Commit dd3bd23e authored by Ramesh Shanmugasundaram's avatar Ramesh Shanmugasundaram Committed by Marc Kleine-Budde

can: rcar_canfd: Add Renesas R-Car CAN FD driver

This patch adds support for the CAN FD controller found in Renesas R-Car
SoCs. The controller operates in CAN FD only mode by default.

CAN FD mode supports both Classical CAN & CAN FD frame formats. The
controller supports ISO 11898-1:2015 CAN FD format only.

This controller supports two channels and the driver can enable either
or both of the channels.

Driver uses Rx FIFOs (one per channel) for reception & Common FIFOs (one
per channel) for transmission. Rx filter rules are configured to the
minimum (one per channel) and it accepts Standard, Extended, Data &
Remote Frame combinations.

Note: There are few documentation errors in R-Car Gen3 Hardware User
Manual v0.5E with respect to CAN FD controller. They are listed below:

1. CAN FD interrupt numbers 29 & 30 are listed as per channel
interrupts. However, they are common to both channels (i.e.) they are
global and channel interrupts respectively.

2. CANFD clock is derived from PLL1. This is not documented.

3. CANFD clock is further divided by (1/2) within the CAN FD controller.
This is not documented.

4. The minimum value of NTSEG1 in RSCFDnCFDCmNCFG register is 2 Tq. It
is specified 4 Tq in the manual.

5. The maximum number of message RAM area the controller can use is 3584
bytes. It is specified 10752 bytes in the manual.
Signed-off-by: default avatarRamesh Shanmugasundaram <ramesh.shanmugasundaram@bp.renesas.com>
Acked-by: default avatarRob Herring <robh@kernel.org>
Reviewed-by: default avatarUlrich Hecht <ulrich.hecht+renesas@gmail.com>
Signed-off-by: default avatarMarc Kleine-Budde <mkl@pengutronix.de>
parent 9be05c7f
Renesas R-Car CAN FD controller Device Tree Bindings
----------------------------------------------------
Required properties:
- compatible: Must contain one or more of the following:
- "renesas,rcar-gen3-canfd" for R-Car Gen3 compatible controller.
- "renesas,r8a7795-canfd" for R8A7795 (R-Car H3) compatible controller.
When compatible with the generic version, nodes must list the
SoC-specific version corresponding to the platform first, followed by the
family-specific and/or generic versions.
- reg: physical base address and size of the R-Car CAN FD register map.
- interrupts: interrupt specifier for the Global & Channel interrupts
- clocks: phandles and clock specifiers for 3 clock inputs.
- clock-names: 3 clock input name strings: "fck", "canfd", "can_clk".
- pinctrl-0: pin control group to be used for this controller.
- pinctrl-names: must be "default".
Required child nodes:
The controller supports two channels and each is represented as a child node.
The name of the child nodes are "channel0" and "channel1" respectively. Each
child node supports the "status" property only, which is used to
enable/disable the respective channel.
Required properties for "renesas,r8a7795-canfd" compatible:
In R8A7795 SoC, canfd clock is a div6 clock and can be used by both CAN
and CAN FD controller at the same time. It needs to be scaled to maximum
frequency if any of these controllers use it. This is done using the
below properties.
- assigned-clocks: phandle of canfd clock.
- assigned-clock-rates: maximum frequency of this clock.
Example
-------
SoC common .dtsi file:
canfd: can@e66c0000 {
compatible = "renesas,r8a7795-canfd",
"renesas,rcar-gen3-canfd";
reg = <0 0xe66c0000 0 0x8000>;
interrupts = <GIC_SPI 29 IRQ_TYPE_LEVEL_HIGH>,
<GIC_SPI 30 IRQ_TYPE_LEVEL_HIGH>;
clocks = <&cpg CPG_MOD 914>,
<&cpg CPG_CORE R8A7795_CLK_CANFD>,
<&can_clk>;
clock-names = "fck", "canfd", "can_clk";
assigned-clocks = <&cpg CPG_CORE R8A7795_CLK_CANFD>;
assigned-clock-rates = <40000000>;
power-domains = <&cpg>;
status = "disabled";
channel0 {
status = "disabled";
};
channel1 {
status = "disabled";
};
};
Board specific .dts file:
E.g. below enables Channel 1 alone in the board.
&canfd {
pinctrl-0 = <&canfd1_pins>;
pinctrl-names = "default";
status = "okay";
channel1 {
status = "okay";
};
};
E.g. below enables Channel 0 alone in the board using External clock
as fCAN clock.
&canfd {
pinctrl-0 = <&canfd0_pins &can_clk_pins>;
pinctrl-names = "default";
status = "okay";
channel0 {
status = "okay";
};
};
......@@ -152,6 +152,7 @@ source "drivers/net/can/cc770/Kconfig"
source "drivers/net/can/ifi_canfd/Kconfig"
source "drivers/net/can/m_can/Kconfig"
source "drivers/net/can/mscan/Kconfig"
source "drivers/net/can/rcar/Kconfig"
source "drivers/net/can/sja1000/Kconfig"
source "drivers/net/can/softing/Kconfig"
source "drivers/net/can/spi/Kconfig"
......
......@@ -10,6 +10,7 @@ can-dev-y := dev.o
can-dev-$(CONFIG_CAN_LEDS) += led.o
obj-y += rcar/
obj-y += spi/
obj-y += usb/
obj-y += softing/
......
config CAN_RCAR_CANFD
tristate "Renesas R-Car CAN FD controller"
depends on ARCH_RENESAS || ARM
---help---
Say Y here if you want to use CAN FD controller found on
Renesas R-Car SoCs. The driver puts the controller in CAN FD only
mode, which can interoperate with CAN2.0 nodes but does not support
dedicated CAN 2.0 mode.
To compile this driver as a module, choose M here: the module will
be called rcar_canfd.
#
# Makefile for the Renesas R-Car CAN FD controller driver
#
obj-$(CONFIG_CAN_RCAR_CANFD) += rcar_canfd.o
/* Renesas R-Car CAN FD device driver
*
* Copyright (C) 2015 Renesas Electronics Corp.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version.
*/
/* The R-Car CAN FD controller can operate in either one of the below two modes
* - CAN FD only mode
* - Classical CAN (CAN 2.0) only mode
*
* This driver puts the controller in CAN FD only mode by default. In this
* mode, the controller acts as a CAN FD node that can also interoperate with
* CAN 2.0 nodes.
*
* As of now, this driver does not support the Classical CAN (CAN 2.0) mode,
* which is handled by a different register map compared to CAN FD only mode.
*
* Note: The h/w manual register naming convention is clumsy and not acceptable
* to use as it is in the driver. However, those names are added as comments
* wherever it is modified to a readable name.
*/
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/kernel.h>
#include <linux/types.h>
#include <linux/interrupt.h>
#include <linux/errno.h>
#include <linux/netdevice.h>
#include <linux/platform_device.h>
#include <linux/can/led.h>
#include <linux/can/dev.h>
#include <linux/clk.h>
#include <linux/of.h>
#include <linux/of_device.h>
#include <linux/bitmap.h>
#include <linux/bitops.h>
#include <linux/iopoll.h>
#define RCANFD_DRV_NAME "rcar_canfd"
/* Global register bits */
/* RSCFDnCFDGRMCFG */
#define RCANFD_GRMCFG_RCMC BIT(0)
/* RSCFDnCFDGCFG */
#define RCANFD_GCFG_CMPOC BIT(5)
#define RCANFD_GCFG_DCS BIT(4)
#define RCANFD_GCFG_DCE BIT(1)
#define RCANFD_GCFG_TPRI BIT(0)
/* RSCFDnCFDGCTR */
#define RCANFD_GCTR_TSRST BIT(16)
#define RCANFD_GCTR_CFMPOFIE BIT(11)
#define RCANFD_GCTR_THLEIE BIT(10)
#define RCANFD_GCTR_MEIE BIT(9)
#define RCANFD_GCTR_DEIE BIT(8)
#define RCANFD_GCTR_GSLPR BIT(2)
#define RCANFD_GCTR_GMDC_MASK (0x3)
#define RCANFD_GCTR_GMDC_GOPM (0x0)
#define RCANFD_GCTR_GMDC_GRESET (0x1)
#define RCANFD_GCTR_GMDC_GTEST (0x2)
/* RSCFDnCFDGSTS */
#define RCANFD_GSTS_GRAMINIT BIT(3)
#define RCANFD_GSTS_GSLPSTS BIT(2)
#define RCANFD_GSTS_GHLTSTS BIT(1)
#define RCANFD_GSTS_GRSTSTS BIT(0)
/* Non-operational status */
#define RCANFD_GSTS_GNOPM (BIT(0) | BIT(1) | BIT(2) | BIT(3))
/* RSCFDnCFDGERFL */
#define RCANFD_GERFL_EEF1 BIT(17)
#define RCANFD_GERFL_EEF0 BIT(16)
#define RCANFD_GERFL_CMPOF BIT(3)
#define RCANFD_GERFL_THLES BIT(2)
#define RCANFD_GERFL_MES BIT(1)
#define RCANFD_GERFL_DEF BIT(0)
#define RCANFD_GERFL_ERR(x) ((x) & (RCANFD_GERFL_EEF1 |\
RCANFD_GERFL_EEF0 |\
RCANFD_GERFL_MES |\
RCANFD_GERFL_CMPOF))
/* AFL Rx rules registers */
/* RSCFDnCFDGAFLCFG0 */
#define RCANFD_GAFLCFG_SETRNC(n, x) (((x) & 0xff) << (24 - n * 8))
#define RCANFD_GAFLCFG_GETRNC(n, x) (((x) >> (24 - n * 8)) & 0xff)
/* RSCFDnCFDGAFLECTR */
#define RCANFD_GAFLECTR_AFLDAE BIT(8)
#define RCANFD_GAFLECTR_AFLPN(x) ((x) & 0x1f)
/* RSCFDnCFDGAFLIDj */
#define RCANFD_GAFLID_GAFLLB BIT(29)
/* RSCFDnCFDGAFLP1_j */
#define RCANFD_GAFLP1_GAFLFDP(x) (1 << (x))
/* Channel register bits */
/* RSCFDnCFDCmNCFG */
#define RCANFD_NCFG_NTSEG2(x) (((x) & 0x1f) << 24)
#define RCANFD_NCFG_NTSEG1(x) (((x) & 0x7f) << 16)
#define RCANFD_NCFG_NSJW(x) (((x) & 0x1f) << 11)
#define RCANFD_NCFG_NBRP(x) (((x) & 0x3ff) << 0)
/* RSCFDnCFDCmCTR */
#define RCANFD_CCTR_CTME BIT(24)
#define RCANFD_CCTR_ERRD BIT(23)
#define RCANFD_CCTR_BOM_MASK (0x3 << 21)
#define RCANFD_CCTR_BOM_ISO (0x0 << 21)
#define RCANFD_CCTR_BOM_BENTRY (0x1 << 21)
#define RCANFD_CCTR_BOM_BEND (0x2 << 21)
#define RCANFD_CCTR_TDCVFIE BIT(19)
#define RCANFD_CCTR_SOCOIE BIT(18)
#define RCANFD_CCTR_EOCOIE BIT(17)
#define RCANFD_CCTR_TAIE BIT(16)
#define RCANFD_CCTR_ALIE BIT(15)
#define RCANFD_CCTR_BLIE BIT(14)
#define RCANFD_CCTR_OLIE BIT(13)
#define RCANFD_CCTR_BORIE BIT(12)
#define RCANFD_CCTR_BOEIE BIT(11)
#define RCANFD_CCTR_EPIE BIT(10)
#define RCANFD_CCTR_EWIE BIT(9)
#define RCANFD_CCTR_BEIE BIT(8)
#define RCANFD_CCTR_CSLPR BIT(2)
#define RCANFD_CCTR_CHMDC_MASK (0x3)
#define RCANFD_CCTR_CHDMC_COPM (0x0)
#define RCANFD_CCTR_CHDMC_CRESET (0x1)
#define RCANFD_CCTR_CHDMC_CHLT (0x2)
/* RSCFDnCFDCmSTS */
#define RCANFD_CSTS_COMSTS BIT(7)
#define RCANFD_CSTS_RECSTS BIT(6)
#define RCANFD_CSTS_TRMSTS BIT(5)
#define RCANFD_CSTS_BOSTS BIT(4)
#define RCANFD_CSTS_EPSTS BIT(3)
#define RCANFD_CSTS_SLPSTS BIT(2)
#define RCANFD_CSTS_HLTSTS BIT(1)
#define RCANFD_CSTS_CRSTSTS BIT(0)
#define RCANFD_CSTS_TECCNT(x) (((x) >> 24) & 0xff)
#define RCANFD_CSTS_RECCNT(x) (((x) >> 16) & 0xff)
/* RSCFDnCFDCmERFL */
#define RCANFD_CERFL_ADERR BIT(14)
#define RCANFD_CERFL_B0ERR BIT(13)
#define RCANFD_CERFL_B1ERR BIT(12)
#define RCANFD_CERFL_CERR BIT(11)
#define RCANFD_CERFL_AERR BIT(10)
#define RCANFD_CERFL_FERR BIT(9)
#define RCANFD_CERFL_SERR BIT(8)
#define RCANFD_CERFL_ALF BIT(7)
#define RCANFD_CERFL_BLF BIT(6)
#define RCANFD_CERFL_OVLF BIT(5)
#define RCANFD_CERFL_BORF BIT(4)
#define RCANFD_CERFL_BOEF BIT(3)
#define RCANFD_CERFL_EPF BIT(2)
#define RCANFD_CERFL_EWF BIT(1)
#define RCANFD_CERFL_BEF BIT(0)
#define RCANFD_CERFL_ERR(x) ((x) & (0x7fff)) /* above bits 14:0 */
/* RSCFDnCFDCmDCFG */
#define RCANFD_DCFG_DSJW(x) (((x) & 0x7) << 24)
#define RCANFD_DCFG_DTSEG2(x) (((x) & 0x7) << 20)
#define RCANFD_DCFG_DTSEG1(x) (((x) & 0xf) << 16)
#define RCANFD_DCFG_DBRP(x) (((x) & 0xff) << 0)
/* RSCFDnCFDCmFDCFG */
#define RCANFD_FDCFG_TDCE BIT(9)
#define RCANFD_FDCFG_TDCOC BIT(8)
#define RCANFD_FDCFG_TDCO(x) (((x) & 0x7f) >> 16)
/* RSCFDnCFDRFCCx */
#define RCANFD_RFCC_RFIM BIT(12)
#define RCANFD_RFCC_RFDC(x) (((x) & 0x7) << 8)
#define RCANFD_RFCC_RFPLS(x) (((x) & 0x7) << 4)
#define RCANFD_RFCC_RFIE BIT(1)
#define RCANFD_RFCC_RFE BIT(0)
/* RSCFDnCFDRFSTSx */
#define RCANFD_RFSTS_RFIF BIT(3)
#define RCANFD_RFSTS_RFMLT BIT(2)
#define RCANFD_RFSTS_RFFLL BIT(1)
#define RCANFD_RFSTS_RFEMP BIT(0)
/* RSCFDnCFDRFIDx */
#define RCANFD_RFID_RFIDE BIT(31)
#define RCANFD_RFID_RFRTR BIT(30)
/* RSCFDnCFDRFPTRx */
#define RCANFD_RFPTR_RFDLC(x) (((x) >> 28) & 0xf)
#define RCANFD_RFPTR_RFPTR(x) (((x) >> 16) & 0xfff)
#define RCANFD_RFPTR_RFTS(x) (((x) >> 0) & 0xffff)
/* RSCFDnCFDRFFDSTSx */
#define RCANFD_RFFDSTS_RFFDF BIT(2)
#define RCANFD_RFFDSTS_RFBRS BIT(1)
#define RCANFD_RFFDSTS_RFESI BIT(0)
/* Common FIFO bits */
/* RSCFDnCFDCFCCk */
#define RCANFD_CFCC_CFTML(x) (((x) & 0xf) << 20)
#define RCANFD_CFCC_CFM(x) (((x) & 0x3) << 16)
#define RCANFD_CFCC_CFIM BIT(12)
#define RCANFD_CFCC_CFDC(x) (((x) & 0x7) << 8)
#define RCANFD_CFCC_CFPLS(x) (((x) & 0x7) << 4)
#define RCANFD_CFCC_CFTXIE BIT(2)
#define RCANFD_CFCC_CFE BIT(0)
/* RSCFDnCFDCFSTSk */
#define RCANFD_CFSTS_CFMC(x) (((x) >> 8) & 0xff)
#define RCANFD_CFSTS_CFTXIF BIT(4)
#define RCANFD_CFSTS_CFMLT BIT(2)
#define RCANFD_CFSTS_CFFLL BIT(1)
#define RCANFD_CFSTS_CFEMP BIT(0)
/* RSCFDnCFDCFIDk */
#define RCANFD_CFID_CFIDE BIT(31)
#define RCANFD_CFID_CFRTR BIT(30)
#define RCANFD_CFID_CFID_MASK(x) ((x) & 0x1fffffff)
/* RSCFDnCFDCFPTRk */
#define RCANFD_CFPTR_CFDLC(x) (((x) & 0xf) << 28)
#define RCANFD_CFPTR_CFPTR(x) (((x) & 0xfff) << 16)
#define RCANFD_CFPTR_CFTS(x) (((x) & 0xff) << 0)
/* RSCFDnCFDCFFDCSTSk */
#define RCANFD_CFFDCSTS_CFFDF BIT(2)
#define RCANFD_CFFDCSTS_CFBRS BIT(1)
#define RCANFD_CFFDCSTS_CFESI BIT(0)
/* This controller supports classical CAN only mode or CAN FD only mode. These
* modes are supported in two separate set of register maps & names. However,
* some of the register offsets are common for both modes. Those offsets are
* listed below as Common registers.
*
* The CAN FD only specific registers are listed separately and their names
* starts with RCANFD_F_xxx names. When classical CAN only specific registers
* are added, those specific registers can be prefixed as RCANFD_C_xxx.
*/
/* Common registers */
/* RSCFDnCFDCmNCFG / RSCFDnCmCFG */
#define RCANFD_CCFG(m) (0x0000 + (0x10 * (m)))
/* RSCFDnCFDCmCTR / RSCFDnCmCTR */
#define RCANFD_CCTR(m) (0x0004 + (0x10 * (m)))
/* RSCFDnCFDCmSTS / RSCFDnCmSTS */
#define RCANFD_CSTS(m) (0x0008 + (0x10 * (m)))
/* RSCFDnCFDCmERFL / RSCFDnCmERFL */
#define RCANFD_CERFL(m) (0x000C + (0x10 * (m)))
/* RSCFDnCFDGCFG / RSCFDnGCFG */
#define RCANFD_GCFG (0x0084)
/* RSCFDnCFDGCTR / RSCFDnGCTR */
#define RCANFD_GCTR (0x0088)
/* RSCFDnCFDGCTS / RSCFDnGCTS */
#define RCANFD_GSTS (0x008c)
/* RSCFDnCFDGERFL / RSCFDnGERFL */
#define RCANFD_GERFL (0x0090)
/* RSCFDnCFDGTSC / RSCFDnGTSC */
#define RCANFD_GTSC (0x0094)
/* RSCFDnCFDGAFLECTR / RSCFDnGAFLECTR */
#define RCANFD_GAFLECTR (0x0098)
/* RSCFDnCFDGAFLCFG0 / RSCFDnGAFLCFG0 */
#define RCANFD_GAFLCFG0 (0x009c)
/* RSCFDnCFDGAFLCFG1 / RSCFDnGAFLCFG1 */
#define RCANFD_GAFLCFG1 (0x00a0)
/* RSCFDnCFDRMNB / RSCFDnRMNB */
#define RCANFD_RMNB (0x00a4)
/* RSCFDnCFDRMND / RSCFDnRMND */
#define RCANFD_RMND(y) (0x00a8 + (0x04 * (y)))
/* RSCFDnCFDRFCCx / RSCFDnRFCCx */
#define RCANFD_RFCC(x) (0x00b8 + (0x04 * (x)))
/* RSCFDnCFDRFSTSx / RSCFDnRFSTSx */
#define RCANFD_RFSTS(x) (0x00d8 + (0x04 * (x)))
/* RSCFDnCFDRFPCTRx / RSCFDnRFPCTRx */
#define RCANFD_RFPCTR(x) (0x00f8 + (0x04 * (x)))
/* Common FIFO Control registers */
/* RSCFDnCFDCFCCx / RSCFDnCFCCx */
#define RCANFD_CFCC(ch, idx) (0x0118 + (0x0c * (ch)) + \
(0x04 * (idx)))
/* RSCFDnCFDCFSTSx / RSCFDnCFSTSx */
#define RCANFD_CFSTS(ch, idx) (0x0178 + (0x0c * (ch)) + \
(0x04 * (idx)))
/* RSCFDnCFDCFPCTRx / RSCFDnCFPCTRx */
#define RCANFD_CFPCTR(ch, idx) (0x01d8 + (0x0c * (ch)) + \
(0x04 * (idx)))
/* RSCFDnCFDFESTS / RSCFDnFESTS */
#define RCANFD_FESTS (0x0238)
/* RSCFDnCFDFFSTS / RSCFDnFFSTS */
#define RCANFD_FFSTS (0x023c)
/* RSCFDnCFDFMSTS / RSCFDnFMSTS */
#define RCANFD_FMSTS (0x0240)
/* RSCFDnCFDRFISTS / RSCFDnRFISTS */
#define RCANFD_RFISTS (0x0244)
/* RSCFDnCFDCFRISTS / RSCFDnCFRISTS */
#define RCANFD_CFRISTS (0x0248)
/* RSCFDnCFDCFTISTS / RSCFDnCFTISTS */
#define RCANFD_CFTISTS (0x024c)
/* RSCFDnCFDTMCp / RSCFDnTMCp */
#define RCANFD_TMC(p) (0x0250 + (0x01 * (p)))
/* RSCFDnCFDTMSTSp / RSCFDnTMSTSp */
#define RCANFD_TMSTS(p) (0x02d0 + (0x01 * (p)))
/* RSCFDnCFDTMTRSTSp / RSCFDnTMTRSTSp */
#define RCANFD_TMTRSTS(y) (0x0350 + (0x04 * (y)))
/* RSCFDnCFDTMTARSTSp / RSCFDnTMTARSTSp */
#define RCANFD_TMTARSTS(y) (0x0360 + (0x04 * (y)))
/* RSCFDnCFDTMTCSTSp / RSCFDnTMTCSTSp */
#define RCANFD_TMTCSTS(y) (0x0370 + (0x04 * (y)))
/* RSCFDnCFDTMTASTSp / RSCFDnTMTASTSp */
#define RCANFD_TMTASTS(y) (0x0380 + (0x04 * (y)))
/* RSCFDnCFDTMIECy / RSCFDnTMIECy */
#define RCANFD_TMIEC(y) (0x0390 + (0x04 * (y)))
/* RSCFDnCFDTXQCCm / RSCFDnTXQCCm */
#define RCANFD_TXQCC(m) (0x03a0 + (0x04 * (m)))
/* RSCFDnCFDTXQSTSm / RSCFDnTXQSTSm */
#define RCANFD_TXQSTS(m) (0x03c0 + (0x04 * (m)))
/* RSCFDnCFDTXQPCTRm / RSCFDnTXQPCTRm */
#define RCANFD_TXQPCTR(m) (0x03e0 + (0x04 * (m)))
/* RSCFDnCFDTHLCCm / RSCFDnTHLCCm */
#define RCANFD_THLCC(m) (0x0400 + (0x04 * (m)))
/* RSCFDnCFDTHLSTSm / RSCFDnTHLSTSm */
#define RCANFD_THLSTS(m) (0x0420 + (0x04 * (m)))
/* RSCFDnCFDTHLPCTRm / RSCFDnTHLPCTRm */
#define RCANFD_THLPCTR(m) (0x0440 + (0x04 * (m)))
/* RSCFDnCFDGTINTSTS0 / RSCFDnGTINTSTS0 */
#define RCANFD_GTINTSTS0 (0x0460)
/* RSCFDnCFDGTINTSTS1 / RSCFDnGTINTSTS1 */
#define RCANFD_GTINTSTS1 (0x0464)
/* RSCFDnCFDGTSTCFG / RSCFDnGTSTCFG */
#define RCANFD_GTSTCFG (0x0468)
/* RSCFDnCFDGTSTCTR / RSCFDnGTSTCTR */
#define RCANFD_GTSTCTR (0x046c)
/* RSCFDnCFDGLOCKK / RSCFDnGLOCKK */
#define RCANFD_GLOCKK (0x047c)
/* RSCFDnCFDGRMCFG / RSCFDnGRMCFG */
#define RCANFD_GRMCFG (0x04fc)
/* RSCFDnCFDGAFLIDj / RSCFDnGAFLIDj */
#define RCANFD_GAFLID(offset, j) ((offset) + (0x10 * (j)))
/* RSCFDnCFDGAFLMj / RSCFDnGAFLMj */
#define RCANFD_GAFLM(offset, j) ((offset) + 0x04 + (0x10 * (j)))
/* RSCFDnCFDGAFLP0j / RSCFDnGAFLP0j */
#define RCANFD_GAFLP0(offset, j) ((offset) + 0x08 + (0x10 * (j)))
/* RSCFDnCFDGAFLP1j / RSCFDnGAFLP1j */
#define RCANFD_GAFLP1(offset, j) ((offset) + 0x0c + (0x10 * (j)))
/* CAN FD mode specific regsiter map */
/* RSCFDnCFDCmXXX -> RCANFD_F_XXX(m) */
#define RCANFD_F_DCFG(m) (0x0500 + (0x20 * (m)))
#define RCANFD_F_CFDCFG(m) (0x0504 + (0x20 * (m)))
#define RCANFD_F_CFDCTR(m) (0x0508 + (0x20 * (m)))
#define RCANFD_F_CFDSTS(m) (0x050c + (0x20 * (m)))
#define RCANFD_F_CFDCRC(m) (0x0510 + (0x20 * (m)))
/* RSCFDnCFDGAFLXXXj offset */
#define RCANFD_F_GAFL_OFFSET (0x1000)
/* RSCFDnCFDRMXXXq -> RCANFD_F_RMXXX(q) */
#define RCANFD_F_RMID(q) (0x2000 + (0x20 * (q)))
#define RCANFD_F_RMPTR(q) (0x2004 + (0x20 * (q)))
#define RCANFD_F_RMFDSTS(q) (0x2008 + (0x20 * (q)))
#define RCANFD_F_RMDF(q, b) (0x200c + (0x04 * (b)) + (0x20 * (q)))
/* RSCFDnCFDRFXXx -> RCANFD_F_RFXX(x) */
#define RCANFD_F_RFOFFSET (0x3000)
#define RCANFD_F_RFID(x) (RCANFD_F_RFOFFSET + (0x80 * (x)))
#define RCANFD_F_RFPTR(x) (RCANFD_F_RFOFFSET + 0x04 + \
(0x80 * (x)))
#define RCANFD_F_RFFDSTS(x) (RCANFD_F_RFOFFSET + 0x08 + \
(0x80 * (x)))
#define RCANFD_F_RFDF(x, df) (RCANFD_F_RFOFFSET + 0x0c + \
(0x80 * (x)) + (0x04 * (df)))
/* RSCFDnCFDCFXXk -> RCANFD_F_CFXX(ch, k) */
#define RCANFD_F_CFOFFSET (0x3400)
#define RCANFD_F_CFID(ch, idx) (RCANFD_F_CFOFFSET + (0x180 * (ch)) + \
(0x80 * (idx)))
#define RCANFD_F_CFPTR(ch, idx) (RCANFD_F_CFOFFSET + 0x04 + \
(0x180 * (ch)) + (0x80 * (idx)))
#define RCANFD_F_CFFDCSTS(ch, idx) (RCANFD_F_CFOFFSET + 0x08 + \
(0x180 * (ch)) + (0x80 * (idx)))
#define RCANFD_F_CFDF(ch, idx, df) (RCANFD_F_CFOFFSET + 0x0c + \
(0x180 * (ch)) + (0x80 * (idx)) + \
(0x04 * (df)))
/* RSCFDnCFDTMXXp -> RCANFD_F_TMXX(p) */
#define RCANFD_F_TMID(p) (0x4000 + (0x20 * (p)))
#define RCANFD_F_TMPTR(p) (0x4004 + (0x20 * (p)))
#define RCANFD_F_TMFDCTR(p) (0x4008 + (0x20 * (p)))
#define RCANFD_F_TMDF(p, b) (0x400c + (0x20 * (p)) + (0x04 * (b)))
/* RSCFDnCFDTHLACCm */
#define RCANFD_F_THLACC(m) (0x6000 + (0x04 * (m)))
/* RSCFDnCFDRPGACCr */
#define RCANFD_F_RPGACC(r) (0x6400 + (0x04 * (r)))
/* Constants */
#define RCANFD_FIFO_DEPTH 8 /* Tx FIFO depth */
#define RCANFD_NAPI_WEIGHT 8 /* Rx poll quota */
#define RCANFD_NUM_CHANNELS 2 /* Two channels max */
#define RCANFD_CHANNELS_MASK BIT((RCANFD_NUM_CHANNELS) - 1)
#define RCANFD_GAFL_PAGENUM(entry) ((entry) / 16)
#define RCANFD_CHANNEL_NUMRULES 1 /* only one rule per channel */
/* Rx FIFO is a global resource of the controller. There are 8 such FIFOs
* available. Each channel gets a dedicated Rx FIFO (i.e.) the channel
* number is added to RFFIFO index.
*/
#define RCANFD_RFFIFO_IDX 0
/* Tx/Rx or Common FIFO is a per channel resource. Each channel has 3 Common
* FIFOs dedicated to them. Use the first (index 0) FIFO out of the 3 for Tx.
*/
#define RCANFD_CFFIFO_IDX 0
/* fCAN clock select register settings */
enum rcar_canfd_fcanclk {
RCANFD_CANFDCLK = 0, /* CANFD clock */
RCANFD_EXTCLK, /* Externally input clock */
};
struct rcar_canfd_global;
/* Channel priv data */
struct rcar_canfd_channel {
struct can_priv can; /* Must be the first member */
struct net_device *ndev;
struct rcar_canfd_global *gpriv; /* Controller reference */
void __iomem *base; /* Register base address */
struct napi_struct napi;
u8 tx_len[RCANFD_FIFO_DEPTH]; /* For net stats */
u32 tx_head; /* Incremented on xmit */
u32 tx_tail; /* Incremented on xmit done */
u32 channel; /* Channel number */
spinlock_t tx_lock; /* To protect tx path */
};
/* Global priv data */
struct rcar_canfd_global {
struct rcar_canfd_channel *ch[RCANFD_NUM_CHANNELS];
void __iomem *base; /* Register base address */
struct platform_device *pdev; /* Respective platform device */
struct clk *clkp; /* Peripheral clock */
struct clk *can_clk; /* fCAN clock */
enum rcar_canfd_fcanclk fcan; /* CANFD or Ext clock */
unsigned long channels_mask; /* Enabled channels mask */
};
/* CAN FD mode nominal rate constants */
static const struct can_bittiming_const rcar_canfd_nom_bittiming_const = {
.name = RCANFD_DRV_NAME,
.tseg1_min = 2,
.tseg1_max = 128,
.tseg2_min = 2,
.tseg2_max = 32,
.sjw_max = 32,
.brp_min = 1,
.brp_max = 1024,
.brp_inc = 1,
};
/* CAN FD mode data rate constants */
static const struct can_bittiming_const rcar_canfd_data_bittiming_const = {
.name = RCANFD_DRV_NAME,
.tseg1_min = 2,
.tseg1_max = 16,
.tseg2_min = 2,
.tseg2_max = 8,
.sjw_max = 8,
.brp_min = 1,
.brp_max = 256,
.brp_inc = 1,
};
/* Helper functions */
static inline void rcar_canfd_update(u32 mask, u32 val, u32 __iomem *reg)
{
u32 data = readl(reg);
data &= ~mask;
data |= (val & mask);
writel(data, reg);
}
static inline u32 rcar_canfd_read(void __iomem *base, u32 offset)
{
return readl(base + (offset));
}
static inline void rcar_canfd_write(void __iomem *base, u32 offset, u32 val)
{
writel(val, base + (offset));
}
static void rcar_canfd_set_bit(void __iomem *base, u32 reg, u32 val)
{
rcar_canfd_update(val, val, base + (reg));
}
static void rcar_canfd_clear_bit(void __iomem *base, u32 reg, u32 val)
{
rcar_canfd_update(val, 0, base + (reg));
}
static void rcar_canfd_update_bit(void __iomem *base, u32 reg,
u32 mask, u32 val)
{
rcar_canfd_update(mask, val, base + (reg));
}
static void rcar_canfd_get_data(struct rcar_canfd_channel *priv,
struct canfd_frame *cf, u32 off)
{
u32 i, lwords;
lwords = DIV_ROUND_UP(cf->len, sizeof(u32));
for (i = 0; i < lwords; i++)
*((u32 *)cf->data + i) =
rcar_canfd_read(priv->base, off + (i * sizeof(u32)));
}
static void rcar_canfd_put_data(struct rcar_canfd_channel *priv,
struct canfd_frame *cf, u32 off)
{
u32 i, lwords;
lwords = DIV_ROUND_UP(cf->len, sizeof(u32));
for (i = 0; i < lwords; i++)
rcar_canfd_write(priv->base, off + (i * sizeof(u32)),
*((u32 *)cf->data + i));
}
static void rcar_canfd_tx_failure_cleanup(struct net_device *ndev)
{
u32 i;
for (i = 0; i < RCANFD_FIFO_DEPTH; i++)
can_free_echo_skb(ndev, i);
}
static int rcar_canfd_reset_controller(struct rcar_canfd_global *gpriv)
{
u32 sts, ch;
int err;
/* Check RAMINIT flag as CAN RAM initialization takes place
* after the MCU reset
*/
err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
!(sts & RCANFD_GSTS_GRAMINIT), 2, 500000);
if (err) {
dev_dbg(&gpriv->pdev->dev, "global raminit failed\n");
return err;
}
/* Transition to Global Reset mode */
rcar_canfd_clear_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GSLPR);
rcar_canfd_update_bit(gpriv->base, RCANFD_GCTR,
RCANFD_GCTR_GMDC_MASK, RCANFD_GCTR_GMDC_GRESET);
/* Ensure Global reset mode */
err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
(sts & RCANFD_GSTS_GRSTSTS), 2, 500000);
if (err) {
dev_dbg(&gpriv->pdev->dev, "global reset failed\n");
return err;
}
/* Reset Global error flags */
rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0x0);
/* Set the controller into FD mode */
rcar_canfd_set_bit(gpriv->base, RCANFD_GRMCFG, RCANFD_GRMCFG_RCMC);
/* Transition all Channels to reset mode */
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
rcar_canfd_clear_bit(gpriv->base,
RCANFD_CCTR(ch), RCANFD_CCTR_CSLPR);
rcar_canfd_update_bit(gpriv->base, RCANFD_CCTR(ch),
RCANFD_CCTR_CHMDC_MASK,
RCANFD_CCTR_CHDMC_CRESET);
/* Ensure Channel reset mode */
err = readl_poll_timeout((gpriv->base + RCANFD_CSTS(ch)), sts,
(sts & RCANFD_CSTS_CRSTSTS),
2, 500000);
if (err) {
dev_dbg(&gpriv->pdev->dev,
"channel %u reset failed\n", ch);
return err;
}
}
return 0;
}
static void rcar_canfd_configure_controller(struct rcar_canfd_global *gpriv)
{
u32 cfg, ch;
/* Global configuration settings */
/* Truncate payload to configured message size RFPLS */
cfg = RCANFD_GCFG_CMPOC;
/* Set External Clock if selected */
if (gpriv->fcan != RCANFD_CANFDCLK)
cfg |= RCANFD_GCFG_DCS;
rcar_canfd_set_bit(gpriv->base, RCANFD_GCFG, cfg);
/* Channel configuration settings */
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
rcar_canfd_set_bit(gpriv->base, RCANFD_CCTR(ch),
RCANFD_CCTR_ERRD);
rcar_canfd_update_bit(gpriv->base, RCANFD_CCTR(ch),
RCANFD_CCTR_BOM_MASK,
RCANFD_CCTR_BOM_BENTRY);
}
}
static void rcar_canfd_configure_afl_rules(struct rcar_canfd_global *gpriv,
u32 ch)
{
u32 cfg;
int start, page, num_rules = RCANFD_CHANNEL_NUMRULES;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
if (ch == 0) {
start = 0; /* Channel 0 always starts from 0th rule */
} else {
/* Get number of Channel 0 rules and adjust */
cfg = rcar_canfd_read(gpriv->base, RCANFD_GAFLCFG0);
start = RCANFD_GAFLCFG_GETRNC(0, cfg);
}
/* Enable write access to entry */
page = RCANFD_GAFL_PAGENUM(start);
rcar_canfd_set_bit(gpriv->base, RCANFD_GAFLECTR,
(RCANFD_GAFLECTR_AFLPN(page) |
RCANFD_GAFLECTR_AFLDAE));
/* Write number of rules for channel */
rcar_canfd_set_bit(gpriv->base, RCANFD_GAFLCFG0,
RCANFD_GAFLCFG_SETRNC(ch, num_rules));
/* Accept all IDs */
rcar_canfd_write(gpriv->base,
RCANFD_GAFLID(RCANFD_F_GAFL_OFFSET, start), 0);
/* IDE or RTR is not considered for matching */
rcar_canfd_write(gpriv->base,
RCANFD_GAFLM(RCANFD_F_GAFL_OFFSET, start), 0);
/* Any data length accepted */
rcar_canfd_write(gpriv->base,
RCANFD_GAFLP0(RCANFD_F_GAFL_OFFSET, start), 0);
/* Place the msg in corresponding Rx FIFO entry */
rcar_canfd_write(gpriv->base,
RCANFD_GAFLP1(RCANFD_F_GAFL_OFFSET, start),
RCANFD_GAFLP1_GAFLFDP(ridx));
/* Disable write access to page */
rcar_canfd_clear_bit(gpriv->base,
RCANFD_GAFLECTR, RCANFD_GAFLECTR_AFLDAE);
}
static void rcar_canfd_configure_rx(struct rcar_canfd_global *gpriv, u32 ch)
{
/* Rx FIFO is used for reception */
u32 cfg;
u16 rfdc, rfpls;
/* Select Rx FIFO based on channel */
u32 ridx = ch + RCANFD_RFFIFO_IDX;
rfdc = 2; /* b010 - 8 messages Rx FIFO depth */
rfpls = 7; /* b111 - Max 64 bytes payload */
cfg = (RCANFD_RFCC_RFIM | RCANFD_RFCC_RFDC(rfdc) |
RCANFD_RFCC_RFPLS(rfpls) | RCANFD_RFCC_RFIE);
rcar_canfd_write(gpriv->base, RCANFD_RFCC(ridx), cfg);
}
static void rcar_canfd_configure_tx(struct rcar_canfd_global *gpriv, u32 ch)
{
/* Tx/Rx(Common) FIFO configured in Tx mode is
* used for transmission
*
* Each channel has 3 Common FIFO dedicated to them.
* Use the 1st (index 0) out of 3
*/
u32 cfg;
u16 cftml, cfm, cfdc, cfpls;
cftml = 0; /* 0th buffer */
cfm = 1; /* b01 - Transmit mode */
cfdc = 2; /* b010 - 8 messages Tx FIFO depth */
cfpls = 7; /* b111 - Max 64 bytes payload */
cfg = (RCANFD_CFCC_CFTML(cftml) | RCANFD_CFCC_CFM(cfm) |
RCANFD_CFCC_CFIM | RCANFD_CFCC_CFDC(cfdc) |
RCANFD_CFCC_CFPLS(cfpls) | RCANFD_CFCC_CFTXIE);
rcar_canfd_write(gpriv->base, RCANFD_CFCC(ch, RCANFD_CFFIFO_IDX), cfg);
/* Clear FD mode specific control/status register */
rcar_canfd_write(gpriv->base,
RCANFD_F_CFFDCSTS(ch, RCANFD_CFFIFO_IDX), 0);
}
static void rcar_canfd_enable_global_interrupts(struct rcar_canfd_global *gpriv)
{
u32 ctr;
/* Clear any stray error interrupt flags */
rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0);
/* Global interrupts setup */
ctr = RCANFD_GCTR_MEIE;
ctr |= RCANFD_GCTR_CFMPOFIE;
rcar_canfd_set_bit(gpriv->base, RCANFD_GCTR, ctr);
}
static void rcar_canfd_disable_global_interrupts(struct rcar_canfd_global
*gpriv)
{
/* Disable all interrupts */
rcar_canfd_write(gpriv->base, RCANFD_GCTR, 0);
/* Clear any stray error interrupt flags */
rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0);
}
static void rcar_canfd_enable_channel_interrupts(struct rcar_canfd_channel
*priv)
{
u32 ctr, ch = priv->channel;
/* Clear any stray error flags */
rcar_canfd_write(priv->base, RCANFD_CERFL(ch), 0);
/* Channel interrupts setup */
ctr = (RCANFD_CCTR_TAIE |
RCANFD_CCTR_ALIE | RCANFD_CCTR_BLIE |
RCANFD_CCTR_OLIE | RCANFD_CCTR_BORIE |
RCANFD_CCTR_BOEIE | RCANFD_CCTR_EPIE |
RCANFD_CCTR_EWIE | RCANFD_CCTR_BEIE);
rcar_canfd_set_bit(priv->base, RCANFD_CCTR(ch), ctr);
}
static void rcar_canfd_disable_channel_interrupts(struct rcar_canfd_channel
*priv)
{
u32 ctr, ch = priv->channel;
ctr = (RCANFD_CCTR_TAIE |
RCANFD_CCTR_ALIE | RCANFD_CCTR_BLIE |
RCANFD_CCTR_OLIE | RCANFD_CCTR_BORIE |
RCANFD_CCTR_BOEIE | RCANFD_CCTR_EPIE |
RCANFD_CCTR_EWIE | RCANFD_CCTR_BEIE);
rcar_canfd_clear_bit(priv->base, RCANFD_CCTR(ch), ctr);
/* Clear any stray error flags */
rcar_canfd_write(priv->base, RCANFD_CERFL(ch), 0);
}
static void rcar_canfd_global_error(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct net_device_stats *stats = &ndev->stats;
u32 ch = priv->channel;
u32 gerfl, sts;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
gerfl = rcar_canfd_read(priv->base, RCANFD_GERFL);
if ((gerfl & RCANFD_GERFL_EEF0) && (ch == 0)) {
netdev_dbg(ndev, "Ch0: ECC Error flag\n");
stats->tx_dropped++;
}
if ((gerfl & RCANFD_GERFL_EEF1) && (ch == 1)) {
netdev_dbg(ndev, "Ch1: ECC Error flag\n");
stats->tx_dropped++;
}
if (gerfl & RCANFD_GERFL_MES) {
sts = rcar_canfd_read(priv->base,
RCANFD_CFSTS(ch, RCANFD_CFFIFO_IDX));
if (sts & RCANFD_CFSTS_CFMLT) {
netdev_dbg(ndev, "Tx Message Lost flag\n");
stats->tx_dropped++;
rcar_canfd_write(priv->base,
RCANFD_CFSTS(ch, RCANFD_CFFIFO_IDX),
sts & ~RCANFD_CFSTS_CFMLT);
}
sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(ridx));
if (sts & RCANFD_RFSTS_RFMLT) {
netdev_dbg(ndev, "Rx Message Lost flag\n");
stats->rx_dropped++;
rcar_canfd_write(priv->base, RCANFD_RFSTS(ridx),
sts & ~RCANFD_RFSTS_RFMLT);
}
}
if (gerfl & RCANFD_GERFL_CMPOF) {
/* Message Lost flag will be set for respective channel
* when this condition happens with counters and flags
* already updated.
*/
netdev_dbg(ndev, "global payload overflow interrupt\n");
}
/* Clear all global error interrupts. Only affected channels bits
* get cleared
*/
rcar_canfd_write(priv->base, RCANFD_GERFL, 0);
}
static void rcar_canfd_error(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct net_device_stats *stats = &ndev->stats;
struct can_frame *cf;
struct sk_buff *skb;
u32 cerfl, csts;
u32 txerr = 0, rxerr = 0;
u32 ch = priv->channel;
/* Propagate the error condition to the CAN stack */
skb = alloc_can_err_skb(ndev, &cf);
if (!skb) {
stats->rx_dropped++;
return;
}
/* Channel error interrupt */
cerfl = rcar_canfd_read(priv->base, RCANFD_CERFL(ch));
csts = rcar_canfd_read(priv->base, RCANFD_CSTS(ch));
txerr = RCANFD_CSTS_TECCNT(csts);
rxerr = RCANFD_CSTS_RECCNT(csts);
netdev_dbg(ndev, "ch erfl %x sts %x txerr %u rxerr %u\n",
cerfl, csts, txerr, rxerr);
if (cerfl & RCANFD_CERFL_BEF) {
netdev_dbg(ndev, "Bus error\n");
cf->can_id |= CAN_ERR_BUSERROR | CAN_ERR_PROT;
cf->data[2] = CAN_ERR_PROT_UNSPEC;
priv->can.can_stats.bus_error++;
}
if (cerfl & RCANFD_CERFL_ADERR) {
netdev_dbg(ndev, "ACK Delimiter Error\n");
stats->tx_errors++;
cf->data[3] |= CAN_ERR_PROT_LOC_ACK_DEL;
}
if (cerfl & RCANFD_CERFL_B0ERR) {
netdev_dbg(ndev, "Bit Error (dominant)\n");
stats->tx_errors++;
cf->data[2] |= CAN_ERR_PROT_BIT0;
}
if (cerfl & RCANFD_CERFL_B1ERR) {
netdev_dbg(ndev, "Bit Error (recessive)\n");
stats->tx_errors++;
cf->data[2] |= CAN_ERR_PROT_BIT1;
}
if (cerfl & RCANFD_CERFL_CERR) {
netdev_dbg(ndev, "CRC Error\n");
stats->rx_errors++;
cf->data[3] |= CAN_ERR_PROT_LOC_CRC_SEQ;
}
if (cerfl & RCANFD_CERFL_AERR) {
netdev_dbg(ndev, "ACK Error\n");
stats->tx_errors++;
cf->can_id |= CAN_ERR_ACK;
cf->data[3] |= CAN_ERR_PROT_LOC_ACK;
}
if (cerfl & RCANFD_CERFL_FERR) {
netdev_dbg(ndev, "Form Error\n");
stats->rx_errors++;
cf->data[2] |= CAN_ERR_PROT_FORM;
}
if (cerfl & RCANFD_CERFL_SERR) {
netdev_dbg(ndev, "Stuff Error\n");
stats->rx_errors++;
cf->data[2] |= CAN_ERR_PROT_STUFF;
}
if (cerfl & RCANFD_CERFL_ALF) {
netdev_dbg(ndev, "Arbitration lost Error\n");
priv->can.can_stats.arbitration_lost++;
cf->can_id |= CAN_ERR_LOSTARB;
cf->data[0] |= CAN_ERR_LOSTARB_UNSPEC;
}
if (cerfl & RCANFD_CERFL_BLF) {
netdev_dbg(ndev, "Bus Lock Error\n");
stats->rx_errors++;
cf->can_id |= CAN_ERR_BUSERROR;
}
if (cerfl & RCANFD_CERFL_EWF) {
netdev_dbg(ndev, "Error warning interrupt\n");
priv->can.state = CAN_STATE_ERROR_WARNING;
priv->can.can_stats.error_warning++;
cf->can_id |= CAN_ERR_CRTL;
cf->data[1] = txerr > rxerr ? CAN_ERR_CRTL_TX_WARNING :
CAN_ERR_CRTL_RX_WARNING;
cf->data[6] = txerr;
cf->data[7] = rxerr;
}
if (cerfl & RCANFD_CERFL_EPF) {
netdev_dbg(ndev, "Error passive interrupt\n");
priv->can.state = CAN_STATE_ERROR_PASSIVE;
priv->can.can_stats.error_passive++;
cf->can_id |= CAN_ERR_CRTL;
cf->data[1] = txerr > rxerr ? CAN_ERR_CRTL_TX_PASSIVE :
CAN_ERR_CRTL_RX_PASSIVE;
cf->data[6] = txerr;
cf->data[7] = rxerr;
}
if (cerfl & RCANFD_CERFL_BOEF) {
netdev_dbg(ndev, "Bus-off entry interrupt\n");
rcar_canfd_tx_failure_cleanup(ndev);
priv->can.state = CAN_STATE_BUS_OFF;
priv->can.can_stats.bus_off++;
can_bus_off(ndev);
cf->can_id |= CAN_ERR_BUSOFF;
}
if (cerfl & RCANFD_CERFL_OVLF) {
netdev_dbg(ndev,
"Overload Frame Transmission error interrupt\n");
stats->tx_errors++;
cf->can_id |= CAN_ERR_PROT;
cf->data[2] |= CAN_ERR_PROT_OVERLOAD;
}
/* Clear all channel error interrupts */
rcar_canfd_write(priv->base, RCANFD_CERFL(ch), 0);
stats->rx_packets++;
stats->rx_bytes += cf->can_dlc;
netif_rx(skb);
}
static void rcar_canfd_tx_done(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct net_device_stats *stats = &ndev->stats;
u32 sts;
unsigned long flags;
u32 ch = priv->channel;
do {
u8 unsent, sent;
sent = priv->tx_tail % RCANFD_FIFO_DEPTH;
stats->tx_packets++;
stats->tx_bytes += priv->tx_len[sent];
priv->tx_len[sent] = 0;
can_get_echo_skb(ndev, sent);
spin_lock_irqsave(&priv->tx_lock, flags);
priv->tx_tail++;
sts = rcar_canfd_read(priv->base,
RCANFD_CFSTS(ch, RCANFD_CFFIFO_IDX));
unsent = RCANFD_CFSTS_CFMC(sts);
/* Wake producer only when there is room */
if (unsent != RCANFD_FIFO_DEPTH)
netif_wake_queue(ndev);
if (priv->tx_head - priv->tx_tail <= unsent) {
spin_unlock_irqrestore(&priv->tx_lock, flags);
break;
}
spin_unlock_irqrestore(&priv->tx_lock, flags);
} while (1);
/* Clear interrupt */
rcar_canfd_write(priv->base, RCANFD_CFSTS(ch, RCANFD_CFFIFO_IDX),
sts & ~RCANFD_CFSTS_CFTXIF);
can_led_event(ndev, CAN_LED_EVENT_TX);
}
static irqreturn_t rcar_canfd_global_interrupt(int irq, void *dev_id)
{
struct rcar_canfd_global *gpriv = dev_id;
struct net_device *ndev;
struct rcar_canfd_channel *priv;
u32 sts, gerfl;
u32 ch, ridx;
/* Global error interrupts still indicate a condition specific
* to a channel. RxFIFO interrupt is a global interrupt.
*/
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
priv = gpriv->ch[ch];
ndev = priv->ndev;
ridx = ch + RCANFD_RFFIFO_IDX;
/* Global error interrupts */
gerfl = rcar_canfd_read(priv->base, RCANFD_GERFL);
if (RCANFD_GERFL_ERR(gerfl))
rcar_canfd_global_error(ndev);
/* Handle Rx interrupts */
sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(ridx));
if (sts & RCANFD_RFSTS_RFIF) {
if (napi_schedule_prep(&priv->napi)) {
/* Disable Rx FIFO interrupts */
rcar_canfd_clear_bit(priv->base,
RCANFD_RFCC(ridx),
RCANFD_RFCC_RFIE);
__napi_schedule(&priv->napi);
}
}
}
return IRQ_HANDLED;
}
static irqreturn_t rcar_canfd_channel_interrupt(int irq, void *dev_id)
{
struct rcar_canfd_global *gpriv = dev_id;
struct net_device *ndev;
struct rcar_canfd_channel *priv;
u32 sts, cerfl, ch;
/* Common FIFO is a per channel resource */
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
priv = gpriv->ch[ch];
ndev = priv->ndev;
/* Channel error interrupts */
cerfl = rcar_canfd_read(priv->base, RCANFD_CERFL(ch));
if (RCANFD_CERFL_ERR(cerfl))
rcar_canfd_error(ndev);
/* Handle Tx interrupts */
sts = rcar_canfd_read(priv->base,
RCANFD_CFSTS(ch, RCANFD_CFFIFO_IDX));
if (sts & RCANFD_CFSTS_CFTXIF)
rcar_canfd_tx_done(ndev);
}
return IRQ_HANDLED;
}
static void rcar_canfd_set_bittiming(struct net_device *dev)
{
struct rcar_canfd_channel *priv = netdev_priv(dev);
const struct can_bittiming *bt = &priv->can.bittiming;
const struct can_bittiming *dbt = &priv->can.data_bittiming;
u16 brp, sjw, tseg1, tseg2;
u32 cfg;
u32 ch = priv->channel;
/* Nominal bit timing settings */
brp = bt->brp - 1;
sjw = bt->sjw - 1;
tseg1 = bt->prop_seg + bt->phase_seg1 - 1;
tseg2 = bt->phase_seg2 - 1;
cfg = (RCANFD_NCFG_NTSEG1(tseg1) | RCANFD_NCFG_NBRP(brp) |
RCANFD_NCFG_NSJW(sjw) | RCANFD_NCFG_NTSEG2(tseg2));
rcar_canfd_write(priv->base, RCANFD_CCFG(ch), cfg);
netdev_dbg(priv->ndev, "nrate: brp %u, sjw %u, tseg1 %u, tseg2 %u\n",
brp, sjw, tseg1, tseg2);
/* Data bit timing settings */
brp = dbt->brp - 1;
sjw = dbt->sjw - 1;
tseg1 = dbt->prop_seg + dbt->phase_seg1 - 1;
tseg2 = dbt->phase_seg2 - 1;
cfg = (RCANFD_DCFG_DTSEG1(tseg1) | RCANFD_DCFG_DBRP(brp) |
RCANFD_DCFG_DSJW(sjw) | RCANFD_DCFG_DTSEG2(tseg2));
rcar_canfd_write(priv->base, RCANFD_F_DCFG(ch), cfg);
netdev_dbg(priv->ndev, "drate: brp %u, sjw %u, tseg1 %u, tseg2 %u\n",
brp, sjw, tseg1, tseg2);
}
static int rcar_canfd_start(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
int err = -EOPNOTSUPP;
u32 sts, ch = priv->channel;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
rcar_canfd_set_bittiming(ndev);
rcar_canfd_enable_channel_interrupts(priv);
/* Set channel to Operational mode */
rcar_canfd_update_bit(priv->base, RCANFD_CCTR(ch),
RCANFD_CCTR_CHMDC_MASK, RCANFD_CCTR_CHDMC_COPM);
/* Verify channel mode change */
err = readl_poll_timeout((priv->base + RCANFD_CSTS(ch)), sts,
(sts & RCANFD_CSTS_COMSTS), 2, 500000);
if (err) {
netdev_err(ndev, "channel %u communication state failed\n", ch);
goto fail_mode_change;
}
/* Enable Common & Rx FIFO */
rcar_canfd_set_bit(priv->base, RCANFD_CFCC(ch, RCANFD_CFFIFO_IDX),
RCANFD_CFCC_CFE);
rcar_canfd_set_bit(priv->base, RCANFD_RFCC(ridx), RCANFD_RFCC_RFE);
priv->can.state = CAN_STATE_ERROR_ACTIVE;
return 0;
fail_mode_change:
rcar_canfd_disable_channel_interrupts(priv);
return err;
}
static int rcar_canfd_open(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct rcar_canfd_global *gpriv = priv->gpriv;
int err;
/* Peripheral clock is already enabled in probe */
err = clk_prepare_enable(gpriv->can_clk);
if (err) {
netdev_err(ndev, "failed to enable CAN clock, error %d\n", err);
goto out_clock;
}
err = open_candev(ndev);
if (err) {
netdev_err(ndev, "open_candev() failed, error %d\n", err);
goto out_can_clock;
}
napi_enable(&priv->napi);
err = rcar_canfd_start(ndev);
if (err)
goto out_close;
netif_start_queue(ndev);
can_led_event(ndev, CAN_LED_EVENT_OPEN);
return 0;
out_close:
napi_disable(&priv->napi);
close_candev(ndev);
out_can_clock:
clk_disable_unprepare(gpriv->can_clk);
out_clock:
return err;
}
static void rcar_canfd_stop(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
int err;
u32 sts, ch = priv->channel;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
/* Transition to channel reset mode */
rcar_canfd_update_bit(priv->base, RCANFD_CCTR(ch),
RCANFD_CCTR_CHMDC_MASK, RCANFD_CCTR_CHDMC_CRESET);
/* Check Channel reset mode */
err = readl_poll_timeout((priv->base + RCANFD_CSTS(ch)), sts,
(sts & RCANFD_CSTS_CRSTSTS), 2, 500000);
if (err)
netdev_err(ndev, "channel %u reset failed\n", ch);
rcar_canfd_disable_channel_interrupts(priv);
/* Disable Common & Rx FIFO */
rcar_canfd_clear_bit(priv->base, RCANFD_CFCC(ch, RCANFD_CFFIFO_IDX),
RCANFD_CFCC_CFE);
rcar_canfd_clear_bit(priv->base, RCANFD_RFCC(ridx), RCANFD_RFCC_RFE);
/* Set the state as STOPPED */
priv->can.state = CAN_STATE_STOPPED;
}
static int rcar_canfd_close(struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct rcar_canfd_global *gpriv = priv->gpriv;
netif_stop_queue(ndev);
rcar_canfd_stop(ndev);
napi_disable(&priv->napi);
clk_disable_unprepare(gpriv->can_clk);
close_candev(ndev);
can_led_event(ndev, CAN_LED_EVENT_STOP);
return 0;
}
static netdev_tx_t rcar_canfd_start_xmit(struct sk_buff *skb,
struct net_device *ndev)
{
struct rcar_canfd_channel *priv = netdev_priv(ndev);
struct canfd_frame *cf = (struct canfd_frame *)skb->data;
u32 sts = 0, id, dlc;
unsigned long flags;
u32 ch = priv->channel;
if (can_dropped_invalid_skb(ndev, skb))
return NETDEV_TX_OK;
if (cf->can_id & CAN_EFF_FLAG) {
id = cf->can_id & CAN_EFF_MASK;
id |= RCANFD_CFID_CFIDE;
} else {
id = cf->can_id & CAN_SFF_MASK;
}
if (cf->can_id & CAN_RTR_FLAG)
id |= RCANFD_CFID_CFRTR;
rcar_canfd_write(priv->base,
RCANFD_F_CFID(ch, RCANFD_CFFIFO_IDX), id);
dlc = RCANFD_CFPTR_CFDLC(can_len2dlc(cf->len));
rcar_canfd_write(priv->base,
RCANFD_F_CFPTR(ch, RCANFD_CFFIFO_IDX), dlc);
if (can_is_canfd_skb(skb)) {
/* CAN FD frame format */
sts |= RCANFD_CFFDCSTS_CFFDF;
if (cf->flags & CANFD_BRS)
sts |= RCANFD_CFFDCSTS_CFBRS;
if (priv->can.state == CAN_STATE_ERROR_PASSIVE)
sts |= RCANFD_CFFDCSTS_CFESI;
}
rcar_canfd_write(priv->base, RCANFD_F_CFFDCSTS(ch, RCANFD_CFFIFO_IDX),
sts);
rcar_canfd_put_data(priv, cf,
RCANFD_F_CFDF(ch, RCANFD_CFFIFO_IDX, 0));
priv->tx_len[priv->tx_head % RCANFD_FIFO_DEPTH] = cf->len;
can_put_echo_skb(skb, ndev, priv->tx_head % RCANFD_FIFO_DEPTH);
spin_lock_irqsave(&priv->tx_lock, flags);
priv->tx_head++;
/* Stop the queue if we've filled all FIFO entries */
if (priv->tx_head - priv->tx_tail >= RCANFD_FIFO_DEPTH)
netif_stop_queue(ndev);
/* Start Tx: Write 0xff to CFPC to increment the CPU-side
* pointer for the Common FIFO
*/
rcar_canfd_write(priv->base,
RCANFD_CFPCTR(ch, RCANFD_CFFIFO_IDX), 0xff);
spin_unlock_irqrestore(&priv->tx_lock, flags);
return NETDEV_TX_OK;
}
static void rcar_canfd_rx_pkt(struct rcar_canfd_channel *priv)
{
struct net_device_stats *stats = &priv->ndev->stats;
struct canfd_frame *cf;
struct sk_buff *skb;
u32 sts = 0, id, ptr;
u32 ch = priv->channel;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
id = rcar_canfd_read(priv->base, RCANFD_F_RFID(ridx));
ptr = rcar_canfd_read(priv->base, RCANFD_F_RFPTR(ridx));
sts = rcar_canfd_read(priv->base, RCANFD_F_RFFDSTS(ridx));
if (sts & RCANFD_RFFDSTS_RFFDF)
skb = alloc_canfd_skb(priv->ndev, &cf);
else
skb = alloc_can_skb(priv->ndev,
(struct can_frame **)&cf);
if (!skb) {
stats->rx_dropped++;
return;
}
if (sts & RCANFD_RFFDSTS_RFFDF)
cf->len = can_dlc2len(RCANFD_RFPTR_RFDLC(ptr));
else
cf->len = get_can_dlc(RCANFD_RFPTR_RFDLC(ptr));
if (sts & RCANFD_RFFDSTS_RFESI) {
cf->flags |= CANFD_ESI;
netdev_dbg(priv->ndev, "ESI Error\n");
}
if (id & RCANFD_RFID_RFIDE)
cf->can_id = (id & CAN_EFF_MASK) | CAN_EFF_FLAG;
else
cf->can_id = id & CAN_SFF_MASK;
if (!(sts & RCANFD_RFFDSTS_RFFDF) && (id & RCANFD_RFID_RFRTR)) {
cf->can_id |= CAN_RTR_FLAG;
} else {
if (sts & RCANFD_RFFDSTS_RFBRS)
cf->flags |= CANFD_BRS;
rcar_canfd_get_data(priv, cf, RCANFD_F_RFDF(ridx, 0));
}
/* Write 0xff to RFPC to increment the CPU-side
* pointer of the Rx FIFO
*/
rcar_canfd_write(priv->base, RCANFD_RFPCTR(ridx), 0xff);
can_led_event(priv->ndev, CAN_LED_EVENT_RX);
stats->rx_bytes += cf->len;
stats->rx_packets++;
netif_receive_skb(skb);
}
static int rcar_canfd_rx_poll(struct napi_struct *napi, int quota)
{
struct rcar_canfd_channel *priv =
container_of(napi, struct rcar_canfd_channel, napi);
int num_pkts;
u32 sts;
u32 ch = priv->channel;
u32 ridx = ch + RCANFD_RFFIFO_IDX;
for (num_pkts = 0; num_pkts < quota; num_pkts++) {
sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(ridx));
/* Check FIFO empty condition */
if (sts & RCANFD_RFSTS_RFEMP)
break;
rcar_canfd_rx_pkt(priv);
/* Clear interrupt bit */
if (sts & RCANFD_RFSTS_RFIF)
rcar_canfd_write(priv->base, RCANFD_RFSTS(ridx),
sts & ~RCANFD_RFSTS_RFIF);
}
/* All packets processed */
if (num_pkts < quota) {
napi_complete(napi);
/* Enable Rx FIFO interrupts */
rcar_canfd_set_bit(priv->base, RCANFD_RFCC(ridx),
RCANFD_RFCC_RFIE);
}
return num_pkts;
}
static int rcar_canfd_do_set_mode(struct net_device *ndev, enum can_mode mode)
{
int err;
switch (mode) {
case CAN_MODE_START:
err = rcar_canfd_start(ndev);
if (err)
return err;
netif_wake_queue(ndev);
return 0;
default:
return -EOPNOTSUPP;
}
}
static int rcar_canfd_get_berr_counter(const struct net_device *dev,
struct can_berr_counter *bec)
{
struct rcar_canfd_channel *priv = netdev_priv(dev);
u32 val, ch = priv->channel;
/* Peripheral clock is already enabled in probe */
val = rcar_canfd_read(priv->base, RCANFD_CSTS(ch));
bec->txerr = RCANFD_CSTS_TECCNT(val);
bec->rxerr = RCANFD_CSTS_RECCNT(val);
return 0;
}
static const struct net_device_ops rcar_canfd_netdev_ops = {
.ndo_open = rcar_canfd_open,
.ndo_stop = rcar_canfd_close,
.ndo_start_xmit = rcar_canfd_start_xmit,
.ndo_change_mtu = can_change_mtu,
};
static int rcar_canfd_channel_probe(struct rcar_canfd_global *gpriv, u32 ch,
u32 fcan_freq)
{
struct platform_device *pdev = gpriv->pdev;
struct rcar_canfd_channel *priv;
struct net_device *ndev;
int err = -ENODEV;
ndev = alloc_candev(sizeof(*priv), RCANFD_FIFO_DEPTH);
if (!ndev) {
dev_err(&pdev->dev, "alloc_candev() failed\n");
err = -ENOMEM;
goto fail;
}
priv = netdev_priv(ndev);
ndev->netdev_ops = &rcar_canfd_netdev_ops;
ndev->flags |= IFF_ECHO;
priv->ndev = ndev;
priv->base = gpriv->base;
priv->channel = ch;
priv->can.clock.freq = fcan_freq;
dev_info(&pdev->dev, "can_clk rate is %u\n", priv->can.clock.freq);
priv->can.bittiming_const = &rcar_canfd_nom_bittiming_const;
priv->can.data_bittiming_const =
&rcar_canfd_data_bittiming_const;
/* Controller starts in CAN FD only mode */
can_set_static_ctrlmode(ndev, CAN_CTRLMODE_FD);
priv->can.ctrlmode_supported = CAN_CTRLMODE_BERR_REPORTING;
priv->can.do_set_mode = rcar_canfd_do_set_mode;
priv->can.do_get_berr_counter = rcar_canfd_get_berr_counter;
priv->gpriv = gpriv;
SET_NETDEV_DEV(ndev, &pdev->dev);
netif_napi_add(ndev, &priv->napi, rcar_canfd_rx_poll,
RCANFD_NAPI_WEIGHT);
err = register_candev(ndev);
if (err) {
dev_err(&pdev->dev,
"register_candev() failed, error %d\n", err);
goto fail_candev;
}
spin_lock_init(&priv->tx_lock);
devm_can_led_init(ndev);
gpriv->ch[priv->channel] = priv;
dev_info(&pdev->dev, "device registered (channel %u)\n", priv->channel);
return 0;
fail_candev:
netif_napi_del(&priv->napi);
free_candev(ndev);
fail:
return err;
}
static void rcar_canfd_channel_remove(struct rcar_canfd_global *gpriv, u32 ch)
{
struct rcar_canfd_channel *priv = gpriv->ch[ch];
if (priv) {
unregister_candev(priv->ndev);
netif_napi_del(&priv->napi);
free_candev(priv->ndev);
}
}
static int rcar_canfd_probe(struct platform_device *pdev)
{
struct resource *mem;
void __iomem *addr;
u32 sts, ch, fcan_freq;
struct rcar_canfd_global *gpriv;
struct device_node *of_child;
unsigned long channels_mask = 0;
int err, ch_irq, g_irq;
of_child = of_get_child_by_name(pdev->dev.of_node, "channel0");
if (of_child && of_device_is_available(of_child))
channels_mask |= BIT(0); /* Channel 0 */
of_child = of_get_child_by_name(pdev->dev.of_node, "channel1");
if (of_child && of_device_is_available(of_child))
channels_mask |= BIT(1); /* Channel 1 */
ch_irq = platform_get_irq(pdev, 0);
if (ch_irq < 0) {
dev_err(&pdev->dev, "no Channel IRQ resource\n");
err = ch_irq;
goto fail_dev;
}
g_irq = platform_get_irq(pdev, 1);
if (g_irq < 0) {
dev_err(&pdev->dev, "no Global IRQ resource\n");
err = g_irq;
goto fail_dev;
}
/* Global controller context */
gpriv = devm_kzalloc(&pdev->dev, sizeof(*gpriv), GFP_KERNEL);
if (!gpriv) {
err = -ENOMEM;
goto fail_dev;
}
gpriv->pdev = pdev;
gpriv->channels_mask = channels_mask;
/* Peripheral clock */
gpriv->clkp = devm_clk_get(&pdev->dev, "fck");
if (IS_ERR(gpriv->clkp)) {
err = PTR_ERR(gpriv->clkp);
dev_err(&pdev->dev, "cannot get peripheral clock, error %d\n",
err);
goto fail_dev;
}
/* fCAN clock: Pick External clock. If not available fallback to
* CANFD clock
*/
gpriv->can_clk = devm_clk_get(&pdev->dev, "can_clk");
if (IS_ERR(gpriv->can_clk) || (clk_get_rate(gpriv->can_clk) == 0)) {
gpriv->can_clk = devm_clk_get(&pdev->dev, "canfd");
if (IS_ERR(gpriv->can_clk)) {
err = PTR_ERR(gpriv->can_clk);
dev_err(&pdev->dev,
"cannot get canfd clock, error %d\n", err);
goto fail_dev;
}
gpriv->fcan = RCANFD_CANFDCLK;
} else {
gpriv->fcan = RCANFD_EXTCLK;
}
fcan_freq = clk_get_rate(gpriv->can_clk);
if (gpriv->fcan == RCANFD_CANFDCLK)
/* CANFD clock is further divided by (1/2) within the IP */
fcan_freq /= 2;
mem = platform_get_resource(pdev, IORESOURCE_MEM, 0);
addr = devm_ioremap_resource(&pdev->dev, mem);
if (IS_ERR(addr)) {
err = PTR_ERR(addr);
goto fail_dev;
}
gpriv->base = addr;
/* Request IRQ that's common for both channels */
err = devm_request_irq(&pdev->dev, ch_irq,
rcar_canfd_channel_interrupt, 0,
"canfd.chn", gpriv);
if (err) {
dev_err(&pdev->dev, "devm_request_irq(%d) failed, error %d\n",
ch_irq, err);
goto fail_dev;
}
err = devm_request_irq(&pdev->dev, g_irq,
rcar_canfd_global_interrupt, 0,
"canfd.gbl", gpriv);
if (err) {
dev_err(&pdev->dev, "devm_request_irq(%d) failed, error %d\n",
g_irq, err);
goto fail_dev;
}
/* Enable peripheral clock for register access */
err = clk_prepare_enable(gpriv->clkp);
if (err) {
dev_err(&pdev->dev,
"failed to enable peripheral clock, error %d\n", err);
goto fail_dev;
}
err = rcar_canfd_reset_controller(gpriv);
if (err) {
dev_err(&pdev->dev, "reset controller failed\n");
goto fail_clk;
}
/* Controller in Global reset & Channel reset mode */
rcar_canfd_configure_controller(gpriv);
/* Configure per channel attributes */
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
/* Configure Channel's Rx fifo */
rcar_canfd_configure_rx(gpriv, ch);
/* Configure Channel's Tx (Common) fifo */
rcar_canfd_configure_tx(gpriv, ch);
/* Configure receive rules */
rcar_canfd_configure_afl_rules(gpriv, ch);
}
/* Configure common interrupts */
rcar_canfd_enable_global_interrupts(gpriv);
/* Start Global operation mode */
rcar_canfd_update_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GMDC_MASK,
RCANFD_GCTR_GMDC_GOPM);
/* Verify mode change */
err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
!(sts & RCANFD_GSTS_GNOPM), 2, 500000);
if (err) {
dev_err(&pdev->dev, "global operational mode failed\n");
goto fail_mode;
}
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
err = rcar_canfd_channel_probe(gpriv, ch, fcan_freq);
if (err)
goto fail_channel;
}
platform_set_drvdata(pdev, gpriv);
dev_info(&pdev->dev, "global operational state (clk %d)\n",
gpriv->fcan);
return 0;
fail_channel:
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS)
rcar_canfd_channel_remove(gpriv, ch);
fail_mode:
rcar_canfd_disable_global_interrupts(gpriv);
fail_clk:
clk_disable_unprepare(gpriv->clkp);
fail_dev:
return err;
}
static int rcar_canfd_remove(struct platform_device *pdev)
{
struct rcar_canfd_global *gpriv = platform_get_drvdata(pdev);
u32 ch;
rcar_canfd_reset_controller(gpriv);
rcar_canfd_disable_global_interrupts(gpriv);
for_each_set_bit(ch, &gpriv->channels_mask, RCANFD_NUM_CHANNELS) {
rcar_canfd_disable_channel_interrupts(gpriv->ch[ch]);
rcar_canfd_channel_remove(gpriv, ch);
}
/* Enter global sleep mode */
rcar_canfd_set_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GSLPR);
clk_disable_unprepare(gpriv->clkp);
return 0;
}
static int __maybe_unused rcar_canfd_suspend(struct device *dev)
{
return 0;
}
static int __maybe_unused rcar_canfd_resume(struct device *dev)
{
return 0;
}
static SIMPLE_DEV_PM_OPS(rcar_canfd_pm_ops, rcar_canfd_suspend,
rcar_canfd_resume);
static const struct of_device_id rcar_canfd_of_table[] = {
{ .compatible = "renesas,rcar-gen3-canfd" },
{ }
};
MODULE_DEVICE_TABLE(of, rcar_canfd_of_table);
static struct platform_driver rcar_canfd_driver = {
.driver = {
.name = RCANFD_DRV_NAME,
.of_match_table = of_match_ptr(rcar_canfd_of_table),
.pm = &rcar_canfd_pm_ops,
},
.probe = rcar_canfd_probe,
.remove = rcar_canfd_remove,
};
module_platform_driver(rcar_canfd_driver);
MODULE_AUTHOR("Ramesh Shanmugasundaram <ramesh.shanmugasundaram@bp.renesas.com>");
MODULE_LICENSE("GPL");
MODULE_DESCRIPTION("CAN FD driver for Renesas R-Car SoC");
MODULE_ALIAS("platform:" RCANFD_DRV_NAME);
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