/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2009 by Michael Sparmann * * 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 "panic.h" #include "system.h" #include "kernel.h" #include "cpu.h" #include "inttypes.h" #include "nand-target.h" #include #include #include #include "led.h" #define NAND_CMD_READ 0x00 #define NAND_CMD_PROGCNFRM 0x10 #define NAND_CMD_READ2 0x30 #define NAND_CMD_BLOCKERASE 0x60 #define NAND_CMD_GET_STATUS 0x70 #define NAND_CMD_PROGRAM 0x80 #define NAND_CMD_ERASECNFRM 0xD0 #define NAND_CMD_RESET 0xFF #define NAND_STATUS_READY 0x40 #define NAND_DEVICEINFOTABLE_ENTRIES 33 static const struct nand_device_info_type nand_deviceinfotable[] = { {0x1580F1EC, 1024, 968, 0x40, 6, 2, 1, 2, 1}, {0x1580DAEC, 2048, 1936, 0x40, 6, 2, 1, 2, 1}, {0x15C1DAEC, 2048, 1936, 0x40, 6, 2, 1, 2, 1}, {0x1510DCEC, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0x95C1DCEC, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0x2514DCEC, 2048, 1936, 0x80, 7, 2, 1, 2, 1}, {0x2514D3EC, 4096, 3872, 0x80, 7, 2, 1, 2, 1}, {0x2555D3EC, 4096, 3872, 0x80, 7, 2, 1, 2, 1}, {0x2555D5EC, 8192, 7744, 0x80, 7, 2, 1, 2, 1}, {0x2585D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2}, {0x9580DCAD, 4096, 3872, 0x40, 6, 3, 2, 3, 2}, {0xA514D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2}, {0xA550D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2}, {0xA560D5AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2}, {0xA555D5AD, 8192, 7744, 0x80, 7, 3, 2, 3, 2}, {0xA585D598, 8320, 7744, 0x80, 7, 3, 1, 2, 1}, {0xA584D398, 4160, 3872, 0x80, 7, 3, 1, 2, 1}, {0x95D1D32C, 8192, 7744, 0x40, 6, 2, 1, 2, 1}, {0x1580DC2C, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0x15C1D32C, 8192, 7744, 0x40, 6, 2, 1, 2, 1}, {0x9590DC2C, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0xA594D32C, 4096, 3872, 0x80, 7, 2, 1, 2, 1}, {0x2584DC2C, 2048, 1936, 0x80, 7, 2, 1, 2, 1}, {0xA5D5D52C, 8192, 7744, 0x80, 7, 3, 2, 2, 1}, {0x95D1D389, 8192, 7744, 0x40, 6, 2, 1, 2, 1}, {0x1580DC89, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0x15C1D389, 8192, 7744, 0x40, 6, 2, 1, 2, 1}, {0x9590DC89, 4096, 3872, 0x40, 6, 2, 1, 2, 1}, {0xA594D389, 4096, 3872, 0x80, 7, 2, 1, 2, 1}, {0x2584DC89, 2048, 1936, 0x80, 7, 2, 1, 2, 1}, {0xA5D5D589, 8192, 7744, 0x80, 7, 2, 1, 2, 1}, {0xA514D320, 4096, 3872, 0x80, 7, 2, 1, 2, 1}, {0xA555D520, 8192, 3872, 0x80, 7, 2, 1, 2, 1} }; uint8_t nand_tunk1[4]; uint8_t nand_twp[4]; uint8_t nand_tunk2[4]; uint8_t nand_tunk3[4]; uint32_t nand_type[4]; int nand_powered = 0; long nand_last_activity_value = -1; static long nand_stack[32]; static struct mutex nand_mtx; static struct wakeup nand_wakeup; static struct mutex ecc_mtx; static struct wakeup ecc_wakeup; static uint8_t nand_data[0x800] __attribute__((aligned(16))); static uint8_t nand_ctrl[0x200] __attribute__((aligned(16))); static uint8_t nand_spare[0x40] __attribute__((aligned(16))); static uint8_t nand_ecc[0x30] __attribute__((aligned(16))); uint32_t nand_unlock(uint32_t rc) { led(false); nand_last_activity_value = current_tick; mutex_unlock(&nand_mtx); return rc; } uint32_t ecc_unlock(uint32_t rc) { mutex_unlock(&ecc_mtx); return rc; } uint32_t nand_timeout(long timeout) { if (TIME_AFTER(current_tick, timeout)) return 1; else { yield(); return 0; } } uint32_t nand_wait_rbbdone(void) { long timeout = current_tick + HZ / 50; while (!(FMCSTAT & FMCSTAT_RBBDONE)) if (nand_timeout(timeout)) return 1; FMCSTAT = FMCSTAT_RBBDONE; return 0; } uint32_t nand_wait_cmddone(void) { long timeout = current_tick + HZ / 50; while (!(FMCSTAT & FMCSTAT_CMDDONE)) if (nand_timeout(timeout)) return 1; FMCSTAT = FMCSTAT_CMDDONE; return 0; } uint32_t nand_wait_addrdone(void) { long timeout = current_tick + HZ / 50; while (!(FMCSTAT & FMCSTAT_ADDRDONE)) if (nand_timeout(timeout)) return 1; FMCSTAT = FMCSTAT_ADDRDONE; return 0; } uint32_t nand_wait_chip_ready(uint32_t bank) { long timeout = current_tick + HZ / 50; while (!(FMCSTAT & (FMCSTAT_BANK0READY << bank))) if (nand_timeout(timeout)) return 1; FMCSTAT = (FMCSTAT_BANK0READY << bank); return 0; } void nand_set_fmctrl0(uint32_t bank, uint32_t flags) { FMCTRL0 = (nand_tunk1[bank] << 16) | (nand_twp[bank] << 12) | (1 << 11) | 1 | (1 << (bank + 1)) | flags; } uint32_t nand_send_cmd(uint32_t cmd) { FMCMD = cmd; return nand_wait_rbbdone(); } uint32_t nand_send_address(uint32_t page, uint32_t offset) { FMANUM = 4; FMADDR0 = (page << 16) | offset; FMADDR1 = (page >> 16) & 0xFF; FMCTRL1 = FMCTRL1_DOTRANSADDR; return nand_wait_cmddone(); } uint32_t nand_reset(uint32_t bank) { nand_set_fmctrl0(bank, 0); if (nand_send_cmd(NAND_CMD_RESET)) return 1; if (nand_wait_chip_ready(bank)) return 1; FMCTRL1 = FMCTRL1_CLEARRFIFO | FMCTRL1_CLEARWFIFO; sleep(0); return 0; } uint32_t nand_wait_status_ready(uint32_t bank) { long timeout = current_tick + HZ / 50; nand_set_fmctrl0(bank, 0); if ((FMCSTAT & (FMCSTAT_BANK0READY << bank))) FMCSTAT = (FMCSTAT_BANK0READY << bank); FMCTRL1 = FMCTRL1_CLEARRFIFO; if (nand_send_cmd(NAND_CMD_GET_STATUS)) return 1; while (1) { if (nand_timeout(timeout)) return 1; FMDNUM = 0; FMCTRL1 = FMCTRL1_DOREADDATA; if (nand_wait_addrdone()) return 1; if ((FMFIFO & NAND_STATUS_READY)) break; FMCTRL1 = FMCTRL1_CLEARRFIFO; } FMCTRL1 = FMCTRL1_CLEARRFIFO; return nand_send_cmd(NAND_CMD_READ); } void nand_transfer_data_start(uint32_t bank, uint32_t direction, void* buffer, uint32_t size) { nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA); FMDNUM = size - 1; FMCTRL1 = FMCTRL1_DOREADDATA << direction; DMACON3 = (2 << DMACON_DEVICE_SHIFT) | (direction << DMACON_DIRECTION_SHIFT) | (2 << DMACON_DATA_SIZE_SHIFT) | (3 << DMACON_BURST_LEN_SHIFT); while ((DMAALLST & DMAALLST_CHAN3_MASK)) DMACOM3 = DMACOM_CLEARBOTHDONE; DMABASE3 = (uint32_t)buffer; DMATCNT3 = (size >> 4) - 1; clean_dcache(); DMACOM3 = 4; } uint32_t nand_transfer_data_collect(uint32_t direction) { long timeout = current_tick + HZ / 50; while ((DMAALLST & DMAALLST_DMABUSY3)) if (nand_timeout(timeout)) return 1; if (!direction) invalidate_dcache(); if (nand_wait_addrdone()) return 1; if (!direction) FMCTRL1 = FMCTRL1_CLEARRFIFO | FMCTRL1_CLEARWFIFO; else FMCTRL1 = FMCTRL1_CLEARRFIFO; return 0; } uint32_t nand_transfer_data(uint32_t bank, uint32_t direction, void* buffer, uint32_t size) { nand_transfer_data_start(bank, direction, buffer, size); uint32_t rc = nand_transfer_data_collect(direction); return rc; } void ecc_start(uint32_t size, void* databuffer, void* sparebuffer, uint32_t type) { mutex_lock(&ecc_mtx); ECC_INT_CLR = 1; SRCPND = INTMSK_ECC; ECC_UNK1 = size; ECC_DATA_PTR = (uint32_t)databuffer; ECC_SPARE_PTR = (uint32_t)sparebuffer; clean_dcache(); ECC_CTRL = type; } uint32_t ecc_collect(void) { long timeout = current_tick + HZ / 50; while (!(SRCPND & INTMSK_ECC)) if (nand_timeout(timeout)) return ecc_unlock(1); invalidate_dcache(); ECC_INT_CLR = 1; SRCPND = INTMSK_ECC; return ecc_unlock(ECC_RESULT); } uint32_t ecc_decode(uint32_t size, void* databuffer, void* sparebuffer) { ecc_start(size, databuffer, sparebuffer, ECCCTRL_STARTDECODING); uint32_t rc = ecc_collect(); return rc; } uint32_t ecc_encode(uint32_t size, void* databuffer, void* sparebuffer) { ecc_start(size, databuffer, sparebuffer, ECCCTRL_STARTENCODING); ecc_collect(); return 0; } uint32_t nand_check_empty(uint8_t* buffer) { uint32_t i, count; count = 0; for (i = 0; i < 0x40; i++) if (buffer[i] != 0xFF) count++; if (count < 2) return 1; return 0; } uint32_t nand_get_chip_type(uint32_t bank) { mutex_lock(&nand_mtx); uint32_t result; if (nand_reset(bank)) return nand_unlock(0xFFFFFFFF); if (nand_send_cmd(0x90)) return nand_unlock(0xFFFFFFFF); FMANUM = 0; FMADDR0 = 0; FMCTRL1 = FMCTRL1_DOTRANSADDR; if (nand_wait_cmddone()) return nand_unlock(0xFFFFFFFF); FMDNUM = 4; FMCTRL1 = FMCTRL1_DOREADDATA; if (nand_wait_addrdone()) return nand_unlock(0xFFFFFFFF); result = FMFIFO; FMCTRL1 = FMCTRL1_CLEARRFIFO; return nand_unlock(result); } void nand_set_active(void) { nand_last_activity_value = current_tick; } long nand_last_activity(void) { return nand_last_activity_value; } void nand_power_up(void) { uint32_t i; mutex_lock(&nand_mtx); nand_last_activity_value = current_tick; PWRCONEXT &= ~0x40; PWRCON &= ~0x100000; PCON2 = 0x33333333; PDAT2 = 0; PCON3 = 0x11113333; PDAT3 = 0; PCON4 = 0x33333333; PDAT4 = 0; PCON5 = (PCON5 & ~0xF) | 3; PUNK5 = 1; pmu_ldo_set_voltage(4, 0x15); pmu_ldo_power_on(4); sleep(HZ / 20); nand_last_activity_value = current_tick; for (i = 0; i < 4; i++) { if(nand_type[i] != 0xFFFFFFFF) { if(nand_reset(i)) panicf("nand_power_up: nand_reset(bank=%d) failed.",(unsigned int)i); } } nand_powered = 1; nand_last_activity_value = current_tick; mutex_unlock(&nand_mtx); } void nand_power_down(void) { if (!nand_powered) return; mutex_lock(&nand_mtx); pmu_ldo_power_off(4); PCON2 = 0x11111111; PDAT2 = 0; PCON3 = 0x11111111; PDAT3 = 0; PCON4 = 0x11111111; PDAT4 = 0; PCON5 = (PCON5 & ~0xF) | 1; PUNK5 = 1; PWRCONEXT |= 0x40; PWRCON |= 0x100000; nand_powered = 0; mutex_unlock(&nand_mtx); } uint32_t nand_read_page(uint32_t bank, uint32_t page, void* databuffer, void* sparebuffer, uint32_t doecc, uint32_t checkempty) { uint8_t* data = nand_data; uint8_t* spare = nand_spare; if (databuffer && !((uint32_t)databuffer & 0xf)) data = (uint8_t*)databuffer; if (sparebuffer && !((uint32_t)sparebuffer & 0xf)) spare = (uint8_t*)sparebuffer; mutex_lock(&nand_mtx); nand_last_activity_value = current_tick; led(true); if (!nand_powered) nand_power_up(); uint32_t rc, eccresult; nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA); if (nand_send_cmd(NAND_CMD_READ)) return nand_unlock(1); if (nand_send_address(page, databuffer ? 0 : 0x800)) return nand_unlock(1); if (nand_send_cmd(NAND_CMD_READ2)) return nand_unlock(1); if (nand_wait_status_ready(bank)) return nand_unlock(1); if (databuffer) if (nand_transfer_data(bank, 0, data, 0x800)) return nand_unlock(1); rc = 0; if (!doecc) { if (databuffer && data != databuffer) memcpy(databuffer, data, 0x800); if (sparebuffer) { if (nand_transfer_data(bank, 0, spare, 0x40)) return nand_unlock(1); if (sparebuffer && spare != sparebuffer) memcpy(sparebuffer, spare, 0x800); if (checkempty) rc = nand_check_empty((uint8_t*)sparebuffer) << 1; } return nand_unlock(rc); } if (nand_transfer_data(bank, 0, spare, 0x40)) return nand_unlock(1); if (databuffer) { memcpy(nand_ecc, &spare[0xC], 0x28); rc |= (ecc_decode(3, data, nand_ecc) & 0xF) << 4; if (data != databuffer) memcpy(databuffer, data, 0x800); } memset(nand_ctrl, 0xFF, 0x200); memcpy(nand_ctrl, spare, 0xC); memcpy(nand_ecc, &spare[0x34], 0xC); eccresult = ecc_decode(0, nand_ctrl, nand_ecc); rc |= (eccresult & 0xF) << 8; if (sparebuffer) { if (spare != sparebuffer) memcpy(sparebuffer, spare, 0x40); if (eccresult & 1) memset(sparebuffer, 0xFF, 0xC); else memcpy(sparebuffer, nand_ctrl, 0xC); } if (checkempty) rc |= nand_check_empty(spare) << 1; return nand_unlock(rc); } uint32_t nand_write_page(uint32_t bank, uint32_t page, void* databuffer, void* sparebuffer, uint32_t doecc) { uint8_t* data = nand_data; uint8_t* spare = nand_spare; if (databuffer && !((uint32_t)databuffer & 0xf)) data = (uint8_t*)databuffer; if (sparebuffer && !((uint32_t)sparebuffer & 0xf)) spare = (uint8_t*)sparebuffer; mutex_lock(&nand_mtx); nand_last_activity_value = current_tick; led(true); if (!nand_powered) nand_power_up(); if (sparebuffer) { if (spare != sparebuffer) memcpy(spare, sparebuffer, 0x40); } else memset(spare, 0xFF, 0x40); if (doecc) { if (databuffer && data != databuffer) memcpy(data, databuffer, 0x800); if (ecc_encode(3, data, nand_ecc)) return nand_unlock(1); memcpy(&spare[0xC], nand_ecc, 0x28); memset(nand_ctrl, 0xFF, 0x200); memcpy(nand_ctrl, spare, 0xC); if (ecc_encode(0, nand_ctrl, nand_ecc)) return nand_unlock(1); memcpy(&spare[0x34], nand_ecc, 0xC); } nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA); if (nand_send_cmd(NAND_CMD_PROGRAM)) return nand_unlock(1); if (nand_send_address(page, databuffer ? 0 : 0x800)) return nand_unlock(1); if (databuffer) if (nand_transfer_data(bank, 1, data, 0x800)) return nand_unlock(1); if (sparebuffer || doecc) if (nand_transfer_data(bank, 1, spare, 0x40)) return nand_unlock(1); if (nand_send_cmd(NAND_CMD_PROGCNFRM)) return nand_unlock(1); return nand_unlock(nand_wait_status_ready(bank)); } uint32_t nand_block_erase(uint32_t bank, uint32_t page) { mutex_lock(&nand_mtx); nand_last_activity_value = current_tick; led(true); if (!nand_powered) nand_power_up(); nand_set_fmctrl0(bank, 0); if (nand_send_cmd(NAND_CMD_BLOCKERASE)) return nand_unlock(1); FMANUM = 2; FMADDR0 = page; FMCTRL1 = FMCTRL1_DOTRANSADDR; if (nand_wait_cmddone()) return nand_unlock(1); if (nand_send_cmd(NAND_CMD_ERASECNFRM)) return nand_unlock(1); if (nand_wait_status_ready(bank)) return nand_unlock(1); return nand_unlock(0); } uint32_t nand_read_page_fast(uint32_t page, void* databuffer, void* sparebuffer, uint32_t doecc, uint32_t checkempty) { uint32_t i, rc = 0; if (((uint32_t)databuffer & 0xf) || ((uint32_t)sparebuffer & 0xf) || !databuffer || !sparebuffer || !doecc) { for (i = 0; i < 4; i++) { if (nand_type[i] == 0xFFFFFFFF) continue; void* databuf = (void*)0; void* sparebuf = (void*)0; if (databuffer) databuf = (void*)((uint32_t)databuffer + 0x800 * i); if (sparebuffer) sparebuf = (void*)((uint32_t)sparebuffer + 0x40 * i); uint32_t ret = nand_read_page(i, page, databuf, sparebuf, doecc, checkempty); if (ret & 1) rc |= 1 << (i << 2); if (ret & 2) rc |= 2 << (i << 2); if (ret & 0x10) rc |= 4 << (i << 2); if (ret & 0x100) rc |= 8 << (i << 2); } return rc; } mutex_lock(&nand_mtx); nand_last_activity_value = current_tick; led(true); if (!nand_powered) nand_power_up(); for (i = 0; i < 4; i++) { if (nand_type[i] == 0xFFFFFFFF) continue; nand_set_fmctrl0(i, FMCTRL0_ENABLEDMA); if (nand_send_cmd(NAND_CMD_READ)) { rc |= 1 << (i << 2); continue; } if (nand_send_address(page, databuffer ? 0 : 0x800)) { rc |= 1 << (i << 2); continue; } if (nand_send_cmd(NAND_CMD_READ2)) { rc |= 1 << (i << 2); continue; } } uint8_t status[4]; for (i = 0; i < 4; i++) status[i] = (nand_type[i] == 0xFFFFFFFF); if (!status[0]) if (nand_wait_status_ready(0)) status[0] = 1; if (!status[0]) if (nand_transfer_data(0, 0, databuffer, 0x800)) status[0] = 1; if (!status[0]) if (nand_transfer_data(0, 0, sparebuffer, 0x40)) status[0] = 1; for (i = 1; i < 4; i++) { if (!status[i]) if (nand_wait_status_ready(i)) status[i] = 1; if (!status[i]) nand_transfer_data_start(i, 0, (void*)((uint32_t)databuffer + 0x800 * i), 0x800); if (!status[i - 1]) { memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0xC), 0x28); ecc_start(3, (void*)((uint32_t)databuffer + 0x800 * (i - 1)), nand_ecc, ECCCTRL_STARTDECODING); } if (!status[i]) if (nand_transfer_data_collect(0)) status[i] = 1; if (!status[i]) nand_transfer_data_start(i, 0, (void*)((uint32_t)sparebuffer + 0x40 * i), 0x40); if (!status[i - 1]) if (ecc_collect() & 1) status[i - 1] = 4; if (!status[i - 1]) { memset(nand_ctrl, 0xFF, 0x200); memcpy(nand_ctrl, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xC); memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0x34), 0xC); ecc_start(0, nand_ctrl, nand_ecc, ECCCTRL_STARTDECODING); } if (!status[i]) if (nand_transfer_data_collect(0)) status[i] = 1; if (!status[i - 1]) { if (ecc_collect() & 1) { status[i - 1] |= 8; memset((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xFF, 0xC); } else memcpy((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), nand_ctrl, 0xC); if (checkempty) status[i - 1] |= nand_check_empty((void*)((uint32_t)sparebuffer + 0x40 * (i - 1))) << 1; } } if (!status[i - 1]) { memcpy(nand_ecc,(void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0xC), 0x28); if (ecc_decode(3, (void*)((uint32_t)databuffer + 0x800 * (i - 1)), nand_ecc) & 1) status[i - 1] = 4; } if (!status[i - 1]) { memset(nand_ctrl, 0xFF, 0x200); memcpy(nand_ctrl, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xC); memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0x34), 0xC); if (ecc_decode(0, nand_ctrl, nand_ecc) & 1) { status[i - 1] |= 8; memset((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xFF, 0xC); } else memcpy((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), nand_ctrl, 0xC); if (checkempty) status[i - 1] |= nand_check_empty((void*)((uint32_t)sparebuffer + 0x40 * (i - 1))) << 1; } for (i = 0; i < 4; i++) if (nand_type[i] != 0xFFFFFFFF) rc |= status[i] << (i << 2); return nand_unlock(rc); } const struct nand_device_info_type* nand_get_device_type(uint32_t bank) { if (nand_type[bank] == 0xFFFFFFFF) return (struct nand_device_info_type*)0; return &nand_deviceinfotable[nand_type[bank]]; } static void nand_thread(void) { while (1) { if (TIME_AFTER(current_tick, nand_last_activity_value + HZ / 5) && nand_powered) nand_power_down(); sleep(HZ / 10); } } uint32_t nand_device_init(void) { mutex_init(&nand_mtx); wakeup_init(&nand_wakeup); mutex_init(&ecc_mtx); wakeup_init(&ecc_wakeup); uint32_t type; uint32_t i, j; /* Assume there are 0 banks, to prevent nand_power_up from talking with them yet. */ for(i = 0; i < 4; i++) nand_type[i] = 0xFFFFFFFF; nand_power_up(); /* Now that the flash is powered on, detect how many banks we really have and initialize them. */ for (i = 0; i < 4; i++) { nand_tunk1[i] = 7; nand_twp[i] = 7; nand_tunk2[i] = 7; nand_tunk3[i] = 7; type = nand_get_chip_type(i); if (type == 0xFFFFFFFF) continue; for (j = 0; ; j++) { if (j == ARRAYLEN(nand_deviceinfotable)) break; else if (nand_deviceinfotable[j].id == type) { nand_type[i] = j; break; } } nand_tunk1[i] = nand_deviceinfotable[nand_type[i]].tunk1; nand_twp[i] = nand_deviceinfotable[nand_type[i]].twp; nand_tunk2[i] = nand_deviceinfotable[nand_type[i]].tunk2; nand_tunk3[i] = nand_deviceinfotable[nand_type[i]].tunk3; } if (nand_type[0] == 0xFFFFFFFF) return 1; nand_last_activity_value = current_tick; create_thread(nand_thread, nand_stack, sizeof(nand_stack), 0, "nand" IF_PRIO(, PRIORITY_USER_INTERFACE) IF_COP(, CPU)); return 0; }