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authorDenys Dmytriyenko <denis@denix.org>2009-03-17 14:32:59 -0400
committerDenys Dmytriyenko <denis@denix.org>2009-03-17 14:32:59 -0400
commit709c4d66e0b107ca606941b988bad717c0b45d9b (patch)
tree37ee08b1eb308f3b2b6426d5793545c38396b838 /recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch
parentfa6cd5a3b993f16c27de4ff82b42684516d433ba (diff)
rename packages/ to recipes/ per earlier agreement
See links below for more details: http://thread.gmane.org/gmane.comp.handhelds.openembedded/21326 http://thread.gmane.org/gmane.comp.handhelds.openembedded/21816 Signed-off-by: Denys Dmytriyenko <denis@denix.org> Acked-by: Mike Westerhof <mwester@dls.net> Acked-by: Philip Balister <philip@balister.org> Acked-by: Khem Raj <raj.khem@gmail.com> Acked-by: Marcin Juszkiewicz <hrw@openembedded.org> Acked-by: Koen Kooi <koen@openembedded.org> Acked-by: Frans Meulenbroeks <fransmeulenbroeks@gmail.com>
Diffstat (limited to 'recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch')
-rw-r--r--recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch4093
1 files changed, 4093 insertions, 0 deletions
diff --git a/recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch b/recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch
new file mode 100644
index 0000000000..cb5a9c5f72
--- /dev/null
+++ b/recipes/linux/linux-rp-2.6.23/zylonite_mtd-r0.patch
@@ -0,0 +1,4093 @@
+Gross hacks to make the Zylonite boot from flash in VGA.
+
+Flash driver forward ported to 2.6.14
+
+Index: linux-2.6.23/drivers/mtd/nand/Kconfig
+===================================================================
+--- linux-2.6.23.orig/drivers/mtd/nand/Kconfig 2007-10-09 21:31:38.000000000 +0100
++++ linux-2.6.23/drivers/mtd/nand/Kconfig 2008-02-13 00:59:45.000000000 +0000
+@@ -223,6 +223,10 @@
+ tristate "Support for NAND Flash on Sharp SL Series (C7xx + others)"
+ depends on ARCH_PXA
+
++config MTD_NAND_ZYLONITE
++ tristate "Support for NAND Flash on Zylonite"
++ depends on ARCH_PXA
++
+ config MTD_NAND_BASLER_EXCITE
+ tristate "Support for NAND Flash on Basler eXcite"
+ depends on BASLER_EXCITE
+Index: linux-2.6.23/drivers/mtd/nand/Makefile
+===================================================================
+--- linux-2.6.23.orig/drivers/mtd/nand/Makefile 2007-10-09 21:31:38.000000000 +0100
++++ linux-2.6.23/drivers/mtd/nand/Makefile 2008-02-13 00:59:45.000000000 +0000
+@@ -19,6 +19,7 @@
+ obj-$(CONFIG_MTD_NAND_H1900) += h1910.o
+ obj-$(CONFIG_MTD_NAND_RTC_FROM4) += rtc_from4.o
+ obj-$(CONFIG_MTD_NAND_SHARPSL) += sharpsl.o
++obj-$(CONFIG_MTD_NAND_ZYLONITE) += mhn_nand.o
+ obj-$(CONFIG_MTD_NAND_TS7250) += ts7250.o
+ obj-$(CONFIG_MTD_NAND_NANDSIM) += nandsim.o
+ obj-$(CONFIG_MTD_NAND_CS553X) += cs553x_nand.o
+Index: linux-2.6.23/drivers/mtd/nand/mhn_nand.c
+===================================================================
+--- /dev/null 1970-01-01 00:00:00.000000000 +0000
++++ linux-2.6.23/drivers/mtd/nand/mhn_nand.c 2008-02-13 00:59:45.000000000 +0000
+@@ -0,0 +1,3869 @@
++/*
++ * drivers/mtd/nand/mhn_nand.c
++ *
++ * Copyright (C) 2005 Intel Coporation (chao.xie@intel.com)
++ *
++ * This program is free software; you can redistribute it and/or modify
++ * it under the terms of the GNU General Public License version 2 as
++ * published by the Free Software Foundation.
++ *
++ * Overview:
++ * This is a device driver for the NAND flash device on zylonite board
++ * which utilizes the Samsung K9K1216Q0C parts. This is a 64Mibit NAND
++ * flash device.
++
++ *(C) Copyright 2006 Marvell International Ltd.
++ * All Rights Reserved
++ */
++
++#include <linux/slab.h>
++#include <linux/module.h>
++#include <linux/mtd/mtd.h>
++#include <linux/mtd/nand.h>
++#include <linux/mtd/partitions.h>
++#include <linux/interrupt.h>
++#include <linux/device.h>
++#include <linux/platform_device.h>
++#include <linux/delay.h>
++#include <linux/dma-mapping.h>
++#include <asm/hardware.h>
++#include <asm/io.h>
++#include <asm/irq.h>
++#include <asm/delay.h>
++#include <asm/dma.h>
++#include <asm/arch/mfp.h>
++//#include <asm/arch/cpu-freq-voltage-mhn.h>
++
++//#define NDCR 0xf0000000
++//#define NDCR (*((volatile u32 *)0xf0000000))
++//#define NDCR __REG_2(0x43100000) /* Data Flash Control register */
++#define NDCR_SPARE_EN (0x1<<31)
++#define NDCR_ECC_EN (0x1<<30)
++#define NDCR_DMA_EN (0x1<<29)
++#define NDCR_ND_RUN (0x1<<28)
++#define NDCR_DWIDTH_C (0x1<<27)
++#define NDCR_DWIDTH_M (0x1<<26)
++#define NDCR_PAGE_SZ (0x1<<24)
++#define NDCR_NCSX (0x1<<23)
++#define NDCR_ND_MODE (0x3<<21)
++#define NDCR_NAND_MODE 0x0
++#define NDCR_CLR_PG_CNT (0x1<<20)
++#define NDCR_CLR_ECC ( 0x1<<19)
++#define NDCR_RD_ID_CNT_MASK (0x7<<16)
++#define NDCR_RD_ID_CNT(x) (((x) << 16) & NDCR_RD_ID_CNT_MASK)
++#define NDCR_RA_START (0x1<<15)
++#define NDCR_PG_PER_BLK (0x1<<14)
++#define NDCR_ND_ARB_EN (0x1<<12)
++
++//#define NDSR (*((volatile u32 *)0xf0000014))
++//#define NDSR __REG_2(0x43100014) /* Data Controller Status Register */
++#define NDSR_RDY (0x1<<11)
++#define NDSR_CS0_PAGED (0x1<<10)
++#define NDSR_CS1_PAGED (0x1<<9)
++#define NDSR_CS0_CMDD (0x1<<8)
++#define NDSR_CS1_CMDD (0x1<<7)
++#define NDSR_CS0_BBD (0x1<<6)
++#define NDSR_CS1_BBD (0x1<<5)
++#define NDSR_DBERR (0x1<<4)
++#define NDSR_SBERR (0x1<<3)
++#define NDSR_WRDREQ (0x1<<2)
++#define NDSR_RDDREQ (0x1<<1)
++#define NDSR_WRCMDREQ (0x1)
++
++#define OSCR __REG(0x40A00010) /* OS Timer Counter Register */
++//#define NDCB0 __REG_2(0x43100048) /* Data Controller Command Buffer0 */
++//#define NDCB1 __REG_2(0x4310004C) /* Data Controller Command Buffer1 */
++//#define NDCB2 __REG_2(0x43100050) /* Data Controller Command Buffer2 */
++#define NDCB0_AUTO_RS (0x1<<25)
++#define NDCB0_CSEL (0x1<<24)
++#define NDCB0_CMD_TYPE_MASK (0x7<<21)
++#define NDCB0_CMD_TYPE(x) (((x) << 21) & NDCB0_CMD_TYPE_MASK)
++#define NDCB0_NC (0x1<<20)
++#define NDCB0_DBC (0x1<<19)
++#define NDCB0_ADDR_CYC_MASK (0x7<<16)
++#define NDCB0_ADDR_CYC(x) (((x) << 16) & NDCB0_ADDR_CYC_MASK)
++#define NDCB0_CMD2_MASK (0xff<<8)
++#define NDCB0_CMD1_MASK (0xff)
++#define NDCB0_ADDR_CYC_SHIFT (16)
++#define DCMD0 __REG(0x4000020c) /* DMA Command Address Register Channel 0 */
++#define DCMD1 __REG(0x4000021c) /* DMA Command Address Register Channel 1 */
++#define DCMD2 __REG(0x4000022c) /* DMA Command Address Register Channel 2 */
++#define DCMD3 __REG(0x4000023c) /* DMA Command Address Register Channel 3 */
++#define DCMD4 __REG(0x4000024c) /* DMA Command Address Register Channel 4 */
++#define DCMD5 __REG(0x4000025c) /* DMA Command Address Register Channel 5 */
++#define DCMD6 __REG(0x4000026c) /* DMA Command Address Register Channel 6 */
++#define DCMD7 __REG(0x4000027c) /* DMA Command Address Register Channel 7 */
++#define DCMD8 __REG(0x4000028c) /* DMA Command Address Register Channel 8 */
++#define DCMD9 __REG(0x4000029c) /* DMA Command Address Register Channel 9 */
++#define DCMD10 __REG(0x400002ac) /* DMA Command Address Register Channel 10 */
++#define DCMD11 __REG(0x400002bc) /* DMA Command Address Register Channel 11 */
++#define DCMD12 __REG(0x400002cc) /* DMA Command Address Register Channel 12 */
++#define DCMD13 __REG(0x400002dc) /* DMA Command Address Register Channel 13 */
++#define DCMD14 __REG(0x400002ec) /* DMA Command Address Register Channel 14 */
++#define DCMD15 __REG(0x400002fc) /* DMA Command Address Register Channel 15 */
++#define DCMD(x) __REG2(0x4000020c, (x) << 4)
++#define DCMD_INCSRCADDR (1 << 31) /* Source Address Increment Setting. */
++#define DCMD_INCTRGADDR (1 << 30) /* Target Address Increment Setting. */
++#define DCMD_FLOWSRC (1 << 29) /* Flow Control by the source. */
++#define DCMD_FLOWTRG (1 << 28) /* Flow Control by the target. */
++#define DCMD_STARTIRQEN (1 << 22) /* Start Interrupt Enable */
++#define DCMD_ENDIRQEN (1 << 21) /* End Interrupt Enable */
++#define DCMD_ENDIAN (1 << 18) /* Device Endian-ness. */
++#define DCMD_BURST8 (1 << 16) /* 8 byte burst */
++#define DCMD_BURST16 (2 << 16) /* 16 byte burst */
++#define DCMD_BURST32 (3 << 16) /* 32 byte burst */
++#define DCMD_WIDTH1 (1 << 14) /* 1 byte width */
++#define DCMD_WIDTH2 (2 << 14) /* 2 byte width (HalfWord) */
++#define DCMD_WIDTH4 (3 << 14) /* 4 byte width (Word) */
++#define DCMD_LENGTH 0x01fff /* length mask (max = 8K - 1) */
++#define DCMD_RXPCDR (DCMD_INCTRGADDR|DCMD_FLOWSRC|DCMD_BURST32|DCMD_WIDTH4)
++#define DCMD_RXMCDR (DCMD_INCTRGADDR|DCMD_FLOWSRC|DCMD_BURST32|DCMD_WIDTH4)
++#define DCMD_TXPCDR (DCMD_INCSRCADDR|DCMD_FLOWTRG|DCMD_BURST32|DCMD_WIDTH4)
++#define DRCMR(n) __REG2(0x40000100, (n)<<2)
++#define DRCMR97 __REG(0x40001184) /* Request to Channel Map Register for NAND interface data transmit & receive Request */
++#define DRCMR98 __REG(0x40001188) /* Reserved */
++#define DRCMR99 __REG(0x4000118C) /* Request to Channel Map Register for NAND interface command transmit Request */
++#define DRCMRRXSADR DRCMR2
++#define DRCMRTXSADR DRCMR3
++#define DRCMRRXBTRBR DRCMR4
++#define DRCMRTXBTTHR DRCMR5
++#define DRCMRRXFFRBR DRCMR6
++#define DRCMRTXFFTHR DRCMR7
++#define DRCMRRXMCDR DRCMR8
++#define DRCMRRXMODR DRCMR9
++#define DRCMRTXMODR DRCMR10
++#define DRCMRRXPCDR DRCMR11
++#define DRCMRTXPCDR DRCMR12
++#define DRCMRRXSSDR DRCMR13
++#define DRCMRTXSSDR DRCMR14
++#define DRCMRRXICDR DRCMR17
++#define DRCMRTXICDR DRCMR18
++#define DRCMRRXSTRBR DRCMR19
++#define DRCMRTXSTTHR DRCMR20
++#define DRCMRRXMMC DRCMR21
++#define DRCMRTXMMC DRCMR22
++#define DRCMRRXMMC2 DRCMR93
++#define DRCMRTXMMC2 DRCMR94
++#define DRCMRRXMMC3 DRCMR100
++#define DRCMRTXMMC3 DRCMR101
++#define DRCMRUDC(x) DRCMR((x) + 24)
++#define DRCMR_MAPVLD (1 << 7) /* Map Valid (read / write) */
++#define DRCMR_CHLNUM 0x1f /* mask for Channel Number (read / write) */
++#define DCSR0 __REG(0x40000000) /* DMA Control / Status Register for Channel 0 */
++#define DCSR1 __REG(0x40000004) /* DMA Control / Status Register for Channel 1 */
++#define DCSR2 __REG(0x40000008) /* DMA Control / Status Register for Channel 2 */
++#define DCSR3 __REG(0x4000000c) /* DMA Control / Status Register for Channel 3 */
++#define DCSR4 __REG(0x40000010) /* DMA Control / Status Register for Channel 4 */
++#define DCSR5 __REG(0x40000014) /* DMA Control / Status Register for Channel 5 */
++#define DCSR6 __REG(0x40000018) /* DMA Control / Status Register for Channel 6 */
++#define DCSR7 __REG(0x4000001c) /* DMA Control / Status Register for Channel 7 */
++#define DCSR8 __REG(0x40000020) /* DMA Control / Status Register for Channel 8 */
++#define DCSR9 __REG(0x40000024) /* DMA Control / Status Register for Channel 9 */
++#define DCSR10 __REG(0x40000028) /* DMA Control / Status Register for Channel 10 */
++#define DCSR11 __REG(0x4000002c) /* DMA Control / Status Register for Channel 11 */
++#define DCSR12 __REG(0x40000030) /* DMA Control / Status Register for Channel 12 */
++#define DCSR13 __REG(0x40000034) /* DMA Control / Status Register for Channel 13 */
++#define DCSR14 __REG(0x40000038) /* DMA Control / Status Register for Channel 14 */
++#define DCSR15 __REG(0x4000003c) /* DMA Control / Status Register for Channel 15 */
++#define DCSR16 __REG(0x40000040) /* DMA Control / Status Register for Channel 16 */
++#define DCSR17 __REG(0x40000044) /* DMA Control / Status Register for Channel 17 */
++#define DCSR18 __REG(0x40000048) /* DMA Control / Status Register for Channel 18 */
++#define DCSR19 __REG(0x4000004c) /* DMA Control / Status Register for Channel 19 */
++#define DCSR20 __REG(0x40000050) /* DMA Control / Status Register for Channel 20 */
++#define DCSR21 __REG(0x40000054) /* DMA Control / Status Register for Channel 21 */
++#define DCSR22 __REG(0x40000058) /* DMA Control / Status Register for Channel 22 */
++#define DCSR23 __REG(0x4000005c) /* DMA Control / Status Register for Channel 23 */
++#define DCSR24 __REG(0x40000060) /* DMA Control / Status Register for Channel 24 */
++#define DCSR25 __REG(0x40000064) /* DMA Control / Status Register for Channel 25 */
++#define DCSR26 __REG(0x40000068) /* DMA Control / Status Register for Channel 26 */
++#define DCSR27 __REG(0x4000006c) /* DMA Control / Status Register for Channel 27 */
++#define DCSR28 __REG(0x40000070) /* DMA Control / Status Register for Channel 28 */
++#define DCSR29 __REG(0x40000074) /* DMA Control / Status Register for Channel 29 */
++#define DCSR30 __REG(0x40000078) /* DMA Control / Status Register for Channel 30 */
++#define DCSR31 __REG(0x4000007c) /* DMA Control / Status Register for Channel 31 */
++#define DCSR(x) __REG2(0x40000000, (x) << 2)
++#define DCSR_RUN (1 << 31) /* Run Bit (read / write) */
++#define DCSR_NODESC (1 << 30) /* No-Descriptor Fetch (read / write) */
++#define DCSR_STOPIRQEN (1 << 29) /* Stop Interrupt Enable (read / write) */
++#define DCSR_EORIRQEN (1 << 28) /* End of Receive Interrupt Enable (R/W) */
++#define DCSR_EORJMPEN (1 << 27) /* Jump to next descriptor on EOR */
++#define DCSR_EORSTOPEN (1 << 26) /* STOP on an EOR */
++#define DCSR_SETCMPST (1 << 25) /* Set Descriptor Compare Status */
++#define DCSR_CLRCMPST (1 << 24) /* Clear Descriptor Compare Status */
++#define DCSR_CMPST (1 << 10) /* The Descriptor Compare Status */
++#define DCSR_EORINTR (1 << 9) /* The end of Receive */
++#define DCSR_REQPEND (1 << 8) /* Request Pending (read-only) */
++#define DCSR_RASINTR (1 << 4) /* Request After Channel Stopped */
++#define DCSR_STOPSTATE (1 << 3) /* Stop State (read-only) */
++#define DCSR_ENDINTR (1 << 2) /* End Interrupt (read / write) */
++#define DCSR_STARTINTR (1 << 1) /* Start Interrupt (read / write) */
++#define DCSR_BUSERR (1 << 0) /* Bus Error Interrupt (read / write) */
++#define DDADR(x) __REG2(0x40000200, (x) << 4)
++//#define __REG_2(x) (*((volatile u32 *)io_p2v_2(x)))
++#define IRQ_NAND PXA_IRQ(45)
++#define CKEN_NAND 4 ///< NAND Flash Controller Clock Enable
++
++/* #define CONFIG_MTD_NAND_MONAHANS_DEBUG */
++#ifdef CONFIG_MTD_NAND_MONAHANS_DEBUG
++#define D1(x) do { \
++ printk(KERN_DEBUG "%s: ", __FUNCTION__); \
++ x; \
++ }while(0)
++
++#define DPRINTK(fmt,args...) printk(KERN_DEBUG fmt, ##args )
++#define PRINT_BUF(buf, num) print_buf(buf, num)
++#else
++#define D1(x)
++#define DPRINTK(fmt,args...)
++#define PRINT_BUF(buf, num)
++#endif
++
++/* DFC timing 0 register */
++#define DFC_TIMING_tRP 0
++#define DFC_TIMING_tRH 3
++#define DFC_TIMING_tWP 8
++#define DFC_TIMING_tWH 11
++#define DFC_TIMING_tCS 16
++#define DFC_TIMING_tCH 19
++
++/* DFC timing 1 register */
++#define DFC_TIMING_tAR 0
++#define DFC_TIMING_tWHR 4
++#define DFC_TIMING_tR 16
++
++/* max value for each timing setting in DFC */
++#define DFC_TIMING_MAX_tCH 7
++#define DFC_TIMING_MAX_tCS 7
++#define DFC_TIMING_MAX_tWH 7
++#define DFC_TIMING_MAX_tWP 7
++#define DFC_TIMING_MAX_tRH 7
++#define DFC_TIMING_MAX_tRP 7
++#define DFC_TIMING_MAX_tR 65535
++#define DFC_TIMING_MAX_tWHR 15
++#define DFC_TIMING_MAX_tAR 15
++
++/*
++ * The Data Flash Controller Flash timing structure
++ * For NAND flash used on Zylonite board(Samsung K9K1216Q0C),
++ * user should use value at end of each row of following member
++ * bracketed.
++ */
++struct dfc_flash_timing {
++ uint32_t tCH; /* Enable signal hold time */
++ uint32_t tCS; /* Enable signal setup time */
++ uint32_t tWH; /* ND_nWE high duration */
++ uint32_t tWP; /* ND_nWE pulse time */
++ uint32_t tRH; /* ND_nRE high duration */
++ uint32_t tRP; /* ND_nRE pulse width */
++ uint32_t tR; /* ND_nWE high to ND_nRE low for read */
++ uint32_t tWHR;/* ND_nWE high to ND_nRE low delay for status read */
++ uint32_t tAR; /* ND_ALE low to ND_nRE low delay */
++};
++
++/* DFC command type */
++enum {
++ DFC_CMD_READ = 0x00000000,
++ DFC_CMD_PROGRAM = 0x00200000,
++ DFC_CMD_ERASE = 0x00400000,
++ DFC_CMD_READ_ID = 0x00600000,
++ DFC_CMD_STATUS_READ = 0x00800000,
++ DFC_CMD_RESET = 0x00a00000
++};
++
++/*
++ * The Data Flash Controller Flash specification structure
++ * For NAND flash used on Zylonite board(Samsung K9K1216Q0C),
++ * user should use value at end of each row of following member
++ * bracketed.
++ */
++struct dfc_flash_info {
++ struct dfc_flash_timing timing; /* NAND Flash timing */
++
++ int enable_arbiter;/* Data flash bus arbiter enable (ND_ARB_EN) */
++ uint32_t page_per_block;/* Pages per block (PG_PER_BLK) */
++ uint32_t row_addr_start;/* Row address start position (RA_START) */
++ uint32_t read_id_bytes; /* returned ID bytes(RD_ID_CNT) */
++ uint32_t dfc_mode; /* NAND, CARBONDALE, PIXLEY... (ND_MODE) */
++ uint32_t ncsx; /* Chip select don't care bit (NCSX) */
++ uint32_t page_size; /* Page size in bytes (PAGE_SZ) */
++ uint32_t oob_size; /* OOB size */
++ uint32_t flash_width; /* Width of Flash memory (DWIDTH_M) */
++ uint32_t dfc_width; /* Width of flash controller(DWIDTH_C) */
++ uint32_t num_blocks; /* Number of physical blocks in Flash */
++ uint32_t chip_id;
++
++ /* command codes */
++ uint32_t read1; /* Read */
++ uint32_t read2; /* unused, DFC don't support yet */
++ uint32_t program; /* two cycle command */
++ uint32_t read_status;
++ uint32_t read_id;
++ uint32_t erase; /* two cycle command */
++ uint32_t reset;
++ uint32_t lock; /* lock whole flash */
++ uint32_t unlock; /* two cycle command, supporting partial unlock */
++ uint32_t lock_status; /* read block lock status */
++
++ /* addr2ndcb1 - encode address cycles into register NDCB1 */
++ /* ndbbr2addr - convert register NDBBR to bad block address */
++ int (*addr2ndcb1)(uint16_t cmd, uint32_t addr, uint32_t *p);
++ int (*ndbbr2addr)(uint16_t cmd, uint32_t ndbbr,uint32_t *p);
++};
++
++enum {
++ DFC_FLASH_NULL = 0 ,
++ DFC_FLASH_Samsung_512Mb_X_16 = 1,
++ DFC_FLASH_Micron_1Gb_X_8 = 2,
++ DFC_FLASH_Micron_1Gb_X_16 = 3,
++ DFC_FLASH_STM_1Gb_X_16 = 4,
++ DFC_FLASH_STM_2Gb_X_16 = 5,
++ DFC_FLASH_END,
++};
++
++static int dfc_get_flash_info(int type, struct dfc_flash_info **flash_info);
++
++#define DFC_NDCR 0
++#define DFC_NDTR0CS0 1
++#define DFC_NDTR1CS0 3
++#define DFC_NDSR 5
++#define DFC_NDPCR 6
++#define DFC_NDBDR0 7
++#define DFC_NDBDR1 8
++#define DFC_NDDB 16
++#define DFC_NDCB0 18
++#define DFC_NDCB1 19
++#define DFC_NDCB2 20
++
++/* The Data Flash Controller Mode structure */
++struct dfc_mode {
++ int enable_dma; /* DMA, or nonDMA mode */
++ int enable_ecc; /* ECC on/off */
++ int enable_spare; /* Spare enable */
++ int chip_select; /* CS0 or CS1 */
++};
++
++/* The Data Flash Controller Context structure */
++struct dfc_context {
++ unsigned char __iomem *membase; /* DFC register base */
++ struct dfc_mode *dfc_mode; /* DFC mode */
++ int data_dma_ch; /* Data DMA channel number */
++ int cmd_dma_ch; /* CMD DMA channel number */
++ struct dfc_flash_info *flash_info; /* Flash Spec */
++ struct mtd_info *mtd;
++};
++
++#define NDCB0_DMA_ADDR 0x43100048
++#define NDDB_DMA_ADDR 0x43100040
++
++#define NDSR_MASK 0xFFF
++
++/* The following data is a rough evaluation */
++
++/* microsecond, for readID/readStatus/reset */
++#define NAND_OTHER_TIMEOUT 10
++/* microsecond, for readID/readStatus/reset */
++#define NAND_CMD_TIMEOUT 10
++
++#define BBT_BLOCK_BAD 0x03
++#define BBT_BLOCK_GOOD 0x00
++#define BBT_BLOCK_REV1 0x01
++#define BBT_BLOCK_REV2 0x02
++
++#define BUFLEN (2048 + 64)
++
++/*
++ * DFC data size enumeration transfered from/to controller,
++ * including padding (zero)to be a multiple of 32.
++ */
++enum {
++ DFC_DATA_SIZE_STATUS = 8, /* ReadStatus/ReadBlockLockStatus */
++ DFC_DATA_SIZE_ID = 7, /* ReadID */
++
++ DFC_DATA_SIZE_32 = 32,
++ DFC_DATA_SIZE_512 = 512, /* R/W disabling spare area */
++ DFC_DATA_SIZE_520 = 520, /* Spare=1, ECC=1 */
++ DFC_DATA_SIZE_528 = 528, /* Spare=1, ECC=0 */
++ DFC_DATA_SIZE_544 = 544, /* R/W enabling spare area.(DMA mode)*/
++
++ DFC_DATA_SIZE_64 = 64,
++ DFC_DATA_SIZE_2048 = 2048, /* R/W disabling spare area */
++ DFC_DATA_SIZE_2088 = 2088, /* R/W enabling spare area with ecc */
++ DFC_DATA_SIZE_2112 = 2112, /* R/W enabling spare area without ecc*/
++ DFC_DATA_SIZE_2096 = 2096, /* R/W enabling spare area */
++ DFC_DATA_SIZE_UNUSED = 0xFFFF
++};
++
++/* DFC padding size enumeration transfered from/to controller */
++enum {
++ /*
++ * ReadStatus/ReadBlockLockStatus/ReadID/
++ * Read/Program disabling spare area(Both 512 and 2048)
++ * Read/Program enabling spare area, disabling ECC
++ */
++ DFC_PADDING_SIZE_0 = 0,
++
++ /* Read/program with SPARE_EN=1, ECC_EN=0, pgSize=512 */
++ DFC_PADDING_SIZE_16 = 16,
++ /* for read/program with SPARE_EN=1, ECC_EN=1, pgSize=512 and 2048 */
++ DFC_PADDING_SIZE_24 = 24,
++ DFC_PADDING_SIZE_UNUSED = 0xFFFF
++};
++
++static unsigned int flash_config = DFC_FLASH_NULL;
++
++void dfc_set_timing(struct dfc_context *context, struct dfc_flash_timing *t);
++void dfc_set_dma(struct dfc_context *context);
++void dfc_set_ecc(struct dfc_context *context);
++void dfc_set_spare(struct dfc_context *context);
++
++int dfc_get_pattern(struct dfc_context *context, uint16_t cmd,
++ int *data_size, int *padding);
++
++static int dfc_wait_event(struct dfc_context *context, uint32_t event,
++ uint32_t *event_out, uint32_t timeout, int enable_int);
++
++int dfc_send_cmd(struct dfc_context *context, uint16_t cmd,
++ uint32_t addr, int num_pages);
++
++void dfc_stop(struct dfc_context *context);
++void dfc_read_fifo_partial(struct dfc_context *context, uint8_t *buffer,
++ int nbytes, int data_size);
++void dfc_write_fifo_partial(struct dfc_context *context, uint8_t *buffer,
++ int nbytes, int data_size);
++
++void dfc_read_fifo(struct dfc_context *context, uint8_t *buffer, int nbytes);
++void dfc_write_fifo(struct dfc_context *context, uint8_t *buffer, int nbytes);
++
++void dfc_read_badblock_addr(struct dfc_context *context, uint32_t *bbaddr);
++
++void dfc_clear_int(struct dfc_context *context, uint32_t int_mask);
++void dfc_enable_int(struct dfc_context *context, uint32_t int_mask);
++void dfc_disable_int(struct dfc_context *context, uint32_t int_mask);
++
++/* high level primitives */
++int dfc_init(struct dfc_context *context, int type);
++int dfc_init_no_gpio(struct dfc_context *context, int type);
++
++int dfc_reset_flash(struct dfc_context *context);
++
++int dfc_setup_cmd_dma(struct dfc_context *context,
++ uint16_t cmd, uint32_t addr, int num_pages,
++ uint32_t *buf, uint32_t buf_phys,
++ uint32_t next_desc_phys, uint32_t dma_int_en,
++ struct pxa_dma_desc *dma_desc);
++
++int dfc_setup_data_dma(struct dfc_context *context,
++ uint16_t cmd, uint32_t buf_phys,
++ uint32_t next_desc_phys, uint32_t dma_int_en,
++ struct pxa_dma_desc *dma_desc);
++
++void dfc_start_cmd_dma(struct dfc_context *context,
++ struct pxa_dma_desc *dma_desc);
++void dfc_start_data_dma(struct dfc_context *context,
++ struct pxa_dma_desc *dma_desc);
++static int monahans_df_dev_ready(struct mtd_info *mtd);
++
++#ifdef CONFIG_DVFM
++static int mhn_nand_dvfm_notifier(unsigned cmd, void *client_data, void *info);
++static struct mhn_fv_notifier dvfm_notifier = {
++ .name = "monahans-nand-flash",
++ .priority = 0,
++ .notifier_call = mhn_nand_dvfm_notifier,
++};
++#endif
++
++static unsigned short search_rel_block(int block, struct mtd_info *mtd);
++
++/*****************************************************************************
++ * The DFC registers read/write routines
++ *****************************************************************************/
++static inline void dfc_write(struct dfc_context *context, int offset,
++ unsigned long value)
++{
++ offset <<= 2;
++ writel(value, context->membase + offset);
++}
++
++static inline unsigned int dfc_read(struct dfc_context *context, int offset)
++{
++ offset <<= 2;
++ return __raw_readl(context->membase + offset);
++}
++
++/****************************************************************************
++ * Flash Information
++ ***************************************************************************/
++
++static int Samsung512MbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p);
++static int Samsung512MbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p);
++
++static struct dfc_flash_info samsung512MbX16 =
++{
++ .timing = {
++ .tCH = 10, /* tCH, Enable signal hold time */
++ .tCS = 0, /* tCS, Enable signal setup time */
++ .tWH = 20, /* tWH, ND_nWE high duration */
++ .tWP = 40, /* tWP, ND_nWE pulse time */
++ .tRH = 30, /* tRH, ND_nRE high duration */
++ .tRP = 40, /* tRP, ND_nRE pulse width */
++ /* tR = tR+tRR+tWB+1, ND_nWE high to ND_nRE low for read */
++ .tR = 11123,
++ /* tWHR, ND_nWE high to ND_nRE low delay for status read */
++ .tWHR = 110,
++ .tAR = 10, /* tAR, ND_ALE low to ND_nRE low delay */
++ },
++ .enable_arbiter = 1, /* Data flash bus arbiter enable */
++ .page_per_block = 32, /* Pages per block */
++ .row_addr_start = 0, /* Second cycle start, Row address start position */
++ .read_id_bytes = 2, /* 2 bytes, returned ID bytes */
++ .dfc_mode = 0, /* NAND mode */
++ .ncsx = 0,
++ .page_size = 512, /* Page size in bytes */
++ .oob_size = 16, /* OOB size in bytes */
++ .flash_width = 16, /* Width of Flash memory */
++ .dfc_width = 16, /* Width of flash controller */
++ .num_blocks = 4096, /* Number of physical blocks in Flash */
++ .chip_id = 0x46ec,
++
++ /* command codes */
++ .read1 = 0x0000, /* Read */
++ .read2 = 0x0050, /* Read1 unused, current DFC don't support */
++ .program = 0x1080, /* Write, two cycle command */
++ .read_status = 0x0070, /* Read status */
++ .read_id = 0x0090, /* Read ID */
++ .erase = 0xD060, /* Erase, two cycle command */
++ .reset = 0x00FF, /* Reset */
++ .lock = 0x002A, /* Lock whole flash */
++ .unlock = 0x2423, /* Unlock, two cycle command, supporting partial unlock */
++ .lock_status = 0x007A, /* Read block lock status */
++ .addr2ndcb1 = Samsung512MbX16Addr2NDCB1,
++ .ndbbr2addr = Samsung512MbX16NDBBR2Addr,
++};
++
++static int Samsung512MbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p)
++{
++ uint32_t ndcb1 = 0;
++
++ if (addr >= 0x4000000) return -EINVAL;
++
++ if (cmd == samsung512MbX16.read1 || cmd == samsung512MbX16.program) {
++ ndcb1 = (addr & 0xFF) | ((addr >> 1) & 0x01FFFF00);
++ } else if (cmd == samsung512MbX16.erase) {
++ ndcb1 = ((addr >> 9) & 0x00FFFFFF);
++ }
++
++ *p = ndcb1;
++ return 0;
++
++}
++
++static int Samsung512MbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p)
++{
++ *p = ndbbr << 9;
++ return 0;
++}
++
++static int Micron1GbX8Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p);
++static int Micron1GbX8NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p);
++
++static struct dfc_flash_info micron1GbX8 =
++{
++ .timing = {
++ .tCH = 10, /* tCH, Enable signal hold time */
++ .tCS = 25, /* tCS, Enable signal setup time */
++ .tWH = 15, /* tWH, ND_nWE high duration */
++ .tWP = 25, /* tWP, ND_nWE pulse time */
++ .tRH = 15, /* tRH, ND_nRE high duration */
++ .tRP = 25, /* tRP, ND_nRE pulse width */
++ /* tR = tR+tRR+tWB+1, ND_nWE high to ND_nRE low for read */
++ .tR = 25000,
++ /* tWHR, ND_nWE high to ND_nRE low delay for status read */
++ .tWHR = 60,
++ .tAR = 10, /* tAR, ND_ALE low to ND_nRE low delay */
++ },
++ .enable_arbiter = 1, /* Data flash bus arbiter enable */
++ .page_per_block = 64, /* Pages per block */
++ .row_addr_start = 1, /* Second cycle start, Row address start position */
++ .read_id_bytes = 4, /* Returned ID bytes */
++ .dfc_mode = 0, /* NAND mode */
++ .ncsx = 0,
++ .page_size = 2048, /* Page size in bytes */
++ .oob_size = 64, /* OOB size in bytes */
++ .flash_width = 8, /* Width of Flash memory */
++ .dfc_width = 8, /* Width of flash controller */
++ .num_blocks = 1024, /* Number of physical blocks in Flash */
++ .chip_id = 0xa12c,
++ /* command codes */
++ .read1 = 0x3000, /* Read */
++ .read2 = 0x0050, /* Read1 unused, current DFC don't support */
++ .program = 0x1080, /* Write, two cycle command */
++ .read_status = 0x0070, /* Read status */
++ .read_id = 0x0090, /* Read ID */
++ .erase = 0xD060, /* Erase, two cycle command */
++ .reset = 0x00FF, /* Reset */
++ .lock = 0x002A, /* Lock whole flash */
++ .unlock = 0x2423, /* Unlock, two cycle command, supporting partial unlock */
++ .lock_status = 0x007A, /* Read block lock status */
++ .addr2ndcb1 = Micron1GbX8Addr2NDCB1,
++ .ndbbr2addr = Micron1GbX8NDBBR2Addr,
++};
++
++static int Micron1GbX8Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p)
++{
++ uint32_t ndcb1 = 0;
++ uint32_t page;
++
++ if (addr >= 0x8000000)
++ return -EINVAL;
++ page = addr / micron1GbX8.page_size;
++ addr = (page / micron1GbX8.page_per_block) << 18 |
++ (page % micron1GbX8.page_per_block) << 12;
++
++ if (cmd == micron1GbX8.read1 || cmd == micron1GbX8.program) {
++ ndcb1 = (addr & 0xFFF) | ((addr << 4) & 0xFFFF0000);
++ }
++ else if (cmd == micron1GbX8.erase) {
++ ndcb1 = ((addr >> 18) << 6) & 0xFFFF;
++ }
++
++ *p = ndcb1;
++ return 0;
++}
++
++static int Micron1GbX8NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p)
++{
++ if (cmd == micron1GbX8.read1 || cmd == micron1GbX8.program) {
++ *p = ((ndbbr & 0xF) << 8) | ((ndbbr >> 8) << 16);
++ }
++ else if (cmd == micron1GbX8.erase) {
++ *p = (ndbbr >> 6) << 18;
++ }
++
++
++ return 0;
++}
++
++
++static int Micron1GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p);
++static int Micron1GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p);
++
++static struct dfc_flash_info micron1GbX16 =
++{
++ .timing = {
++ .tCH = 10, /* tCH, Enable signal hold time */
++ .tCS = 25, /* tCS, Enable signal setup time */
++ .tWH = 15, /* tWH, ND_nWE high duration */
++ .tWP = 25, /* tWP, ND_nWE pulse time */
++ .tRH = 15, /* tRH, ND_nRE high duration */
++ .tRP = 25, /* tRP, ND_nRE pulse width */
++ /* tR = tR+tRR+tWB+1, ND_nWE high to ND_nRE low for read */
++ .tR = 25000,
++ /* tWHR, ND_nWE high to ND_nRE low delay for status read */
++ .tWHR = 60,
++ .tAR = 10, /* tAR, ND_ALE low to ND_nRE low delay */
++ },
++ .enable_arbiter = 1, /* Data flash bus arbiter enable */
++ .page_per_block = 64, /* Pages per block */
++ .row_addr_start = 1, /* Second cycle start, Row address start position */
++ .read_id_bytes = 4, /* Returned ID bytes */
++ .dfc_mode = 0, /* NAND mode */
++ .ncsx = 0,
++ .page_size = 2048, /* Page size in bytes */
++ .oob_size = 64, /* OOB size in bytes */
++ .flash_width = 16, /* Width of Flash memory */
++ .dfc_width = 16, /* Width of flash controller */
++ .num_blocks = 1024, /* Number of physical blocks in Flash */
++ .chip_id = 0xb12c,
++
++ /* command codes */
++ .read1 = 0x3000, /* Read */
++ .read2 = 0x0050, /* Read1 unused, current DFC don't support */
++ .program = 0x1080, /* Write, two cycle command */
++ .read_status = 0x0070, /* Read status */
++ .read_id = 0x0090, /* Read ID */
++ .erase = 0xD060, /* Erase, two cycle command */
++ .reset = 0x00FF, /* Reset */
++ .lock = 0x002A, /* Lock whole flash */
++ .unlock = 0x2423, /* Unlock, two cycle command, supporting partial unlock */
++ .lock_status = 0x007A, /* Read block lock status */
++ .addr2ndcb1 = Micron1GbX16Addr2NDCB1,
++ .ndbbr2addr = Micron1GbX16NDBBR2Addr,
++};
++
++static int Micron1GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p)
++{
++ uint32_t ndcb1 = 0;
++ uint32_t page;
++
++ if (addr >= 0x8000000)
++ return -EINVAL;
++ page = addr / micron1GbX16.page_size;
++ addr = (page / micron1GbX16.page_per_block) << 17 |
++ (page % micron1GbX16.page_per_block) << 11;
++
++ if (cmd == micron1GbX16.read1 || cmd == micron1GbX16.program) {
++ ndcb1 = (addr & 0x7FF) | ((addr << 5) & 0xFFFF0000);
++ }
++ else if (cmd == micron1GbX16.erase) {
++ ndcb1 = ((addr >> 17) << 6) & 0xFFFF;
++ }
++ *p = ndcb1;
++ return 0;
++}
++
++static int Micron1GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p)
++{
++ if (cmd == micron1GbX16.read1 || cmd == micron1GbX16.program) {
++ *p = ((ndbbr & 0x7) << 8) | ((ndbbr >> 8) << 16);
++ }
++ else if (cmd == micron1GbX16.erase) {
++ *p = (ndbbr >> 6) << 17;
++ }
++
++ return 0;
++}
++
++static int STM1GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p);
++static int STM1GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p);
++
++static struct dfc_flash_info stm1GbX16 =
++{
++ .timing = {
++ .tCH = 10, /* tCH, Enable signal hold time */
++ .tCS = 10, /* tCS, Enable signal setup time */
++ .tWH = 20, /* tWH, ND_nWE high duration */
++ .tWP = 25, /* tWP, ND_nWE pulse time */
++ .tRH = 20, /* tRH, ND_nRE high duration */
++ .tRP = 25, /* tRP, ND_nRE pulse width */
++ /* tR = tR+tRR+tWB+1, ND_nWE high to ND_nRE low for read */
++ .tR = 25000,
++ /* tWHR, ND_nWE high to ND_nRE low delay for status read */
++ .tWHR = 60,
++ .tAR = 10, /* tAR, ND_ALE low to ND_nRE low delay */
++ },
++ .enable_arbiter = 1, /* Data flash bus arbiter enable */
++ .page_per_block = 64, /* Pages per block */
++ .row_addr_start = 1, /* Second cycle start, Row address start position */
++ .read_id_bytes = 4, /* Returned ID bytes */
++ .dfc_mode = 0, /* NAND mode */
++ .ncsx = 0,
++ .page_size = 2048, /* Page size in bytes */
++ .oob_size = 64, /* OOB size in bytes */
++ .flash_width = 16, /* Width of Flash memory */
++ .dfc_width = 16, /* Width of flash controller */
++ .num_blocks = 1024, /* Number of physical blocks in Flash */
++ .chip_id = 0xb120,
++
++ /* command codes */
++ .read1 = 0x3000, /* Read */
++ .read2 = 0x0050, /* Read1 unused, current DFC don't support */
++ .program = 0x1080, /* Write, two cycle command */
++ .read_status = 0x0070, /* Read status */
++ .read_id = 0x0090, /* Read ID */
++ .erase = 0xD060, /* Erase, two cycle command */
++ .reset = 0x00FF, /* Reset */
++ .lock = 0x002A, /* Lock whole flash */
++ .unlock = 0x2423, /* Unlock, two cycle command, supporting partial unlock */
++ .lock_status = 0x007A, /* Read block lock status */
++ .addr2ndcb1 = STM1GbX16Addr2NDCB1,
++ .ndbbr2addr = STM1GbX16NDBBR2Addr,
++};
++
++static int STM1GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p)
++{
++ uint32_t ndcb1 = 0;
++ uint32_t page;
++
++ if (addr >= 0x8000000)
++ return -EINVAL;
++ page = addr / stm1GbX16.page_size;
++ addr = (page / stm1GbX16.page_per_block) << 17 |
++ (page % stm1GbX16.page_per_block) << 11;
++
++ if (cmd == stm1GbX16.read1 || cmd == stm1GbX16.program) {
++ ndcb1 = (addr & 0x7FF) | ((addr << 5) & 0xFFFF0000);
++ }
++ else if (cmd == stm1GbX16.erase) {
++ ndcb1 = ((addr >> 17) << 6) & 0xFFFF;
++ }
++ *p = ndcb1;
++ return 0;
++}
++
++static int STM1GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p)
++{
++ if (cmd == stm1GbX16.read1 || cmd == stm1GbX16.program) {
++ *p = ((ndbbr & 0x7) << 8) | ((ndbbr >> 8) << 16);
++ }
++ else if (cmd == stm1GbX16.erase) {
++ *p = (ndbbr >> 6) << 17;
++ }
++
++ return 0;
++}
++
++static int STM2GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p);
++static int STM2GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p);
++
++static struct dfc_flash_info stm2GbX16 =
++{
++ .timing = {
++ .tCH = 10, /* tCH, Enable signal hold time */
++ .tCS = 10, /* tCS, Enable signal setup time */
++ .tWH = 20, /* tWH, ND_nWE high duration */
++ .tWP = 25, /* tWP, ND_nWE pulse time */
++ .tRH = 20, /* tRH, ND_nRE high duration */
++ .tRP = 25, /* tRP, ND_nRE pulse width */
++ /* tR = tR+tRR+tWB+1, ND_nWE high to ND_nRE low for read */
++ .tR = 25000,
++ /* tWHR, ND_nWE high to ND_nRE low delay for status read */
++ .tWHR = 60,
++ .tAR = 10, /* tAR, ND_ALE low to ND_nRE low delay */
++ },
++ .enable_arbiter = 1, /* Data flash bus arbiter enable */
++ .page_per_block = 64, /* Pages per block */
++ .row_addr_start = 1, /* Second cycle start, Row address start position */
++ .read_id_bytes = 4, /* Returned ID bytes */
++ .dfc_mode = 0, /* NAND mode */
++ .ncsx = 0,
++ .page_size = 2048, /* Page size in bytes */
++ .oob_size = 64, /* OOB size in bytes */
++ .flash_width = 16, /* Width of Flash memory */
++ .dfc_width = 16, /* Width of flash controller */
++ .num_blocks = 2048, /* Number of physical blocks in Flash */
++ .chip_id = 0xca20,
++
++ /* command codes */
++ .read1 = 0x3000, /* Read */
++ .read2 = 0x0050, /* Read1 unused, current DFC don't support */
++ .program = 0x1080, /* Write, two cycle command */
++ .read_status = 0x0070, /* Read status */
++ .read_id = 0x0090, /* Read ID */
++ .erase = 0xD060, /* Erase, two cycle command */
++ .reset = 0x00FF, /* Reset */
++ .lock = 0x002A, /* Lock whole flash */
++ .unlock = 0x2423, /* Unlock, two cycle command, supporting partial unlock */
++ .lock_status = 0x007A, /* Read block lock status */
++ .addr2ndcb1 = STM2GbX16Addr2NDCB1,
++ .ndbbr2addr = STM2GbX16NDBBR2Addr,
++};
++
++static int STM2GbX16Addr2NDCB1(uint16_t cmd, uint32_t addr, uint32_t *p)
++{
++ uint32_t ndcb1 = 0;
++ uint32_t page;
++
++ if (addr >= 0x8000000)
++ return -EINVAL;
++ page = addr / stm2GbX16.page_size;
++ addr = (page / stm2GbX16.page_per_block) << 17 |
++ (page % stm2GbX16.page_per_block) << 11;
++
++ if (cmd == stm2GbX16.read1 || cmd == stm2GbX16.program) {
++ ndcb1 = (addr & 0x7FF) | ((addr << 5) & 0xFFFF0000);
++ }
++ else if (cmd == stm2GbX16.erase) {
++ ndcb1 = ((addr >> 17) << 6) & 0xFFFF;
++ }
++ *p = ndcb1;
++ return 0;
++}
++
++static int STM2GbX16NDBBR2Addr(uint16_t cmd, uint32_t ndbbr, uint32_t *p)
++{
++ if (cmd == stm2GbX16.read1 || cmd == stm2GbX16.program) {
++ *p = ((ndbbr & 0x7) << 8) | ((ndbbr >> 8) << 16);
++ }
++ else if (cmd == stm2GbX16.erase) {
++ *p = (ndbbr >> 6) << 17;
++ }
++
++ return 0;
++}
++
++static struct {
++ int type;
++ struct dfc_flash_info *flash_info;
++} type_info[] = {
++ { DFC_FLASH_Samsung_512Mb_X_16, &samsung512MbX16},
++ { DFC_FLASH_Micron_1Gb_X_8, &micron1GbX8},
++ { DFC_FLASH_Micron_1Gb_X_16, &micron1GbX16},
++ { DFC_FLASH_STM_1Gb_X_16, &stm1GbX16},
++ { DFC_FLASH_STM_2Gb_X_16, &stm2GbX16},
++ { DFC_FLASH_NULL, NULL},
++};
++
++int dfc_get_flash_info(int type, struct dfc_flash_info **flash_info)
++{
++ uint32_t i = 0;
++
++ while(type_info[i].type != DFC_FLASH_NULL) {
++ if (type_info[i].type == type) {
++ *flash_info = type_info[i].flash_info;
++ return 0;
++ }
++ i++;
++ }
++ *flash_info = NULL;
++ return -EINVAL;
++}
++
++/******************************************************************************
++ dfc_set_timing
++
++ Description:
++ This function sets flash timing property in DFC timing register
++ according to input timing value embodied in context structure.
++ It is called once during the hardware initialization.
++ Input Parameters:
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++//#if defined(CONFIG_CPU_MONAHANS_L) || defined(CONFIG_CPU_MONAHANS_LV)
++#define DFC_CLOCK 208
++//#else
++//#define DFC_CLOCK 104
++//#endif
++#define CLOCK_NS DFC_CLOCK/1000
++
++void dfc_set_timing(struct dfc_context *context, struct dfc_flash_timing *t)
++{
++ struct dfc_flash_timing timing = *t;
++
++ uint32_t r0 = 0;
++ uint32_t r1 = 0;
++
++ /*
++ * num of clock cycles = time (ns) / one clock sycle (ns) + 1
++ * - integer division will truncate the result, so add a 1 in all cases
++ * - subtract the extra 1 cycle added to all register timing values
++ */
++ timing.tCH = min(((int) (timing.tCH * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tCH);
++ timing.tCS = min(((int) (timing.tCS * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tCS);
++ timing.tWH = min(((int) (timing.tWH * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tWH);
++ timing.tWP = min(((int) (timing.tWP * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tWP);
++ timing.tRH = min(((int) (timing.tRH * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tRH);
++ timing.tRP = min(((int) (timing.tRP * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tRP);
++
++ r0 = (timing.tCH << DFC_TIMING_tCH) |
++ (timing.tCS << DFC_TIMING_tCS) |
++ (timing.tWH << DFC_TIMING_tWH) |
++ (timing.tWP << DFC_TIMING_tWP) |
++ (timing.tRH << DFC_TIMING_tRH) |
++ (timing.tRP << DFC_TIMING_tRP);
++
++ dfc_write(context, DFC_NDTR0CS0, r0);
++
++ timing.tR = min(((int) (timing.tR * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tR);
++ timing.tWHR = min(((int) (timing.tWHR * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tWHR);
++ timing.tAR = min(((int) (timing.tAR * CLOCK_NS) + 1),
++ DFC_TIMING_MAX_tAR);
++
++ r1 = (timing.tR << DFC_TIMING_tR) |
++ (timing.tWHR << DFC_TIMING_tWHR) |
++ (timing.tAR << DFC_TIMING_tAR);
++
++ dfc_write(context, DFC_NDTR1CS0, r1);
++ return;
++}
++
++/******************************************************************************
++ dfc_set_dma
++
++ Description:
++ Enables or Disables DMA in line with setting in DFC mode of context
++ structure. DMA mode of DFC. Performs a read-modify-write operation that
++ only changes the driven DMA_EN bit field In DMA mode, all commands and
++ data are transferred by DMA. DMA can be enable/disable on the fly.
++ Input Parameters:
++ context -Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void
++dfc_set_dma(struct dfc_context* context)
++{
++ uint32_t ndcr;
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ if (context->dfc_mode->enable_dma)
++ ndcr |= NDCR_DMA_EN;
++ else
++ ndcr &= ~NDCR_DMA_EN;
++
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ /* Read again to make sure write work */
++ ndcr = dfc_read(context, DFC_NDCR);
++ return;
++}
++
++
++/******************************************************************************
++ dfc_set_ecc
++
++ Description:
++ This function enables or disables hardware ECC capability of DFC in line
++ with setting in DFC mode of context structure.
++ Input Parameters:
++ context -Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void
++dfc_set_ecc(struct dfc_context* context)
++{
++ uint32_t ndcr;
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ if (context->dfc_mode->enable_ecc)
++ ndcr |= NDCR_ECC_EN;
++ else
++ ndcr &= ~NDCR_ECC_EN;
++
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ /* Read again to make sure write work */
++ ndcr = dfc_read(context, DFC_NDCR);
++ return;
++}
++
++/******************************************************************************
++ dfc_set_spare
++
++ Description:
++ This function enables or disables accesses to spare area of NAND Flash
++ through DFC in line with setting in DFC mode of context structure.
++ Input Parameters:
++ context -Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void
++dfc_set_spare(struct dfc_context* context)
++{
++ uint32_t ndcr;
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ if (context->dfc_mode->enable_spare)
++ ndcr |= NDCR_SPARE_EN;
++ else
++ ndcr &= ~NDCR_SPARE_EN;
++
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ /* Read again to make sure write work */
++ ndcr = dfc_read(context, DFC_NDCR);
++ return;
++}
++
++static unsigned int get_delta (unsigned int start)
++{
++ unsigned int stop = OSCR;
++ return (stop - start);
++}
++
++static int dfc_wait_event(struct dfc_context *context, uint32_t event,
++ uint32_t *event_out, uint32_t timeout, int enable_int)
++{
++ uint32_t ndsr;
++ uint32_t to = 3 * timeout; /* 3 ticks ~ 1us */
++ int status;
++ int start = OSCR;
++
++ if (enable_int)
++ dfc_enable_int(context, event);
++
++ while (1) {
++ ndsr = dfc_read(context, DFC_NDSR);
++ ndsr &= NDSR_MASK;
++ if (ndsr & event) {
++ /* event happened */
++ *event_out = ndsr & event;
++ dfc_clear_int(context, *event_out);
++ status = 0;
++ break;
++ } else if (get_delta(start) > to) {
++ status = -ETIME;
++ break;
++ }
++ }
++
++ if (enable_int)
++ dfc_disable_int(context, event);
++ return status;
++}
++
++/******************************************************************************
++ dfc_get_pattern
++
++ Description:
++ This function is used to retrieve buffer size setting for a transaction
++ based on cmd.
++ Input Parameters:
++ context - Pointer to DFC context structure
++ cmd
++ Specifies type of command to be sent to NAND flash .The LSB of this
++ parameter defines the first command code for 2-cycles command. The
++ MSB defines the second command code for 2-cycles command. If MSB is
++ set to zero, this indicates that one cycle command
++ Output Parameters:
++ data_size
++ It is used to retrieve length of data transferred to/from DFC,
++ which includes padding bytes
++ padding
++ It is used to retrieve how many padding bytes there should be
++ in buffer of data_size.
++ Returns:
++ 0
++ If size setting is returned successfully
++ -EINVAL
++ If page size specified in flash spec of context structure is not 512 or
++ 2048;If specified command index is not read1/program/erase/reset/readID/
++ readStatus.
++*******************************************************************************/
++int dfc_get_pattern(struct dfc_context *context, uint16_t cmd,
++ int *data_size, int *padding)
++{
++ struct dfc_mode* dfc_mode = context->dfc_mode;
++ struct dfc_flash_info * flash_info = context->flash_info;
++ uint32_t page_size = context->flash_info->page_size; /* 512 or 2048 */
++
++ if (cmd == flash_info->read1 ||
++ cmd == flash_info->program) {
++ if (512 == page_size) {
++ /* add for DMA */
++ if (dfc_mode->enable_dma) {
++ *data_size = DFC_DATA_SIZE_544;
++ if (dfc_mode->enable_ecc)
++ *padding = DFC_PADDING_SIZE_24;
++ else
++ *padding = DFC_PADDING_SIZE_16;
++ } else if (!dfc_mode->enable_spare) {
++ *data_size = DFC_DATA_SIZE_512;
++ *padding = DFC_PADDING_SIZE_0;
++ } else {
++
++ if (dfc_mode->enable_ecc)
++ *data_size = DFC_DATA_SIZE_520;
++ else
++ *data_size = DFC_DATA_SIZE_528;
++
++ *padding = DFC_PADDING_SIZE_0;
++ }
++ } else if (2048 == page_size) {
++ /* add for DMA */
++ if (dfc_mode->enable_dma) {
++ *data_size = DFC_DATA_SIZE_2112;
++ if (dfc_mode->enable_ecc)
++ *padding = DFC_PADDING_SIZE_24;
++ else
++ *padding = DFC_PADDING_SIZE_0;
++ } else if (!dfc_mode->enable_spare) {
++ *data_size = DFC_DATA_SIZE_2048;
++ *padding = DFC_PADDING_SIZE_0;
++ } else {
++
++ if (dfc_mode->enable_ecc)
++ *data_size = DFC_DATA_SIZE_2088;
++ else
++ *data_size = DFC_DATA_SIZE_2112;
++
++ *padding = DFC_PADDING_SIZE_0;
++ }
++ } else /* if the page_size is neither 512 or 2048 */
++ return -EINVAL;
++ } else if (cmd == flash_info->read_id) {
++ *data_size = DFC_DATA_SIZE_ID;
++ *padding = DFC_PADDING_SIZE_0;
++ } else if(cmd == flash_info->read_status) {
++ *data_size = DFC_DATA_SIZE_STATUS;
++ *padding = DFC_PADDING_SIZE_0;
++ } else if (cmd == flash_info->erase || cmd == flash_info->reset) {
++ *data_size = DFC_DATA_SIZE_UNUSED;
++ *padding = DFC_PADDING_SIZE_UNUSED;
++ } else
++ return -EINVAL;
++ return 0;
++}
++
++
++/******************************************************************************
++ dfc_send_cmd
++
++ Description:
++ This function configures DFC to send command through DFC to NAND flash
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ cmd
++ Specifies type of command to be sent to NAND flash .The LSB of this
++ parameter defines the first command code for 2-cycles command. The
++ MSB defines the second command code for 2-cycles command. If MSB is
++ set to zero, this indicates that one cycle command
++ addr
++ Address sent out to the flash device withthis command. For page read/
++ program commands , 4-cycles address is sent. For erase command only
++ 3-cycles address is sent. If it is equal to 0xFFFFFFFF, the address
++ should not be used.
++ num_pages
++ It specifies the number of pages of data to be transferred for
++ a program or read commands. Unused for any other commands than
++ read/program.
++
++ Output Parameters:
++ None
++ Returns:
++ 0
++ If size setting is returned successfully
++ -EINVAL
++ If specified command index is not read1/program/erase/reset/readID/
++ readStatus.
++*******************************************************************************/
++int dfc_send_cmd(struct dfc_context *context, uint16_t cmd,
++ uint32_t addr, int num_pages)
++{
++ struct dfc_flash_info *flash_info = context->flash_info;
++ struct dfc_mode *dfc_mode = context->dfc_mode;
++ uint8_t cmd2;
++ uint32_t event_out;
++ uint32_t ndcb0=0, ndcb1=0, ndcb2=0, ndcr;
++ int status;
++
++ /* It is a must to set ND_RUN firstly, then write command buffer
++ * If conversely,it does not work
++ */
++ dfc_write(context, DFC_NDSR, NDSR_MASK);
++
++ /* Set ND_RUN */
++ ndcr = dfc_read(context, DFC_NDCR);
++ dfc_write(context, DFC_NDCR, (ndcr | NDCR_ND_RUN));
++
++ // Wait for write command request
++ status = dfc_wait_event(context, NDSR_WRCMDREQ,
++ &event_out, NAND_CMD_TIMEOUT, 0);
++
++ if (status) /* Timeout */
++ return status;
++
++ cmd2 = (cmd>>8) & 0xFF;
++ ndcb0 = cmd | (dfc_mode->chip_select<<24) | ((cmd2?1:0)<<19);
++
++ if (cmd == flash_info->read1) {
++ if (0xFFFFFFFF != addr) {
++ ndcb0 |= NDCB0_ADDR_CYC(4);
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ ndcb2 = (num_pages - 1) << 8;
++ }
++ } else if (cmd == flash_info->program) {
++ ndcb0 |= NDCB0_CMD_TYPE(1) | NDCB0_AUTO_RS;
++ ndcb0 |= NDCB0_ADDR_CYC(4);
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ ndcb2 = (num_pages-1) << 8;
++ } else if (cmd == flash_info->erase) {
++ ndcb0 |= NDCB0_CMD_TYPE(2) | NDCB0_AUTO_RS;
++ ndcb0 |= NDCB0_ADDR_CYC(3);
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ } else if (cmd == flash_info->read_id) {
++ ndcb0 |= NDCB0_CMD_TYPE(3);
++ } else if(cmd == flash_info->read_status) {
++ ndcb0 |= NDCB0_CMD_TYPE(4);
++ } else if(cmd == flash_info->reset) {
++ ndcb0 |= NDCB0_CMD_TYPE(5);
++ } else if (cmd == flash_info->lock) {
++ ndcb0 |= NDCB0_CMD_TYPE(5);
++ } else
++ return -EINVAL;
++
++ /* Write to DFC command register */
++ dfc_write(context, DFC_NDCB0, ndcb0);
++ dfc_write(context, DFC_NDCB0, ndcb1);
++ dfc_write(context, DFC_NDCB0, ndcb2);
++
++ return 0;
++}
++
++/******************************************************************************
++ dfc_stop
++
++ Description:
++ This function clears ND_RUN bit of NDCR.
++ Input Parameters:
++ context--Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_stop(struct dfc_context *context)
++{
++ unsigned int ndcr;
++ ndcr = dfc_read(context, DFC_NDCR);
++ dfc_write(context, DFC_NDCR, (ndcr & ~NDCR_ND_RUN));
++ ndcr = dfc_read(context, DFC_NDCR);
++
++ return;
++}
++
++int dfc_setup_cmd_dma(struct dfc_context *context,
++ uint16_t cmd, uint32_t addr, int num_pages,
++ uint32_t *buf, uint32_t buf_phys,
++ uint32_t next_desc_phys, uint32_t dma_int_en,
++ struct pxa_dma_desc *dma_desc)
++{
++ struct dfc_flash_info *flash_info = context->flash_info;
++ struct dfc_mode *dfc_mode = context->dfc_mode;
++ uint8_t cmd2;
++ uint32_t event_out;
++ uint32_t ndcb0=0, ndcb1=0, ndcb2=0, ndcr;
++ int status;
++
++ /*
++ * It is a must to set ND_RUN firstly, then write command buffer
++ * If conversely,it does not work
++ */
++ dfc_write(context, DFC_NDSR, NDSR_MASK);
++
++ /* Set ND_RUN */
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr |= NDCR_ND_RUN;
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ /* Wait for write command request */
++ status = dfc_wait_event(context, NDSR_WRCMDREQ,
++ &event_out, NAND_CMD_TIMEOUT, 0);
++
++ if (status)
++ return status; /* Timeout */
++
++ cmd2 = (cmd>>8) & 0xFF;
++ ndcb0 = cmd | (dfc_mode->chip_select<<24) | ((cmd2?1:0)<<19);
++
++ if (cmd == flash_info->read1) {
++ if (0xFFFFFFFF != addr) {
++ ndcb0 |= NDCB0_ADDR_CYC(4);
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ ndcb2 = (num_pages-1) << 8;
++ }
++ } else if (cmd == flash_info->program) {
++ ndcb0 |= NDCB0_CMD_TYPE(1) | NDCB0_AUTO_RS;
++ ndcb0 |= NDCB0_ADDR_CYC(4);
++
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ ndcb2 = (num_pages-1) << 8;
++ } else if (cmd == flash_info->erase) {
++ ndcb0 |= NDCB0_CMD_TYPE(2) | NDCB0_AUTO_RS;
++ ndcb0 |= NDCB0_ADDR_CYC(3);
++
++ status = flash_info->addr2ndcb1(cmd, addr, &ndcb1);
++ if (status)
++ return status;
++ } else if (cmd == flash_info->read_id) {
++ ndcb0 |= NDCB0_CMD_TYPE(3);
++ } else if (cmd == flash_info->read_status) {
++ ndcb0 |= NDCB0_CMD_TYPE(4);
++ } else if (cmd == flash_info->reset) {
++ ndcb0 |= NDCB0_CMD_TYPE(5);
++ } else if (cmd == flash_info->lock) {
++ ndcb0 |= NDCB0_CMD_TYPE(5);
++ } else
++ return -EINVAL;
++
++ *((uint32_t *)buf) = ndcb0;
++ *((uint32_t *)buf + 1) = ndcb1;
++ *((uint32_t *)buf + 2) = ndcb2;
++
++ dma_int_en &= (DCMD_STARTIRQEN | DCMD_ENDIRQEN);
++
++ dma_desc->ddadr = next_desc_phys;
++ dma_desc->dsadr = buf_phys;
++ dma_desc->dtadr = NDCB0_DMA_ADDR;
++ dma_desc->dcmd = DCMD_INCSRCADDR | DCMD_FLOWTRG | dma_int_en |
++ DCMD_WIDTH4 | DCMD_BURST16 | 12;
++ return 0;
++}
++
++int dfc_setup_data_dma(struct dfc_context* context,
++ uint16_t cmd, uint32_t buf_phys,
++ uint32_t next_desc_phys, uint32_t dma_int_en,
++ struct pxa_dma_desc* dma_desc)
++{
++ struct dfc_flash_info * flash_info = context->flash_info;
++ int data_size, padding;
++
++ dfc_get_pattern(context, cmd, &data_size, &padding);
++
++ dma_desc->ddadr = next_desc_phys;
++ dma_int_en &= (DCMD_STARTIRQEN | DCMD_ENDIRQEN);
++
++ if (cmd == flash_info->program) {
++
++ dma_desc->dsadr = buf_phys;
++ dma_desc->dtadr = NDDB_DMA_ADDR;
++ dma_desc->dcmd = DCMD_INCSRCADDR | DCMD_FLOWTRG | dma_int_en |
++ DCMD_WIDTH4 | DCMD_BURST32 | data_size;
++
++ } else if (cmd == flash_info->read1 || cmd == flash_info->read_id ||
++ cmd == flash_info->read_status) {
++
++ dma_desc->dsadr = NDDB_DMA_ADDR;
++ dma_desc->dtadr = buf_phys;
++ dma_desc->dcmd = DCMD_INCTRGADDR | DCMD_FLOWSRC | dma_int_en |
++ DCMD_WIDTH4 | DCMD_BURST32 | data_size;
++ }
++ else
++ return -EINVAL;
++ return 0;
++}
++
++void dfc_start_cmd_dma(struct dfc_context* context, struct pxa_dma_desc* dma_desc)
++{
++ DRCMR99 = DRCMR_MAPVLD | context->cmd_dma_ch; /* NAND CMD DRCMR */
++ DDADR(context->cmd_dma_ch) = (uint32_t)dma_desc;
++ DCSR(context->cmd_dma_ch) |= DCSR_RUN;
++}
++
++void dfc_start_data_dma(struct dfc_context* context, struct pxa_dma_desc* dma_desc)
++{
++ DRCMR97 = DRCMR_MAPVLD | context->data_dma_ch;
++ DDADR(context->data_dma_ch) = (uint32_t)dma_desc;
++ DCSR(context->data_dma_ch) |= DCSR_RUN;
++}
++
++/******************************************************************************
++ dfc_read_fifo_partial
++
++ Description:
++ This function reads data from data buffer of DFC.Bytes can be any less than
++ or equal to data_size, the left is ignored by ReadFIFO though they will be
++ read from NDDB to clear data buffer.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ nbytes
++ Indicating how much data should be read into buffer.
++ data_size
++ Specifing length of data transferred to/from DFC, which includes
++ padding bytes
++ Output Parameters:
++ pBuffer
++ Pointer to the data buffer where data should be placed.
++ Returns:
++ None
++*******************************************************************************/
++void dfc_read_fifo_partial(struct dfc_context *context, uint8_t *buffer,
++ int nbytes, int data_size)
++{
++ uint32_t data = 0;
++ uint32_t i = 0;
++ uint32_t bytes_multi;
++ uint32_t bytes_remain;
++
++
++ if (1 == data_size) {
++ data = dfc_read(context, DFC_NDDB) & 0xFF;
++ *buffer++ = (uint8_t)data;
++ } else if (2 == data_size) {
++ data = dfc_read(context, DFC_NDDB) & 0xFFFF;
++ *buffer++ = data & 0xFF;
++ *buffer++ = (data >> 8) & 0xFF;
++ } else {
++ bytes_multi = (nbytes & 0xFFFFFFFC);
++ bytes_remain = nbytes & 0x03;
++
++ i = 0;
++ /* Read the bytes_multi*4 bytes data */
++ while (i < bytes_multi) {
++ data = dfc_read(context, DFC_NDDB);
++ /* FIXME: we don't know whether the buffer
++ * align to 4 bytes or not. Cast the buffer
++ * to int is not safe here. Especially under
++ * gcc 4.x. Used memcpy here. But the memcpy
++ * may be not correct on BE architecture.
++ * --by Yin, Fengwei
++ */
++ memcpy(buffer, &data, sizeof(data));
++ i += sizeof(data);
++ buffer += sizeof(data);
++ }
++
++ /* Read the left bytes_remain bytes data */
++ if (bytes_remain) {
++ data = dfc_read(context, DFC_NDDB);
++ for (i = 0; i < bytes_remain; i++)
++ *buffer++ = (uint8_t)((data >> (8*i)) & 0xFF);
++ }
++
++ /* When read the remain bytes, we always read 4 bytes data
++ * to DFC. So the data_size should subtract following number.
++ */
++ data_size -= bytes_multi + (bytes_remain ? sizeof(data) : 0);
++
++ /* We need Read data_size bytes data totally */
++ while (data_size > 0) {
++ data = dfc_read(context, DFC_NDDB);
++ data_size -= sizeof(data);
++ }
++
++/*
++ while(i < ((uint32_t)data_size) ) {
++ if (i < bytes_multi) {
++ temp = (uint32_t *)buffer;
++ *temp = dfc_reg->nddb;
++ } else if (i == bytes_multi && bytes_remain){
++ uint32_t j = 0;
++ data = dfc_reg->nddb;
++ while (j++ < bytes_remain) {
++ *buffer++ = (uint8_t) \
++ ((data>>(8*j)) & 0xFF);
++ }
++ } else {
++ data = dfc_reg->nddb;
++ }
++ i += 4;
++ buffer += 4;
++ }
++*/
++ }
++ return;
++}
++
++/******************************************************************************
++ dfc_write_fifo_partial
++
++ Description:
++ Write to data buffer of DFC from a buffer. Bytes can be same as
++ data_size, also can be data_size-padding, but can¡¯t be random value,
++ the left will be automatically padded by WriteFIFO.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ bytes
++ Indicating how much data should be read into buffer.
++ data_size
++ Specifing length of data transferred to/from DFC, which includes
++ padding bytes
++ buffer
++ Pointer to the data buffer where data will be taken from to be written
++ to DFC data buffer
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_write_fifo_partial(struct dfc_context *context, uint8_t *buffer,
++ int nbytes, int data_size)
++{
++ uint32_t i = 0;
++
++ uint32_t bytes_multi = (nbytes & 0xFFFFFFFC);
++ uint32_t bytes_remain = nbytes & 0x03;
++ uint32_t temp;
++ /*
++ * caller guarantee buffer contains appropriate data thereby
++ * it is impossible for nbytes not to be a multiple of 4 byte
++ */
++
++ /* Write the bytes_multi*4 bytes data */
++ while (i < bytes_multi) {
++ temp = buffer[0] | buffer[1] << 8 |
++ buffer[2] << 16 | buffer[3] << 24;
++ dfc_write(context, DFC_NDDB, temp);
++ buffer += 4;
++ i += 4;
++ }
++
++ /* Write the left bytes_remain bytes data */
++ if (bytes_remain) {
++ temp = 0xFFFFFFFF;
++ for (i = 0; i < bytes_remain; i++)
++ temp &= *buffer++ << i*8;
++
++ dfc_write(context, DFC_NDDB, temp);
++ }
++
++ /* When write the remain bytes, we always write 4 bytes data
++ * to DFC. So the data_size should subtract following number.
++ */
++ data_size -= bytes_multi + (bytes_remain ? sizeof(temp) : 0);
++
++ while (data_size > 0) {
++ dfc_write(context, DFC_NDDB, 0xFFFFFFFF);
++ data_size -= 4;
++ }
++
++/*
++ while (i < ((uint32_t)data_size)) {
++ if (i < bytes_multi) {
++ temp = (uint32_t *)buffer;
++ dfc_reg->nddb = *temp;
++ }
++ else if (i == bytes_multi && bytes_remain) {
++ uint32_t j = 0, data = 0xFFFFFFFF;
++ while (j < bytes_remain) {
++ data &= (uint8_t)(*buffer) << j;
++ buffer++;
++ j++;
++ }
++ dfc_reg->nddb = data;
++ }
++ else {
++ dfc_reg->nddb = 0xFFFFFFFF;
++ }
++ i += 4;
++ buffer += 4;
++ }
++*/
++
++ return;
++}
++
++/******************************************************************************
++ dfc_read_fifo
++ Description:
++ This function reads data from data buffer of DFC.Bytes can be any less
++ than or equal to data_size, the left is ignored by ReadFIFO though they
++ will be read from NDDB to clear data buffer.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ nbytes
++ Indicating how much data should be read into buffer.
++ data_size
++ Specifing length of data transferred to/from DFC, which includes
++ padding bytes
++ Output Parameters:
++ buffer
++ Pointer to the data buffer where data should be placed.
++ Returns:
++ None
++*******************************************************************************/
++
++void dfc_read_fifo(struct dfc_context *context, uint8_t *buffer, int nbytes)
++{
++ uint32_t i = 0;
++
++ uint32_t bytes_multi = (nbytes & 0xFFFFFFFC);
++ uint32_t bytes_remain = nbytes & 0x03;
++ uint32_t temp;
++
++ /* Read the bytes_multi*4 bytes data */
++ while (i < bytes_multi) {
++ temp = dfc_read(context, DFC_NDDB);
++ /* FIXME: we don't know whether the buffer
++ * align to 4 bytes or not. Cast the buffer
++ * to int is not safe here. Especially under
++ * gcc 4.x. Used memcpy here. But the memcpy
++ * may be not correct on BE architecture.
++ * --by Yin, Fengwei
++ */
++ memcpy(buffer, &temp, sizeof(temp));
++ i += sizeof(temp);
++ buffer += sizeof(temp);
++ }
++
++ /* Read the left bytes_remain bytes data */
++ temp = dfc_read(context, DFC_NDDB);
++ for (i = 0; i < bytes_remain; i++) {
++ *buffer++ = (uint8_t)((temp >> (8*i)) & 0xFF);
++ }
++
++/*
++ while (i < bytes_multi) {
++ temp = (uint32_t *)buffer;
++ *temp = dfc_reg->nddb;
++ i += 4;
++ buffer += 4;
++ }
++
++ if (bytes_remain) {
++ data = dfc_reg->nddb;
++ for (i = 0; i < bytes_remain; i++) {
++ *buffer++ = (uint8_t)((data>>(8*i)) & 0xFF);
++ }
++ }
++*/
++
++ return;
++}
++
++/******************************************************************************
++ dfc_write_fifo
++ Description:
++ Write to data buffer of DFC from a buffer.Bytes can be same as data_size,
++ also can be data_size-padding, but can¡¯t be random value, the left will
++ be automatically padded by WriteFIFO.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ nbytes
++ Indicating how much data should be read into buffer.
++ data_size
++ Specifing length of data transferred to/from DFC, which includes
++ padding bytes
++ buffer
++ Pointer to the data buffer where data will be taken from to be written to
++ DFC data buffer
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_write_fifo(struct dfc_context *context, uint8_t *buffer, int nbytes)
++{
++ uint32_t bytes_multi = (nbytes & 0xFFFFFFFC);
++ uint32_t bytes_remain = nbytes & 0x03;
++ uint32_t i=0;
++ uint32_t temp;
++
++ /* Write the bytes_multi*4 bytes data */
++ while (i < bytes_multi) {
++ temp = buffer[0] | buffer[1] << 8 |
++ buffer[2] << 16 | buffer[3] << 24;
++ dfc_write(context, DFC_NDDB, temp);
++ buffer += 4;
++ i += 4;
++ }
++
++ /* Write the left bytes_remain bytes data */
++ temp = 0xFFFFFFFF;
++ for (i = 0; i < bytes_remain; i++)
++ temp &= *buffer++ << i*8;
++ dfc_write(context, DFC_NDDB, temp);
++
++/*
++ while (i < nbytes) {
++ temp = (uint32_t *)buffer;
++ dfc_reg->nddb = *temp;
++ i += 4;
++ buffer += 4;
++ }
++*/
++}
++
++/******************************************************************************
++ dfc_read_badblock_addr
++
++ Description:
++ This function reads bad block address in units of block starting from 0
++ if bad block is detected. It takes into the account if the operation is
++ for CS0 or CS1 depending on settings of chip_select parameter of DFC
++ Mode structure.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ Output Parameters:
++ pBadBlockAddr
++ Used to retrieve bad block address back to caller if bad block is
++ detected
++ Returns:
++ None
++*******************************************************************************/
++void dfc_read_badblock_addr(struct dfc_context *context, uint32_t *bbaddr)
++{
++ uint32_t ndbdr;
++ if (0 == context->dfc_mode->chip_select)
++ ndbdr = dfc_read(context, DFC_NDBDR0);
++ else
++ ndbdr = dfc_read(context, DFC_NDBDR1);
++
++ if (512 == context->flash_info->page_size) {
++ ndbdr = (ndbdr >> 5) & 0xFFF;
++ *bbaddr = ndbdr;
++ } else if (2048 == context->flash_info->page_size) {
++ /* 16 bits LB */
++ ndbdr = (ndbdr >> 8);
++ *bbaddr = ndbdr;
++ }
++ return;
++}
++
++/******************************************************************************
++ dfc_enable_int
++
++ Description:
++ This function is used to enable DFC interrupts. The bits in int_mask
++ will be used to unmask NDCR register to enable corresponding interrupts.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ int_mask
++ Specifies what interrupts to enable
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_enable_int(struct dfc_context *context, uint32_t int_mask)
++{
++ uint32_t ndcr;
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr &= ~int_mask;
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ return;
++}
++
++/******************************************************************************
++ dfc_disable_int
++
++ Description:
++ This function is used to disable DFC interrupts.
++ The bits inint_mask will be used to mask NDCR register to disable
++ corresponding interrupts.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ int_mask
++ Specifies what interrupts to disable
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_disable_int(struct dfc_context *context, uint32_t int_mask)
++{
++ uint32_t ndcr;
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr |= int_mask;
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ ndcr = dfc_read(context, DFC_NDCR);
++ return;
++}
++
++/******************************************************************************
++ dfc_clear_int
++
++ Description:
++ This function is used to disable DFC interrupts.
++ The bits in int_mask will be used to clear corresponding interrupts
++ in NDCR register
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ int_mask
++ Specifies what interrupts to clear
++ Output Parameters:
++ None
++ Returns:
++ None
++*******************************************************************************/
++void dfc_clear_int(struct dfc_context *context, uint32_t int_mask)
++{
++ dfc_write(context, DFC_NDSR, int_mask);
++
++ dfc_read(context, DFC_NDSR);
++ return;
++}
++
++/*
++ * high level primitives
++ */
++
++/******************************************************************************
++ dfc_init
++
++ Description:
++ This function does entire DFC initialization according to the NAND
++ flash type currently used with platform, including setting MFP, set
++ flash timing, set DFC mode, configuring specified flash parameters
++ in DFC, clear ECC logic and page count register.
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ 0
++ if MFPRs are set correctly
++ -EINVAL
++ if specified flash is not support by check bytes per page and pages per
++ block
++******************************************************************************/
++
++static mfp_cfg_t pxa300_nand_cfg[] = {
++ /* NAND */
++ MFP_CFG_X(DF_INT_RnB, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nRE_nOE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nWE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_CLE_nOE, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nADV1_ALE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nCS0, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nCS1, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_IO0, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO1, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO2, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO3, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO4, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO5, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO6, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO7, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO8, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO9, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO10, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO11, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO12, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO13, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO14, AF1, DS08X, PULL_LOW),
++};
++
++#define ARRAY_AND_SIZE(x) (x), ARRAY_SIZE(x)
++
++int dfc_init(struct dfc_context* context, int type)
++{
++ int status;
++ struct dfc_flash_info * flash_info;
++ uint32_t ndcr = 0x00000FFF; /* disable all interrupts */
++
++ status = dfc_get_flash_info(type, &flash_info);
++ if (status)
++ return status;
++ context->flash_info = flash_info;
++
++ pxa3xx_mfp_config(ARRAY_AND_SIZE(pxa300_nand_cfg));
++ //enable_dfc_pins();
++
++ dfc_set_timing(context, &context->flash_info->timing);
++
++ if (flash_info->enable_arbiter)
++ ndcr |= NDCR_ND_ARB_EN;
++
++ if (64 == flash_info->page_per_block)
++ ndcr |= NDCR_PG_PER_BLK;
++ else if (32 != flash_info->page_per_block)
++ return -EINVAL;
++
++ if (flash_info->row_addr_start)
++ ndcr |= NDCR_RA_START;
++
++ ndcr |= (flash_info->read_id_bytes)<<16;
++
++ ndcr |= (flash_info->dfc_mode) << 21;
++
++ if (flash_info->ncsx)
++ ndcr |= NDCR_NCSX;
++
++ if (2048 == flash_info->page_size)
++ ndcr |= NDCR_PAGE_SZ;
++ else if (512 != flash_info->page_size)
++ return -EINVAL;
++
++ if (16 == flash_info->flash_width)
++ ndcr |= NDCR_DWIDTH_M;
++ else if (8 != flash_info->flash_width)
++ return -EINVAL;
++
++ if (16 == flash_info->dfc_width)
++ ndcr |= NDCR_DWIDTH_C;
++ else if (8 != flash_info->dfc_width)
++ return -EINVAL;
++
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ dfc_set_dma(context);
++ dfc_set_ecc(context);
++ dfc_set_spare(context);
++
++ return 0;
++}
++
++/******************************************************************************
++ dfc_init_no_gpio
++
++ Description:
++ This function does entire DFC initialization according to the NAND
++ flash type currently used with platform, including set flash timing,
++ set DFC mode, configuring specified flash parameters in DFC, clear
++ ECC logic and page count register. The only difference with dfc_init
++ is that it does not set MFP&GPIO, very useful in OS loader
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ 0
++ if MFPRs are set correctly
++ -EINVAL
++ if specified flash is not support by check bytes per page and pages
++ per block
++******************************************************************************/
++int dfc_init_no_gpio(struct dfc_context* context, int type)
++{
++ struct dfc_flash_info * flash_info;
++ uint32_t ndcr = 0x00000FFF; /* disable all interrupts */
++ int status;
++
++ status = dfc_get_flash_info(type, &flash_info);
++ if (status)
++ return status;
++ context->flash_info = flash_info;
++
++ dfc_set_timing(context, &context->flash_info->timing);
++
++ if (flash_info->enable_arbiter)
++ ndcr |= NDCR_ND_ARB_EN;
++
++ if (64 == flash_info->page_per_block)
++ ndcr |= NDCR_PG_PER_BLK;
++ else if (32 != flash_info->page_per_block)
++ return -EINVAL;
++
++ if (flash_info->row_addr_start)
++ ndcr |= NDCR_RA_START;
++
++ ndcr |= (flash_info->read_id_bytes)<<16;
++
++ ndcr |= (flash_info->dfc_mode) << 21;
++
++ if (flash_info->ncsx)
++ ndcr |= NDCR_NCSX;
++
++ if (2048 == flash_info->page_size)
++ ndcr |= NDCR_PAGE_SZ;
++ else if (512 != flash_info->page_size)
++ return -EINVAL;
++
++ if (16 == flash_info->flash_width)
++ ndcr |= NDCR_DWIDTH_M;
++ else if (8 != flash_info->flash_width)
++ return -EINVAL;
++
++ if (16 == flash_info->dfc_width)
++ ndcr |= NDCR_DWIDTH_C;
++ else if (8 != flash_info->dfc_width)
++ return -EINVAL;
++
++ dfc_write(context, DFC_NDCR, ndcr);
++
++ dfc_set_dma(context);
++ dfc_set_ecc(context);
++ dfc_set_spare(context);
++
++ return 0;
++}
++
++/*
++ * This macro will be used in following NAND operation functions.
++ * It is used to clear command buffer to ensure cmd buffer is empty
++ * in case of operation is timeout
++ */
++#define ClearCMDBuf() do { \
++ dfc_stop(context); \
++ udelay(NAND_OTHER_TIMEOUT); \
++ } while (0)
++
++/******************************************************************************
++ dfc_reset_flash
++
++ Description:
++ It reset the flash. The function can be called at any time when the
++ device is in Busy state during random read/program/erase mode and
++ reset operation will abort all these operations. After reset operation
++ the device is ready to wait for next command
++ Input Parameters:
++ context
++ Pointer to DFC context structure
++ Output Parameters:
++ None
++ Returns:
++ 0
++ execution succeeds
++ -ETIME
++ if timeout
++*******************************************************************************/
++int dfc_reset_flash(struct dfc_context *context)
++{
++ struct dfc_flash_info *flash_info = context->flash_info;
++ uint32_t event, event_out;
++ unsigned long timeo;
++ int status;
++
++ /* Send command */
++ dfc_send_cmd(context, (uint16_t)flash_info->reset, 0xFFFFFFFF, 0);
++
++ event = (context->dfc_mode->chip_select)? \
++ NDSR_CS1_CMDD : NDSR_CS0_CMDD;
++
++ /* Wait for CMDDM(command done successfully) */
++ status = dfc_wait_event(context, event, &event_out,
++ NAND_OTHER_TIMEOUT, 0);
++
++ if (status) {
++ ClearCMDBuf();
++ return status;
++ }
++
++
++ /* Wait until flash device is stable or timeout (10ms) */
++ timeo = jiffies + HZ;
++ do {
++ if (monahans_df_dev_ready(context->mtd))
++ break;
++ } while (time_before(jiffies, timeo));
++
++ return 0;
++}
++
++int dfc_readid(struct dfc_context *context, uint32_t *id)
++{
++ struct dfc_flash_info *flash_info = context->flash_info;
++ uint32_t event_out;
++ int status;
++ char tmp[DFC_DATA_SIZE_ID];
++
++ /* Send command */
++ status = dfc_send_cmd(context, (uint16_t)flash_info->read_id,
++ 0xFFFFFFFF, 0);
++ if (status) {
++ ClearCMDBuf();
++ return status;
++ }
++
++ /* Wait for CMDDM(command done successfully) */
++ status = dfc_wait_event(context, NDSR_RDDREQ, &event_out,
++ NAND_OTHER_TIMEOUT, 0);
++ if (status) {
++ ClearCMDBuf();
++ return status;
++ }
++ dfc_read_fifo_partial(context, (unsigned char *)tmp,
++ context->flash_info->read_id_bytes, DFC_DATA_SIZE_ID);
++
++ *id = tmp[0] | (tmp[1] << 8);
++ return 0;
++}
++
++#define ERR_NONE 0x0
++#define ERR_DMABUSERR (-0x01)
++#define ERR_SENDCMD (-0x02)
++#define ERR_DBERR (-0x03)
++#define ERR_BBERR (-0x04)
++#define ERR_BUSY (-0x05)
++
++#define STATE_CMD_SEND 0x1
++#define STATE_CMD_HANDLE 0x2
++#define STATE_DMA_TRANSFER 0x3
++#define STATE_DMA_DONE 0x4
++#define STATE_READY 0x5
++#define STATE_SUSPENDED 0x6
++#define STATE_DATA_TRANSFER 0x7
++
++#define NAND_RELOC_MAX 127
++#define NAND_RELOC_HEADER 0x524e
++#define MAX_CHIP 1
++#define NAND_CMD_DMA_LEN 12
++
++#define MAX_TIM_SIZE 0x1000
++#define MAX_BBT_SLOTS 24
++
++struct reloc_item {
++ unsigned short from;
++ unsigned short to;
++};
++
++struct reloc_table {
++ unsigned short header;
++ unsigned short total;
++ struct reloc_item reloc[NAND_RELOC_MAX];
++};
++
++struct monahans_dfc_info {
++ unsigned int state;
++ struct dfc_context *context;
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ dma_addr_t data_buf_addr;
++ char *data_buf;
++ int data_dma;
++ struct pxa_dma_desc *data_desc;
++ dma_addr_t data_desc_addr;
++ dma_addr_t cmd_buf_addr;
++ char *cmd_buf;
++ int cmd_dma;
++ struct pxa_dma_desc *cmd_desc;
++ dma_addr_t cmd_desc_addr;
++ u64 dma_mask;
++#else
++ char *data_buf;
++#endif
++ u32 current_slot;
++ struct reloc_table table;
++ unsigned int table_init;
++ /* relate to the command */
++ unsigned int cmd;
++ unsigned int addr;
++ unsigned int column;
++ int retcode;
++ unsigned int buf_count;
++ struct completion cmd_complete;
++};
++
++static struct dfc_mode dfc_mode =
++{
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ 1, /* enable DMA */
++#else
++ 0,
++#endif
++ 1, /* enable ECC */
++ 1, /* enable SPARE */
++ 0, /* CS0 */
++};
++
++
++struct dfc_context dfc_context =
++{
++ 0, /* Initialized at function monahans_df_init() */
++ &dfc_mode,
++ 0, /* data dma channel */
++ 0, /* cmd dma channel */
++ NULL, /* &zylonite_flashinfo */
++};
++
++
++/*
++ * MTD structure for Zylonite board
++ */
++static struct mtd_info *monahans_mtd = NULL;
++
++/*
++ * BootRom and XDB will use last 127 block, and they will keep all the status
++ * of the bootloader and image, so skip the first 2M size and last 2M size
++ */
++static struct mtd_partition partition_info[] = {
++ {
++ name: "Bootloader",
++//#ifdef CONFIG_CPU_MONAHANS_LV
++ size: 0x00060000,
++//#else
++// size: 0x00040000,
++//#endif
++ offset: 0,
++ mask_flags: MTD_WRITEABLE /* force read-only */
++ },{
++ name: "Kernel",
++ size: 0x00200000,
++//#ifdef CONFIG_CPU_MONAHANS_LV
++ offset: 0x00060000,
++//#else
++// offset: 0x00040000,
++//#endif
++ mask_flags: MTD_WRITEABLE /* force read-only */
++ },{
++ name: "Filesystem",
++ size: 0x05000000,
++//#ifdef CONFIG_CPU_MONAHANS_LV
++ offset: 0x00260000,
++//#else
++// offset: 0x00240000,
++//#endif
++ }, {
++ name: "MassStorage",
++ size: 0x0, /* It will be set at probe function */
++ offset: MTDPART_OFS_APPEND /* Append after fs section */
++ }, {
++ name: "BBT",
++ size: 0x0, /* It will be set at probe function */
++ offset: MTDPART_OFS_APPEND,/* Append after fs section */
++ mask_flags: MTD_WRITEABLE /* force read-only */
++ }
++};
++
++#define PART_NUM ARRAY_SIZE(partition_info)
++
++/* MHN_OBM_V2 is related to BBT in MOBM V2
++ * MHN_OBM_V3 is related to BBT in MOBM V3
++ */
++enum {
++ MHN_OBM_NULL = 0,
++ MHN_OBM_V1,
++ MHN_OBM_V2,
++ MHN_OBM_V3,
++ MHN_OBM_INVAL
++} MHN_OBM_TYPE;
++
++static uint8_t scan_ff_pattern[] = { 0xff, 0xff };
++static uint8_t scan_main_bbt_pattern[] = { 'p', 'x', 'a', '1' };
++static uint8_t scan_mirror_bbt_pattern[] = { '0', 'a', 'x', 'p' };
++
++static struct nand_bbt_descr monahans_bbt_default = {
++ .options = NAND_BBT_LASTBLOCK | NAND_BBT_CREATE | NAND_BBT_WRITE
++ | NAND_BBT_2BIT | NAND_BBT_VERSION,
++ .maxblocks = 2,
++ .len = 2,
++ .offs = 0,
++ .pattern = scan_ff_pattern,
++};
++
++static struct nand_bbt_descr monahans_bbt_main = {
++ .options = NAND_BBT_LASTBLOCK | NAND_BBT_CREATE | NAND_BBT_WRITE
++ | NAND_BBT_2BIT | NAND_BBT_VERSION,
++ .veroffs = 6,
++ .maxblocks = 2,
++ .offs = 2,
++ .len = 4,
++ .pattern = scan_main_bbt_pattern,
++};
++
++static struct nand_bbt_descr monahans_bbt_mirror = {
++ .options = NAND_BBT_LASTBLOCK | NAND_BBT_CREATE | NAND_BBT_WRITE
++ | NAND_BBT_2BIT | NAND_BBT_VERSION,
++ .veroffs = 6,
++ .maxblocks = 2,
++ .offs = 2,
++ .len = 4,
++ .pattern = scan_mirror_bbt_pattern,
++};
++
++#if 0
++static struct nand_bbt_descr monahans_bbt_main = {
++ .options = NAND_BBT_LASTBLOCK | NAND_BBT_CREATE | NAND_BBT_WRITE
++ | NAND_BBT_2BIT | NAND_BBT_VERSION,
++ .veroffs = 2,
++ .maxblocks = 2,
++ .offs = 0x0,
++ .len = 2,
++ .pattern = scan_ff_pattern
++};
++static struct nand_bbt_descr monahans_bbt_mirror = {
++ .options = NAND_BBT_LASTBLOCK | NAND_BBT_CREATE | NAND_BBT_WRITE
++ | NAND_BBT_2BIT | NAND_BBT_VERSION,
++ .veroffs = 2,
++ .maxblocks = 2,
++ .offs = 0x0,
++ .len = 2,
++ .pattern = scan_ff_pattern
++};
++#endif
++
++static struct nand_ecclayout monahans_lb_nand_oob = {
++ .eccbytes = 24,
++ .eccpos = {
++ 40, 41, 42, 43, 44, 45, 46, 47,
++ 48, 49, 50, 51, 52, 53, 54, 55,
++ 56, 57, 58, 59, 60, 61, 62, 63},
++ .oobfree = { {2, 38} }
++};
++
++/*
++ * Monahans OOB size is only 8 bytes, and the rest 8 bytes is controlled by
++ * hardware for ECC. We construct virutal ECC buffer. Acutally, ECC is 6 bytes
++ * and the remain 2 bytes are reserved.
++ */
++static struct nand_ecclayout monahans_sb_nand_oob = {
++ .eccbytes = 6,
++ .eccpos = {8, 9, 10, 11, 12, 13 },
++ .oobfree = { {2, 6} }
++};
++
++
++static inline int is_buf_blank(u8 * buf, int size)
++{
++ int i = 0;
++ while(i < size) {
++ if (*((unsigned long *)(buf + i)) != 0xFFFFFFFF)
++ return 0;
++ i += 4;
++ }
++ if (i > size) {
++ i -= 4;
++ while( i < size) {
++ if(*(buf + i) != 0xFF)
++ return 0;
++ i++;
++ }
++ }
++ return 1;
++}
++
++static void print_buf(char *buf, int num)
++{
++ int i = 0;
++
++ while (i < num) {
++ printk(KERN_ERR "0x%08x: %02x %02x %02x %02x %02x %02x %02x"
++ " %02x %02x %02x %02x %02x %02x %02x %02x %02x\n",
++ (unsigned int) (i), buf[i], buf[i+1], buf[i+2],
++ buf[i+3], buf[i+4], buf[i+5], buf[i+6], buf[i+7],
++ buf[i+8], buf[i+9], buf[i+10],buf[i+11], buf[i+12],
++ buf[i+13], buf[i+14], buf[i+15]);
++ i += 16;
++ }
++}
++
++static int inline enable_dfc_dma(struct dfc_context *context, int enable)
++{
++ int ret = dfc_mode.enable_dma;
++ unsigned long ndcr;
++
++ if (!enable) {
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr &= ~NDCR_DMA_EN;
++ dfc_write(context, DFC_NDCR, ndcr);
++ dfc_mode.enable_dma = 0;
++ } else {
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr |= NDCR_DMA_EN;
++ dfc_write(context, DFC_NDCR, ndcr);
++ dfc_mode.enable_dma = 1;
++ }
++ return ret;
++}
++
++
++static void inline dump_info(struct monahans_dfc_info *info)
++{
++ if (!info)
++ return;
++
++ printk(KERN_ERR "cmd:0x%x; addr:0x%x; retcode:%d; state:%d \n",
++ info->cmd, info->addr, info->retcode, info->state);
++}
++
++static void inline enable_hw_ecc(struct dfc_context* context, int enable)
++{
++ unsigned long ndcr;
++
++ if (!enable) {
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr &= ~NDCR_ECC_EN;
++ dfc_write(context, DFC_NDCR, ndcr);
++ dfc_mode.enable_ecc = 0;
++ }
++ else {
++ ndcr = dfc_read(context, DFC_NDCR);
++ ndcr |= NDCR_ECC_EN;
++ dfc_write(context, DFC_NDCR, ndcr);
++ dfc_mode.enable_ecc = 1;
++ }
++}
++
++/*
++ * Now, we are not sure that the NDSR_RDY mean the flash is ready.
++ * Need more test.
++ */
++static int monahans_df_dev_ready(struct mtd_info *mtd)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ struct dfc_context* context = info->context;
++
++ return ((dfc_read(context, DFC_NDSR) & NDSR_RDY));
++}
++
++/* each read, we can only read 4bytes from NDDB, we must buffer it */
++static u_char monahans_df_read_byte(struct mtd_info *mtd)
++{
++ char retval = 0xFF;
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ if (info->column < info->buf_count) {
++ /* Has just send a new command? */
++ retval = info->data_buf[info->column++];
++ }
++ return retval;
++}
++
++static void monahans_df_write_byte(struct mtd_info *mtd, u8 byte)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++ info->data_buf[info->column++] = byte;
++}
++
++static u16 monahans_df_read_word(struct mtd_info *mtd)
++{
++ u16 retval = 0xFFFF;
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ if (!(info->column & 0x01) && info->column < info->buf_count) {
++ retval = *((u16 *)(info->data_buf+info->column));
++ info->column += 2;
++ }
++ return retval;
++}
++
++static void monahans_df_write_word(struct mtd_info *mtd, u16 word)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ if (!(info->column & 0x01) && info->column < info->buf_count) {
++ *((u16 *)(info->data_buf+info->column)) = word;
++ info->column += 2;
++ }
++}
++
++static void monahans_df_read_buf(struct mtd_info *mtd, u_char *buf, int len)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++ int real_len = min((unsigned int)len, info->buf_count - info->column);
++
++ memcpy(buf, info->data_buf + info->column, real_len);
++ info->column += real_len;
++}
++
++static void monahans_df_write_buf(struct mtd_info *mtd,
++ const u_char *buf, int len)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++ int real_len = min((unsigned int)len, info->buf_count - info->column);
++
++ memcpy(info->data_buf + info->column, buf, real_len);
++ info->column += real_len;
++}
++
++static int monahans_df_verify_buf(struct mtd_info *mtd,
++ const u_char *buf, int len)
++{
++ return 0;
++}
++
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++static void monahans_dfc_cmd_dma_irq(int channel, void *data,
++ struct pt_regs *regs)
++{
++ unsigned int dcsr;
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)data;
++ struct dfc_context* context = info->context;
++ struct dfc_mode* dfc_mode = context->dfc_mode;
++ unsigned int intm;
++
++ dcsr = DCSR(channel);
++ DCSR(channel) = dcsr;
++
++ intm = (dfc_mode->chip_select) ? \
++ (NDSR_CS1_BBD | NDSR_CS1_CMDD) : (NDSR_CS0_BBD | NDSR_CS0_CMDD);
++
++ D1(printk("cmd dma interrupt, channel:%d, DCSR:0x%08x\n", \
++ channel, dcsr));
++
++ if (dcsr & DCSR_BUSERR) {
++ info->retcode = ERR_DMABUSERR;
++ complete(&info->cmd_complete);
++ } else {
++ if ((info->cmd == NAND_CMD_READ0) ||
++ (info->cmd == NAND_CMD_READOOB)|| \
++ (info->cmd == NAND_CMD_READID) || \
++ (info->cmd == NAND_CMD_STATUS)) {
++ dfc_enable_int(context, NDSR_RDDREQ | NDSR_DBERR);
++ } else if (info->cmd == NAND_CMD_PAGEPROG)
++ dfc_enable_int(context, NDSR_WRDREQ);
++ else if (info->cmd == NAND_CMD_ERASE1)
++ dfc_enable_int(context, intm);
++ }
++
++ return;
++}
++
++
++static void monahans_dfc_data_dma_irq(int channel, void *data,
++ struct pt_regs *regs)
++{
++ unsigned int dcsr, intm;
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)data;
++ struct dfc_context* context = info->context;
++ struct dfc_mode* dfc_mode = context->dfc_mode;
++
++ dcsr = DCSR(channel);
++ DCSR(channel) = dcsr;
++
++ intm = (dfc_mode->chip_select) ? \
++ (NDSR_CS1_BBD | NDSR_CS1_CMDD) : (NDSR_CS0_BBD | NDSR_CS0_CMDD);
++
++ D1(printk("data dma interrupt, channel:%d, DCSR:0x%08x\n",
++ channel, dcsr));
++ if (dcsr & DCSR_BUSERR) {
++ info->retcode = ERR_DMABUSERR;
++ complete(&info->cmd_complete);
++ }
++
++ if (info->cmd == NAND_CMD_PAGEPROG) {
++ /* DMA interrupt may be interrupted by other IRQs*/
++ info->state = STATE_DMA_DONE;
++ dfc_enable_int(context, intm);
++ } else {
++ info->state = STATE_READY;
++ complete(&info->cmd_complete);
++ }
++
++}
++#endif
++
++static irqreturn_t monahans_dfc_irq(int irq, void *devid)
++{
++ unsigned int status, event, intm, cmd;
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)devid;
++ struct dfc_context* context = info->context;
++ struct dfc_mode* dfc_mode = context->dfc_mode;
++
++ intm = (dfc_mode->chip_select) ? \
++ (NDSR_CS1_BBD | NDSR_CS1_CMDD) : (NDSR_CS0_BBD | NDSR_CS0_CMDD);
++ event = (dfc_mode->chip_select) ? \
++ (NDSR_CS1_BBD | NDSR_CS1_CMDD) : (NDSR_CS0_BBD | NDSR_CS0_CMDD);
++
++ status = dfc_read(context, DFC_NDSR);
++ D1(printk("DFC irq, NDSR:0x%x\n", status));
++ if (status & (NDSR_RDDREQ | NDSR_DBERR)) {
++ if (status & NDSR_DBERR) {
++ info->retcode = ERR_DBERR;
++ }
++
++ dfc_disable_int(context, NDSR_RDDREQ | NDSR_DBERR);
++ dfc_clear_int(context, NDSR_RDDREQ | NDSR_DBERR);
++ if (info->cmd == NAND_CMD_READID)
++ cmd = context->flash_info->read_id;
++ else if (info->cmd == NAND_CMD_STATUS)
++ cmd = context->flash_info->read_status;
++ else if (info->cmd == NAND_CMD_READ0 ||
++ info->cmd == NAND_CMD_READOOB)
++ cmd = context->flash_info->read1;
++ else {
++ printk(KERN_ERR "No according command:0x%x happens\n",
++ info->cmd);
++ goto out;
++ }
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ info->state = STATE_DMA_TRANSFER;
++ dfc_start_data_dma(context,
++ (struct pxa_dma_desc*)info->data_desc_addr);
++#else
++ info->state = STATE_DATA_TRANSFER;
++ complete(&info->cmd_complete);
++#endif
++ } else if (status & NDSR_WRDREQ) {
++ dfc_disable_int(context, NDSR_WRDREQ);
++ dfc_clear_int(context, NDSR_WRDREQ);
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ info->state = STATE_DMA_TRANSFER;
++ dfc_start_data_dma(context,
++ (struct pxa_dma_desc*)info->data_desc_addr);
++#else
++ info->state = STATE_DATA_TRANSFER;
++ complete(&info->cmd_complete);
++#endif
++ } else if (status & event) {
++ if (status & NDSR_CS0_BBD) {
++ info->retcode = ERR_BBERR;
++ }
++
++ dfc_disable_int(context, intm);
++ dfc_clear_int(context, event);
++ info->state = STATE_READY;
++ complete(&info->cmd_complete);
++ }
++out:
++ return IRQ_HANDLED;
++}
++
++static int dfc_send_command(struct mtd_info *mtd, unsigned int cmd,
++ unsigned int addr, unsigned int num_pages,
++ unsigned int event)
++{
++
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++ struct dfc_context* context = info->context;
++ int status;
++ int ret;
++
++ D1(printk("ready send command, cmd:0x%x, at address:0x%x,"
++ " num_pages:%d, wait event:0x%x\n", cmd, addr, num_pages, event));
++
++ info->state = STATE_CMD_SEND;
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ status = dfc_setup_cmd_dma(context, cmd, addr, num_pages,
++ (uint32_t *)info->cmd_buf, info->cmd_buf_addr,
++ DDADR_STOP, DCMD_ENDIRQEN, info->cmd_desc);
++#else
++ status = dfc_send_cmd(context, cmd, addr, num_pages);
++#endif
++ if (status) {
++ info->retcode = ERR_SENDCMD;
++ dfc_stop(context);
++ udelay(20);
++ printk(KERN_ERR "fail send command\n");
++ return info->retcode;
++ }
++ info->state = STATE_CMD_HANDLE;
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_setup_data_dma(context, cmd, info->data_buf_addr,
++ DDADR_STOP, DCMD_ENDIRQEN, info->data_desc);
++ dfc_start_cmd_dma(context, (struct pxa_dma_desc*)info->cmd_desc_addr);
++#endif
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_enable_int(context, event);
++#endif
++ ret = wait_for_completion_timeout(&info->cmd_complete, 2*HZ);
++ if (!ret){
++ printk(KERN_ERR "Command time out\n");
++ dump_info(info);
++ }
++ D1(printk("command return, cmd:0x%x, retcode:%d\n",
++ info->cmd, info->retcode));
++ return 0;
++}
++
++static void monahans_df_command(struct mtd_info *mtd, unsigned command,
++ int column, int page_addr )
++{
++ struct nand_chip *this = (struct nand_chip *)(mtd->priv);
++ struct monahans_dfc_info *info =
++ (struct monahans_dfc_info *)(this->priv);
++ struct dfc_context *context = info->context;
++ struct dfc_flash_info * flash_info = context->flash_info;
++ int ret, pages_shift;
++ int status;
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ int datasize;
++ int paddingsize;
++#endif
++ unsigned int to;
++
++ D1(printk("command:0x%x at address:0x%x, column:0x%x\n",
++ command, page_addr, column));
++
++ if (info->state != STATE_READY) {
++ printk(KERN_ERR "CHIP is not ready.\n");
++ dump_info(info);
++ info->retcode = ERR_BUSY;
++ return;
++ }
++ info->retcode = ERR_NONE;
++ pages_shift = this->phys_erase_shift - this->page_shift;
++ if (info->table_init) {
++ to = search_rel_block((page_addr >> pages_shift), mtd);
++ if (to) {
++ page_addr = (to << pages_shift) | (page_addr
++ & ((1 << pages_shift) - 1));
++ }
++ }
++
++ switch ( command ) {
++ case NAND_CMD_READOOB:
++ /*
++ * DFC has mark the last 8 bytes OOB data if HARDEARE_ECC is
++ * enabled. We must first disable the HARDWARE_ECC for getting
++ * all the 16 bytes OOB
++ */
++ enable_hw_ecc(context, 0);
++ info->buf_count = mtd->writesize + mtd->oobsize;
++ info->column = mtd->writesize + column;
++ info->cmd = command;
++ info->addr = page_addr << this->page_shift;
++ ret = dfc_send_command(mtd, flash_info->read1, info->addr,
++ 1, NDSR_RDDREQ | NDSR_DBERR);
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_get_pattern(info->context, flash_info->read1, &datasize,
++ &paddingsize);
++ dfc_read_fifo_partial(info->context, info->data_buf,
++ min(info->buf_count, datasize), datasize);
++ info->state = STATE_READY;
++#endif
++ /* We only are OOB, so if the data has error, does not matter */
++ if (info->retcode == ERR_DBERR)
++ info->retcode = ERR_NONE;
++ enable_hw_ecc(context, 1);
++ break;
++
++ case NAND_CMD_READ0:
++ enable_hw_ecc(context, 1);
++ info->column = column;
++ info->cmd = command;
++ info->buf_count = mtd->writesize + mtd->oobsize;
++ memset(info->data_buf, 0xFF, info->buf_count);
++ info->addr = page_addr << this->page_shift;
++
++ ret = dfc_send_command(mtd, flash_info->read1, info->addr,
++ 1, NDSR_RDDREQ | NDSR_DBERR);
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_get_pattern(info->context, flash_info->read1, &datasize,
++ &paddingsize);
++ dfc_read_fifo_partial(info->context, info->data_buf,
++ min(info->buf_count, datasize), datasize);
++ info->state = STATE_READY;
++#endif
++ /* When the data buf is blank, the DFC will report DB error */
++ if (info->retcode == ERR_DBERR && is_buf_blank(info->data_buf,
++ mtd->writesize))
++ info->retcode = ERR_NONE;
++
++ if (info->retcode == ERR_DBERR) {
++ printk(KERN_ERR "DB error at address 0x%x\n",
++ info->addr);
++ print_buf(info->data_buf, info->buf_count);
++ }
++ break;
++ case NAND_CMD_SEQIN:
++ /* Write only OOB? */
++
++ info->cmd = command;
++ if (column >= mtd->writesize) {
++ info->buf_count = mtd->writesize + mtd->oobsize;
++ enable_hw_ecc(context, 0);
++ } else {
++ info->buf_count = mtd->writesize + mtd->oobsize;
++ enable_hw_ecc(context, 1);
++ }
++ memset(info->data_buf, 0xFF, mtd->writesize + mtd->oobsize);
++ info->column = column;
++ info->addr = page_addr << this->page_shift;
++ break;
++ case NAND_CMD_PAGEPROG:
++ /* prevois command is NAND_CMD_SEIN ?*/
++ if (info->cmd != NAND_CMD_SEQIN) {
++ info->cmd = command;
++ info->retcode = ERR_SENDCMD;
++ printk(KERN_ERR "Monahans NAND device: "
++ "No NAND_CMD_SEQIN executed before.\n");
++ enable_hw_ecc(context, 1);
++ break;
++ }
++ info->cmd = command;
++ ret = dfc_send_command(mtd, flash_info->program, info->addr,
++ 1, NDSR_WRDREQ);
++
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ if (ret != 0)
++ break;
++
++ dfc_get_pattern(info->context, flash_info->program, &datasize,
++ &paddingsize);
++ dfc_write_fifo_partial(info->context, info->data_buf, datasize,
++ datasize);
++
++ if (info->context->dfc_mode->chip_select)
++ dfc_enable_int(info->context,
++ NDSR_CS1_BBD | NDSR_CS1_CMDD);
++ else
++ dfc_enable_int(info->context,
++ NDSR_CS0_BBD | NDSR_CS0_CMDD);
++
++ ret = wait_for_completion_timeout(&info->cmd_complete, 2*HZ);
++ if (!ret){
++ printk(KERN_ERR "Programm Command time out\n");
++ dump_info(info);
++ }
++
++ if (info->retcode == ERR_BBERR) {
++ mtd->block_markbad(mtd, info->addr);
++ }
++#endif
++ break;
++ case NAND_CMD_ERASE1:
++ info->cmd = command;
++ info->addr = (page_addr >> pages_shift) << this->phys_erase_shift;
++
++ if (info->context->dfc_mode->chip_select)
++ ret = dfc_send_command(mtd, flash_info->erase,
++ info->addr, 0, NDSR_CS1_BBD | NDSR_CS1_CMDD);
++ else
++ ret = dfc_send_command(mtd, flash_info->erase,
++ info->addr, 0, NDSR_CS0_BBD | NDSR_CS0_CMDD);
++
++ if (info->retcode == ERR_BBERR) {
++ mtd->block_markbad(mtd, info->addr);
++ }
++ break;
++ case NAND_CMD_ERASE2:
++ break;
++ case NAND_CMD_READID:
++ info->cmd = command;
++ info->buf_count = flash_info->read_id_bytes;
++ info->column = 0;
++ info->addr = 0xFFFFFFFF;
++ ret = dfc_send_command(mtd, flash_info->read_id, info->addr,
++ 0, NDSR_RDDREQ);
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_get_pattern(info->context, flash_info->read_id, &datasize,
++ &paddingsize);
++ dfc_read_fifo_partial(info->context, info->data_buf,
++ info->buf_count, datasize);
++ info->state = STATE_READY;
++#endif
++ D1(printk("ReadID, [1]:0x%x, [2]:0x%x\n",
++ info->data_buf[0], info->data_buf[1]));
++ break;
++ case NAND_CMD_STATUS:
++ info->cmd = command;
++ info->buf_count = 1;
++ info->column = 0;
++ info->addr = 0xFFFFFFFF;
++ ret = dfc_send_command(mtd, flash_info->read_status,
++ info->addr, 0, NDSR_RDDREQ);
++#ifndef CONFIG_MTD_NAND_MONAHANS_DMA
++ dfc_get_pattern(info->context, flash_info->read_status,
++ &datasize, &paddingsize);
++ dfc_read_fifo_partial(info->context, info->data_buf,
++ info->buf_count, datasize);
++ info->state = STATE_READY;
++#endif
++ break;
++
++ case NAND_CMD_RESET:
++ status = dfc_reset_flash(&dfc_context);
++ if (status) {
++ printk(KERN_WARNING "Monahans NAND device:"
++ "NAND_CMD_RESET error\n");
++ }
++ break;
++ default:
++ printk(KERN_WARNING "Monahans NAND device:"
++ "Non-support the command.\n");
++ break;
++ }
++
++ if (info->retcode != ERR_NONE)
++ dfc_stop(info->context);
++}
++
++static void monahans_df_select_chip(struct mtd_info *mtd, int chip)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ if (chip <= MAX_CHIP)
++ info->context->dfc_mode->chip_select = chip;
++ else
++ printk(KERN_ERR "Monahans NAND device:"
++ "not select the NAND chips!\n");
++}
++
++static int monahans_df_waitfunc(struct mtd_info *mtd,
++ struct nand_chip *this)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ /* monahans_df_send_command has waited for command complete */
++ if (this->state == FL_WRITING || this->state == FL_ERASING) {
++ if (info->retcode == ERR_NONE)
++ return 0;
++ else {
++ /*
++ * any error make it return 0x01 which will tell
++ * the caller the erase and write fail
++ */
++ return 0x01;
++ }
++ }
++
++ return 0;
++}
++
++static int monahans_df_calculate_ecc(struct mtd_info *mtd,
++ const u_char *dat, u_char *ecc_code)
++{
++ return 0;
++}
++
++static int monahans_df_correct_data(struct mtd_info *mtd,
++ u_char *dat, u_char *read_ecc, u_char *calc_ecc)
++{
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ /*
++ * Any error include ERR_SEND_CMD, ERR_DBERR, ERR_BUSERR, we
++ * consider it as a ecc error which will tell the caller the
++ * read fail We have distinguish all the errors, but the
++ * nand_read_ecc only check this function return value
++ */
++ if (info->retcode != ERR_NONE)
++ return -1;
++
++ return 0;
++}
++
++static void monahans_df_enable_hwecc(struct mtd_info *mtd, int mode)
++{
++ return;
++}
++
++/*
++ * The relocation table management is different between MOBM V2 and V3.
++ *
++ * MOBM V2 is applied on chips taped out before MhnLV A0.
++ * MOBM V3 is applied on chips taped out after MhnLV A0. It's also applied
++ * on MhnLV A0.
++ */
++static int calc_obm_ver(void)
++{
++ unsigned int cpuid;
++ /* read CPU ID */
++ __asm__ (
++ "mrc p15, 0, %0, c0, c0, 0\n"
++ : "=r" (cpuid)
++ );
++ /* It's not xscale chip. */
++ if ((cpuid & 0xFFFF0000) != 0x69050000)
++ return MHN_OBM_INVAL;
++ /* It's MhnP Ax */
++ if ((cpuid & 0x0000FFF0) == 0x00006420)
++ return MHN_OBM_V2;
++ /* It's MhnP Bx */
++ if ((cpuid & 0x0000FFF0) == 0x00006820) {
++ if ((cpuid & 0x0F) <= 5)
++ return MHN_OBM_V2;
++ else
++ return MHN_OBM_V3;
++ }
++ /* It's MhnL Ax */
++ if ((cpuid & 0x0000FFF0) == 0x00006880) {
++ if ((cpuid & 0x0F) == 0)
++ return MHN_OBM_V2;
++ else
++ return MHN_OBM_V3;
++ }
++ /* It's MhnLV Ax */
++ if ((cpuid & 0x0000FFF0) == 0x00006890)
++ return MHN_OBM_V3;
++ return MHN_OBM_INVAL;
++}
++
++
++/*
++ * MOBM maintains a relocation table. It's used to replace bad blocks.
++ * If block A is bad, it will use block B instead.
++ * There're 127 relocated blocks. All of them reside in the bottom of NAND
++ * flash. So they're reserved and can't be calculated in mtd size and chip
++ * size.
++ */
++static int read_reloc_table(struct mtd_info *mtd)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ struct dfc_context *context = NULL;
++ struct reloc_table *table = NULL;
++ int page, maxslot;
++ int obm, valid;
++
++ obm = calc_obm_ver();
++ this = (struct nand_chip *)(mtd->priv);
++ info = (struct monahans_dfc_info *)(this->priv);
++ context = info->context;
++
++ mtd->size -= (NAND_RELOC_MAX * mtd->erasesize);
++ this->chipsize -= (NAND_RELOC_MAX << this->phys_erase_shift);
++ page = (1 << (this->phys_erase_shift - this->page_shift)) - 1;
++
++ this->select_chip(mtd, 0);
++ valid = 0;
++ if (obm == MHN_OBM_V2) {
++ /* On MOBM V2, the relocation table resides in the last page
++ * of the first block.
++ */
++ memset(info->data_buf, 0, BUFLEN);
++ monahans_df_command(mtd, NAND_CMD_READ0, 0, page);
++ memcpy(((unsigned char *)&(info->table)), info->data_buf,
++ sizeof(struct reloc_table));
++ if (info->table.header == NAND_RELOC_HEADER)
++ valid = 1;
++ } else if (obm == MHN_OBM_V3) {
++ /* On MOBM V3, there're several relocation tables in the first
++ * block.
++ * When new bad blocks are found, a new relocation table will
++ * be generated and written back to the first block. But the
++ * original relocation table won't be erased. Even if the new
++ * relocation table is written wrong, system can still find an
++ * old one.
++ * One page contains one slot.
++ */
++ maxslot = 1 << (this->phys_erase_shift - this->page_shift);
++ page = maxslot - MAX_BBT_SLOTS;
++ for (; page < maxslot; page++) {
++ monahans_df_command(mtd, NAND_CMD_READ0, 0, page);
++ table = (struct reloc_table *)info->data_buf;
++ if (info->retcode == ERR_NONE) {
++ if (table->header != NAND_RELOC_HEADER) {
++ continue;
++ } else {
++ memcpy(((unsigned char *)&(info->table)),
++ table, sizeof(struct reloc_table));
++ valid = 1;
++ break;
++ }
++ }
++ }
++
++ } else {
++ printk(KERN_ERR "The version of MOBM isn't supported\n");
++ }
++ if (valid) {
++ memcpy(((unsigned char *)&(info->table)), info->data_buf,
++ sizeof(struct reloc_table));
++ printk(KERN_DEBUG "relocation table at page:%d\n", page);
++ PRINT_BUF((unsigned char *)&(info->table),
++ sizeof(struct reloc_table));
++ info->table_init = 1;
++ } else {
++ /* There should be a valid relocation table slot at least. */
++ printk(KERN_ERR "NO VALID relocation table can be \
++ recognized\n");
++ printk(KERN_ERR "CAUTION: It may cause unpredicated error\n");
++ printk(KERN_ERR "Please re-initialize the NAND flash.\n");
++ memset((unsigned char *)&(info->table), 0,
++ sizeof(struct reloc_table));
++ info->table_init = 0;
++ return -EINVAL;
++ }
++ return 0;
++}
++
++/* add the relocation entry into the relocation table
++ * It's valid on MOBM V3.
++ * If the relocated block is bad, an new entry will be added into the
++ * bottom of the relocation table.
++ */
++static int update_rel_table(struct mtd_info *mtd, int block)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ struct reloc_table *table = NULL;
++ int obm, reloc_block;
++
++ this = (struct nand_chip *)(mtd->priv);
++ info = (struct monahans_dfc_info *)(this->priv);
++ obm = calc_obm_ver();
++ if (obm == MHN_OBM_V3) {
++ table = &info->table;
++ if (info->table_init == 0) {
++ printk(KERN_ERR "Error: the initial relocation \
++ table can't be read\n");
++ memset(table, 0, sizeof(struct reloc_table));
++ table->header = NAND_RELOC_HEADER;
++ info->table_init = 1;
++ }
++ if (table->total == 0) {
++ /* Point to the first relocated block.
++ * It resides in the last block of flash.
++ * the relocation entry has calculated in
++ * chipsize
++ */
++ reloc_block = (this->chipsize
++ >> this->phys_erase_shift)
++ + NAND_RELOC_MAX - 1;
++ } else if (table->total < NAND_RELOC_MAX) {
++ reloc_block = table->reloc[table->total - 1].to - 1;
++ } else {
++ printk(KERN_ERR "Relocation table exceed max number, \
++ cannot mark block 0x%x as bad block\n", block);
++ return -ENOSPC;
++ }
++ /* Make sure that reloc_block is pointing to a valid block */
++ for (; ; reloc_block--) {
++ /* The relocate table is full */
++ if (reloc_block < (this->chipsize
++ >> this->phys_erase_shift))
++ return -ENOSPC;
++ this->cmdfunc(mtd, NAND_CMD_ERASE1, 0, reloc_block
++ << (this->phys_erase_shift
++ - this->page_shift));
++ if (info->retcode == ERR_NONE)
++ break;
++ }
++ /* Create the relocated block information in the table */
++ table->reloc[table->total].from = block;
++ table->reloc[table->total].to = reloc_block;
++ table->total++;
++ }
++ return 0;
++}
++
++/* Write the relocation table back to device, if there's room. */
++static int sync_rel_table(struct mtd_info *mtd, int *idx)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ int obm, start_page, len;
++
++ if (*idx >= MAX_BBT_SLOTS) {
++ printk(KERN_ERR "Can't write relocation table to device \
++ any more.\n");
++ return -1;
++ }
++ if (*idx < 0) {
++ printk(KERN_ERR "Wrong Slot is specified.\n");
++ return -1;
++ }
++ this = (struct nand_chip *)(mtd->priv);
++ info = (struct monahans_dfc_info *)(this->priv);
++ len = 4;
++ len += info->table.total << 2;
++ obm = calc_obm_ver();
++ if (obm == MHN_OBM_V3) {
++ /* write to device */
++ start_page = 1 << (this->phys_erase_shift - this->page_shift);
++ start_page = start_page - 1 - *idx;
++ memset(&(info->data_buf), 0xFF, BUFLEN);
++ memcpy(&(info->data_buf), &(info->table), len);
++
++ printk(KERN_DEBUG "DUMP relocation table before write. \
++ page:0x%x\n", start_page);
++ monahans_df_command(mtd, NAND_CMD_SEQIN, 0, start_page);
++ monahans_df_command(mtd, NAND_CMD_PAGEPROG, 0, start_page);
++ /* write to idx */
++ (*idx)++;
++ /* dump it */
++ memset(&(info->data_buf), 0, BUFLEN);
++ monahans_df_command(mtd, NAND_CMD_READOOB, 0, start_page);
++ PRINT_BUF(info->data_buf, len);
++ }
++ return 0;
++}
++
++
++/* Find the relocated block of the bad one.
++ * If it's a good block, return 0. Otherwise, return a relocated one.
++ * idx points to the next relocation entry
++ * If the relocated block is bad, an new entry will be added into the
++ * bottom of the relocation table.
++ */
++static unsigned short search_rel_block(int block, struct mtd_info *mtd)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ struct reloc_table *table = NULL;
++ int i, max, reloc_block = 0;
++
++ this = (struct nand_chip *)(mtd->priv);
++ info = (struct monahans_dfc_info *)(this->priv);
++ table = &(info->table);
++ if ((block <= 0) || (block > this->chipsize)
++ || (info->table_init == 0) || (table->total == 0))
++ return 0;
++ if (table->total > NAND_RELOC_MAX)
++ table->total = NAND_RELOC_MAX;
++ max = table->total;
++ for (i = 0; i < max; i++) {
++ if (block == table->reloc[i].from)
++ reloc_block = table->reloc[i].to;
++ }
++ return reloc_block;
++}
++
++/*
++ * Check whether the block is a bad one.
++ * At first, it will search the relocation table.
++ * If necessary, it will search the BBT. Because relocation table can only
++ * maintain limited record. If there're more bad blocks, they can't be
++ * recorded in relocation table. They can only be recorded in BBT.
++ */
++static int monahans_df_block_bad(struct mtd_info *mtd, loff_t ofs, int getchip)
++{
++ struct nand_chip *this = NULL;
++ int page, block, reloc_block, chipnr, res = 0;
++ u16 bad;
++
++ /* At here, we only support one flash chip */
++ this = (struct nand_chip *)mtd->priv;
++ block = (int)(ofs >> this->phys_erase_shift);
++ /* search the block in the relocation table */
++ reloc_block = search_rel_block(block, mtd);
++ if (reloc_block) {
++ ofs = ((reloc_block << this->phys_erase_shift) |
++ (ofs & ((1 << this->phys_erase_shift) - 1)));
++ }
++
++ /* search BBT
++ * Maybe the relocation table is full, but some bad blocks aren't
++ * recordered in it.
++ * The below code are copied from nand_block_bad().
++ */
++ if (getchip) {
++ page = (int)(ofs >> this->page_shift);
++ chipnr = (int)(ofs >> this->chip_shift);
++
++ /* Select the NAND chips */
++ this->select_chip(mtd, chipnr);
++ } else
++ page = (int)ofs;
++
++ if (this->options & NAND_BUSWIDTH_16) {
++ this->cmdfunc(mtd, NAND_CMD_READOOB, this->badblockpos & 0xFE,
++ page & this->pagemask);
++ bad = cpu_to_le16(this->read_word(mtd));
++ if (this->badblockpos & 0x1)
++ bad >>= 1;
++ if ((bad & 0xFF) != 0xFF)
++ res = 1;
++ } else {
++ this->cmdfunc(mtd, NAND_CMD_READOOB, this->badblockpos,
++ page & this->pagemask);
++ if (this->read_byte(mtd) != 0xFF)
++ res = 1;
++ }
++
++ return res;
++}
++
++static int monahans_df_block_markbad(struct mtd_info *mtd, loff_t ofs)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ unsigned char buf[2] = {0, 0};
++ int block, reloc_block, page, ret;
++
++ this = (struct nand_chip *)mtd->priv;
++ info = (struct monahans_dfc_info *)(this->priv);
++ /* Get block number */
++ block = ((int)ofs) >> this->bbt_erase_shift;
++ ret = update_rel_table(mtd, block);
++ if (!ret) {
++ sync_rel_table(mtd, &(info->current_slot));
++ return 0;
++ } else {
++ reloc_block = search_rel_block(block, mtd);
++ if (reloc_block)
++ block = reloc_block;
++ if (this->bbt)
++ this->bbt[block >> 2] |= 0x01 << ((block & 0x03) << 1);
++ }
++
++ /* Do we have a flash based bad block table ? */
++ if (this->options & NAND_USE_FLASH_BBT)
++ return nand_update_bbt(mtd, ofs);
++
++ /* mark the bad block flag at the first two pages */
++ page = block << (this->phys_erase_shift - this->page_shift);
++ ofs = mtd->writesize + this->badblockpos;
++ this->cmdfunc(mtd, NAND_CMD_SEQIN, ofs, page);
++ this->write_buf(mtd, buf, 2);
++ this->cmdfunc(mtd, NAND_CMD_PAGEPROG, -1, -1);
++ page++;
++ this->cmdfunc(mtd, NAND_CMD_SEQIN, ofs, page);
++ this->write_buf(mtd, buf, 2);
++ this->cmdfunc(mtd, NAND_CMD_PAGEPROG, -1, -1);
++ return 0;
++}
++
++static int dump_bbt_flash(struct mtd_info *mtd)
++{
++ struct nand_chip *this = NULL;
++ struct monahans_dfc_info *info = NULL;
++ int block, page, totlen;
++
++ this = (struct nand_chip *)mtd->priv;
++ info = (struct monahans_dfc_info *)this->priv;
++ block = (this->chipsize >> this->phys_erase_shift) - 1;
++ totlen = (this->chipsize >> this->phys_erase_shift) >> 2;
++ printk(KERN_ERR "totlen:0x%x\n", totlen);
++ this->select_chip(mtd, 0);
++ if (this->bbt_td) {
++ printk(KERN_ERR "BBT page:0x%x\n", this->bbt_td->pages[0]);
++ page = this->bbt_td->pages[0];
++ if (this->bbt_td->pages[0] <= 0) {
++ page = block << (this->phys_erase_shift
++ - this->page_shift);
++ }
++ while (totlen > 0) {
++ printk(KERN_ERR "page:0x%x\n", page);
++ monahans_df_command(mtd, NAND_CMD_READ0, 0, page);
++ printk(KERN_ERR "read result:0x%x\n", info->retcode);
++ PRINT_BUF(info->data_buf, BUFLEN);
++ totlen -= (1 << this->page_shift);
++ page++;
++ }
++ }
++ if (this->bbt_md) {
++ printk(KERN_ERR "BBT page:0x%x\n", this->bbt_md->pages[0]);
++ page = this->bbt_md->pages[0];
++ if (this->bbt_td->pages[0] <= 0) {
++ page = block << (this->phys_erase_shift
++ - this->page_shift);
++ }
++ while (totlen > 0) {
++ printk(KERN_ERR "page:0x%x\n", page);
++ monahans_df_command(mtd, NAND_CMD_READ0, 0, page);
++ printk(KERN_ERR "read result:0x%x\n", info->retcode);
++ PRINT_BUF(info->data_buf, BUFLEN);
++ totlen -= (1 << this->page_shift);
++ page++;
++ }
++
++ }
++ return 0;
++}
++
++static int dump_bbt_mem(struct mtd_info *mtd)
++{
++ struct nand_chip *this = NULL;
++
++ this = (struct nand_chip *)mtd->priv;
++ PRINT_BUF(this->bbt, 225);
++ return 0;
++}
++
++static int monahans_df_scan_bbt(struct mtd_info *mtd)
++{
++ struct nand_chip *this = NULL;
++ int ret;
++
++ this = (struct nand_chip *)mtd->priv;
++ ret = read_reloc_table(mtd);
++ if (ret) {
++ printk(KERN_ERR "Failed to get relocation table\n");
++ printk(KERN_ERR "Try to build a new BBT. It may result \
++ unpredicated error.\n");
++ /* Create new memory based and flash based BBT */
++ }
++ nand_scan_bbt(mtd, &monahans_bbt_default);
++ //dump_bbt_flash(mtd);
++ dump_bbt_mem(mtd);
++ return 0;
++#if 0
++ /* Read flashed based BBT from device */
++ return (nand_scan_bbt(mtd, &monahans_bbt_main));
++#endif
++}
++
++
++static int monahans_df_probe(struct platform_device *pdev)
++{
++ struct nand_chip *this;
++ struct monahans_dfc_info *info;
++ int status = -1;
++ unsigned int data_buf_len;
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ unsigned int buf_len;
++#endif
++ int i, ret = 0;
++
++ printk(KERN_ERR "Nand driver probe\n");
++
++ dfc_context.membase = ioremap_nocache(0x43100000, 0x100000);
++ if (!dfc_context.membase)
++ printk(KERN_ERR "Couldn't ioremap\n");
++
++ pxa_set_cken(CKEN_NAND, 1);
++
++ for (i = DFC_FLASH_NULL + 1; i < DFC_FLASH_END; i++)
++ {
++ uint32_t id;
++
++ status = dfc_init(&dfc_context, i);
++ if (status)
++ continue;
++ status = dfc_readid(&dfc_context, &id);
++ if (status)
++ continue;
++ printk(KERN_DEBUG "id:0x%x, chipid:0x%x\n",
++ id, dfc_context.flash_info->chip_id);
++ if (id == dfc_context.flash_info->chip_id)
++ break;
++ }
++
++ if(i == DFC_FLASH_END) {
++ printk(KERN_ALERT "Monahans NAND device:"
++ "Nand Flash initialize failure!\n");
++ ret = -ENXIO;
++ goto out;
++ }
++ flash_config = i;
++
++ monahans_mtd = kzalloc(sizeof(struct mtd_info) + sizeof(struct nand_chip) +
++ sizeof(struct monahans_dfc_info) , GFP_KERNEL);
++ if (!monahans_mtd) {
++ printk (KERN_ERR "Monahans NAND device:"
++ "Unable to allocate NAND MTD device structure.\n");
++ ret = -ENOMEM;
++ goto out;
++ }
++
++ /* Get pointer to private data */
++ this = (struct nand_chip *)((void *)monahans_mtd + sizeof(struct mtd_info));
++ info = (struct monahans_dfc_info *)((void *)this + sizeof(struct nand_chip));
++ dfc_context.mtd = monahans_mtd;
++
++ monahans_mtd->priv = this;
++ this->priv = info;
++ data_buf_len = dfc_context.flash_info->page_size +
++ dfc_context.flash_info->oob_size;
++ info->state = STATE_READY;
++ init_completion(&info->cmd_complete);
++ info->table_init = 0;
++ memset(&info->table, 0x0, sizeof(struct reloc_table));
++ printk(KERN_DEBUG "%s: this->controller: 0x%x, &this->controller: 0x%x\n",__func__, (unsigned int)this->controller, (unsigned int)&(this->controller));
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ info->dma_mask = 0xffffffffUL;
++
++ dev->dma_mask = &info->dma_mask;
++ dev->coherent_dma_mask = 0xffffffffUL;
++
++ /* alloc dma data buffer for data
++ * buffer + 2*descriptor + command buffer
++ */
++ buf_len = ALIGN(2*sizeof(struct pxa_dma_desc), 32) +
++ ALIGN(data_buf_len, 32) + ALIGN(NAND_CMD_DMA_LEN, 32);
++
++ printk(KERN_INFO "Try to allocate dma buffer(len:%d)"
++ "for data buffer + 2*descriptor + command buffer\n", buf_len);
++ info->data_desc = (struct pxa_dma_desc*)dma_alloc_writecombine(dev,
++ buf_len, &info->data_desc_addr, GFP_KERNEL);
++ if (!info->data_desc) {
++ printk(KERN_ERR "Monahans NAND device:"
++ "Unable to alloc dma buffer\n");
++ ret = -ENOMEM;
++ goto free_mtd;
++ }
++
++ info->cmd_desc = (struct pxa_dma_desc*)((char *)info->data_desc +
++ sizeof(struct pxa_dma_desc));
++ info->cmd_desc_addr = (dma_addr_t)((char *)info->data_desc_addr +
++ sizeof(struct pxa_dma_desc));
++ info->data_buf = (char *)info->data_desc +
++ ALIGN(2*sizeof(struct pxa_dma_desc), 32);
++ info->data_buf_addr = (dma_addr_t)((char *)info->data_desc_addr +
++ ALIGN(2*sizeof(struct pxa_dma_desc), 32));
++ info->cmd_buf = (char *)info->data_buf + ALIGN(data_buf_len, 32);
++ info->cmd_buf_addr = (dma_addr_t)((char *)info->data_buf_addr +
++ ALIGN(data_buf_len, 32));
++
++ D1(printk("Get dma buffer for data dma descriptor, virt:0x%x, phys0x:%x\n",
++ (unsigned int)info->data_desc, info->data_desc_addr));
++ D1(printk("Get dma buffer for command dma descriptors, virt:0x%x,"
++ "phys0x:%x\n", (unsigned int)info->cmd_desc, info->cmd_desc_addr));
++ D1(printk("Get dma buffer for data, virt:0x%x, phys0x:%x\n",
++ (unsigned int)info->data_buf, info->data_buf_addr));
++ D1(printk("Get dma buffer for command, virt:0x%x, phys0x:%x\n",
++ (unsigned int)info->cmd_buf, info->cmd_buf_addr));
++
++ D1(printk("Try to allocate dma channel for data\n"));
++
++ info->data_dma = pxa_request_dma("NAND DATA", DMA_PRIO_LOW,
++ monahans_dfc_data_dma_irq, info);
++ if (info->data_dma < 0) {
++ printk(KERN_ERR "Monahans NAND device:"
++ "Unable to alloc dma channel for data\n");
++ ret = info->data_dma;
++ goto free_buf;
++ }
++ D1(printk("Get dma channel:%d for data\n", info->data_dma));
++
++ D1(printk("Try to allocate dma channel for command\n"));
++ info->cmd_dma = pxa_request_dma("NAND CMD", DMA_PRIO_LOW,
++ monahans_dfc_cmd_dma_irq, info);
++ if (info->cmd_dma < 0) {
++ printk(KERN_ERR "Monahans NAND device:"
++ "Unable to alloc dma channel for command\n");
++ ret = info->cmd_dma;
++ goto free_data_dma;
++ }
++ D1(printk("Get dma channel:%d for command\n", info->cmd_dma));
++
++ dfc_context.cmd_dma_ch = info->cmd_dma;
++ dfc_context.data_dma_ch = info->data_dma;
++#else
++ printk(KERN_DEBUG "Try to allocate data buffer(len:%d)\n", data_buf_len);
++ info->data_buf = kmalloc(data_buf_len, GFP_KERNEL);
++ if (!info->data_buf) {
++ printk(KERN_ERR "Monahans NAND device:"
++ "Unable to alloc data buffer\n");
++ ret = -ENOMEM;
++ goto free_mtd;
++ }
++#endif
++
++ D1(printk("Try to request irq:%d\n", IRQ_NAND));
++ ret = request_irq(IRQ_NAND, monahans_dfc_irq, 0, pdev->name, info);
++ if (ret < 0) {
++ printk(KERN_ERR "Monahans NAND device: Unable to request irq\n");
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ goto free_cmd_dma;
++#else
++ goto free_buf;
++#endif
++ }
++
++ D1(printk("Success request irq\n"));
++
++ /* set address of NAND IO lines */
++ this->options = (dfc_context.flash_info->flash_width == 16)? \
++ NAND_BUSWIDTH_16: 0 | NAND_USE_FLASH_BBT;
++
++ /* this->IO_ADDR_R = this->IO_ADDR_W = NDDB */
++ this->waitfunc = monahans_df_waitfunc;
++ this->select_chip = monahans_df_select_chip;
++ this->dev_ready = monahans_df_dev_ready;
++ this->cmdfunc = monahans_df_command;
++ this->read_word= monahans_df_read_word;
++ /*this->write_word= monahans_df_write_word;*/
++ this->read_byte = monahans_df_read_byte;
++ this->read_buf = monahans_df_read_buf;
++ this->write_buf = monahans_df_write_buf;
++ this->verify_buf = monahans_df_verify_buf;
++ this->ecc.hwctl = monahans_df_enable_hwecc;
++ this->ecc.calculate = monahans_df_calculate_ecc;
++ this->ecc.correct = monahans_df_correct_data;
++ this->block_bad = monahans_df_block_bad;
++ this->block_markbad = monahans_df_block_markbad;
++ this->scan_bbt = monahans_df_scan_bbt;
++ this->chip_delay= 25;
++ this->bbt_td = &monahans_bbt_main;
++ this->bbt_md = &monahans_bbt_mirror;
++
++ /* If the NAND flash is small block flash, only 512-byte pagesize
++ * is supported.
++ * Adjust parameters of BBT what is depended on large block nand
++ * flash or small block nand flash.
++ */
++ if (dfc_context.flash_info->oob_size > 16) {
++ this->ecc.layout = &monahans_lb_nand_oob;
++ this->ecc.mode = NAND_ECC_HW;
++ this->ecc.size = 2048;
++ this->ecc.bytes = 24;
++ this->bbt_td->offs = 2;
++ this->bbt_td->veroffs = 6;
++ this->bbt_md->offs = 2;
++ this->bbt_md->veroffs = 6;
++ this->badblockpos = NAND_LARGE_BADBLOCK_POS;
++ monahans_bbt_default.offs = NAND_LARGE_BADBLOCK_POS;
++ monahans_bbt_default.len = 2;
++ /* when scan_bbt() is executed, bbt version can get */
++ monahans_bbt_default.veroffs = 2;
++ } else {
++ this->ecc.layout = &monahans_sb_nand_oob;
++ this->ecc.mode = NAND_ECC_HW;
++ this->ecc.size = 512;
++ this->ecc.bytes = 6;
++ this->bbt_td->offs = 8;
++ this->bbt_td->veroffs = 12;
++ this->bbt_md->offs = 8;
++ this->bbt_md->veroffs = 12;
++ this->badblockpos = NAND_SMALL_BADBLOCK_POS;
++ monahans_bbt_default.offs = NAND_SMALL_BADBLOCK_POS;
++ monahans_bbt_default.len = 1;
++ monahans_bbt_default.veroffs = 8;
++ }
++
++ info->context = &dfc_context;
++ /* TODO: allocate dma buffer and channel */
++
++ platform_set_drvdata(pdev, monahans_mtd);
++
++ if (nand_scan(monahans_mtd, 1)) {
++ printk(KERN_ERR "Nand scan failed\n");
++ ret = -ENXIO;
++ goto free_irq;
++ }
++
++ /* There is a potential limitation that no more partition can be
++ * added between MassStorage and BBT(last block).
++ *
++ * The last 127 blocks is reserved for relocation table, they aren't
++ * statistical data of mtd size and chip size.
++ *
++ * BBT partitions contains 4 blocks. Two blocks are used to store
++ * main descriptor, the other two are used to store mirror descriptor.
++ */
++ partition_info[PART_NUM - 1].size = (monahans_bbt_main.maxblocks
++ + monahans_bbt_mirror.maxblocks)
++ << this->phys_erase_shift;
++ partition_info[PART_NUM - 1].offset = this->chipsize
++ - partition_info[PART_NUM - 1].size;
++ partition_info[PART_NUM - 2].offset = partition_info[PART_NUM - 3].offset
++ + partition_info[PART_NUM - 3].size;
++ partition_info[PART_NUM - 2].size = this->chipsize
++ - partition_info[PART_NUM - 2].offset
++ - partition_info[PART_NUM - 1].size;
++ add_mtd_partitions(monahans_mtd, partition_info, PART_NUM);
++
++#ifdef CONFIG_DVFM
++ dvfm_notifier.client_data = info;
++ mhn_fv_register_notifier(&dvfm_notifier);
++#endif
++
++ return 0;
++
++free_irq:
++ free_irq(IRQ_NAND, info);
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++free_cmd_dma:
++ pxa_free_dma(info->cmd_dma);
++free_data_dma:
++ pxa_free_dma(info->data_dma);
++free_buf:
++ dma_free_writecombine(dev, buf_len, info->data_desc, info->data_desc_addr);
++#else
++free_buf:
++ kfree(info->data_buf);
++#endif
++free_mtd:
++ kfree(monahans_mtd);
++out:
++ return ret;
++
++}
++
++static int __devexit monahans_df_remove(struct platform_device *dev)
++{
++ struct mtd_info *mtd = (struct mtd_info *)platform_get_drvdata(dev);
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ unsigned int data_buf_len = dfc_context.flash_info->page_size +
++ dfc_context.flash_info->oob_size;
++ unsigned int buf_len = ALIGN(2*sizeof(struct pxa_dma_desc), 32) +
++ ALIGN(data_buf_len, 32) + ALIGN(NAND_CMD_DMA_LEN, 32);
++#endif
++
++#ifdef CONFIG_DVFM
++ mhn_fv_unregister_notifier(&dvfm_notifier);
++#endif
++
++ platform_set_drvdata(dev, NULL);
++
++ del_mtd_device(mtd);
++ del_mtd_partitions(mtd);
++ free_irq(IRQ_NAND, info);
++#ifdef CONFIG_MTD_NAND_MONAHANS_DMA
++ pxa_free_dma(info->cmd_dma);
++ pxa_free_dma(info->data_dma);
++ dma_free_writecombine(dev, buf_len, info->data_desc,
++ info->data_desc_addr);
++#else
++ kfree(info->data_buf);
++#endif
++ kfree(mtd);
++
++ return 0;
++}
++
++#ifdef CONFIG_PM
++static int monahans_df_suspend(struct platform_device *dev, pm_message_t state, u32 level)
++{
++ struct mtd_info *mtd = (struct mtd_info *)platform_get_drvdata(dev);
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++
++ if( SUSPEND_DISABLE == level){ /*SUSPEND_NOTIFY*/
++ if (info->state != STATE_READY) {
++ printk(KERN_ERR "current state is %d\n", info->state);
++ return -EAGAIN;
++ }
++ info->state = STATE_SUSPENDED;
++ /*
++ * The PM code need read the mobm from NAND.
++ * So the NAND clock can't be stop here.
++ * The PM code will cover this.
++ */
++ /* pxa_set_cken(CKEN_NAND, 0); */
++ }
++ return 0;
++}
++
++static int monahans_df_resume(struct platform_device *dev, u32 level)
++{
++ struct mtd_info *mtd = (struct mtd_info *)platform_get_drvdata(dev);
++ struct monahans_dfc_info *info = (struct monahans_dfc_info *)
++ (((struct nand_chip *)(mtd->priv))->priv);
++ int status;
++
++ if(RESUME_ENABLE == level){
++ if (info->state != STATE_SUSPENDED)
++ printk(KERN_WARNING "Error State after resume back\n");
++
++ info->state = STATE_READY;
++
++ pxa_set_cken(CKEN_NAND, 1);
++
++ status = dfc_init(&dfc_context, flash_config);
++ if (status) {
++ printk(KERN_ALERT "Monahans NAND device:"
++ "Nand Flash initialize failure!\n");
++ return -ENXIO;
++ }
++ }
++ return 0;
++}
++#endif
++
++#ifdef CONFIG_DVFM
++static int mhn_nand_dvfm_notifier(unsigned cmd, void *client_data, void *info)
++{
++ struct monahans_dfc_info *dfc_info =
++ (struct monahans_dfc_info *)client_data;
++
++ switch (cmd) {
++ case FV_NOTIFIER_QUERY_SET :
++ if (dfc_info->state != STATE_READY)
++ return -1;
++ break;
++
++ case FV_NOTIFIER_PRE_SET :
++ break;
++
++ case FV_NOTIFIER_POST_SET :
++ break;
++ }
++
++ return 0;
++}
++#endif
++
++static struct platform_driver monahans_df_driver = {
++ .probe = monahans_df_probe,
++ .remove = __devexit_p(monahans_df_remove),
++#ifdef CONFIG_PM
++ .suspend = monahans_df_suspend,
++ .resume = monahans_df_resume,
++#endif
++ .driver = {
++ .name = "monahans-nand-flash",
++ }
++};
++
++static void __exit monahans_df_cleanup(void)
++{
++ printk(KERN_ERR "Nand driver registered\n");
++ platform_driver_unregister(&monahans_df_driver);
++}
++
++static int __init monahans_df_init(void)
++{
++ return platform_driver_register(&monahans_df_driver);
++}
++
++module_init(monahans_df_init);
++module_exit(monahans_df_cleanup);
++
++MODULE_LICENSE("GPL");
++MODULE_AUTHOR("Jingqing.xu (jingqing.xu@intel.com)");
++MODULE_DESCRIPTION("Glue logic layer for NAND flash on monahans DFC");
++
++
+Index: linux-2.6.23/arch/arm/mach-pxa/zylonite.c
+===================================================================
+--- linux-2.6.23.orig/arch/arm/mach-pxa/zylonite.c 2008-02-13 00:59:45.000000000 +0000
++++ linux-2.6.23/arch/arm/mach-pxa/zylonite.c 2008-02-13 09:11:02.000000000 +0000
+@@ -29,6 +29,8 @@
+ #include "generic.h"
+
+ int gpio_backlight;
++int gpio_vsync;
++int gpio_vsync1;
+ int gpio_eth_irq;
+
+ int lcd_id;
+@@ -54,6 +56,16 @@
+ .resource = smc91x_resources,
+ };
+
++static struct platform_device nand_device = {
++ .name = "monahans-nand-flash",
++ .id = -1,
++};
++
++static struct platform_device touch_device = {
++ .name = "pxa2xx-touch",
++ .id = -1,
++};
++
+ #if defined(CONFIG_FB_PXA) || (CONFIG_FB_PXA_MODULES)
+ static void zylonite_backlight_power(int on)
+ {
+@@ -96,7 +108,7 @@
+ };
+
+ static struct pxafb_mode_info sharp_ls037_modes[] = {
+- [0] = {
++ [1] = {
+ .pixclock = 158000,
+ .xres = 240,
+ .yres = 320,
+@@ -109,8 +121,8 @@
+ .lower_margin = 3,
+ .sync = 0,
+ },
+- [1] = {
+- .pixclock = 39700,
++ [0] = {
++ .pixclock = 45000,
+ .xres = 480,
+ .yres = 640,
+ .bpp = 16,
+@@ -137,6 +149,11 @@
+ /* backlight GPIO: output, default on */
+ gpio_direction_output(gpio_backlight, 1);
+
++ gpio_direction_output(gpio_vsync, 0);
++ gpio_direction_output(gpio_vsync1, 0);
++
++ printk(KERN_ERR "LCD ID is %x\n", lcd_id);
++
+ if (lcd_id & 0x20) {
+ set_pxa_fb_info(&zylonite_sharp_lcd_info);
+ return;
+@@ -169,6 +186,8 @@
+ smc91x_resources[1].start = gpio_to_irq(gpio_eth_irq);
+ smc91x_resources[1].end = gpio_to_irq(gpio_eth_irq);
+ platform_device_register(&smc91x_device);
++ platform_device_register(&nand_device);
++ platform_device_register(&touch_device);
+
+ zylonite_init_lcd();
+ }
+Index: linux-2.6.23/arch/arm/mach-pxa/zylonite_pxa300.c
+===================================================================
+--- linux-2.6.23.orig/arch/arm/mach-pxa/zylonite_pxa300.c 2008-02-13 00:59:45.000000000 +0000
++++ linux-2.6.23/arch/arm/mach-pxa/zylonite_pxa300.c 2008-02-13 14:01:13.000000000 +0000
+@@ -62,12 +62,12 @@
+ GPIO110_UART3_RXD,
+
+ /* AC97 */
+- GPIO23_AC97_nACRESET,
++ /*GPIO23_AC97_nACRESET,
+ GPIO24_AC97_SYSCLK,
+ GPIO29_AC97_BITCLK,
+ GPIO25_AC97_SDATA_IN_0,
+ GPIO27_AC97_SDATA_OUT,
+- GPIO28_AC97_SYNC,
++ GPIO28_AC97_SYNC,*/
+
+ /* Keypad */
+ GPIO107_KP_DKIN_0,
+@@ -104,6 +104,41 @@
+ /* Ethernet */
+ GPIO2_nCS3,
+ GPIO99_GPIO,
++
++ /* NAND */
++ MFP_CFG_X(DF_INT_RnB, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nRE_nOE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nWE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_CLE_nOE, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nADV1_ALE, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nCS0, AF1, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_nCS1, AF0, DS10X, PULL_LOW),
++ MFP_CFG_X(DF_IO0, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO1, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO2, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO3, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO4, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO5, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO6, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO7, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO8, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO9, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO10, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO11, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO12, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO13, AF1, DS08X, PULL_LOW),
++ MFP_CFG_X(DF_IO14, AF1, DS08X, PULL_LOW),
++
++ /* AC97 */
++ MFP_CFG_X(GPIO23, AF1, DS03X, PULL_LOW),
++ MFP_CFG_X(GPIO27, AF1, DS03X, PULL_LOW),
++ MFP_CFG_X(GPIO28, AF1, DS03X, PULL_LOW),
++ MFP_CFG_X(GPIO29, AF1, DS03X, PULL_LOW),
++ MFP_CFG_X(GPIO25, AF1, DS03X, PULL_LOW),
++
++ MFP_CFG_X(GPIO26, AF0, DS01X, PULL_LOW), /* Interrupt */
++ MFP_CFG_X(GPIO24, AF0, DS03X, PULL_LOW), /*SYSCLK external */
++ MFP_CFG_X(GPIO11, AF0, DS01X, PULL_LOW),
+ };
+
+ static mfp_cfg_t pxa310_mfp_cfg[] __initdata = {
+@@ -163,6 +198,9 @@
+ pxa3xx_mfp_write(lcd_detect_pins[i], mfpr_save[i]);
+ }
+
++extern int gpio_vsync;
++extern int gpio_vsync1;
++
+ void __init zylonite_pxa300_init(void)
+ {
+ if (cpu_is_pxa300() || cpu_is_pxa310()) {
+@@ -174,6 +212,8 @@
+
+ /* GPIO pin assignment */
+ gpio_backlight = mfp_to_gpio(MFP_PIN_GPIO20);
++ gpio_vsync = mfp_to_gpio(GPIO76_LCD_VSYNC);
++ gpio_vsync1 = mfp_to_gpio(GPIO71_LCD_LDD_17);
+ }
+
+ if (cpu_is_pxa300()) {
+Index: linux-2.6.23/drivers/video/pxafb.c
+===================================================================
+--- linux-2.6.23.orig/drivers/video/pxafb.c 2008-02-13 00:59:45.000000000 +0000
++++ linux-2.6.23/drivers/video/pxafb.c 2008-02-13 00:59:45.000000000 +0000
+@@ -1543,9 +1543,9 @@
+ if (inf->lccr0 & LCCR0_INVALID_CONFIG_MASK)
+ dev_warn(&dev->dev, "machine LCCR0 setting contains illegal bits: %08x\n",
+ inf->lccr0 & LCCR0_INVALID_CONFIG_MASK);
+- if (inf->lccr3 & LCCR3_INVALID_CONFIG_MASK)
+- dev_warn(&dev->dev, "machine LCCR3 setting contains illegal bits: %08x\n",
+- inf->lccr3 & LCCR3_INVALID_CONFIG_MASK);
++ //if (inf->lccr3 & LCCR3_INVALID_CONFIG_MASK)
++ // dev_warn(&dev->dev, "machine LCCR3 setting contains illegal bits: %08x\n",
++ // inf->lccr3 & LCCR3_INVALID_CONFIG_MASK);
+ if (inf->lccr0 & LCCR0_DPD &&
+ ((inf->lccr0 & LCCR0_PAS) != LCCR0_Pas ||
+ (inf->lccr0 & LCCR0_SDS) != LCCR0_Sngl ||
+Index: linux-2.6.23/include/asm-arm/arch-pxa/mfp-pxa300.h
+===================================================================
+--- linux-2.6.23.orig/include/asm-arm/arch-pxa/mfp-pxa300.h 2008-02-13 00:59:45.000000000 +0000
++++ linux-2.6.23/include/asm-arm/arch-pxa/mfp-pxa300.h 2008-02-13 00:59:45.000000000 +0000
+@@ -175,13 +175,13 @@
+ #define GPIO68_LCD_LDD_14 MFP_CFG_DRV(GPIO68, AF1, DS01X)
+ #define GPIO69_LCD_LDD_15 MFP_CFG_DRV(GPIO69, AF1, DS01X)
+ #define GPIO70_LCD_LDD_16 MFP_CFG_DRV(GPIO70, AF1, DS01X)
+-#define GPIO71_LCD_LDD_17 MFP_CFG_DRV(GPIO71, AF1, DS01X)
++#define GPIO71_LCD_LDD_17 MFP_CFG_DRV(GPIO71, AF0, DS01X)
+ #define GPIO62_LCD_CS_N MFP_CFG_DRV(GPIO62, AF2, DS01X)
+ #define GPIO72_LCD_FCLK MFP_CFG_DRV(GPIO72, AF1, DS01X)
+ #define GPIO73_LCD_LCLK MFP_CFG_DRV(GPIO73, AF1, DS01X)
+ #define GPIO74_LCD_PCLK MFP_CFG_DRV(GPIO74, AF1, DS01X)
+ #define GPIO75_LCD_BIAS MFP_CFG_DRV(GPIO75, AF1, DS01X)
+-#define GPIO76_LCD_VSYNC MFP_CFG_DRV(GPIO76, AF2, DS01X)
++#define GPIO76_LCD_VSYNC MFP_CFG_DRV(GPIO76, AF0, DS01X)
+
+ #define GPIO15_LCD_CS_N MFP_CFG_DRV(GPIO15, AF2, DS01X)
+ #define GPIO127_LCD_CS_N MFP_CFG_DRV(GPIO127, AF1, DS01X)