blob: c492274935be650cd29d2bd2b869683eda3c71fb [file] [log] [blame] [edit]
/*
* Copyright (c) 2020-2024, Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
/dts-v1/;
#include <dt-bindings/interrupt-controller/arm-gic.h>
#include <dt-bindings/interrupt-controller/irq.h>
#include <platform_def.h>
#if TARGET_FLAVOUR_FVP
#define LIT_CAPACITY 406
#define MID_CAPACITY 912
#else /* TARGET_FLAVOUR_FPGA */
#define LIT_CAPACITY 280
#define MID_CAPACITY 775
/* this is an area optimized configuration of the big core */
#define BIG2_CAPACITY 930
#endif /* TARGET_FLAVOUR_FPGA */
#define BIG_CAPACITY 1024
#define MHU_TX_ADDR 45000000 /* hex */
#define MHU_TX_COMPAT "arm,mhuv2-tx","arm,primecell"
#define MHU_TX_INT_NAME "mhu_tx"
#define MHU_RX_ADDR 45010000 /* hex */
#define MHU_RX_COMPAT "arm,mhuv2-rx","arm,primecell"
#define MHU_OFFSET 0x1000
#define MHU_MBOX_CELLS 2
#define MHU_RX_INT_NUM 317
#define MHU_RX_INT_NAME "mhu_rx"
#define LIT_CPU_PMU_COMPATIBLE "arm,cortex-a520-pmu"
#define MID_CPU_PMU_COMPATIBLE "arm,cortex-a720-pmu"
#define BIG_CPU_PMU_COMPATIBLE "arm,cortex-x4-pmu"
#define MPAM_ADDR 0x1 0x00010000 /* 0x1_0001_0000 */
#define UARTCLK_FREQ 5000000
#define DPU_ADDR 2cc00000
#define DPU_IRQ 69
#define ETHERNET_ADDR 18000000
#define ETHERNET_INT 109
#define SYS_REGS_ADDR 1c010000
#define MMC_ADDR 1c050000
#define MMC_INT_0 107
#define MMC_INT_1 108
#define RTC_ADDR 1c170000
#define RTC_INT 100
#define KMI_0_ADDR 1c060000
#define KMI_0_INT 197
#define KMI_1_ADDR 1c070000
#define KMI_1_INT 103
#define VIRTIO_BLOCK_ADDR 1c130000
#define VIRTIO_BLOCK_INT 204
#include "tc-common.dtsi"
#if TARGET_FLAVOUR_FVP
#include "tc-fvp.dtsi"
#else
#include "tc-fpga.dtsi"
#endif /* TARGET_FLAVOUR_FVP */
#include "tc-base.dtsi"
/ {
cpus {
#if TARGET_FLAVOUR_FPGA
cpu-map {
cluster0 {
core8 {
cpu = <&CPU8>;
};
core9 {
cpu = <&CPU9>;
};
core10 {
cpu = <&CPU10>;
};
core11 {
cpu = <&CPU11>;
};
core12 {
cpu = <&CPU12>;
};
core13 {
cpu = <&CPU13>;
};
};
};
#endif
CPU2:cpu@200 {
clocks = <&scmi_dvfs 0>;
capacity-dmips-mhz = <LIT_CAPACITY>;
};
CPU3:cpu@300 {
clocks = <&scmi_dvfs 0>;
capacity-dmips-mhz = <LIT_CAPACITY>;
};
CPU6:cpu@600 {
clocks = <&scmi_dvfs 1>;
capacity-dmips-mhz = <MID_CAPACITY>;
};
CPU7:cpu@700 {
clocks = <&scmi_dvfs 1>;
capacity-dmips-mhz = <MID_CAPACITY>;
};
#if TARGET_FLAVOUR_FPGA
CPU8:cpu@800 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0x800>;
enable-method = "psci";
clocks = <&scmi_dvfs 1>;
capacity-dmips-mhz = <MID_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
CPU9:cpu@900 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0x900>;
enable-method = "psci";
clocks = <&scmi_dvfs 2>;
capacity-dmips-mhz = <BIG2_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
CPU10:cpu@A00 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0xA00>;
enable-method = "psci";
clocks = <&scmi_dvfs 2>;
capacity-dmips-mhz = <BIG2_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
CPU11:cpu@B00 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0xB00>;
enable-method = "psci";
clocks = <&scmi_dvfs 2>;
capacity-dmips-mhz = <BIG2_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
CPU12:cpu@C00 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0xC00>;
enable-method = "psci";
clocks = <&scmi_dvfs 3>;
capacity-dmips-mhz = <BIG_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
CPU13:cpu@D00 {
device_type = "cpu";
compatible = "arm,armv8";
reg = <0xD00>;
enable-method = "psci";
clocks = <&scmi_dvfs 3>;
capacity-dmips-mhz = <BIG_CAPACITY>;
amu = <&amu>;
supports-mpmm;
};
#endif
};
#if TARGET_FLAVOUR_FPGA
ete8 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU8>;
};
ete9 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU9>;
};
ete10 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU10>;
};
ete11 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU11>;
};
ete12 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU12>;
};
ete13 {
compatible = "arm,embedded-trace-extension";
cpu = <&CPU13>;
};
#endif /* TARGET_FLAVOUR_FPGA */
cmn-pmu {
compatible = "arm,ci-700";
reg = <0x0 0x50000000 0x0 0x10000000>;
interrupts = <GIC_SPI 460 IRQ_TYPE_LEVEL_HIGH 0>;
};
mbox_db_rx: mhu@MHU_RX_ADDR {
arm,mhuv2-protocols = <0 1>;
};
mbox_db_tx: mhu@MHU_TX_ADDR {
arm,mhuv2-protocols = <0 1>;
};
firmware {
/*
* TC2 does not have a P2A channel, but wiring one was needed to make Linux work
* (by chance). At the time the SCMI driver did not support bidirectional
* mailboxes so as a workaround, the A2P channel was wired for TX communication
* and the synchronous replies would be read asyncrhonously as if coming from
* the P2A channel, while being the actual A2P channel.
*
* This will not work with kernels > 5.15, but keep it around to keep TC2
* working with its target kernel. Newer kernels will still work, but SCMI
* won't as they check that the two regions are distinct.
*/
scmi {
mboxes = <&mbox_db_tx 0 0 &mbox_db_rx 0 0>;
shmem = <&cpu_scp_scmi_a2p &cpu_scp_scmi_a2p>;
};
};
gic: interrupt-controller@GIC_CTRL_ADDR {
ppi-partitions {
ppi_partition_little: interrupt-partition-0 {
affinity = <&CPU0>, <&CPU1>, <&CPU2>, <&CPU3>;
};
#if TARGET_FLAVOUR_FVP
ppi_partition_mid: interrupt-partition-1 {
affinity = <&CPU4>, <&CPU5>, <&CPU6>;
};
ppi_partition_big: interrupt-partition-2 {
affinity = <&CPU7>;
};
#elif TARGET_FLAVOUR_FPGA
ppi_partition_mid: interrupt-partition-1 {
affinity = <&CPU4>, <&CPU5>, <&CPU6>, <&CPU7>, <&CPU8>;
};
ppi_partition_big: interrupt-partition-2 {
affinity = <&CPU9>, <&CPU10>, <&CPU11>, <&CPU12>, <&CPU13>;
};
#endif
};
};
spe-pmu-big {
status = "okay";
};
smmu_700: iommu@3f000000 {
status = "okay";
};
dp0: display@DPU_ADDR {
#if TC_SCMI_PD_CTRL_EN
power-domains = <&scmi_devpd (PLAT_MAX_CPUS_PER_CLUSTER + 2)>;
#endif
iommus = <&smmu_700 0x100>;
};
gpu: gpu@2d000000 {
interrupts = <GIC_SPI 66 IRQ_TYPE_LEVEL_HIGH 0>,
<GIC_SPI 67 IRQ_TYPE_LEVEL_HIGH 0>,
<GIC_SPI 65 IRQ_TYPE_LEVEL_HIGH 0>;
interrupt-names = "JOB", "MMU", "GPU";
iommus = <&smmu_700 0x200>;
};
};