mirror of
https://github.com/AsahiLinux/u-boot
synced 2024-11-18 10:48:51 +00:00
e6f6f9e648
Move this uncommon header out of the common header. Signed-off-by: Simon Glass <sjg@chromium.org>
308 lines
7.6 KiB
C
308 lines
7.6 KiB
C
// SPDX-License-Identifier: GPL-2.0+
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/*
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* NAND boot for Freescale Integrated Flash Controller, NAND FCM
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*
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* Copyright 2011 Freescale Semiconductor, Inc.
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* Author: Dipen Dudhat <dipen.dudhat@freescale.com>
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*/
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#include <common.h>
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#include <cpu_func.h>
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#include <asm/io.h>
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#include <fsl_ifc.h>
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#include <part.h>
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#include <linux/mtd/rawnand.h>
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#ifdef CONFIG_CHAIN_OF_TRUST
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#include <fsl_validate.h>
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#endif
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static inline int is_blank(uchar *addr, int page_size)
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{
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int i;
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for (i = 0; i < page_size; i++) {
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if (__raw_readb(&addr[i]) != 0xff)
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return 0;
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}
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/*
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* For the SPL, don't worry about uncorrectable errors
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* where the main area is all FFs but shouldn't be.
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*/
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return 1;
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}
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/* returns nonzero if entire page is blank */
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static inline int check_read_ecc(uchar *buf, u32 *eccstat,
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unsigned int bufnum, int page_size)
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{
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u32 reg = eccstat[bufnum / 4];
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int errors = (reg >> ((3 - bufnum % 4) * 8)) & 0xf;
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if (errors == 0xf) { /* uncorrectable */
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/* Blank pages fail hw ECC checks */
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if (is_blank(buf, page_size))
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return 1;
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puts("ecc error\n");
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for (;;)
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;
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}
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return 0;
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}
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static inline struct fsl_ifc_runtime *runtime_regs_address(void)
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{
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struct fsl_ifc regs = {(void *)CONFIG_SYS_IFC_ADDR, NULL};
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int ver = 0;
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ver = ifc_in32(®s.gregs->ifc_rev);
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if (ver >= FSL_IFC_V2_0_0)
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regs.rregs = (void *)CONFIG_SYS_IFC_ADDR + IFC_RREGS_64KOFFSET;
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else
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regs.rregs = (void *)CONFIG_SYS_IFC_ADDR + IFC_RREGS_4KOFFSET;
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return regs.rregs;
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}
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static inline void nand_wait(uchar *buf, int bufnum, int page_size)
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{
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struct fsl_ifc_runtime *ifc = runtime_regs_address();
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u32 status;
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u32 eccstat[8];
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int bufperpage = page_size / 512;
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int bufnum_end, i;
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bufnum *= bufperpage;
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bufnum_end = bufnum + bufperpage - 1;
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do {
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status = ifc_in32(&ifc->ifc_nand.nand_evter_stat);
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} while (!(status & IFC_NAND_EVTER_STAT_OPC));
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if (status & IFC_NAND_EVTER_STAT_FTOER) {
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puts("flash time out error\n");
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for (;;)
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;
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}
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for (i = bufnum / 4; i <= bufnum_end / 4; i++)
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eccstat[i] = ifc_in32(&ifc->ifc_nand.nand_eccstat[i]);
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for (i = bufnum; i <= bufnum_end; i++) {
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if (check_read_ecc(buf, eccstat, i, page_size))
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break;
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}
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ifc_out32(&ifc->ifc_nand.nand_evter_stat, status);
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}
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static inline int bad_block(uchar *marker, int port_size)
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{
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if (port_size == 8)
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return __raw_readb(marker) != 0xff;
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else
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return __raw_readw((u16 *)marker) != 0xffff;
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}
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int nand_spl_load_image(uint32_t offs, unsigned int uboot_size, void *vdst)
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{
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struct fsl_ifc_fcm *gregs = (void *)CONFIG_SYS_IFC_ADDR;
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struct fsl_ifc_runtime *ifc = NULL;
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uchar *buf = (uchar *)CONFIG_SYS_NAND_BASE;
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int page_size;
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int port_size;
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int pages_per_blk;
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int blk_size;
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int bad_marker = 0;
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int bufnum_mask, bufnum, ver = 0;
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int csor, cspr;
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int pos = 0;
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int j = 0;
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int sram_addr;
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int pg_no;
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uchar *dst = vdst;
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ifc = runtime_regs_address();
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/* Get NAND Flash configuration */
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csor = CONFIG_SYS_NAND_CSOR;
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cspr = CONFIG_SYS_NAND_CSPR;
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port_size = (cspr & CSPR_PORT_SIZE_16) ? 16 : 8;
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if ((csor & CSOR_NAND_PGS_MASK) == CSOR_NAND_PGS_8K) {
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page_size = 8192;
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bufnum_mask = 0x0;
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} else if ((csor & CSOR_NAND_PGS_MASK) == CSOR_NAND_PGS_4K) {
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page_size = 4096;
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bufnum_mask = 0x1;
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} else if ((csor & CSOR_NAND_PGS_MASK) == CSOR_NAND_PGS_2K) {
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page_size = 2048;
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bufnum_mask = 0x3;
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} else {
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page_size = 512;
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bufnum_mask = 0xf;
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if (port_size == 8)
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bad_marker = 5;
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}
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ver = ifc_in32(&gregs->ifc_rev);
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if (ver >= FSL_IFC_V2_0_0)
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bufnum_mask = (bufnum_mask * 2) + 1;
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pages_per_blk =
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32 << ((csor & CSOR_NAND_PB_MASK) >> CSOR_NAND_PB_SHIFT);
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blk_size = pages_per_blk * page_size;
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/* Open Full SRAM mapping for spare are access */
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ifc_out32(&ifc->ifc_nand.ncfgr, 0x0);
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/* Clear Boot events */
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ifc_out32(&ifc->ifc_nand.nand_evter_stat, 0xffffffff);
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/* Program FIR/FCR for Large/Small page */
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if (page_size > 512) {
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ifc_out32(&ifc->ifc_nand.nand_fir0,
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(IFC_FIR_OP_CW0 << IFC_NAND_FIR0_OP0_SHIFT) |
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(IFC_FIR_OP_CA0 << IFC_NAND_FIR0_OP1_SHIFT) |
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(IFC_FIR_OP_RA0 << IFC_NAND_FIR0_OP2_SHIFT) |
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(IFC_FIR_OP_CMD1 << IFC_NAND_FIR0_OP3_SHIFT) |
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(IFC_FIR_OP_BTRD << IFC_NAND_FIR0_OP4_SHIFT));
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ifc_out32(&ifc->ifc_nand.nand_fir1, 0x0);
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ifc_out32(&ifc->ifc_nand.nand_fcr0,
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(NAND_CMD_READ0 << IFC_NAND_FCR0_CMD0_SHIFT) |
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(NAND_CMD_READSTART << IFC_NAND_FCR0_CMD1_SHIFT));
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} else {
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ifc_out32(&ifc->ifc_nand.nand_fir0,
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(IFC_FIR_OP_CW0 << IFC_NAND_FIR0_OP0_SHIFT) |
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(IFC_FIR_OP_CA0 << IFC_NAND_FIR0_OP1_SHIFT) |
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(IFC_FIR_OP_RA0 << IFC_NAND_FIR0_OP2_SHIFT) |
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(IFC_FIR_OP_BTRD << IFC_NAND_FIR0_OP3_SHIFT));
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ifc_out32(&ifc->ifc_nand.nand_fir1, 0x0);
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ifc_out32(&ifc->ifc_nand.nand_fcr0,
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NAND_CMD_READ0 << IFC_NAND_FCR0_CMD0_SHIFT);
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}
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/* Program FBCR = 0 for full page read */
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ifc_out32(&ifc->ifc_nand.nand_fbcr, 0);
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/* Read and copy u-boot on SDRAM from NAND device, In parallel
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* check for Bad block if found skip it and read continue to
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* next Block
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*/
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while (pos < uboot_size) {
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int i = 0;
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do {
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pg_no = offs / page_size;
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bufnum = pg_no & bufnum_mask;
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sram_addr = bufnum * page_size * 2;
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ifc_out32(&ifc->ifc_nand.row0, pg_no);
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ifc_out32(&ifc->ifc_nand.col0, 0);
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/* start read */
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ifc_out32(&ifc->ifc_nand.nandseq_strt,
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IFC_NAND_SEQ_STRT_FIR_STRT);
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/* wait for read to complete */
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nand_wait(&buf[sram_addr], bufnum, page_size);
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/*
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* If either of the first two pages are marked bad,
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* continue to the next block.
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*/
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if (i++ < 2 &&
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bad_block(&buf[sram_addr + page_size + bad_marker],
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port_size)) {
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puts("skipping\n");
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offs = (offs + blk_size) & ~(blk_size - 1);
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pos &= ~(blk_size - 1);
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break;
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}
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for (j = 0; j < page_size; j++)
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dst[pos + j] = __raw_readb(&buf[sram_addr + j]);
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pos += page_size;
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offs += page_size;
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} while ((offs & (blk_size - 1)) && (pos < uboot_size));
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}
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return 0;
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}
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/*
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* Main entrypoint for NAND Boot. It's necessary that SDRAM is already
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* configured and available since this code loads the main U-Boot image
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* from NAND into SDRAM and starts from there.
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*/
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void nand_boot(void)
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{
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__attribute__((noreturn)) void (*uboot)(void);
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/*
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* Load U-Boot image from NAND into RAM
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*/
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nand_spl_load_image(CONFIG_SYS_NAND_U_BOOT_OFFS,
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CONFIG_SYS_NAND_U_BOOT_SIZE,
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(uchar *)CONFIG_SYS_NAND_U_BOOT_DST);
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#ifdef CONFIG_NAND_ENV_DST
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nand_spl_load_image(CONFIG_ENV_OFFSET, CONFIG_ENV_SIZE,
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(uchar *)CONFIG_NAND_ENV_DST);
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#ifdef CONFIG_ENV_OFFSET_REDUND
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nand_spl_load_image(CONFIG_ENV_OFFSET_REDUND, CONFIG_ENV_SIZE,
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(uchar *)CONFIG_NAND_ENV_DST + CONFIG_ENV_SIZE);
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#endif
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#endif
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/*
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* Jump to U-Boot image
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*/
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#ifdef CONFIG_SPL_FLUSH_IMAGE
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/*
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* Clean d-cache and invalidate i-cache, to
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* make sure that no stale data is executed.
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*/
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flush_cache(CONFIG_SYS_NAND_U_BOOT_DST, CONFIG_SYS_NAND_U_BOOT_SIZE);
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#endif
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#ifdef CONFIG_CHAIN_OF_TRUST
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/*
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* U-Boot header is appended at end of U-boot image, so
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* calculate U-boot header address using U-boot header size.
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*/
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#define CONFIG_U_BOOT_HDR_ADDR \
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((CONFIG_SYS_NAND_U_BOOT_START + \
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CONFIG_SYS_NAND_U_BOOT_SIZE) - \
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CONFIG_U_BOOT_HDR_SIZE)
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spl_validate_uboot(CONFIG_U_BOOT_HDR_ADDR,
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CONFIG_SYS_NAND_U_BOOT_START);
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/*
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* In case of failure in validation, spl_validate_uboot would
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* not return back in case of Production environment with ITS=1.
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* Thus U-Boot will not start.
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* In Development environment (ITS=0 and SB_EN=1), the function
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* may return back in case of non-fatal failures.
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*/
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#endif
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uboot = (void *)CONFIG_SYS_NAND_U_BOOT_START;
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uboot();
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}
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#ifndef CONFIG_SPL_NAND_INIT
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void nand_init(void)
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{
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}
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void nand_deselect(void)
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{
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}
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#endif
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