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/*
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 * Copyright (C) 2010 OKI SEMICONDUCTOR CO., LTD.
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 *
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 * This program is free software; you can redistribute it and/or modify
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 * it under the terms of the GNU General Public License as published by
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 * the Free Software Foundation; version 2 of the License.
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 *
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 * This program is distributed in the hope that it will be useful,
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 * but WITHOUT ANY WARRANTY; without even the implied warranty of
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 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
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 * GNU General Public License for more details.
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 *
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 * You should have received a copy of the GNU General Public License
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 * along with this program; if not, write to the Free Software
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 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307, USA.
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 */
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#include <linux/module.h>
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#include <linux/kernel.h>
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#include <linux/delay.h>
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#include <linux/init.h>
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#include <linux/errno.h>
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#include <linux/i2c.h>
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#include <linux/fs.h>
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#include <linux/io.h>
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#include <linux/types.h>
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#include <linux/interrupt.h>
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#include <linux/jiffies.h>
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#include <linux/pci.h>
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#include <linux/mutex.h>
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#include <linux/ktime.h>
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#include <linux/slab.h>
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#define PCH_EVENT_SET	0	/* I2C Interrupt Event Set Status */
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#define PCH_EVENT_NONE	1	/* I2C Interrupt Event Clear Status */
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#define PCH_MAX_CLK		100000	/* Maximum Clock speed in MHz */
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#define PCH_BUFFER_MODE_ENABLE	0x0002	/* flag for Buffer mode enable */
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#define PCH_EEPROM_SW_RST_MODE_ENABLE	0x0008	/* EEPROM SW RST enable flag */
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#define PCH_I2CSADR	0x00	/* I2C slave address register */
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#define PCH_I2CCTL	0x04	/* I2C control register */
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#define PCH_I2CSR	0x08	/* I2C status register */
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#define PCH_I2CDR	0x0C	/* I2C data register */
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#define PCH_I2CMON	0x10	/* I2C bus monitor register */
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#define PCH_I2CBC	0x14	/* I2C bus transfer rate setup counter */
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#define PCH_I2CMOD	0x18	/* I2C mode register */
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#define PCH_I2CBUFSLV	0x1C	/* I2C buffer mode slave address register */
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#define PCH_I2CBUFSUB	0x20	/* I2C buffer mode subaddress register */
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#define PCH_I2CBUFFOR	0x24	/* I2C buffer mode format register */
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#define PCH_I2CBUFCTL	0x28	/* I2C buffer mode control register */
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#define PCH_I2CBUFMSK	0x2C	/* I2C buffer mode interrupt mask register */
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#define PCH_I2CBUFSTA	0x30	/* I2C buffer mode status register */
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#define PCH_I2CBUFLEV	0x34	/* I2C buffer mode level register */
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#define PCH_I2CESRFOR	0x38	/* EEPROM software reset mode format register */
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#define PCH_I2CESRCTL	0x3C	/* EEPROM software reset mode ctrl register */
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#define PCH_I2CESRMSK	0x40	/* EEPROM software reset mode */
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#define PCH_I2CESRSTA	0x44	/* EEPROM software reset mode status register */
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#define PCH_I2CTMR	0x48	/* I2C timer register */
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#define PCH_I2CSRST	0xFC	/* I2C reset register */
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#define PCH_I2CNF	0xF8	/* I2C noise filter register */
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#define BUS_IDLE_TIMEOUT	20
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#define PCH_I2CCTL_I2CMEN	0x0080
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#define TEN_BIT_ADDR_DEFAULT	0xF000
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#define TEN_BIT_ADDR_MASK	0xF0
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#define PCH_START		0x0020
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#define PCH_ESR_START		0x0001
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#define PCH_BUFF_START		0x1
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#define PCH_REPSTART		0x0004
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#define PCH_ACK			0x0008
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#define PCH_GETACK		0x0001
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#define CLR_REG			0x0
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#define I2C_RD			0x1
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#define I2CMCF_BIT		0x0080
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#define I2CMIF_BIT		0x0002
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#define I2CMAL_BIT		0x0010
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#define I2CBMFI_BIT		0x0001
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#define I2CBMAL_BIT		0x0002
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#define I2CBMNA_BIT		0x0004
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#define I2CBMTO_BIT		0x0008
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#define I2CBMIS_BIT		0x0010
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#define I2CESRFI_BIT		0X0001
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#define I2CESRTO_BIT		0x0002
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#define I2CESRFIIE_BIT		0x1
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#define I2CESRTOIE_BIT		0x2
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#define I2CBMDZ_BIT		0x0040
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#define I2CBMAG_BIT		0x0020
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#define I2CMBB_BIT		0x0020
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#define BUFFER_MODE_MASK	(I2CBMFI_BIT | I2CBMAL_BIT | I2CBMNA_BIT | \
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				I2CBMTO_BIT | I2CBMIS_BIT)
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#define I2C_ADDR_MSK		0xFF
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#define I2C_MSB_2B_MSK		0x300
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#define FAST_MODE_CLK		400
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#define FAST_MODE_EN		0x0001
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#define SUB_ADDR_LEN_MAX	4
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#define BUF_LEN_MAX		32
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#define PCH_BUFFER_MODE		0x1
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#define EEPROM_SW_RST_MODE	0x0002
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#define NORMAL_INTR_ENBL	0x0300
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#define EEPROM_RST_INTR_ENBL	(I2CESRFIIE_BIT | I2CESRTOIE_BIT)
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#define EEPROM_RST_INTR_DISBL	0x0
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#define BUFFER_MODE_INTR_ENBL	0x001F
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#define BUFFER_MODE_INTR_DISBL	0x0
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#define NORMAL_MODE		0x0
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#define BUFFER_MODE		0x1
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#define EEPROM_SR_MODE		0x2
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#define I2C_TX_MODE		0x0010
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#define PCH_BUF_TX		0xFFF7
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#define PCH_BUF_RD		0x0008
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#define I2C_ERROR_MASK	(I2CESRTO_EVENT | I2CBMIS_EVENT | I2CBMTO_EVENT | \
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			I2CBMNA_EVENT | I2CBMAL_EVENT | I2CMAL_EVENT)
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#define I2CMAL_EVENT		0x0001
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#define I2CMCF_EVENT		0x0002
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#define I2CBMFI_EVENT		0x0004
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#define I2CBMAL_EVENT		0x0008
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#define I2CBMNA_EVENT		0x0010
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#define I2CBMTO_EVENT		0x0020
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#define I2CBMIS_EVENT		0x0040
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#define I2CESRFI_EVENT		0x0080
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#define I2CESRTO_EVENT		0x0100
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#define PCI_DEVICE_ID_PCH_I2C	0x8817
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#define pch_dbg(adap, fmt, arg...)  \
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	dev_dbg(adap->pch_adapter.dev.parent, "%s :" fmt, __func__, ##arg)
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#define pch_err(adap, fmt, arg...)  \
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	dev_err(adap->pch_adapter.dev.parent, "%s :" fmt, __func__, ##arg)
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#define pch_pci_err(pdev, fmt, arg...)  \
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	dev_err(&pdev->dev, "%s :" fmt, __func__, ##arg)
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#define pch_pci_dbg(pdev, fmt, arg...)  \
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	dev_dbg(&pdev->dev, "%s :" fmt, __func__, ##arg)
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/*
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Set the number of I2C instance max
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Intel EG20T PCH :		1ch
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OKI SEMICONDUCTOR ML7213 IOH :	2ch
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*/
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#define PCH_I2C_MAX_DEV			2
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/**
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 * struct i2c_algo_pch_data - for I2C driver functionalities
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 * @pch_adapter:		stores the reference to i2c_adapter structure
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 * @p_adapter_info:		stores the reference to adapter_info structure
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 * @pch_base_address:		specifies the remapped base address
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 * @pch_buff_mode_en:		specifies if buffer mode is enabled
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 * @pch_event_flag:		specifies occurrence of interrupt events
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 * @pch_i2c_xfer_in_progress:	specifies whether the transfer is completed
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 */
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struct i2c_algo_pch_data {
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	struct i2c_adapter pch_adapter;
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	struct adapter_info *p_adapter_info;
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	void __iomem *pch_base_address;
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	int pch_buff_mode_en;
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	u32 pch_event_flag;
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	bool pch_i2c_xfer_in_progress;
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};
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/**
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 * struct adapter_info - This structure holds the adapter information for the
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			 PCH i2c controller
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 * @pch_data:		stores a list of i2c_algo_pch_data
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 * @pch_i2c_suspended:	specifies whether the system is suspended or not
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 *			perhaps with more lines and words.
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 * @ch_num:		specifies the number of i2c instance
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 *
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 * pch_data has as many elements as maximum I2C channels
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 */
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struct adapter_info {
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	struct i2c_algo_pch_data pch_data[PCH_I2C_MAX_DEV];
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	bool pch_i2c_suspended;
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	int ch_num;
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};
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static int pch_i2c_speed = 100; /* I2C bus speed in Kbps */
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static int pch_clk = 50000;	/* specifies I2C clock speed in KHz */
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static wait_queue_head_t pch_event;
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static DEFINE_MUTEX(pch_mutex);
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/* Definition for ML7213 by OKI SEMICONDUCTOR */
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#define PCI_VENDOR_ID_ROHM		0x10DB
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#define PCI_DEVICE_ID_ML7213_I2C	0x802D
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#define PCI_DEVICE_ID_ML7223_I2C	0x8010
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static struct pci_device_id __devinitdata pch_pcidev_id[] = {
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	{ PCI_VDEVICE(INTEL, PCI_DEVICE_ID_PCH_I2C),   1, },
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	{ PCI_VDEVICE(ROHM, PCI_DEVICE_ID_ML7213_I2C), 2, },
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	{ PCI_VDEVICE(ROHM, PCI_DEVICE_ID_ML7223_I2C), 1, },
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	{0,}
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};
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static irqreturn_t pch_i2c_handler(int irq, void *pData);
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static inline void pch_setbit(void __iomem *addr, u32 offset, u32 bitmask)
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{
198
	u32 val;
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	val = ioread32(addr + offset);
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	val |= bitmask;
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	iowrite32(val, addr + offset);
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}
203

204
static inline void pch_clrbit(void __iomem *addr, u32 offset, u32 bitmask)
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{
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	u32 val;
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	val = ioread32(addr + offset);
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	val &= (~bitmask);
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	iowrite32(val, addr + offset);
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}
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/**
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 * pch_i2c_init() - hardware initialization of I2C module
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 * @adap:	Pointer to struct i2c_algo_pch_data.
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 */
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static void pch_i2c_init(struct i2c_algo_pch_data *adap)
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{
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	void __iomem *p = adap->pch_base_address;
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	u32 pch_i2cbc;
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	u32 pch_i2ctmr;
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	u32 reg_value;
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	/* reset I2C controller */
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	iowrite32(0x01, p + PCH_I2CSRST);
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	msleep(20);
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	iowrite32(0x0, p + PCH_I2CSRST);
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	/* Initialize I2C registers */
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	iowrite32(0x21, p + PCH_I2CNF);
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	pch_setbit(adap->pch_base_address, PCH_I2CCTL, PCH_I2CCTL_I2CMEN);
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	if (pch_i2c_speed != 400)
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		pch_i2c_speed = 100;
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	reg_value = PCH_I2CCTL_I2CMEN;
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	if (pch_i2c_speed == FAST_MODE_CLK) {
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		reg_value |= FAST_MODE_EN;
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		pch_dbg(adap, "Fast mode enabled\n");
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	}
241

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	if (pch_clk > PCH_MAX_CLK)
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		pch_clk = 62500;
244

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	pch_i2cbc = (pch_clk + (pch_i2c_speed * 4)) / pch_i2c_speed * 8;
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	/* Set transfer speed in I2CBC */
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	iowrite32(pch_i2cbc, p + PCH_I2CBC);
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	pch_i2ctmr = (pch_clk) / 8;
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	iowrite32(pch_i2ctmr, p + PCH_I2CTMR);
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	reg_value |= NORMAL_INTR_ENBL;	/* Enable interrupts in normal mode */
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	iowrite32(reg_value, p + PCH_I2CCTL);
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	pch_dbg(adap,
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		"I2CCTL=%x pch_i2cbc=%x pch_i2ctmr=%x Enable interrupts\n",
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		ioread32(p + PCH_I2CCTL), pch_i2cbc, pch_i2ctmr);
258

259
	init_waitqueue_head(&pch_event);
260
}
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262
static inline bool ktime_lt(const ktime_t cmp1, const ktime_t cmp2)
263
{
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	return cmp1.tv64 < cmp2.tv64;
265
}
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267
/**
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 * pch_i2c_wait_for_bus_idle() - check the status of bus.
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 * @adap:	Pointer to struct i2c_algo_pch_data.
270
 * @timeout:	waiting time counter (us).
271
 */
272
static s32 pch_i2c_wait_for_bus_idle(struct i2c_algo_pch_data *adap,
273
				     s32 timeout)
274
{
275
	void __iomem *p = adap->pch_base_address;
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277
	/* MAX timeout value is timeout*1000*1000nsec */
278
	ktime_t ns_val = ktime_add_ns(ktime_get(), timeout*1000*1000);
279
	do {
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		if ((ioread32(p + PCH_I2CSR) & I2CMBB_BIT) == 0)
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			break;
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		msleep(20);
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	} while (ktime_lt(ktime_get(), ns_val));
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285
	pch_dbg(adap, "I2CSR = %x\n", ioread32(p + PCH_I2CSR));
286

287
	if (timeout == 0) {
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		pch_err(adap, "%s: Timeout Error.return%d\n", __func__, -ETIME);
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		return -ETIME;
290
	}
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292
	return 0;
293
}
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/**
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 * pch_i2c_start() - Generate I2C start condition in normal mode.
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 * @adap:	Pointer to struct i2c_algo_pch_data.
298
 *
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 * Generate I2C start condition in normal mode by setting I2CCTL.I2CMSTA to 1.
300
 */
301
static void pch_i2c_start(struct i2c_algo_pch_data *adap)
302
{
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	void __iomem *p = adap->pch_base_address;
304
	pch_dbg(adap, "I2CCTL = %x\n", ioread32(p + PCH_I2CCTL));
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	pch_setbit(adap->pch_base_address, PCH_I2CCTL, PCH_START);
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}
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/**
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 * pch_i2c_wait_for_xfer_complete() - initiates a wait for the tx complete event
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 * @adap:	Pointer to struct i2c_algo_pch_data.
311
 */
312
static s32 pch_i2c_wait_for_xfer_complete(struct i2c_algo_pch_data *adap)
313
{
314
	s32 ret;
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	ret = wait_event_timeout(pch_event,
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			(adap->pch_event_flag != 0), msecs_to_jiffies(50));
317
	if (ret < 0) {
318
		pch_err(adap, "timeout: %x\n", adap->pch_event_flag);
319
		return ret;
320
	}
321

322
	if (ret == 0) {
323
		pch_err(adap, "timeout: %x\n", adap->pch_event_flag);
324
		return -ETIMEDOUT;
325
	}
326

327
	if (adap->pch_event_flag & I2C_ERROR_MASK) {
328
		pch_err(adap, "error bits set: %x\n", adap->pch_event_flag);
329
		return -EIO;
330
	}
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332
	adap->pch_event_flag = 0;
333

334
	return 0;
335
}
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/**
338
 * pch_i2c_getack() - to confirm ACK/NACK
339
 * @adap:	Pointer to struct i2c_algo_pch_data.
340
 */
341
static s32 pch_i2c_getack(struct i2c_algo_pch_data *adap)
342
{
343
	u32 reg_val;
344
	void __iomem *p = adap->pch_base_address;
345
	reg_val = ioread32(p + PCH_I2CSR) & PCH_GETACK;
346

347
	if (reg_val != 0) {
348
		pch_err(adap, "return%d\n", -EPROTO);
349
		return -EPROTO;
350
	}
351

352
	return 0;
353
}
354

355
/**
356
 * pch_i2c_stop() - generate stop condition in normal mode.
357
 * @adap:	Pointer to struct i2c_algo_pch_data.
358
 */
359
static void pch_i2c_stop(struct i2c_algo_pch_data *adap)
360
{
361
	void __iomem *p = adap->pch_base_address;
362
	pch_dbg(adap, "I2CCTL = %x\n", ioread32(p + PCH_I2CCTL));
363
	/* clear the start bit */
364
	pch_clrbit(adap->pch_base_address, PCH_I2CCTL, PCH_START);
365
}
366

367
/**
368
 * pch_i2c_repstart() - generate repeated start condition in normal mode
369
 * @adap:	Pointer to struct i2c_algo_pch_data.
370
 */
371
static void pch_i2c_repstart(struct i2c_algo_pch_data *adap)
372
{
373
	void __iomem *p = adap->pch_base_address;
374
	pch_dbg(adap, "I2CCTL = %x\n", ioread32(p + PCH_I2CCTL));
375
	pch_setbit(adap->pch_base_address, PCH_I2CCTL, PCH_REPSTART);
376
}
377

378
/**
379
 * pch_i2c_writebytes() - write data to I2C bus in normal mode
380
 * @i2c_adap:	Pointer to the struct i2c_adapter.
381
 * @last:	specifies whether last message or not.
382
 *		In the case of compound mode it will be 1 for last message,
383
 *		otherwise 0.
384
 * @first:	specifies whether first message or not.
385
 *		1 for first message otherwise 0.
386
 */
387
static s32 pch_i2c_writebytes(struct i2c_adapter *i2c_adap,
388
			      struct i2c_msg *msgs, u32 last, u32 first)
389
{
390
	struct i2c_algo_pch_data *adap = i2c_adap->algo_data;
391
	u8 *buf;
392
	u32 length;
393
	u32 addr;
394
	u32 addr_2_msb;
395
	u32 addr_8_lsb;
396
	s32 wrcount;
397
	void __iomem *p = adap->pch_base_address;
398

399
	length = msgs->len;
400
	buf = msgs->buf;
401
	addr = msgs->addr;
402

403
	/* enable master tx */
404
	pch_setbit(adap->pch_base_address, PCH_I2CCTL, I2C_TX_MODE);
405

406
	pch_dbg(adap, "I2CCTL = %x msgs->len = %d\n", ioread32(p + PCH_I2CCTL),
407
		length);
408

409
	if (first) {
410
		if (pch_i2c_wait_for_bus_idle(adap, BUS_IDLE_TIMEOUT) == -ETIME)
411
			return -ETIME;
412
	}
413

414
	if (msgs->flags & I2C_M_TEN) {
415
		addr_2_msb = ((addr & I2C_MSB_2B_MSK) >> 7);
416
		iowrite32(addr_2_msb | TEN_BIT_ADDR_MASK, p + PCH_I2CDR);
417
		if (first)
418
			pch_i2c_start(adap);
419
		if (pch_i2c_wait_for_xfer_complete(adap) == 0 &&
420
		    pch_i2c_getack(adap) == 0) {
421
			addr_8_lsb = (addr & I2C_ADDR_MSK);
422
			iowrite32(addr_8_lsb, p + PCH_I2CDR);
423
		} else {
424
			pch_i2c_stop(adap);
425
			return -ETIME;
426
		}
427
	} else {
428
		/* set 7 bit slave address and R/W bit as 0 */
429
		iowrite32(addr << 1, p + PCH_I2CDR);
430
		if (first)
431
			pch_i2c_start(adap);
432
	}
433

434
	if ((pch_i2c_wait_for_xfer_complete(adap) == 0) &&
435
	    (pch_i2c_getack(adap) == 0)) {
436
		for (wrcount = 0; wrcount < length; ++wrcount) {
437
			/* write buffer value to I2C data register */
438
			iowrite32(buf[wrcount], p + PCH_I2CDR);
439
			pch_dbg(adap, "writing %x to Data register\n",
440
				buf[wrcount]);
441

442
			if (pch_i2c_wait_for_xfer_complete(adap) != 0)
443
				return -ETIME;
444

445
			if (pch_i2c_getack(adap))
446
				return -EIO;
447
		}
448

449
		/* check if this is the last message */
450
		if (last)
451
			pch_i2c_stop(adap);
452
		else
453
			pch_i2c_repstart(adap);
454
	} else {
455
		pch_i2c_stop(adap);
456
		return -EIO;
457
	}
458

459
	pch_dbg(adap, "return=%d\n", wrcount);
460

461
	return wrcount;
462
}
463

464
/**
465
 * pch_i2c_sendack() - send ACK
466
 * @adap:	Pointer to struct i2c_algo_pch_data.
467
 */
468
static void pch_i2c_sendack(struct i2c_algo_pch_data *adap)
469
{
470
	void __iomem *p = adap->pch_base_address;
471
	pch_dbg(adap, "I2CCTL = %x\n", ioread32(p + PCH_I2CCTL));
472
	pch_clrbit(adap->pch_base_address, PCH_I2CCTL, PCH_ACK);
473
}
474

475
/**
476
 * pch_i2c_sendnack() - send NACK
477
 * @adap:	Pointer to struct i2c_algo_pch_data.
478
 */
479
static void pch_i2c_sendnack(struct i2c_algo_pch_data *adap)
480
{
481
	void __iomem *p = adap->pch_base_address;
482
	pch_dbg(adap, "I2CCTL = %x\n", ioread32(p + PCH_I2CCTL));
483
	pch_setbit(adap->pch_base_address, PCH_I2CCTL, PCH_ACK);
484
}
485

486
/**
487
 * pch_i2c_readbytes() - read data  from I2C bus in normal mode.
488
 * @i2c_adap:	Pointer to the struct i2c_adapter.
489
 * @msgs:	Pointer to i2c_msg structure.
490
 * @last:	specifies whether last message or not.
491
 * @first:	specifies whether first message or not.
492
 */
493
static s32 pch_i2c_readbytes(struct i2c_adapter *i2c_adap, struct i2c_msg *msgs,
494
			     u32 last, u32 first)
495
{
496
	struct i2c_algo_pch_data *adap = i2c_adap->algo_data;
497

498
	u8 *buf;
499
	u32 count;
500
	u32 length;
501
	u32 addr;
502
	u32 addr_2_msb;
503
	void __iomem *p = adap->pch_base_address;
504

505
	length = msgs->len;
506
	buf = msgs->buf;
507
	addr = msgs->addr;
508

509
	/* enable master reception */
510
	pch_clrbit(adap->pch_base_address, PCH_I2CCTL, I2C_TX_MODE);
511

512
	if (first) {
513
		if (pch_i2c_wait_for_bus_idle(adap, BUS_IDLE_TIMEOUT) == -ETIME)
514
			return -ETIME;
515
	}
516

517
	if (msgs->flags & I2C_M_TEN) {
518
		addr_2_msb = (((addr & I2C_MSB_2B_MSK) >> 7) | (I2C_RD));
519
		iowrite32(addr_2_msb | TEN_BIT_ADDR_MASK, p + PCH_I2CDR);
520

521
	} else {
522
		/* 7 address bits + R/W bit */
523
		addr = (((addr) << 1) | (I2C_RD));
524
		iowrite32(addr, p + PCH_I2CDR);
525
	}
526

527
	/* check if it is the first message */
528
	if (first)
529
		pch_i2c_start(adap);
530

531
	if ((pch_i2c_wait_for_xfer_complete(adap) == 0) &&
532
	    (pch_i2c_getack(adap) == 0)) {
533
		pch_dbg(adap, "return %d\n", 0);
534

535
		if (length == 0) {
536
			pch_i2c_stop(adap);
537
			ioread32(p + PCH_I2CDR); /* Dummy read needs */
538

539
			count = length;
540
		} else {
541
			int read_index;
542
			int loop;
543
			pch_i2c_sendack(adap);
544

545
			/* Dummy read */
546
			for (loop = 1, read_index = 0; loop < length; loop++) {
547
				buf[read_index] = ioread32(p + PCH_I2CDR);
548

549
				if (loop != 1)
550
					read_index++;
551

552
				if (pch_i2c_wait_for_xfer_complete(adap) != 0) {
553
					pch_i2c_stop(adap);
554
					return -ETIME;
555
				}
556
			}	/* end for */
557

558
			pch_i2c_sendnack(adap);
559

560
			buf[read_index] = ioread32(p + PCH_I2CDR);
561

562
			if (length != 1)
563
				read_index++;
564

565
			if (pch_i2c_wait_for_xfer_complete(adap) == 0) {
566
				if (last)
567
					pch_i2c_stop(adap);
568
				else
569
					pch_i2c_repstart(adap);
570

571
				buf[read_index++] = ioread32(p + PCH_I2CDR);
572
				count = read_index;
573
			} else {
574
				count = -ETIME;
575
			}
576

577
		}
578
	} else {
579
		count = -ETIME;
580
		pch_i2c_stop(adap);
581
	}
582

583
	return count;
584
}
585

586
/**
587
 * pch_i2c_cb() - Interrupt handler Call back function
588
 * @adap:	Pointer to struct i2c_algo_pch_data.
589
 */
590
static void pch_i2c_cb(struct i2c_algo_pch_data *adap)
591
{
592
	u32 sts;
593
	void __iomem *p = adap->pch_base_address;
594

595
	sts = ioread32(p + PCH_I2CSR);
596
	sts &= (I2CMAL_BIT | I2CMCF_BIT | I2CMIF_BIT);
597
	if (sts & I2CMAL_BIT)
598
		adap->pch_event_flag |= I2CMAL_EVENT;
599

600
	if (sts & I2CMCF_BIT)
601
		adap->pch_event_flag |= I2CMCF_EVENT;
602

603
	/* clear the applicable bits */
604
	pch_clrbit(adap->pch_base_address, PCH_I2CSR, sts);
605

606
	pch_dbg(adap, "PCH_I2CSR = %x\n", ioread32(p + PCH_I2CSR));
607

608
	wake_up(&pch_event);
609
}
610

611
/**
612
 * pch_i2c_handler() - interrupt handler for the PCH I2C controller
613
 * @irq:	irq number.
614
 * @pData:	cookie passed back to the handler function.
615
 */
616
static irqreturn_t pch_i2c_handler(int irq, void *pData)
617
{
618
	u32 reg_val;
619
	int flag;
620
	int i;
621
	struct adapter_info *adap_info = pData;
622
	void __iomem *p;
623
	u32 mode;
624

625
	for (i = 0, flag = 0; i < adap_info->ch_num; i++) {
626
		p = adap_info->pch_data[i].pch_base_address;
627
		mode = ioread32(p + PCH_I2CMOD);
628
		mode &= BUFFER_MODE | EEPROM_SR_MODE;
629
		if (mode != NORMAL_MODE) {
630
			pch_err(adap_info->pch_data,
631
				"I2C-%d mode(%d) is not supported\n", mode, i);
632
			continue;
633
		}
634
		reg_val = ioread32(p + PCH_I2CSR);
635
		if (reg_val & (I2CMAL_BIT | I2CMCF_BIT | I2CMIF_BIT)) {
636
			pch_i2c_cb(&adap_info->pch_data[i]);
637
			flag = 1;
638
		}
639
	}
640

641
	return flag ? IRQ_HANDLED : IRQ_NONE;
642
}
643

644
/**
645
 * pch_i2c_xfer() - Reading adnd writing data through I2C bus
646
 * @i2c_adap:	Pointer to the struct i2c_adapter.
647
 * @msgs:	Pointer to i2c_msg structure.
648
 * @num:	number of messages.
649
 */
650
static s32 pch_i2c_xfer(struct i2c_adapter *i2c_adap,
651
			struct i2c_msg *msgs, s32 num)
652
{
653
	struct i2c_msg *pmsg;
654
	u32 i = 0;
655
	u32 status;
656
	u32 msglen;
657
	u32 subaddrlen;
658
	s32 ret;
659

660
	struct i2c_algo_pch_data *adap = i2c_adap->algo_data;
661

662
	ret = mutex_lock_interruptible(&pch_mutex);
663
	if (ret)
664
		return -ERESTARTSYS;
665

666
	if (adap->p_adapter_info->pch_i2c_suspended) {
667
		mutex_unlock(&pch_mutex);
668
		return -EBUSY;
669
	}
670

671
	pch_dbg(adap, "adap->p_adapter_info->pch_i2c_suspended is %d\n",
672
		adap->p_adapter_info->pch_i2c_suspended);
673
	/* transfer not completed */
674
	adap->pch_i2c_xfer_in_progress = true;
675

676
	pmsg = &msgs[0];
677
	pmsg->flags |= adap->pch_buff_mode_en;
678
	status = pmsg->flags;
679
	pch_dbg(adap,
680
		"After invoking I2C_MODE_SEL :flag= 0x%x\n", status);
681
	/* calculate sub address length and message length */
682
	/* these are applicable only for buffer mode */
683
	subaddrlen = pmsg->buf[0];
684
	/* calculate actual message length excluding
685
	 * the sub address fields */
686
	msglen = (pmsg->len) - (subaddrlen + 1);
687
	if (status & (I2C_M_RD)) {
688
		pch_dbg(adap, "invoking pch_i2c_readbytes\n");
689
		ret = pch_i2c_readbytes(i2c_adap, pmsg, (i + 1 == num),
690
				   (i == 0));
691
	} else {
692
		pch_dbg(adap, "invoking pch_i2c_writebytes\n");
693
		ret = pch_i2c_writebytes(i2c_adap, pmsg, (i + 1 == num),
694
				    (i == 0));
695
	}
696

697
	adap->pch_i2c_xfer_in_progress = false;	/* transfer completed */
698

699
	mutex_unlock(&pch_mutex);
700

701
	return ret;
702
}
703

704
/**
705
 * pch_i2c_func() - return the functionality of the I2C driver
706
 * @adap:	Pointer to struct i2c_algo_pch_data.
707
 */
708
static u32 pch_i2c_func(struct i2c_adapter *adap)
709
{
710
	return I2C_FUNC_I2C | I2C_FUNC_SMBUS_EMUL | I2C_FUNC_10BIT_ADDR;
711
}
712

713
static struct i2c_algorithm pch_algorithm = {
714
	.master_xfer = pch_i2c_xfer,
715
	.functionality = pch_i2c_func
716
};
717

718
/**
719
 * pch_i2c_disbl_int() - Disable PCH I2C interrupts
720
 * @adap:	Pointer to struct i2c_algo_pch_data.
721
 */
722
static void pch_i2c_disbl_int(struct i2c_algo_pch_data *adap)
723
{
724
	void __iomem *p = adap->pch_base_address;
725

726
	pch_clrbit(adap->pch_base_address, PCH_I2CCTL, NORMAL_INTR_ENBL);
727

728
	iowrite32(EEPROM_RST_INTR_DISBL, p + PCH_I2CESRMSK);
729

730
	iowrite32(BUFFER_MODE_INTR_DISBL, p + PCH_I2CBUFMSK);
731
}
732

733
static int __devinit pch_i2c_probe(struct pci_dev *pdev,
734
				   const struct pci_device_id *id)
735
{
736
	void __iomem *base_addr;
737
	int ret;
738
	int i, j;
739
	struct adapter_info *adap_info;
740
	struct i2c_adapter *pch_adap;
741

742
	pch_pci_dbg(pdev, "Entered.\n");
743

744
	adap_info = kzalloc((sizeof(struct adapter_info)), GFP_KERNEL);
745
	if (adap_info == NULL) {
746
		pch_pci_err(pdev, "Memory allocation FAILED\n");
747
		return -ENOMEM;
748
	}
749

750
	ret = pci_enable_device(pdev);
751
	if (ret) {
752
		pch_pci_err(pdev, "pci_enable_device FAILED\n");
753
		goto err_pci_enable;
754
	}
755

756
	ret = pci_request_regions(pdev, KBUILD_MODNAME);
757
	if (ret) {
758
		pch_pci_err(pdev, "pci_request_regions FAILED\n");
759
		goto err_pci_req;
760
	}
761

762
	base_addr = pci_iomap(pdev, 1, 0);
763

764
	if (base_addr == NULL) {
765
		pch_pci_err(pdev, "pci_iomap FAILED\n");
766
		ret = -ENOMEM;
767
		goto err_pci_iomap;
768
	}
769

770
	/* Set the number of I2C channel instance */
771
	adap_info->ch_num = id->driver_data;
772

773
	for (i = 0; i < adap_info->ch_num; i++) {
774
		pch_adap = &adap_info->pch_data[i].pch_adapter;
775
		adap_info->pch_i2c_suspended = false;
776

777
		adap_info->pch_data[i].p_adapter_info = adap_info;
778

779
		pch_adap->owner = THIS_MODULE;
780
		pch_adap->class = I2C_CLASS_HWMON;
781
		strcpy(pch_adap->name, KBUILD_MODNAME);
782
		pch_adap->algo = &pch_algorithm;
783
		pch_adap->algo_data = &adap_info->pch_data[i];
784

785
		/* base_addr + offset; */
786
		adap_info->pch_data[i].pch_base_address = base_addr + 0x100 * i;
787

788
		pch_adap->dev.parent = &pdev->dev;
789

790
		ret = i2c_add_adapter(pch_adap);
791
		if (ret) {
792
			pch_pci_err(pdev, "i2c_add_adapter[ch:%d] FAILED\n", i);
793
			goto err_i2c_add_adapter;
794
		}
795

796
		pch_i2c_init(&adap_info->pch_data[i]);
797
	}
798
	ret = request_irq(pdev->irq, pch_i2c_handler, IRQF_SHARED,
799
		  KBUILD_MODNAME, adap_info);
800
	if (ret) {
801
		pch_pci_err(pdev, "request_irq FAILED\n");
802
		goto err_i2c_add_adapter;
803
	}
804

805
	pci_set_drvdata(pdev, adap_info);
806
	pch_pci_dbg(pdev, "returns %d.\n", ret);
807
	return 0;
808

809
err_i2c_add_adapter:
810
	for (j = 0; j < i; j++)
811
		i2c_del_adapter(&adap_info->pch_data[j].pch_adapter);
812
	pci_iounmap(pdev, base_addr);
813
err_pci_iomap:
814
	pci_release_regions(pdev);
815
err_pci_req:
816
	pci_disable_device(pdev);
817
err_pci_enable:
818
	kfree(adap_info);
819
	return ret;
820
}
821

822
static void __devexit pch_i2c_remove(struct pci_dev *pdev)
823
{
824
	int i;
825
	struct adapter_info *adap_info = pci_get_drvdata(pdev);
826

827
	free_irq(pdev->irq, adap_info);
828

829
	for (i = 0; i < adap_info->ch_num; i++) {
830
		pch_i2c_disbl_int(&adap_info->pch_data[i]);
831
		i2c_del_adapter(&adap_info->pch_data[i].pch_adapter);
832
	}
833

834
	if (adap_info->pch_data[0].pch_base_address)
835
		pci_iounmap(pdev, adap_info->pch_data[0].pch_base_address);
836

837
	for (i = 0; i < adap_info->ch_num; i++)
838
		adap_info->pch_data[i].pch_base_address = 0;
839

840
	pci_set_drvdata(pdev, NULL);
841

842
	pci_release_regions(pdev);
843

844
	pci_disable_device(pdev);
845
	kfree(adap_info);
846
}
847

848
#ifdef CONFIG_PM
849
static int pch_i2c_suspend(struct pci_dev *pdev, pm_message_t state)
850
{
851
	int ret;
852
	int i;
853
	struct adapter_info *adap_info = pci_get_drvdata(pdev);
854
	void __iomem *p = adap_info->pch_data[0].pch_base_address;
855

856
	adap_info->pch_i2c_suspended = true;
857

858
	for (i = 0; i < adap_info->ch_num; i++) {
859
		while ((adap_info->pch_data[i].pch_i2c_xfer_in_progress)) {
860
			/* Wait until all channel transfers are completed */
861
			msleep(20);
862
		}
863
	}
864

865
	/* Disable the i2c interrupts */
866
	for (i = 0; i < adap_info->ch_num; i++)
867
		pch_i2c_disbl_int(&adap_info->pch_data[i]);
868

869
	pch_pci_dbg(pdev, "I2CSR = %x I2CBUFSTA = %x I2CESRSTA = %x "
870
		"invoked function pch_i2c_disbl_int successfully\n",
871
		ioread32(p + PCH_I2CSR), ioread32(p + PCH_I2CBUFSTA),
872
		ioread32(p + PCH_I2CESRSTA));
873

874
	ret = pci_save_state(pdev);
875

876
	if (ret) {
877
		pch_pci_err(pdev, "pci_save_state\n");
878
		return ret;
879
	}
880

881
	pci_enable_wake(pdev, PCI_D3hot, 0);
882
	pci_disable_device(pdev);
883
	pci_set_power_state(pdev, pci_choose_state(pdev, state));
884

885
	return 0;
886
}
887

888
static int pch_i2c_resume(struct pci_dev *pdev)
889
{
890
	int i;
891
	struct adapter_info *adap_info = pci_get_drvdata(pdev);
892

893
	pci_set_power_state(pdev, PCI_D0);
894
	pci_restore_state(pdev);
895

896
	if (pci_enable_device(pdev) < 0) {
897
		pch_pci_err(pdev, "pch_i2c_resume:pci_enable_device FAILED\n");
898
		return -EIO;
899
	}
900

901
	pci_enable_wake(pdev, PCI_D3hot, 0);
902

903
	for (i = 0; i < adap_info->ch_num; i++)
904
		pch_i2c_init(&adap_info->pch_data[i]);
905

906
	adap_info->pch_i2c_suspended = false;
907

908
	return 0;
909
}
910
#else
911
#define pch_i2c_suspend NULL
912
#define pch_i2c_resume NULL
913
#endif
914

915
static struct pci_driver pch_pcidriver = {
916
	.name = KBUILD_MODNAME,
917
	.id_table = pch_pcidev_id,
918
	.probe = pch_i2c_probe,
919
	.remove = __devexit_p(pch_i2c_remove),
920
	.suspend = pch_i2c_suspend,
921
	.resume = pch_i2c_resume
922
};
923

924
static int __init pch_pci_init(void)
925
{
926
	return pci_register_driver(&pch_pcidriver);
927
}
928
module_init(pch_pci_init);
929

930
static void __exit pch_pci_exit(void)
931
{
932
	pci_unregister_driver(&pch_pcidriver);
933
}
934
module_exit(pch_pci_exit);
935

936
MODULE_DESCRIPTION("Intel EG20T PCH/OKI SEMICONDUCTOR ML7213 IOH I2C Driver");
937
MODULE_LICENSE("GPL");
938
MODULE_AUTHOR("Tomoya MORINAGA. <[email protected]>");
939
module_param(pch_i2c_speed, int, (S_IRUSR | S_IWUSR));
940
module_param(pch_clk, int, (S_IRUSR | S_IWUSR));
941

942