURE) /* adjust grid scale */ if ((maxv - minv) > 50) grid = 50; else grid = 5; lcd_putsf(0, 0, "battery %d.%03dV", power_history[0] / 1000, power_history[0] % 1000); lcd_putsf(0, 1, "%d.%03d-%d.%03dV (%2dmV)", minv / 1000, minv % 1000, maxv / 1000, maxv % 1000, grid); #elif (CONFIG_BATTERY_MEASURE & PERCENTAGE_MEASURE) /* adjust grid scale */ if ((maxv - minv) > 10) grid = 10; else grid = 1; lcd_putsf(0, 0, "battery %d%%", power_history[0]); lcd_putsf(0, 1, "%d%%-%d%% (%d %%)", minv, maxv, grid); #endif i = 1; while ((y = (minv - (minv % grid)+i*grid)) < maxv) { graph = ((y-minv)*BAT_YSPACE)/(maxv-minv); graph = LCD_HEIGHT-1 - graph; /* draw dotted horizontal grid line */ for (x=0; x 0; i--) { if (power_history[i] && power_history[i-1]) { y1 = (power_history[i] - minv) * BAT_YSPACE / (maxv - minv); y1 = MIN(MAX(LCD_HEIGHT-1 - y1, BAT_TSPACE), LCD_HEIGHT-1); y2 = (power_history[i-1] - minv) * BAT_YSPACE / (maxv - minv); y2 = MIN(MAX(LCD_HEIGHT-1 - y2, BAT_TSPACE), LCD_HEIGHT-1); lcd_set_drawmode(DRMODE_SOLID); /* make line thicker */ lcd_drawline(((x*LCD_WIDTH)/(BAT_LAST_VAL)), y1, (((x+1)*LCD_WIDTH)/(BAT_LAST_VAL)), y2); lcd_drawline(((x*LCD_WIDTH)/(BAT_LAST_VAL))+1, y1+1, (((x+1)*LCD_WIDTH)/(BAT_LAST_VAL))+1, y2+1); x++; } } break; case 1: /* status: */ #if CONFIG_CHARGING >= CHARGING_MONITOR lcd_putsf(0, 0, "Pwr status: %s", charging_state() ? "charging" : "discharging"); #else lcd_puts(0, 0, "Power status: unknown"); #endif battery_read_info(&y, &z); if (y > 0) lcd_putsf(0, 1, "Battery: %d.%03d V (%d %%)", y / 1000, y % 1000, z); else if (z > 0) lcd_putsf(0, 1, "Battery: %d %%", z); #ifdef ADC_EXT_POWER y = (adc_read(ADC_EXT_POWER) * EXT_SCALE_FACTOR) / 1000; lcd_putsf(0, 2, "External: %d.%03d V", y / 1000, y % 1000); #endif #if CONFIG_CHARGING #if defined IPOD_NANO || defined IPOD_VIDEO int usb_pwr = (GPIOL_INPUT_VAL & 0x10)?true:false; int ext_pwr = (GPIOL_INPUT_VAL & 0x08)?false:true; int dock = (GPIOA_INPUT_VAL & 0x10)?true:false; int charging = (GPIOB_INPUT_VAL & 0x01)?false:true; int headphone= (GPIOA_INPUT_VAL & 0x80)?true:false; lcd_putsf(0, 3, "USB pwr: %s", usb_pwr ? "present" : "absent"); lcd_putsf(0, 4, "EXT pwr: %s", ext_pwr ? "present" : "absent"); lcd_putsf(0, 5, "Battery: %s", charging ? "charging" : (usb_pwr||ext_pwr) ? "charged" : "discharging"); lcd_putsf(0, 6, "Dock mode: %s", dock ? "enabled" : "disabled"); lcd_putsf(0, 7, "Headphone: %s", headphone ? "connected" : "disconnected"); #ifdef IPOD_VIDEO if(probed_ramsize == 64) x = (adc_read(ADC_4066_ISTAT) * 2400) / (1024 * 2); else #endif x = (adc_read(ADC_4066_ISTAT) * 2400) / (1024 * 3); lcd_putsf(0, 8, "Ibat: %d mA", x); lcd_putsf(0, 9, "Vbat * Ibat: %d mW", x * y / 1000); #elif defined TOSHIBA_GIGABEAT_S int line = 3; unsigned int st; static const unsigned char * const chrgstate_strings[] = { "Disabled", "Error", "Discharging", "Precharge", "Constant Voltage", "Constant Current", "", }; lcd_putsf(0, line++, "Charger: %s", charger_inserted() ? "present" : "absent"); st = power_input_status() & (POWER_INPUT_CHARGER | POWER_INPUT_BATTERY); lcd_putsf(0, line++, "%.*s%.*s", !!(st & POWER_INPUT_MAIN_CHARGER)*5, " Main", !!(st & POWER_INPUT_USB_CHARGER)*4, " USB"); y = ARRAYLEN(chrgstate_strings) - 1; switch (charge_state) { case CHARGE_STATE_DISABLED: y--; case CHARGE_STATE_ERROR: y--; case DISCHARGING: y--; case TRICKLE: y--; case TOPOFF: y--; case CHARGING: y--; default:; } lcd_putsf(0, line++, "State: %s", chrgstate_strings[y]); lcd_putsf(0, line++, "Battery Switch: %s", (st & POWER_INPUT_BATTERY) ? "On" : "Off"); y = chrgraw_adc_voltage(); lcd_putsf(0, line++, "CHRGRAW: %d.%03d V", y / 1000, y % 1000); y = application_supply_adc_voltage(); lcd_putsf(0, line++, "BP : %d.%03d V", y / 1000, y % 1000); y = battery_adc_charge_current(); lcd_putsf(0, line++, "CHRGISN:% d mA", y); y = cccv_regulator_dissipation(); lcd_putsf(0, line++, "P CCCV : %d mW", y); y = battery_charge_current(); lcd_putsf(0, line++, "I Charge:% d mA", y); y = battery_adc_temp(); if (y != INT_MIN) { lcd_putsf(0, line++, "T Battery: %d\u00b0C (%d\u00b0F)", y, (9*y + 160) / 5); } else { /* Conversion disabled */ lcd_puts(0, line++, "T Battery: ?"); } #elif defined(HAVE_AS3514) && CONFIG_CHARGING static const char * const chrgstate_strings[] = { [CHARGE_STATE_DISABLED - CHARGE_STATE_DISABLED]= "Disabled", [CHARGE_STATE_ERROR - CHARGE_STATE_DISABLED] = "Error", [DISCHARGING - CHARGE_STATE_DISABLED] = "Discharging", [CHARGING - CHARGE_STATE_DISABLED] = "Charging", }; const char *str = NULL; lcd_putsf(0, 3, "Charger: %s", charger_inserted() ? "present" : "absent"); y = charge_state - CHARGE_STATE_DISABLED; if ((unsigned)y < ARRAYLEN(chrgstate_strings)) str = chrgstate_strings[y]; lcd_putsf(0, 4, "State: %s", str ? str : ""); lcd_putsf(0, 5, "CHARGER: %02X", ascodec_read_charger()); #elif defined(IPOD_NANO2G) y = pmu_read_battery_voltage(); lcd_putsf(17, 1, "RAW: %d.%03d V", y / 1000, y % 1000); y = pmu_read_battery_current(); lcd_putsf(0, 2, "Battery current: %d mA", y); lcd_putsf(0, 3, "PWRCON: %08x %08x", PWRCON, PWRCONEXT); lcd_putsf(0, 4, "CLKCON: %08x %03x %03x", CLKCON, CLKCON2, CLKCON3); lcd_putsf(0, 5, "PLL: %06x %06x %06x", PLL0PMS, PLL1PMS, PLL2PMS); x = pmu_read(0x1b) & 0xf; y = pmu_read(0x1a) * 25 + 625; lcd_putsf(0, 6, "AUTO: %x / %d mV", x, y); x = pmu_read(0x1f) & 0xf; y = pmu_read(0x1e) * 25 + 625; lcd_putsf(0, 7, "DOWN1: %x / %d mV", x, y); x = pmu_read(0x23) & 0xf; y = pmu_read(0x22) * 25 + 625; lcd_putsf(0, 8, "DOWN2: %x / %d mV", x, y); x = pmu_read(0x27) & 0xf; y = pmu_read(0x26) * 100 + 900; lcd_putsf(0, 9, "MEMLDO: %x / %d mV", x, y); for (i = 0; i < 6; i++) { x = pmu_read(0x2e + (i << 1)) & 0xf; y = pmu_read(0x2d + (i << 1)) * 100 + 900; lcd_putsf(0, 10 + i, "LDO%d: %x / %d mV", i + 1, x, y); } #elif defined(SANSA_CONNECT) lcd_putsf(0, 3, "Charger: %s", charger_inserted() ? "present" : "absent"); x = (avr_hid_hdq_read_short(HDQ_REG_TEMP) / 4) - 273; lcd_putsf(0, 4, "Battery temperature: %d C", x); x = (avr_hid_hdq_read_short(HDQ_REG_AI) * 357) / 200; lcd_putsf(0, 5, "Battery current: %d.%01d mA", x / 10, x % 10); x = (avr_hid_hdq_read_short(HDQ_REG_AP) * 292) / 20; lcd_putsf(0, 6, "Discharge power: %d.%01d mW", x / 10, x % 10); x = (avr_hid_hdq_read_short(HDQ_REG_SAE) * 292) / 2; lcd_putsf(0, 7, "Available energy: %d.%01d mWh", x / 10, x % 10); #else lcd_putsf(0, 3, "Charger: %s", charger_inserted() ? "present" : "absent"); #endif /* target type */ #endif /* CONFIG_CHARGING */ break; case 2: /* voltage deltas: */ #if (CONFIG_BATTERY_MEASURE & VOLTAGE_MEASURE) lcd_puts(0, 0, "Voltage deltas:"); for (i = 0; i < POWER_HISTORY_LEN-1; i++) { y = power_history[i] - power_history[i+1]; lcd_putsf(0, i+1, "-%d min: %c%d.%03d V", i, (y < 0) ? '-' : ' ', ((y < 0) ? y * -1 : y) / 1000, ((y < 0) ? y * -1 : y ) % 1000); } #elif (CONFIG_BATTERY_MEASURE & PERCENTAGE_MEASURE) lcd_puts(0, 0, "Percentage deltas:"); for (i = 0; i < POWER_HISTORY_LEN-1; i++) { y = power_history[i] - power_history[i+1]; lcd_putsf(0, i+1, "-%d min: %c%d%%", i, (y < 0) ? '-' : ' ', ((y < 0) ? y * -1 : y)); } #endif break; case 3: /* remaining time estimation: */ #if (CONFIG_BATTERY_MEASURE & VOLTAGE_MEASURE) lcd_putsf(0, 5, "Last PwrHist: %d.%03dV", power_history[0] / 1000, power_history[0] % 1000); #endif lcd_putsf(0, 6, "battery level: %d%%", battery_level()); int time_left = battery_time(); if (time_left >= 0) lcd_putsf(0, 7, "Est. remain: %d m", time_left); else lcd_puts(0, 7, "Estimation n/a"); break; } lcd_update(); switch(get_action(CONTEXT_STD,HZ/2)) { case ACTION_STD_PREV: if (view) view--; break; case ACTION_STD_NEXT: if (view < 3) view++; break; case ACTION_STD_CANCEL: lcd_setfont(FONT_UI); return false; } } lcd_setfont(FONT_UI); return false; } #endif /* (CONFIG_BATTERY_MEASURE != 0) */ #if (CONFIG_PLATFORM & PLATFORM_NATIVE) #if (CONFIG_STORAGE & STORAGE_MMC) || (CONFIG_STORAGE & STORAGE_SD) #if (CONFIG_STORAGE & STORAGE_MMC) #define CARDTYPE "MMC" #elif (CONFIG_STORAGE & STORAGE_SD) #define CARDTYPE "microSD" #endif static int disk_callback(int btn, struct gui_synclist *lists) { tCardInfo *card; int *cardnum = (int*)lists->data; unsigned char card_name[6]; unsigned char pbuf[32]; char *title = lists->title; static const unsigned char i_vmin[] = { 0, 1, 5, 10, 25, 35, 60, 100 }; static const unsigned char i_vmax[] = { 1, 5, 10, 25, 35, 45, 80, 200 }; static const unsigned char * const kbit_units[] = { "kBit/s", "MBit/s", "GBit/s" }; static const unsigned char * const nsec_units[] = { "ns", "µs", "ms" }; #if (CONFIG_STORAGE & STORAGE_MMC) static const char * const mmc_spec_vers[] = { "1.0-1.2", "1.4", "2.0-2.2", "3.1-3.31", "4.0" }; #endif if ((btn == ACTION_STD_OK) || (btn == SYS_FS_CHANGED) || (btn == ACTION_REDRAW)) { #ifdef HAVE_HOTSWAP if (btn == ACTION_STD_OK) { *cardnum ^= 0x1; /* change cards */ } #endif simplelist_set_line_count(0); card = card_get_info(*cardnum); if (card->initialized > 0) { unsigned i; for (i=0; icid, (103-8*i), 8); } strlcpy(card_name, card_name, sizeof(card_name)); simplelist_addline( "%s Rev %d.%d", card_name, (int) card_extract_bits(card->cid, 63, 4), (int) card_extract_bits(card->cid, 59, 4)); simplelist_addline( "Prod: %d/%d", #if (CONFIG_STORAGE & STORAGE_SD) (int) card_extract_bits(card->cid, 11, 4), (int) card_extract_bits(card->cid, 19, 8) + 2000 #elif (CONFIG_STORAGE & STORAGE_MMC) (int) card_extract_bits(card->cid, 15, 4), (int) card_extract_bits(card->cid, 11, 4) + 1997 #endif ); simplelist_addline( #if (CONFIG_STORAGE & STORAGE_SD) "Ser#: 0x%08lx", card_extract_bits(card->cid, 55, 32) #elif (CONFIG_STORAGE & STORAGE_MMC) "Ser#: 0x%04lx", card_extract_bits(card->cid, 47, 16) #endif ); simplelist_addline("M=%02x, " #if (CONFIG_STORAGE & STORAGE_SD) "O=%c%c", (int) card_extract_bits(card->cid, 127, 8), card_extract_bits(card->cid, 119, 8), card_extract_bits(card->cid, 111, 8) #elif (CONFIG_STORAGE & STORAGE_MMC) "O=%04x", (int) card_extract_bits(card->cid, 127, 8), (int) card_extract_bits(card->cid, 119, 16) #endif ); #if (CONFIG_STORAGE & STORAGE_MMC) int temp = card_extract_bits(card->csd, 125, 4); simplelist_addline( "MMC v%s", temp < 5 ? mmc_spec_vers[temp] : "?.?"); #endif simplelist_addline( "Blocks: 0x%08lx", card->numblocks); output_dyn_value(pbuf, sizeof pbuf, card->speed / 1000, kbit_units, 3, false); simplelist_addline( "Speed: %s", pbuf); output_dyn_value(pbuf, sizeof pbuf, card->taac, nsec_units, 3, false); simplelist_addline( "Taac: %s", pbuf); simplelist_addline( "Nsac: %d clk", card->nsac); simplelist_addline( "R2W: *%d", card->r2w_factor); #if (CONFIG_STORAGE & STORAGE_SD) int csd_structure = card_extract_bits(card->csd, 127, 2); if (csd_structure == 0) /* CSD version 1.0 */ #endif { simplelist_addline( "IRmax: %d..%d mA", i_vmin[card_extract_bits(card->csd, 61, 3)], i_vmax[card_extract_bits(card->csd, 58, 3)]); simplelist_addline( "IWmax: %d..%d mA", i_vmin[card_extract_bits(card->csd, 55, 3)], i_vmax[card_extract_bits(card->csd, 52, 3)]); } } else if (card->initialized == 0) { simplelist_addline("Not Found!"); } #if (CONFIG_STORAGE & STORAGE_SD) else /* card->initialized < 0 */ { simplelist_addline("Init Error! (%d)", card->initialized); } #endif snprintf(title, 16, "[" CARDTYPE " %d]", *cardnum); gui_synclist_set_title(lists, title, Icon_NOICON); gui_synclist_set_nb_items(lists, simplelist_get_line_count()); gui_synclist_select_item(lists, 0); btn = ACTION_REDRAW; } return btn; } #elif (CONFIG_STORAGE & STORAGE_ATA) static int disk_callback(int btn, struct gui_synclist *lists) { static const char atanums[] = { " 0 1 2 3 4 5 6" }; (void)lists; int i; char buf[128]; unsigned short* identify_info = ata_get_identify(); bool timing_info_present = false; (void)btn; simplelist_set_line_count(0); for (i=0; i < 20; i++) ((unsigned short*)buf)[i]=htobe16(identify_info[i+27]); buf[40]=0; /* kill trailing space */ for (i=39; i && buf[i]==' '; i--) buf[i] = 0; simplelist_addline("Model: %s", buf); for (i=0; i < 4; i++) ((unsigned short*)buf)[i]=htobe16(identify_info[i+23]); buf[8]=0; simplelist_addline( "Firmware: %s", buf); snprintf(buf, sizeof buf, "%ld MB", ((unsigned long)identify_info[61] << 16 | (unsigned long)identify_info[60]) / 2048 ); simplelist_addline( "Size: %s", buf); unsigned long free; volume_size( IF_MV(0,) NULL, &free ); simplelist_addline( "Free: %ld MB", free / 1024); simplelist_addline( "Spinup time: %d ms", storage_spinup_time() * (1000/HZ)); i = identify_info[82] & (1<<3); simplelist_addline( "Power mgmt: %s", i ? "enabled" : "unsupported"); i = identify_info[83] & (1<<3); simplelist_addline( "Adv Power mgmt: %s", i ? "enabled" : "unsupported"); i = identify_info[83] & (1<<9); simplelist_addline( "Noise mgmt: %s", i ? "enabled" : "unsupported"); i = identify_info[82] & (1<<6); simplelist_addline( "Read-ahead: %s", i ? "enabled" : "unsupported"); timing_info_present = identify_info[53] & (1<<1); if(timing_info_present) { simplelist_addline( "PIO modes: 0 1 2%.*s%.*s", (identify_info[64] & (1<<0)) << 1, &atanums[3*2], (identify_info[64] & (1<<1)) , &atanums[4*2]); } else { simplelist_addline( "No PIO mode info"); } timing_info_present = identify_info[53] & (1<<1); if(timing_info_present) { simplelist_addline( "Cycle times %dns/%dns", identify_info[67], identify_info[68] ); } else { simplelist_addline( "No timing info"); } int sector_size = 512; if((identify_info[106] & 0xe000) == 0x6000) sector_size *= BIT_N(identify_info[106] & 0x000f); simplelist_addline( "Physical sector size: %d", sector_size); #ifdef HAVE_ATA_DMA if (identify_info[63] & (1<<0)) { simplelist_addline( "MDMA modes:%.*s%.*s%.*s", (identify_info[63] & (1<<0)) << 1, &atanums[0*2], (identify_info[63] & (1<<1)) , &atanums[1*2], (identify_info[63] & (1<<2)) >> 1, &atanums[2*2]); simplelist_addline( "MDMA Cycle times %dns/%dns", identify_info[65], identify_info[66] ); } else { simplelist_addline( "No MDMA mode info"); } if (identify_info[53] & (1<<2)) { simplelist_addline( "UDMA modes:%.*s%.*s%.*s%.*s%.*s%.*s%.*s", (identify_info[88] & (1<<0)) << 1, &atanums[0*2], (identify_info[88] & (1<<1)) , &atanums[1*2], (identify_info[88] & (1<<2)) >> 1, &atanums[2*2], (identify_info[88] & (1<<3)) >> 2, &atanums[3*2], (identify_info[88] & (1<<4)) >> 3, &atanums[4*2], (identify_info[88] & (1<<5)) >> 4, &atanums[5*2], (identify_info[88] & (1<<6)) >> 5, &atanums[6*2]); } else { simplelist_addline( "No UDMA mode info"); } #endif /* HAVE_ATA_DMA */ timing_info_present = identify_info[53] & (1<<1); if(timing_info_present) { i = identify_info[49] & (1<<11); simplelist_addline( "IORDY support: %s", i ? "yes" : "no"); i = identify_info[49] & (1<<10); simplelist_addline( "IORDY disable: %s", i ? "yes" : "no"); } else { simplelist_addline( "No timing info"); } simplelist_addline( "Cluster size: %d bytes", volume_get_cluster_size(IF_MV(0))); #ifdef HAVE_ATA_DMA i = ata_get_dma_mode(); if (i == 0) { simplelist_addline( "DMA not enabled"); } else { simplelist_addline( "DMA mode: %s %c", (i & 0x40) ? "UDMA" : "MDMA", '0' + (i & 7)); } #endif /* HAVE_ATA_DMA */ i = identify_info[0] & (1 << 15); simplelist_addline( "CF compatible: %s", i ? "yes" : "no"); i = identify_info[0] & (1 << 6); simplelist_addline( "Fixed device: %s", i ? "yes" : "no"); i = identify_info[0] & (1 << 7); simplelist_addline( "Removeable media: %s", i ? "yes" : "no"); return btn; } #ifdef HAVE_ATA_SMART static struct ata_smart_values smart_data STORAGE_ALIGN_ATTR; static const char * ata_smart_get_attr_name(unsigned char id) { if (id == 1) return "Raw Read Error Rate"; if (id == 2) return "Throughput Performance"; if (id == 3) return "Spin-Up Time"; if (id == 4) return "Start/Stop Count"; if (id == 5) return "Reallocated Sector Count"; if (id == 7) return "Seek Error Rate"; if (id == 8) return "Seek Time Performance"; if (id == 9) return "Power-On Hours Count"; if (id == 10) return "Spin-Up Retry Count"; if (id == 12) return "Power Cycle Count"; if (id == 191) return "G-Sense Error Rate"; if (id == 192) return "Power-Off Retract Count"; if (id == 193) return "Load/Unload Cycle Count"; if (id == 194) return "HDA Temperature"; if (id == 195) return "Hardware ECC Recovered"; if (id == 196) return "Reallocated Event Count"; if (id == 197) return "Current Pending Sector Count"; if (id == 198) return "Uncorrectable Sector Count"; if (id == 199) return "UDMA CRC Error Count"; if (id == 200) return "Write Error Rate"; if (id == 201) return "TA Counter Detected"; if (id == 220) return "Disk Shift"; if (id == 222) return "Loaded Hours"; if (id == 223) return "Load/Unload Retry Count"; if (id == 224) return "Load Friction"; if (id == 225) return "Load Cycle Count"; if (id == 226) return "Load-In Time"; if (id == 240) return "Transfer Error Rate"; /* Fujitsu */ return "Unknown Attribute"; }; static int ata_smart_get_attr_rawfmt(unsigned char id) { if (id == 3) /* Spin-up time */ return RAWFMT_RAW16_OPT_AVG16; if (id == 5 || /* Reallocated sector count */ id == 196) /* Reallocated event count */ return RAWFMT_RAW16_OPT_RAW16; if (id == 190 || /* Airflow Temperature */ id == 194) /* HDA Temperature */ return RAWFMT_TEMPMINMAX; return RAWFMT_RAW48; }; static int ata_smart_attr_to_string( struct ata_smart_attribute *attr, char *str, int size) { uint16_t w[3]; /* 3 words to store 6 bytes of raw data */ char buf[size]; /* temp string to store attribute data */ int len, slen; int id = attr->id; if (id == 0) return 0; /* null attribute */ /* align and convert raw data */ memcpy(w, attr->raw, 6); w[0] = letoh16(w[0]); w[1] = letoh16(w[1]); w[2] = letoh16(w[2]); len = snprintf(buf, size, ": %u,%u ", attr->current, attr->worst); switch (ata_smart_get_attr_rawfmt(id)) { case RAWFMT_RAW16_OPT_RAW16: len += snprintf(buf+len, size-len, "%u", w[0]); if ((w[1] || w[2]) && (len < size)) len += snprintf(buf+len, size-len, " %u %u", w[1],w[2]); break; case RAWFMT_RAW16_OPT_AVG16: len += snprintf(buf+len, size-len, "%u", w[0]); if (w[1] && (len < size)) len += snprintf(buf+len, size-len, " Avg: %u", w[1]); break; case RAWFMT_TEMPMINMAX: len += snprintf(buf+len, size-len, "%u -/+: %u/%u", w[0],w[1],w[2]); break; case RAWFMT_RAW48: default: { uint32_t tmp; memcpy(&tmp, w, sizeof(tmp)); /* shows first 4 bytes of raw data as uint32 LE, and the ramaining 2 bytes as uint16 LE */ len += snprintf(buf+len, size-len, "%lu", letoh32(tmp)); if (w[2] && (len < size)) len += snprintf(buf+len, size-len, " %u", w[2]); break; } } /* ignore trailing \0 when truncated */ if (len >= size) len = size-1; /* fill return string; when max. size is exceded: first truncate attribute name, then attribute data and finally attribute id */ slen = snprintf(str, size, "%d ", id); if (slen < size) { /* maximum space disponible for attribute name, including initial space separator */ int name_sz = size - (slen + len); if (name_sz > 1) { len = snprintf(str+slen, name_sz, " %s", ata_smart_get_attr_name(id)); if (len >= name_sz) len = name_sz-1; slen += len; } snprintf(str+slen, size-slen, "%s", buf); } return 1; /* ok */ } static bool ata_smart_dump(void) { int fd; fd = creat("/smart_data.bin", 0666); if(fd >= 0) { write(fd, &smart_data, sizeof(struct ata_smart_values)); close(fd); } fd = creat("/smart_data.txt", 0666); if(fd >= 0) { int i; char buf[128]; for (i = 0; i < NUMBER_ATA_SMART_ATTRIBUTES; i++) { if (ata_smart_attr_to_string( &smart_data.vendor_attributes[i], buf, sizeof(buf))) { write(fd, buf, strlen(buf)); write(fd, "\n", 1); } } close(fd); } return false; } static int ata_smart_callback(int btn, struct gui_synclist *lists) { (void)lists; static bool read_done = false; if (btn == ACTION_STD_CANCEL) { read_done = false; return btn; } /* read S.M.A.R.T. data only on first redraw */ if (!read_done) { int rc; memset(&smart_data, 0, sizeof(struct ata_smart_values)); rc = ata_read_smart(&smart_data); simplelist_set_line_count(0); if (rc == 0) { int i; char buf[SIMPLELIST_MAX_LINELENGTH]; simplelist_addline("Id Name: Current,Worst Raw"); for (i = 0; i < NUMBER_ATA_SMART_ATTRIBUTES; i++) { if (ata_smart_attr_to_string( &smart_data.vendor_attributes[i], buf, sizeof(buf))) { simplelist_addline(buf); } } } else { simplelist_addline("ATA SMART error: %#x", rc); } read_done = true; } if (btn == ACTION_STD_CONTEXT) { splash(0, "Dumping data..."); ata_smart_dump(); splash(HZ, "SMART data dumped"); } return btn; } static bool dbg_ata_smart(void) { struct simplelist_info info; simplelist_info_init(&info, "S.M.A.R.T. Data [CONTEXT to dump]", 1, NULL); info.action_callback = ata_smart_callback; info.hide_selection = true; info.scroll_all = true; return simplelist_show_list(&info); } #endif /* HAVE_ATA_SMART */ #else /* No SD, MMC or ATA */ static int disk_callback(int btn, struct gui_synclist *lists) { (void)lists; struct storage_info info; storage_get_info(0,&info); simplelist_addline("Vendor: %s", info.vendor); simplelist_addline("Model: %s", info.product); simplelist_addline("Firmware: %s", info.revision); simplelist_addline( "Size: %ld MB", info.num_sectors*(info.sector_size/512)/2024); unsigned long free; volume_size( IF_MV(0,) NULL, &free ); simplelist_addline( "Free: %ld MB", free / 1024); simplelist_addline( "Cluster size: %d bytes", volume_get_cluster_size(IF_MV(0))); return btn; } #endif #if (CONFIG_STORAGE & STORAGE_ATA) static bool dbg_identify_info(void) { int fd = creat("/identify_info.bin", 0666); if(fd >= 0) { #ifdef ROCKBOX_LITTLE_ENDIAN ecwrite(fd, ata_get_identify(), SECTOR_SIZE/2, "s", true); #else write(fd, ata_get_identify(), SECTOR_SIZE); #endif close(fd); } return false; } #endif static bool dbg_disk_info(void) { struct simplelist_info info; simplelist_info_init(&info, "Disk Info", 1, NULL); #if (CONFIG_STORAGE & STORAGE_MMC) || (CONFIG_STORAGE & STORAGE_SD) char title[16]; int card = 0; info.callback_data = (void*)&card; info.title = title; #endif info.action_callback = disk_callback; info.hide_selection = true; info.scroll_all = true; return simplelist_show_list(&info); } #endif /* PLATFORM_NATIVE */ #ifdef HAVE_DIRCACHE static int dircache_callback(int btn, struct gui_synclist *lists) { (void)lists; struct dircache_info info; dircache_get_info(&info); if (global_settings.dircache) { switch (btn) { case ACTION_STD_CONTEXT: splash(HZ/2, "Rebuilding cache"); dircache_suspend(); *(int *)lists->data = dircache_resume(); /* Fallthrough */ case ACTION_UNKNOWN: btn = ACTION_NONE; break; #ifdef DIRCACHE_DUMPSTER case ACTION_STD_OK: splash(0, "Dumping cache"); dircache_dump(); btn = ACTION_NONE; break; #endif /* DIRCACHE_DUMPSTER */ case ACTION_STD_CANCEL: if (*(int *)lists->data > 0 && info.status == DIRCACHE_SCANNING) { splash(HZ, str(LANG_SCANNING_DISK)); btn = ACTION_NONE; } break; } } simplelist_set_line_count(0); simplelist_addline("Cache status: %s", info.statusdesc); simplelist_addline("Last size: %lu B", info.last_size); simplelist_addline("Size: %lu B", info.size); unsigned int utilized = info.size ? 1000ull*info.sizeused / info.size : 0; simplelist_addline("Used: %lu B (%u.%u%%)", info.sizeused, utilized / 10, utilized % 10); simplelist_addline("Limit: %lu B", info.size_limit); simplelist_addline("Reserve: %lu/%lu B", info.reserve_used, info.reserve); long ticks = ALIGN_UP(info.build_ticks, HZ / 10); simplelist_addline("Scanning took: %ld.%ld s", ticks / HZ, (ticks*10 / HZ) % 10); simplelist_addline("Entry count: %u", info.entry_count); if (btn == ACTION_NONE) btn = ACTION_REDRAW; return btn; } static bool dbg_dircache_info(void) { struct simplelist_info info; int syncbuild = 0; simplelist_info_init(&info, "Dircache Info", 8, &syncbuild); info.action_callback = dircache_callback; info.hide_selection = true; info.scroll_all = true; return simplelist_show_list(&info); } #endif /* HAVE_DIRCACHE */ #ifdef HAVE_TAGCACHE static int database_callback(int btn, struct gui_synclist *lists) { (void)lists; struct tagcache_stat *stat = tagcache_get_stat(); static bool synced = false; simplelist_set_line_count(0); simplelist_addline("Initialized: %s", stat->initialized ? "Yes" : "No"); simplelist_addline("DB Ready: %s", stat->ready ? "Yes" : "No"); simplelist_addline("RAM Cache: %s", stat->ramcache ? "Yes" : "No"); simplelist_addline("RAM: %d/%d B", stat->ramcache_used, stat->ramcache_allocated); simplelist_addline("Progress: %d%% (%d entries)", stat->progress, stat->processed_entries); simplelist_addline("Curfile: %s", stat->curentry ? stat->curentry : "---"); simplelist_addline("Commit step: %d", stat->commit_step); simplelist_addline("Commit delayed: %s", stat->commit_delayed ? "Yes" : "No"); simplelist_addline("Queue length: %d", stat->queue_length); if (synced) { synced = false; tagcache_screensync_event(); } if (!btn && stat->curentry) { synced = true; return ACTION_REDRAW; } if (btn == ACTION_STD_CANCEL) tagcache_screensync_enable(false); return btn; } static bool dbg_tagcache_info(void) { struct simplelist_info info; simplelist_info_init(&info, "Database Info", 8, NULL); info.action_callback = database_callback; info.hide_selection = true; info.scroll_all = true; /* Don't do nonblock here, must give enough processing time for tagcache thread. */ /* info.timeout = TIMEOUT_NOBLOCK; */ info.timeout = 1; tagcache_screensync_enable(true); return simplelist_show_list(&info); } #endif #if defined CPU_COLDFIRE static bool dbg_save_roms(void) { int fd; int oldmode = system_memory_guard(MEMGUARD_NONE); #if defined(IRIVER_H100_SERIES) fd = creat("/internal_rom_000000-1FFFFF.bin", 0666); #elif defined(IRIVER_H300_SERIES) fd = creat("/internal_rom_000000-3FFFFF.bin", 0666); #elif defined(IAUDIO_X5) || defined(IAUDIO_M5) || defined(IAUDIO_M3) fd = creat("/internal_rom_000000-3FFFFF.bin", 0666); #elif defined(MPIO_HD200) || defined(MPIO_HD300) fd = creat("/internal_rom_000000-1FFFFF.bin", 0666); #endif if(fd >= 0) { write(fd, (void *)0, FLASH_SIZE); close(fd); } system_memory_guard(oldmode); #ifdef HAVE_EEPROM fd = creat("/internal_eeprom.bin", 0666); if (fd >= 0) { int old_irq_level; char buf[EEPROM_SIZE]; int err; old_irq_level = disable_irq_save(); err = eeprom_24cxx_read(0, buf, sizeof buf); restore_irq(old_irq_level); if (err) splashf(HZ*3, "Eeprom read failure (%d)", err); else { write(fd, buf, sizeof buf); } close(fd); } #endif return false; } #elif defined(CPU_PP) && !(CONFIG_STORAGE & STORAGE_SD) static bool dbg_save_roms(void) { int fd = creat("/internal_rom_000000-0FFFFF.bin", 0666); if(fd >= 0) { write(fd, (void *)0x20000000, FLASH_SIZE); close(fd); } return false; } #elif CONFIG_CPU == AS3525v2 || CONFIG_CPU == AS3525 static bool dbg_save_roms(void) { int fd = creat("/rom.bin", 0666); if(fd >= 0) { write(fd, (void *)0x80000000, 0x20000); close(fd); } return false; } #elif CONFIG_CPU == IMX31L bool __dbg_dvfs_dptc(void); static bool dbg_save_roms(void) { int fd = creat("/flash_rom_A0000000-A01FFFFF.bin", 0666); if (fd >= 0) { write(fd, (void*)0xa0000000, FLASH_SIZE); close(fd); } return false; } #elif defined(CPU_TCC780X) static bool dbg_save_roms(void) { int fd = creat("/eeprom_E0000000-E0001FFF.bin", 0666); if (fd >= 0) { write(fd, (void*)0xe0000000, 0x2000); close(fd); } return false; } #elif CONFIG_CPU == RK27XX static bool dbg_save_roms(void) { char buf[0x200]; int fd = creat("/rom.bin", 0666); if(fd < 0) return false; for(int addr = 0; addr < 0x2000; addr += sizeof(buf)) { int old_irq = disable_irq_save(); /* map rom at 0 */ SCU_REMAP = 0; commit_discard_idcache(); /* copy rom */ memcpy((void *)buf, (void *)addr, sizeof(buf)); /* map iram back at 0 */ SCU_REMAP = 0xdeadbeef; commit_discard_idcache(); restore_irq(old_irq); write(fd, (void *)buf, sizeof(buf)); } close(fd); return false; } #endif /* CPU */ #ifndef SIMULATOR #if CONFIG_TUNER #ifdef CONFIG_TUNER_MULTI static int tuner_type = 0; #define IF_TUNER_TYPE(type) if(tuner_type==type) #else #define IF_TUNER_TYPE(type) #endif static int radio_callback(int btn, struct gui_synclist *lists) { (void)lists; if (btn == ACTION_STD_CANCEL) return btn; simplelist_set_line_count(1); #if (CONFIG_TUNER & LV24020LP) simplelist_addline( "CTRL_STAT: %02X", lv24020lp_get(LV24020LP_CTRL_STAT) ); simplelist_addline( "RADIO_STAT: %02X", lv24020lp_get(LV24020LP_REG_STAT) ); simplelist_addline( "MSS_FM: %d kHz", lv24020lp_get(LV24020LP_MSS_FM) ); simplelist_addline( "MSS_IF: %d Hz", lv24020lp_get(LV24020LP_MSS_IF) ); simplelist_addline( "MSS_SD: %d Hz", lv24020lp_get(LV24020LP_MSS_SD) ); simplelist_addline( "if_set: %d Hz", lv24020lp_get(LV24020LP_IF_SET) ); simplelist_addline( "sd_set: %d Hz", lv24020lp_get(LV24020LP_SD_SET) ); #endif /* LV24020LP */ #if (CONFIG_TUNER & TEA5767) struct tea5767_dbg_info nfo; tea5767_dbg_info(&nfo); simplelist_addline("Philips regs:"); simplelist_addline( " Read: %02X %02X %02X %02X %02X", (unsigned)nfo.read_regs[0], (unsigned)nfo.read_regs[1], (unsigned)nfo.read_regs[2], (unsigned)nfo.read_regs[3], (unsigned)nfo.read_regs[4]); simplelist_addline( " Write: %02X %02X %02X %02X %02X", (unsigned)nfo.write_regs[0], (unsigned)nfo.write_regs[1], (unsigned)nfo.write_regs[2], (unsigned)nfo.write_regs[3], (unsigned)nfo.write_regs[4]); #endif /* TEA5767 */ #if (CONFIG_TUNER & SI4700) IF_TUNER_TYPE(SI4700) { struct si4700_dbg_info nfo; si4700_dbg_info(&nfo); simplelist_addline("SI4700 regs:"); for (int i = 0; i < 16; i += 4) { simplelist_addline("%02X: %04X %04X %04X %04X", i, nfo.regs[i], nfo.regs[i+1], nfo.regs[i+2], nfo.regs[i+3]); } } #endif /* SI4700 */ #if (CONFIG_TUNER & RDA5802) IF_TUNER_TYPE(RDA5802) { struct rda5802_dbg_info nfo; rda5802_dbg_info(&nfo); simplelist_addline("RDA5802 regs:"); for (int i = 0; i < 16; i += 4) { simplelist_addline("%02X: %04X %04X %04X %04X", i, nfo.regs[i], nfo.regs[i+1], nfo.regs[i+2], nfo.regs[i+3]); } } #endif /* RDA55802 */ #if (CONFIG_TUNER & STFM1000) IF_TUNER_TYPE(STFM1000) { struct stfm1000_dbg_info nfo; stfm1000_dbg_info(&nfo); simplelist_addline("STFM1000 regs:"); simplelist_addline("chipid: 0x%x", nfo.chipid); } #endif /* STFM1000 */ #if (CONFIG_TUNER & TEA5760) IF_TUNER_TYPE(TEA5760) { struct tea5760_dbg_info nfo; tea5760_dbg_info(&nfo); simplelist_addline("TEA5760 regs:"); for (int i = 0; i < 16; i += 4) { simplelist_addline("%02X: %02X %02X %02X %02X", i, nfo.read_regs[i], nfo.read_regs[i+1], nfo.read_regs[i+2], nfo.read_regs[i+3]); } } #endif /* TEA5760 */ #ifdef HAVE_RDS_CAP { char buf[65*4]; uint16_t pi; time_t seconds; tuner_get_rds_info(RADIO_RDS_NAME, buf, sizeof (buf)); tuner_get_rds_info(RADIO_RDS_PROGRAM_INFO, &pi, sizeof (pi)); simplelist_addline("PI:%04X PS:'%-8s'", pi, buf); tuner_get_rds_info(RADIO_RDS_TEXT, buf, sizeof (buf)); simplelist_addline("RT:%s", buf); tuner_get_rds_info(RADIO_RDS_CURRENT_TIME, &seconds, sizeof (seconds)); struct tm* time = gmtime(&seconds); simplelist_addline( "CT:%4d-%02d-%02d %02d:%02d:%02d", time->tm_year + 1900, time->tm_mon + 1, time->tm_mday, time->tm_hour, time->tm_min, time->tm_sec); } #endif /* HAVE_RDS_CAP */ return ACTION_REDRAW; } static bool dbg_fm_radio(void) { struct simplelist_info info; #ifdef CONFIG_TUNER_MULTI tuner_type = tuner_detect_type(); #endif info.scroll_all = true; simplelist_info_init(&info, "FM Radio", 1, NULL); simplelist_set_line_count(0); simplelist_addline("HW detected: %s", radio_hardware_present() ? "yes" : "no"); info.action_callback = radio_hardware_present()?radio_callback : NULL; info.hide_selection = true; return simplelist_show_list(&info); } #endif /* CONFIG_TUNER */ #endif /* !SIMULATOR */ #if !defined(APPLICATION) extern bool do_screendump_instead_of_usb; static bool dbg_screendump(void) { do_screendump_instead_of_usb = !do_screendump_instead_of_usb; splashf(HZ, "Screendump %sabled", do_screendump_instead_of_usb?"en":"dis"); return false; } #endif /* !APPLICATION */ extern bool write_metadata_log; static bool dbg_metadatalog(void) { write_metadata_log = !write_metadata_log; splashf(HZ, "Metadata log %sabled", write_metadata_log ? "en" : "dis"); return false; } #if defined(CPU_COLDFIRE) static bool dbg_set_memory_guard(void) { static const struct opt_items names[MAXMEMGUARD] = { { "None", -1 }, { "Flash ROM writes", -1 }, { "Zero area (all)", -1 } }; int mode = system_memory_guard(MEMGUARD_KEEP); set_option( "Catch mem accesses", &mode, INT, names, MAXMEMGUARD, NULL); system_memory_guard(mode); return false; } #endif /* defined(CPU_COLDFIRE) */ #if defined(HAVE_EEPROM) && !defined(HAVE_EEPROM_SETTINGS) static bool dbg_write_eeprom(void) { int fd = open("/internal_eeprom.bin", O_RDONLY); if (fd >= 0) { char buf[EEPROM_SIZE]; int rc = read(fd, buf, EEPROM_SIZE); if(rc == EEPROM_SIZE) { int old_irq_level = disable_irq_save(); int err = eeprom_24cxx_write(0, buf, sizeof buf); if (err) splashf(HZ*3, "Eeprom write failure (%d)", err); else splash(HZ*3, "Eeprom written successfully"); restore_irq(old_irq_level); } else { splashf(HZ*3, "File read error (%d)",rc); } close(fd); } else { splash(HZ*3, "Failed to open 'internal_eeprom.bin'"); } return false; } #endif /* defined(HAVE_EEPROM) && !defined(HAVE_EEPROM_SETTINGS) */ #ifdef CPU_BOOST_LOGGING static bool cpu_boost_log(void) { int count = cpu_boost_log_getcount(); char *str = cpu_boost_log_getlog_first(); bool done; lcd_setfont(FONT_SYSFIXED); for (int i = 0; i < count ;) { lcd_clear_display(); for(int j=0; j LCD_WIDTH/SYSFONT_WIDTH) lcd_puts_scroll(0, j, str); else lcd_puts(0, j,str); } str = NULL; } lcd_update(); done = false; while (!done) { switch(get_action(CONTEXT_STD,TIMEOUT_BLOCK)) { case ACTION_STD_OK: case ACTION_STD_PREV: case ACTION_STD_NEXT: done = true; break; case ACTION_STD_CANCEL: i = count; done = true; break; } } } lcd_scroll_stop(); get_action(CONTEXT_STD,TIMEOUT_BLOCK); lcd_setfont(FONT_UI); return false; } static bool cpu_boost_log_dump(void) { int fd; #if CONFIG_RTC struct tm *nowtm; char fname[MAX_PATH]; #endif int count = cpu_boost_log_getcount(); char *str = cpu_boost_log_getlog_first(); splashf(HZ, "Boost Log File Dumped"); /* nothing to print ? */ if(count == 0) return false; #if CONFIG_RTC nowtm = get_time(); snprintf(fname, MAX_PATH, "%s/boostlog_%04d%02d%02d%02d%02d%02d.txt", ROCKBOX_DIR, nowtm->tm_year + 1900, nowtm->tm_mon + 1, nowtm->tm_mday, nowtm->tm_hour, nowtm->tm_min, nowtm->tm_sec); fd = open(fname, O_CREAT|O_WRONLY|O_TRUNC); #else fd = open(ROCKBOX_DIR "/boostlog.txt", O_CREAT|O_WRONLY|O_TRUNC, 0666); #endif if(-1 != fd) { for (int i = 0; i < count; i++) { if (!str) str = cpu_boost_log_getlog_next(); if (str) { fdprintf(fd, "%s\n", str); str = NULL; } } close(fd); return true; } return false; } #endif #if (defined(HAVE_WHEEL_ACCELERATION) && (CONFIG_KEYPAD==IPOD_4G_PAD) \ && !defined(IPOD_MINI) && !defined(SIMULATOR)) extern bool wheel_is_touched; extern int old_wheel_value; extern int new_wheel_value; extern int wheel_delta; extern unsigned int accumulated_wheel_delta; extern unsigned int wheel_velocity; static bool dbg_scrollwheel(void) { lcd_setfont(FONT_SYSFIXED); while (1) { if (action_userabort(HZ/10)) break; lcd_clear_display(); /* show internal variables of scrollwheel driver */ lcd_putsf(0, 0, "wheel touched: %s", (wheel_is_touched) ? "true" : "false"); lcd_putsf(0, 1, "new position: %2d", new_wheel_value); lcd_putsf(0, 2, "old position: %2d", old_wheel_value); lcd_putsf(0, 3, "wheel delta: %2d", wheel_delta); lcd_putsf(0, 4, "accumulated delta: %2d", accumulated_wheel_delta); lcd_putsf(0, 5, "velo [deg/s]: %4d", (int)wheel_velocity); /* show effective accelerated scrollspeed */ lcd_putsf(0, 6, "accel. speed: %4d", button_apply_acceleration((1<<31)|(1<<24)|wheel_velocity) ); lcd_update(); } lcd_setfont(FONT_UI); return false; } #endif static const char* dbg_talk_get_name(int selected_item, void *data, char *buffer, size_t buffer_len) { struct talk_debug_data *talk_data = data; switch(selected_item) { case 0: if (talk_data->status != TALK_STATUS_ERR_NOFILE) snprintf(buffer, buffer_len, "Current voice file: %s", talk_data->voicefile); else buffer = "No voice information available"; break; case 1: if (talk_data->status != TALK_STATUS_OK) snprintf(buffer, buffer_len, "Talk Status: ERR (%i)", talk_data->status); else buffer = "Talk Status: OK"; break; case 2: snprintf(buffer, buffer_len, "Number of (empty) clips in voice file: (%d) %d", talk_data->num_empty_clips, talk_data->num_clips); break; case 3: snprintf(buffer, buffer_len, "Min/Avg/Max size of clips: %d / %d / %d", talk_data->min_clipsize, talk_data->avg_clipsize, talk_data->max_clipsize); break; case 4: snprintf(buffer, buffer_len, "Memory allocated: %ld.%02ld KB", talk_data->memory_allocated / 1024, talk_data->memory_allocated % 1024); break; case 5: snprintf(buffer, buffer_len, "Memory used: %ld.%02ld KB", talk_data->memory_used / 1024, talk_data->memory_used % 1024); break; case 6: snprintf(buffer, buffer_len, "Number of clips in cache: %d", talk_data->cached_clips); break; case 7: snprintf(buffer, buffer_len, "Cache hits / misses: %d / %d", talk_data->cache_hits, talk_data->cache_misses); break; default: buffer = "TODO"; break; } return buffer; } static bool dbg_talk(void) { struct simplelist_info list; struct talk_debug_data data; if (talk_get_debug_data(&data)) simplelist_info_init(&list, "Voice Information:", 8, &data); else simplelist_info_init(&list, "Voice Information:", 2, &data); list.scroll_all = true; list.hide_selection = true; list.timeout = HZ; list.get_name = dbg_talk_get_name; return simplelist_show_list(&list); } #ifdef HAVE_USBSTACK #if defined(ROCKBOX_HAS_LOGF) && defined(USB_ENABLE_SERIAL) static bool toggle_usb_serial(void) { bool enabled = !usb_core_driver_enabled(USB_DRIVER_SERIAL); usb_core_enable_driver(USB_DRIVER_SERIAL, enabled); splashf(HZ, "USB Serial %sabled", enabled ? "en" : "dis"); return false; } #endif #endif #if CONFIG_USBOTG == USBOTG_ISP1583 extern int dbg_usb_num_items(void); extern const char* dbg_usb_item(int selected_item, void *data, char *buffer, size_t buffer_len); static int isp1583_action_callback(int action, struct gui_synclist *lists) { (void)lists; if (action == ACTION_NONE) action = ACTION_REDRAW; return action; } static bool dbg_isp1583(void) { struct simplelist_info isp1583; isp1583.scroll_all = true; simplelist_info_init(&isp1583, "ISP1583", dbg_usb_num_items(), NULL); isp1583.timeout = HZ/100; isp1583.hide_selection = true; isp1583.get_name = dbg_usb_item; isp1583.action_callback = isp1583_action_callback; return simplelist_show_list(&isp1583); } #endif #if defined(CREATIVE_ZVx) && !defined(SIMULATOR) extern int pic_dbg_num_items(void); extern const char* pic_dbg_item(int selected_item, void *data, char *buffer, size_t buffer_len); static int pic_action_callback(int action, struct gui_synclist *lists) { (void)lists; if (action == ACTION_NONE) action = ACTION_REDRAW; return action; } static bool dbg_pic(void) { struct simplelist_info pic; pic.scroll_all = true; simplelist_info_init(&pic, "PIC", pic_dbg_num_items(), NULL); pic.timeout = HZ/100; pic.hide_selection = true; pic.get_name = pic_dbg_item; pic.action_callback = pic_action_callback; return simplelist_show_list(&pic); } #endif static bool dbg_skin_engine(void) { struct simplelist_info info; int i, total = 0; #if defined(HAVE_BACKDROP_IMAGE) int ref_count; char *path; size_t bytes; int path_prefix_len = strlen(ROCKBOX_DIR "/wps/"); #endif simplelist_info_init(&info, "Skin engine usage", 0, NULL); simplelist_set_line_count(0); info.hide_selection = true; FOR_NB_SCREENS(j) { #if NB_SCREENS > 1 simplelist_addline("%s display:", j == 0 ? "Main" : "Remote"); #endif for (i = 0; i < skin_get_num_skins(); i++) { struct skin_stats *stats = skin_get_stats(i, j); if (stats->buflib_handles) { simplelist_addline("Skin ID: %d, %d allocations", i, stats->buflib_handles); simplelist_addline("\tskin: %d bytes", stats->tree_size); simplelist_addline("\tImages: %d bytes", stats->images_size); simplelist_addline("\tTotal: %d bytes", stats->tree_size + stats->images_size); total += stats->tree_size + stats->images_size; } } } simplelist_addline("Skin total usage: %d bytes", total); #if defined(HAVE_BACKDROP_IMAGE) simplelist_addline("Backdrop Images:"); i = 0; while (skin_backdrop_get_debug(i++, &path, &ref_count, &bytes)) { if (ref_count > 0) { if (!strncasecmp(path, ROCKBOX_DIR "/wps/", path_prefix_len)) path += path_prefix_len; simplelist_addline("%s", path); simplelist_addline("\tref_count: %d", ref_count); simplelist_addline("\tsize: %d", bytes); total += bytes; } } simplelist_addline("Total usage: %d bytes", total); #endif return simplelist_show_list(&info); } #if defined(HAVE_BOOTDATA) && !defined(SIMULATOR) static bool dbg_boot_data(void) { unsigned int crc = 0; struct simplelist_info info; info.scroll_all = true; simplelist_info_init(&info, "Boot data", 1, NULL); simplelist_set_line_count(0); crc = crc_32(boot_data.payload, boot_data.length, 0xffffffff); #if defined(HAVE_MULTIBOOT) int boot_volume = 0; if(crc == boot_data.crc) { boot_volume = boot_data.boot_volume; /* boot volume contained in uint8_t payload */ } simplelist_addline("Boot Volume: <%lu>", boot_volume); simplelist_addline(""); #endif simplelist_addline("Bootdata RAW:"); if (crc != boot_data.crc) simplelist_addline("Magic: %.8s", boot_data.magic); simplelist_addline("Length: %lu", boot_data.length); simplelist_addline("CRC: %lx", boot_data.crc); (crc == boot_data.crc) ? simplelist_addline("CRC: OK!") : simplelist_addline("CRC: BAD"); for (unsigned i = 0; i < boot_data.length; i += 4) { simplelist_addline("%02x: %02x %02x %02x %02x", i, boot_data.payload[i], boot_data.payload[i+1], boot_data.payload[i+2], boot_data.payload[i+3]); } info.hide_selection = true; return simplelist_show_list(&info); } #endif /* defined(HAVE_BOOTDATA) && !defined(SIMULATOR) */ /****** The menu *********/ static const struct { unsigned char *desc; /* string or ID */ bool (*function) (void); /* return true if USB was connected */ } menuitems[] = { #if defined(CPU_COLDFIRE) || \ (defined(CPU_PP) && !(CONFIG_STORAGE & STORAGE_SD)) || \ CONFIG_CPU == IMX31L || defined(CPU_TCC780X) || CONFIG_CPU == AS3525v2 || \ CONFIG_CPU == AS3525 || CONFIG_CPU == RK27XX { "Dump ROM contents", dbg_save_roms }, #endif #if defined(CPU_COLDFIRE) || defined(CPU_PP) \ || CONFIG_CPU == S3C2440 || CONFIG_CPU == IMX31L || CONFIG_CPU == AS3525 \ || CONFIG_CPU == DM320 || defined(CPU_S5L870X) || CONFIG_CPU == AS3525v2 \ || CONFIG_CPU == RK27XX || CONFIG_CPU == JZ4760B { "View I/O ports", dbg_ports }, #endif #if (CONFIG_RTC == RTC_PCF50605) && (CONFIG_PLATFORM & PLATFORM_NATIVE) { "View PCF registers", dbg_pcf }, #endif #if defined(HAVE_TSC2100) && (CONFIG_PLATFORM & PLATFORM_NATIVE) { "TSC2100 debug", tsc2100_debug }, #endif #ifdef HAVE_ADJUSTABLE_CPU_FREQ { "CPU frequency", dbg_cpufreq }, #endif #if CONFIG_CPU == IMX31L { "DVFS/DPTC", __dbg_dvfs_dptc }, #endif #if defined(IRIVER_H100_SERIES) && !defined(SIMULATOR) { "S/PDIF analyzer", dbg_spdif }, #endif #if defined(CPU_COLDFIRE) { "Catch mem accesses", dbg_set_memory_guard }, #endif { "View OS stacks", dbg_os }, #ifdef __linux__ { "View CPU stats", dbg_cpuinfo }, #endif #if (CONFIG_BATTERY_MEASURE != 0) && !defined(SIMULATOR) { "View battery", view_battery }, #endif #ifndef APPLICATION { "Screendump", dbg_screendump }, #endif { "Skin Engine RAM usage", dbg_skin_engine }, #if ((CONFIG_PLATFORM & PLATFORM_NATIVE) || defined(SONY_NWZ_LINUX) || defined(HIBY_LINUX) || defined(FIIO_M3K_LINUX)) && !defined(SIMULATOR) { "View HW info", dbg_hw_info }, #endif #if (CONFIG_PLATFORM & PLATFORM_NATIVE) { "View partitions", dbg_partitions }, #endif #if (CONFIG_PLATFORM & PLATFORM_NATIVE) { "View disk info", dbg_disk_info }, #if (CONFIG_STORAGE & STORAGE_ATA) { "Dump ATA identify info", dbg_identify_info}, #ifdef HAVE_ATA_SMART { "View/Dump S.M.A.R.T. data", dbg_ata_smart}, #endif #endif #endif { "Metadata log", dbg_metadatalog }, #ifdef HAVE_DIRCACHE { "View dircache info", dbg_dircache_info }, #endif #ifdef HAVE_TAGCACHE { "View database info", dbg_tagcache_info }, #endif { "View buffering thread", dbg_buffering_thread }, #ifdef PM_DEBUG { "pm histogram", peak_meter_histogram}, #endif /* PM_DEBUG */ { "View buflib allocs", dbg_buflib_allocs }, #ifndef SIMULATOR #if CONFIG_TUNER { "FM Radio", dbg_fm_radio }, #endif #endif #if defined(HAVE_EEPROM) && !defined(HAVE_EEPROM_SETTINGS) { "Write back EEPROM", dbg_write_eeprom }, #endif #if CONFIG_USBOTG == USBOTG_ISP1583 { "View ISP1583 info", dbg_isp1583 }, #endif #if defined(CREATIVE_ZVx) && !defined(SIMULATOR) { "View PIC info", dbg_pic }, #endif #ifdef ROCKBOX_HAS_LOGF {"Show Log File", logfdisplay }, {"Dump Log File", logfdump }, #endif #if defined(HAVE_USBSTACK) #if defined(ROCKBOX_HAS_LOGF) && defined(USB_ENABLE_SERIAL) {"USB Serial driver (logf)", toggle_usb_serial }, #endif #endif /* HAVE_USBSTACK */ #ifdef CPU_BOOST_LOGGING {"Show cpu_boost log",cpu_boost_log}, {"Dump cpu_boost log",cpu_boost_log_dump}, #endif #if (defined(HAVE_WHEEL_ACCELERATION) && (CONFIG_KEYPAD==IPOD_4G_PAD) \ && !defined(IPOD_MINI) && !defined(SIMULATOR)) {"Debug scrollwheel", dbg_scrollwheel }, #endif {"Talk engine stats", dbg_talk }, #if defined(HAVE_BOOTDATA) && !defined(SIMULATOR) {"Boot data", dbg_boot_data }, #endif }; static int menu_action_callback(int btn, struct gui_synclist *lists) { int selection = gui_synclist_get_sel_pos(lists); if (btn == ACTION_STD_OK) { FOR_NB_SCREENS(i) viewportmanager_theme_enable(i, false, NULL); menuitems[selection].function(); btn = ACTION_REDRAW; FOR_NB_SCREENS(i) viewportmanager_theme_undo(i, false); } else if (btn == ACTION_STD_CONTEXT) { MENUITEM_STRINGLIST(menu_items, "Debug Menu", NULL, ID2P(LANG_ADD_TO_FAVES)); if (do_menu(&menu_items, NULL, NULL, false) == 0) shortcuts_add(SHORTCUT_DEBUGITEM, menuitems[selection].desc); return ACTION_STD_CANCEL; } return btn; } static const char* menu_get_name(int item, void * data, char *buffer, size_t buffer_len) { (void)data; (void)buffer; (void)buffer_len; return menuitems[item].desc; } static int menu_get_talk(int item, void *data) { (void)data; if (global_settings.talk_menu && menuitems[item].desc) { talk_number(item + 1, true); talk_id(VOICE_PAUSE, true); #if 0 /* no debug items currently have lang ids */ long id = P2ID((const unsigned char *)(menuitems[item].desc)); if(id>=0) talk_id(id, true); else #endif talk_spell(menuitems[item].desc, true); } return 0; } int debug_menu(void) { struct simplelist_info info; simplelist_info_init(&info, "Debug Menu", ARRAYLEN(menuitems), NULL); info.action_callback = menu_action_callback; info.get_name = menu_get_name; info.get_talk = menu_get_talk; return (simplelist_show_list(&info)) ? 1 : 0; } bool run_debug_screen(char* screen) { for (unsigned i=0; i