/* * Copyright (c) 2014 The DragonFly Project. All rights reserved. * * This code is derived from software contributed to The DragonFly Project * by Matthew Dillon and was subsequently ported * to FreeBSD by Michael Gmelin * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name of The DragonFly Project nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific, prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Intel fourth generation mobile cpus integrated I2C device. * * Datasheet reference: Section 22. * * https://www.intel.com/content/dam/www/public/us/en/documents/datasheets/4th-gen-core-family-mobile-i-o-datasheet.pdf * * This is a from-scratch driver under the BSD license using the Intel data * sheet and the linux driver for reference. All code is freshly written * without referencing the linux driver code. However, during testing * I am also using the linux driver code as a reference to help resolve any * issues that come. These will be specifically documented in the code. * * This controller is an I2C master only and cannot act as a slave. The IO * voltage should be set by the BIOS. Standard (100Kb/s) and Fast (400Kb/s) * and fast mode plus (1MB/s) is supported. High speed mode (3.4 MB/s) is NOT * supported. */ #ifndef _ICHIIC_IG4_REG_H_ #define _ICHIIC_IG4_REG_H_ /* * 22.2 MMIO registers can be accessed through BAR0 in PCI mode or through * BAR1 when in ACPI mode. * * Register width is 32-bits * * 22.2 Default Values on device reset are 0 except as specified here: * TAR_ADD 0x00000055 * SS_SCL_HCNT 0x00000264 * SS_SCL_LCNT 0x000002C2 * FS_SCL_HCNT 0x0000006E * FS_SCL_LCNT 0x000000CF * INTR_MASK 0x000008FF * I2C_STA 0x00000006 * SDA_HOLD 0x00000001 * SDA_SETUP 0x00000064 * COMP_PARAM1 0x00FFFF6E */ #define IG4_REG_CTL 0x0000 /* RW Control Register */ #define IG4_REG_TAR_ADD 0x0004 /* RW Target Address */ #define IG4_REG_HS_MADDR 0x000C /* RW High Speed Master Mode Code Address*/ #define IG4_REG_DATA_CMD 0x0010 /* RW Data Buffer and Command */ #define IG4_REG_SS_SCL_HCNT 0x0014 /* RW Std Speed clock High Count */ #define IG4_REG_SS_SCL_LCNT 0x0018 /* RW Std Speed clock Low Count */ #define IG4_REG_FS_SCL_HCNT 0x001C /* RW Fast Speed clock High Count */ #define IG4_REG_FS_SCL_LCNT 0x0020 /* RW Fast Speed clock Low Count */ #define IG4_REG_INTR_STAT 0x002C /* RO Interrupt Status */ #define IG4_REG_INTR_MASK 0x0030 /* RW Interrupt Mask */ #define IG4_REG_RAW_INTR_STAT 0x0034 /* RO Raw Interrupt Status */ #define IG4_REG_RX_TL 0x0038 /* RW Receive FIFO Threshold */ #define IG4_REG_TX_TL 0x003C /* RW Transmit FIFO Threshold */ #define IG4_REG_CLR_INTR 0x0040 /* RO Clear Interrupt */ #define IG4_REG_CLR_RX_UNDER 0x0044 /* RO Clear RX_Under Interrupt */ #define IG4_REG_CLR_RX_OVER 0x0048 /* RO Clear RX_Over Interrupt */ #define IG4_REG_CLR_TX_OVER 0x004C /* RO Clear TX_Over Interrupt */ #define IG4_REG_CLR_RD_REQ 0x0050 /* RO Clear RD_Req Interrupt */ #define IG4_REG_CLR_TX_ABORT 0x0054 /* RO Clear TX_Abort Interrupt */ #define IG4_REG_CLR_RX_DONE 0x0058 /* RO Clear RX_Done Interrupt */ #define IG4_REG_CLR_ACTIVITY 0x005C /* RO Clear Activity Interrupt */ #define IG4_REG_CLR_STOP_DET 0x0060 /* RO Clear STOP Detection Int */ #define IG4_REG_CLR_START_DET 0x0064 /* RO Clear START Detection Int */ #define IG4_REG_CLR_GEN_CALL 0x0068 /* RO Clear General Call Interrupt */ #define IG4_REG_I2C_EN 0x006C /* RW I2C Enable */ #define IG4_REG_I2C_STA 0x0070 /* RO I2C Status */ #define IG4_REG_TXFLR 0x0074 /* RO Transmit FIFO Level */ #define IG4_REG_RXFLR 0x0078 /* RO Receive FIFO Level */ #define IG4_REG_SDA_HOLD 0x007C /* RW SDA Hold Time Length */ #define IG4_REG_TX_ABRT_SOURCE 0x0080 /* RO Transmit Abort Source */ #define IG4_REG_SLV_DATA_NACK 0x0084 /* RW General Slave Data NACK */ #define IG4_REG_DMA_CTRL 0x0088 /* RW DMA Control */ #define IG4_REG_DMA_TDLR 0x008C /* RW DMA Transmit Data Level */ #define IG4_REG_DMA_RDLR 0x0090 /* RW DMA Receive Data Level */ #define IG4_REG_SDA_SETUP 0x0094 /* RW SDA Setup */ #define IG4_REG_ACK_GENERAL_CALL 0x0098 /* RW I2C ACK General Call */ #define IG4_REG_ENABLE_STATUS 0x009C /* RO Enable Status */ /* Available at least on Atom SoCs, Haswell mobile and some Skylakes. */ #define IG4_REG_COMP_PARAM1 0x00F4 /* RO Component Parameter */ #define IG4_REG_COMP_VER 0x00F8 /* RO Component Version */ /* Available at least on Atom SoCs */ #define IG4_REG_COMP_TYPE 0x00FC /* RO Probe width/endian? (linux) */ /* 0x200-0x2FF - Additional registers available on Skylake-U/Y and others */ #define IG4_REG_RESETS_SKL 0x0204 /* RW Reset Register */ #define IG4_REG_ACTIVE_LTR_VALUE 0x0210 /* RW Active LTR Value */ #define IG4_REG_IDLE_LTR_VALUE 0x0214 /* RW Idle LTR Value */ #define IG4_REG_TX_ACK_COUNT 0x0218 /* RO TX ACK Count */ #define IG4_REG_RX_BYTE_COUNT 0x021C /* RO RX ACK Count */ #define IG4_REG_DEVIDLE_CTRL 0x024C /* RW Device Control */ /* Available at least on Atom SoCs */ #define IG4_REG_CLK_PARMS 0x0800 /* RW Clock Parameters */ /* Available at least on Atom SoCs and Haswell mobile */ #define IG4_REG_RESETS_HSW 0x0804 /* RW Reset Register */ #define IG4_REG_GENERAL 0x0808 /* RW General Register */ /* These LTR config registers are at least available on Haswell mobile. */ #define IG4_REG_SW_LTR_VALUE 0x0810 /* RW SW LTR Value */ #define IG4_REG_AUTO_LTR_VALUE 0x0814 /* RW Auto LTR Value */ /* * CTL - Control Register 22.2.1 * Default Value: 0x0000007F. * * RESTARTEN - RW Restart Enable * 10BIT - RW Controller operates in 10-bit mode, else 7-bit * * NOTE: When restart is disabled the controller is incapable of * performing the following functions: * * Sending a START Byte * Performing any high-speed mode op * Performing direction changes in combined format mode * Performing a read operation with a 10-bit address * * Attempting to perform the above operations will result in the * TX_ABORT bit being set in RAW_INTR_STAT. */ #define IG4_CTL_SLAVE_DISABLE 0x0040 /* snarfed from linux */ #define IG4_CTL_RESTARTEN 0x0020 /* Allow Restart when master */ #define IG4_CTL_10BIT 0x0010 /* ctlr accepts 10-bit addresses */ #define IG4_CTL_SPEED_MASK 0x0006 /* speed at which the I2C operates */ #define IG4_CTL_MASTER 0x0001 /* snarfed from linux */ #define IG4_CTL_SPEED_HIGH 0x0006 /* snarfed from linux */ #define IG4_CTL_SPEED_FAST 0x0004 /* snarfed from linux */ #define IG4_CTL_SPEED_STD 0x0002 /* snarfed from linux */ /* * TAR_ADD - Target Address Register 22.2.2 * Default Value: 0x00000055F * * 10BIT - RW controller starts its transfers in 10-bit * address mode, else 7-bit. * * SPECIAL - RW Indicates whether software performs a General Call * or START BYTE command. * * 0 Ignore GC_OR_START and use TAR address. * * 1 Perform special I2C Command based on GC_OR_START. * * GC_OR_START - RW (only if SPECIAL is set) * * 0 General Call Address. After issuing a General Call, * only writes may be performed. Attempting to issue * a read command results in IX_ABRT in RAW_INTR_STAT. * The controller remains in General Call mode until * bit 11 (SPECIAL) is cleared. * * 1 START BYTE. * * * IC_TAR - RW when transmitting a general call, these bits are * ignored. To generate a START BYTE, the address * needs to be written into these bits once. * * This register should only be updated when the IIC is disabled (I2C_ENABLE=0) */ #define IG4_TAR_10BIT 0x1000 /* start xfer in 10-bit mode */ #define IG4_TAR_SPECIAL 0x0800 /* Perform special command */ #define IG4_TAR_GC_OR_START 0x0400 /* General Call or Start */ #define IG4_TAR_ADDR_MASK 0x03FF /* Target address */ /* * TAR_DATA_CMD - Data Buffer and Command Register 22.2.3 * * RESTART - RW This bit controls whether a forced RESTART is * issued before the byte is sent or received. * * 0 If not set a RESTART is only issued if the transfer * direction is changing from the previous command. * * 1 A RESTART is issued before the byte is sent or * received, regardless of whether or not the transfer * direction is changing from the previous command. * * STOP - RW This bit controls whether a STOP is issued after * the byte is sent or received. * * 0 STOP is not issued after this byte, regardless * of whether or not the Tx FIFO is empty. * * 1 STOP is issued after this byte, regardless of * whether or not the Tx FIFO is empty. If the * Tx FIFO is not empty the master immediately tries * to start a new transfer by issuing a START and * arbitrating for the bus. * * i.e. the STOP is issued along with this byte, * within the write stream. * * COMMAND - RW Control whether a read or write is performed. * * 0 WRITE * * 1 READ * * DATA (7:0) - RW Contains the data to be transmitted or received * on the I2C bus. * * NOTE: Writing to this register causes a START + slave + RW to be * issued if the direction has changed or the last data byte was * sent with a STOP. * * NOTE: We control termination? so this register must be written * for each byte we wish to receive. We can then drain the * receive FIFO. */ #define IG4_DATA_RESTART 0x0400 /* Force RESTART */ #define IG4_DATA_STOP 0x0200 /* Force STOP[+START] */ #define IG4_DATA_COMMAND_RD 0x0100 /* bus direction 0=write 1=read */ #define IG4_DATA_MASK 0x00FF /* * SS_SCL_HCNT - Standard Speed Clock High Count Register 22.2.4 * SS_SCL_LCNT - Standard Speed Clock Low Count Register 22.2.5 * FS_SCL_HCNT - Fast Speed Clock High Count Register 22.2.6 * FS_SCL_LCNT - Fast Speed Clock Low Count Register 22.2.7 * * COUNT (15:0) - Set the period count to a value between 6 and * 65525. */ #define IG4_SCL_CLOCK_MASK 0xFFFFU /* count bits in register */ /* * INTR_STAT - (RO) Interrupt Status Register 22.2.8 * INTR_MASK - (RW) Interrupt Mask Register 22.2.9 * RAW_INTR_STAT- (RO) Raw Interrupt Status Register 22.2.10 * * GEN_CALL Set only when a general call (broadcast) address * is received and acknowleged, stays set until * cleared by reading CLR_GEN_CALL. * * START_DET Set when a START or RESTART condition has occurred * on the interface. * * STOP_DET Set when a STOP condition has occurred on the * interface. * * ACTIVITY Set by any activity on the interface. Cleared * by reading CLR_ACTIVITY or CLR_INTR. * * TX_ABRT Indicates the controller as a transmitter is * unable to complete the intended action. When set, * the controller will hold the TX FIFO in a reset * state (flushed) until CLR_TX_ABORT is read to * clear the condition. Once cleared, the TX FIFO * will be available again. * * TX_EMPTY Indicates that the transmitter is at or below * the specified TX_TL threshold. Automatically * cleared by HW when the buffer level goes above * the threshold. * * TX_OVER Indicates that the processor attempted to write * to the TX FIFO while the TX FIFO was full. Cleared * by reading CLR_TX_OVER. * * RX_FULL Indicates that the receive FIFO has reached or * exceeded the specified RX_TL threshold. Cleared * by HW when the cpu drains the FIFO to below the * threshold. * * RX_OVER Indicates that the receive FIFO was unable to * accept new data and data was lost. Cleared by * reading CLR_RX_OVER. * * RX_UNDER Indicates that the cpu attempted to read data * from the receive buffer while the RX FIFO was * empty. Cleared by reading CLR_RX_UNDER. * * NOTES ON RAW_INTR_STAT: * * This register can be used to monitor the GEN_CALL, START_DET, * STOP_DET, ACTIVITY, TX_ABRT, TX_EMPTY, TX_OVER, RX_FULL, RX_OVER, * and RX_UNDER bits. The documentation is a bit unclear but presumably * this is the unlatched version. * * Code should test FIFO conditions using the I2C_STA (status) register, * not the interrupt status registers. */ #define IG4_INTR_GEN_CALL 0x0800 #define IG4_INTR_START_DET 0x0400 #define IG4_INTR_STOP_DET 0x0200 #define IG4_INTR_ACTIVITY 0x0100 #define IG4_INTR_TX_ABRT 0x0040 #define IG4_INTR_TX_EMPTY 0x0010 #define IG4_INTR_TX_OVER 0x0008 #define IG4_INTR_RX_FULL 0x0004 #define IG4_INTR_RX_OVER 0x0002 #define IG4_INTR_RX_UNDER 0x0001 #define IG4_INTR_ERR_MASK (IG4_INTR_TX_ABRT | IG4_INTR_TX_OVER | \ IG4_INTR_RX_OVER | IG4_INTR_RX_UNDER) /* * RX_TL - (RW) Receive FIFO Threshold Register 22.2.11 * TX_TL - (RW) Transmit FIFO Threshold Register 22.2.12 * * Specify the receive and transmit FIFO threshold register. The * FIFOs have 16 elements. The valid range is 0-15. Setting a * value greater than 15 causes the actual value to be the maximum * depth of the FIFO. * * Generally speaking since everything is messaged, we can use a * mid-level setting for both parameters and (e.g.) fully drain the * receive FIFO on the STOP_DET condition to handle loose ends. */ #define IG4_FIFO_MASK 0x00FF #define IG4_FIFO_LIMIT 16 /* * CLR_INTR - (RO) Clear Interrupt Register 22.2.13 * CLR_RX_UNDER - (RO) Clear Interrupt Register (specific) 22.2.14 * CLR_RX_OVER - (RO) Clear Interrupt Register (specific) 22.2.15 * CLR_TX_OVER - (RO) Clear Interrupt Register (specific) 22.2.16 * CLR_TX_ABORT - (RO) Clear Interrupt Register (specific) 22.2.17 * CLR_ACTIVITY - (RO) Clear Interrupt Register (specific) 22.2.18 * CLR_STOP_DET - (RO) Clear Interrupt Register (specific) 22.2.19 * CLR_START_DET- (RO) Clear Interrupt Register (specific) 22.2.20 * CLR_GEN_CALL - (RO) Clear Interrupt Register (specific) 22.2.21 * * CLR_* specific operations clear the appropriate bit in the * RAW_INTR_STAT register. Intel does not really document whether * these operations clear the normal interrupt status register. * * CLR_INTR clears bits in the normal interrupt status register and * presumably also the raw(?) register? Intel is again unclear. * * NOTE: CLR_INTR only clears software-clearable interrupts. Hardware * clearable interrupts are controlled entirely by the hardware. * CLR_INTR also clears the TX_ABRT_SOURCE register. * * NOTE: CLR_TX_ABORT also clears the TX_ABRT_SOURCE register and releases * the TX FIFO from its flushed/reset state, allowing more writes * to the TX FIFO. * * NOTE: CLR_ACTIVITY has no effect if the I2C bus is still active. * Intel documents that the bit is automatically cleared when * there is no further activity on the bus. */ #define IG4_CLR_BIT 0x0001 /* Reflects source */ /* * I2C_EN - (RW) I2C Enable Register 22.2.22 * * ABORT Software can abort an I2C transfer by setting this * bit. In response, the controller issues the STOP * condition over the I2C bus, followed by TX FIFO flush. * Hardware will clear the bit once the STOP has * been detected. This bit can only be set while the * I2C interface is enabled. * * I2C_ENABLE Enable the controller, else disable it. * (Use I2C_ENABLE_STATUS to poll enable status * & wait for changes) */ #define IG4_I2C_ABORT 0x0002 #define IG4_I2C_ENABLE 0x0001 /* * I2C_STA - (RO) I2C Status Register 22.2.23 */ #define IG4_STATUS_ACTIVITY 0x0020 /* Controller is active */ #define IG4_STATUS_RX_FULL 0x0010 /* RX FIFO completely full */ #define IG4_STATUS_RX_NOTEMPTY 0x0008 /* RX FIFO not empty */ #define IG4_STATUS_TX_EMPTY 0x0004 /* TX FIFO completely empty */ #define IG4_STATUS_TX_NOTFULL 0x0002 /* TX FIFO not full */ #define IG4_STATUS_I2C_ACTIVE 0x0001 /* I2C bus is active */ /* * TXFLR - (RO) Transmit FIFO Level Register 22.2.24 * RXFLR - (RO) Receive FIFO Level Register 22.2.25 * * Read the number of entries currently in the Transmit or Receive * FIFOs. Note that for some reason the mask is 9 bits instead of * the 8 bits the fill level controls. */ #define IG4_FIFOLVL_MASK 0x01FF /* * SDA_HOLD - (RW) SDA Hold Time Length Register 22.2.26 * * Set the SDA hold time length register in I2C clocks. */ #define IG4_SDA_TX_HOLD_MASK 0x0000FFFF /* * TX_ABRT_SOURCE- (RO) Transmit Abort Source Register 22.2.27 * * Indicates the cause of a transmit abort. This can indicate a * software programming error or a device expected address width * mismatch or other issues. The NORESTART conditions and GENCALL_NOACK * can only occur if a programming error was made in the driver software. * * In particular, it should be possible to detect whether any devices * are on the bus by observing the GENCALL_READ status, and it might * be possible to detect ADDR7 vs ADDR10 mismatches. */ #define IG4_ABRTSRC_TRANSFER 0x00010000 /* Abort initiated by user */ #define IG4_ABRTSRC_ARBLOST 0x00001000 /* Arbitration lost */ #define IG4_ABRTSRC_NORESTART_10 0x00000400 /* RESTART disabled */ #define IG4_ABRTSRC_NORESTART_START 0x00000200 /* RESTART disabled */ #define IG4_ABRTSRC_ACKED_START 0x00000080 /* Improper acked START */ #define IG4_ABRTSRC_GENCALL_READ 0x00000020 /* Improper GENCALL */ #define IG4_ABRTSRC_GENCALL_NOACK 0x00000010 /* Nobody acked GENCALL */ #define IG4_ABRTSRC_TXNOACK_DATA 0x00000008 /* data phase no ACK */ #define IG4_ABRTSRC_TXNOACK_ADDR10_2 0x00000004 /* addr10/1 phase no ACK */ #define IG4_ABRTSRC_TXNOACK_ADDR10_1 0x00000002 /* addr10/2 phase no ACK */ #define IG4_ABRTSRC_TXNOACK_ADDR7 0x00000001 /* addr7 phase no ACK */ /* * SLV_DATA_NACK - (RW) Generate Slave DATA NACK Register 22.2.28 * * When the controller is a receiver a NACK can be generated on * receipt of data. * * NACK_GENERATE Set to 0 for normal NACK/ACK generation. * Set to 1 to generate a NACK after next data * byte received. * */ #define IG4_NACK_GENERATE 0x0001 /* * DMA_CTRL - (RW) DMA Control Register 22.2.29 * * Enables DMA on the transmit and/or receive DMA channel. */ #define IG4_TX_DMA_ENABLE 0x0002 #define IG4_RX_DMA_ENABLE 0x0001 /* * DMA_TDLR - (RW) DMA Transmit Data Level Register 22.2.30 * DMA_RDLR - (RW) DMA Receive Data Level Register 22.2.31 * * Similar to RX_TL and TX_TL but controls when a DMA burst occurs * to empty or fill the FIFOs. Use the same IG4_FIFO_MASK and * IG4_FIFO_LIMIT defines for RX_RL and TX_TL. */ /* empty */ /* * SDA_SETUP - (RW) SDA Setup Time Length Register 22.2.32 * * Set the SDA setup time length register in I2C clocks. * The register must be programmed with a value >=2. * (Defaults to 0x64). */ #define IG4_SDA_SETUP_MASK 0x00FF /* * ACK_GEN_CALL - (RW) ACK General Call Register 22.2.33 * * Control whether the controller responds with a ACK or NACK when * it receives an I2C General Call address. * * If set to 0 a NACK is generated and a General Call interrupt is * NOT generated. Otherwise an ACK + interrupt is generated. */ #define IG4_ACKGC_ACK 0x0001 /* * ENABLE_STATUS - (RO) Enable Status Registger 22.2.34 * * DATA_LOST - Indicates that a slave receiver operation has * been aborted with at least one data byte received * from a transfer due to the I2C controller being * disabled (IG4_I2C_ENABLE -> 0) * * ENABLED - Intel documentation is lacking but I assume this * is a reflection of the IG4_I2C_ENABLE bit in the * I2C_EN register. * */ #define IG4_ENASTAT_DATA_LOST 0x0004 #define IG4_ENASTAT_ENABLED 0x0001 /* * COMP_PARAM1 - (RO) Component Parameter Register 22.2.35 * Default Value 0x00FFFF6E * * VALID - Intel documentation is unclear but I believe this * must be read as a 1 to indicate that the rest of * the bits in the register are valid. * * HASDMA - Indicates that the chip is DMA-capable. Presumably * in certain virtualization cases the chip might be * set to not be DMA-capable. * * INTR_IO - Indicates that all interrupts are combined to * generate one interrupt. If not set, interrupts * are individual (more virtualization stuff?) * * HCCNT_RO - Indicates that the clock timing registers are * RW. If not set, the registers are RO. * (more virtualization stuff). * * MAXSPEED - Indicates the maximum speed supported. * * DATAW - Indicates the internal bus width in bits. */ #define IG4_PARAM1_TXFIFO_DEPTH(v) ((((v) >> 16) & 0xFF) + 1) #define IG4_PARAM1_RXFIFO_DEPTH(v) ((((v) >> 8) & 0xFF) + 1) #define IG4_PARAM1_CONFIG_VALID 0x00000080 #define IG4_PARAM1_CONFIG_HASDMA 0x00000040 #define IG4_PARAM1_CONFIG_INTR_IO 0x00000020 #define IG4_PARAM1_CONFIG_HCCNT_RO 0x00000010 #define IG4_PARAM1_CONFIG_MAXSPEED_MASK 0x0000000C #define IG4_PARAM1_CONFIG_DATAW_MASK 0x00000003 #define IG4_CONFIG_MAXSPEED_RESERVED00 0x00000000 #define IG4_CONFIG_MAXSPEED_STANDARD 0x00000004 #define IG4_CONFIG_MAXSPEED_FAST 0x00000008 #define IG4_CONFIG_MAXSPEED_HIGH 0x0000000C #define IG4_CONFIG_DATAW_8 0x00000000 #define IG4_CONFIG_DATAW_16 0x00000001 #define IG4_CONFIG_DATAW_32 0x00000002 #define IG4_CONFIG_DATAW_RESERVED11 0x00000003 /* * COMP_VER - (RO) Component Version Register 22.2.36 * * Contains the chip version number. All 32 bits. */ #define IG4_COMP_MIN_VER 0x3131352A /* * COMP_TYPE - (RO) (linux) Endian and bus width probe * * Read32 from this register and test against IG4_COMP_TYPE * to determine the bus width. e.g. 01404457 = endian-reversed, * and 00000140 or 00004457 means internal 16-bit bus (?). * * This register is not in the intel documentation, I pulled it * from the linux driver i2c-designware-core.c. */ #define IG4_COMP_TYPE 0x44570140 /* * RESETS - (RW) Resets Register 22.2.37 * * Used to reset the I2C host controller by SW. There is no timing * requirement, software can assert and de-assert in back-to-back * transactions. * * 00 I2C host controller is NOT in reset. * 01 (reserved) * 10 (reserved) * 11 I2C host controller is in reset. */ #define IG4_RESETS_ASSERT_HSW 0x0003 #define IG4_RESETS_DEASSERT_HSW 0x0000 /* Skylake-U/Y and Kaby Lake-U/Y have the reset bits inverted */ #define IG4_RESETS_DEASSERT_SKL 0x0003 #define IG4_RESETS_ASSERT_SKL 0x0000 /* Newer versions of the I2C controller allow to check whether * the above ASSERT/DEASSERT is necessary by querying the DEVIDLE_CONTROL * register. * * the RESTORE_REQUIRED bit can be cleared by writing 1 * the DEVICE_IDLE status can be set to put the controller in an idle state * */ #define IG4_RESTORE_REQUIRED 0x0008 #define IG4_DEVICE_IDLE 0x0004 /* * GENERAL - (RW) General Reigster 22.2.38 * * IOVOLT 0=1.8V 1=3.3V * * LTR 0=Auto 1=SW * * In Auto mode the BIOS will write to the host controller's * AUTO LTR Value register (offset 0x0814) with the active * state LTR value, and will write to the SW LTR Value register * (offset 0x0810) with the idle state LTR value. * * In SW mode the SW will write to the host controller SW LTR * value (offset 0x0810). It is the SW responsibility to update * the LTR with the appropriate value. */ #define IG4_GENERAL_IOVOLT3_3 0x0008 #define IG4_GENERAL_SWMODE 0x0004 /* * SW_LTR_VALUE - (RW) SW LTR Value Register 22.2.39 * AUTO_LTR_VALUE - (RW) SW LTR Value Register 22.2.40 * * Default value is 0x00000800 which means the best possible * service/response time. * * It isn't quite clear how the snooping works. There are two scale * bits for both sets but two of the four codes are reserved. The * *SNOOP_VALUE() is specified as a 10-bit latency value. If 0, it * indicates that the device cannot tolerate any delay and needs the * best possible service/response time. * * I think this is for snooping (testing) the I2C bus. The lowest * delay (0) probably runs the controller polling at a high, power hungry * rate. But I dunno. */ #define IG4_SWLTR_NSNOOP_REQ 0x80000000 /* (ro) */ #define IG4_SWLTR_NSNOOP_SCALE_MASK 0x1C000000 /* (ro) */ #define IG4_SWLTR_NSNOOP_SCALE_1US 0x08000000 /* (ro) */ #define IG4_SWLTR_NSNOOP_SCALE_32US 0x0C000000 /* (ro) */ #define IG4_SWLTR_NSNOOP_VALUE_DECODE(v) (((v) >> 16) & 0x3F) #define IG4_SWLTR_NSNOOP_VALUE_ENCODE(v) (((v) & 0x3F) << 16) #define IG4_SWLTR_SNOOP_REQ 0x00008000 /* (rw) */ #define IG4_SWLTR_SNOOP_SCALE_MASK 0x00001C00 /* (rw) */ #define IG4_SWLTR_SNOOP_SCALE_1US 0x00000800 /* (rw) */ #define IG4_SWLTR_SNOOP_SCALE_32US 0x00000C00 /* (rw) */ #define IG4_SWLTR_SNOOP_VALUE_DECODE(v) ((v) & 0x3F) #define IG4_SWLTR_SNOOP_VALUE_ENCODE(v) ((v) & 0x3F) #endif /* _ICHIIC_IG4_REG_H_ */