Documentation/devicetree/bindings/riscv/cpus.txt - third_party/linux - Git at Google

 ===================
 RISC-V CPU Bindings
 ===================

 The device tree allows to describe the layout of CPUs in a system through
 the "cpus" node, which in turn contains a number of subnodes (ie "cpu")
 defining properties for every cpu.

 Bindings for CPU nodes follow the Devicetree Specification, available from:

 https://www.devicetree.org/specifications/

 with updates for 32-bit and 64-bit RISC-V systems provided in this document.

 ===========
 Terminology
 ===========

 This document uses some terminology common to the RISC-V community that is not
 widely used, the definitions of which are listed here:

 * hart: A hardware execution context, which contains all the state mandated by
   the RISC-V ISA: a PC and some registers.  This terminology is designed to
   disambiguate software's view of execution contexts from any particular
   microarchitectural implementation strategy.  For example, my Intel laptop is
   described as having one socket with two cores, each of which has two hyper
   threads.  Therefore this system has four harts.

 =====================================
 cpus and cpu node bindings definition
 =====================================

 The RISC-V architecture, in accordance with the Devicetree Specification,
 requires the cpus and cpu nodes to be present and contain the properties
 described below.

 - cpus node

         Description: Container of cpu nodes

         The node name must be "cpus".

         A cpus node must define the following properties:

         - #address-cells
                 Usage: required
                 Value type: <u32>
                 Definition: must be set to 1
         - #size-cells
                 Usage: required
                 Value type: <u32>
                 Definition: must be set to 0

 - cpu node

         Description: Describes a hart context

         PROPERTIES

         - device_type
                 Usage: required
                 Value type: <string>
                 Definition: must be "cpu"
         - reg
                 Usage: required
                 Value type: <u32>
                 Definition: The hart ID of this CPU node
         - compatible:
                 Usage: required
                 Value type: <stringlist>
                 Definition: must contain "riscv", may contain one of
                             "sifive,rocket0"
         - mmu-type:
                 Usage: optional
                 Value type: <string>
                 Definition: Specifies the CPU's MMU type.  Possible values are
                             "riscv,sv32"
                             "riscv,sv39"
                             "riscv,sv48"
         - riscv,isa:
                 Usage: required
                 Value type: <string>
                 Definition: Contains the RISC-V ISA string of this hart.  These
                             ISA strings are defined by the RISC-V ISA manual.

 Example: SiFive Freedom U540G Development Kit
 ---------------------------------------------

 This system contains two harts: a hart marked as disabled that's used for
 low-level system tasks and should be ignored by Linux, and a second hart that
 Linux is allowed to run on.

         cpus {
                 #address-cells = <1>;
                 #size-cells = <0>;
                 timebase-frequency = <1000000>;
                 cpu@0 {
                         clock-frequency = <1600000000>;
                         compatible = "sifive,rocket0", "riscv";
                         device_type = "cpu";
                         i-cache-block-size = <64>;
                         i-cache-sets = <128>;
                         i-cache-size = <16384>;
                         next-level-cache = <&L15 &L0>;
                         reg = <0>;
                         riscv,isa = "rv64imac";
                         status = "disabled";
                         L10: interrupt-controller {
                                 #interrupt-cells = <1>;
                                 compatible = "riscv,cpu-intc";
                                 interrupt-controller;
                         };
                 };
                 cpu@1 {
                         clock-frequency = <1600000000>;
                         compatible = "sifive,rocket0", "riscv";
                         d-cache-block-size = <64>;
                         d-cache-sets = <64>;
                         d-cache-size = <32768>;
                         d-tlb-sets = <1>;
                         d-tlb-size = <32>;
                         device_type = "cpu";
                         i-cache-block-size = <64>;
                         i-cache-sets = <64>;
                         i-cache-size = <32768>;
                         i-tlb-sets = <1>;
                         i-tlb-size = <32>;
                         mmu-type = "riscv,sv39";
                         next-level-cache = <&L15 &L0>;
                         reg = <1>;
                         riscv,isa = "rv64imafdc";
                         status = "okay";
                         tlb-split;
                         L13: interrupt-controller {
                                 #interrupt-cells = <1>;
                                 compatible = "riscv,cpu-intc";
                                 interrupt-controller;
                         };
                 };
         };

 Example: Spike ISA Simulator with 1 Hart
 ----------------------------------------

 This device tree matches the Spike ISA golden model as run with `spike -p1`.

         cpus {
                 cpu@0 {
                         device_type = "cpu";
                         reg = <0x00000000>;
                         status = "okay";
                         compatible = "riscv";
                         riscv,isa = "rv64imafdc";
                         mmu-type = "riscv,sv48";
                         clock-frequency = <0x3b9aca00>;
                         interrupt-controller {
                                 #interrupt-cells = <0x00000001>;
                                 interrupt-controller;
                                 compatible = "riscv,cpu-intc";
                         }
                 }
         }
	===================
	RISC-V CPU Bindings
	===================

	The device tree allows to describe the layout of CPUs in a system through
	the "cpus" node, which in turn contains a number of subnodes (ie "cpu")
	defining properties for every cpu.

	Bindings for CPU nodes follow the Devicetree Specification, available from:

	https://www.devicetree.org/specifications/

	with updates for 32-bit and 64-bit RISC-V systems provided in this document.

	===========
	Terminology
	===========

	This document uses some terminology common to the RISC-V community that is not
	widely used, the definitions of which are listed here:

	* hart: A hardware execution context, which contains all the state mandated by
	the RISC-V ISA: a PC and some registers. This terminology is designed to
	disambiguate software's view of execution contexts from any particular
	microarchitectural implementation strategy. For example, my Intel laptop is
	described as having one socket with two cores, each of which has two hyper
	threads. Therefore this system has four harts.

	=====================================
	cpus and cpu node bindings definition
	=====================================

	The RISC-V architecture, in accordance with the Devicetree Specification,
	requires the cpus and cpu nodes to be present and contain the properties
	described below.

	- cpus node

	Description: Container of cpu nodes

	The node name must be "cpus".

	A cpus node must define the following properties:

	- #address-cells
	Usage: required
	Value type: <u32>
	Definition: must be set to 1
	- #size-cells
	Usage: required
	Value type: <u32>
	Definition: must be set to 0

	- cpu node

	Description: Describes a hart context

	PROPERTIES

	- device_type
	Usage: required
	Value type: <string>
	Definition: must be "cpu"
	- reg
	Usage: required
	Value type: <u32>
	Definition: The hart ID of this CPU node
	- compatible:
	Usage: required
	Value type: <stringlist>
	Definition: must contain "riscv", may contain one of
	"sifive,rocket0"
	- mmu-type:
	Usage: optional
	Value type: <string>
	Definition: Specifies the CPU's MMU type. Possible values are
	"riscv,sv32"
	"riscv,sv39"
	"riscv,sv48"
	- riscv,isa:
	Usage: required
	Value type: <string>
	Definition: Contains the RISC-V ISA string of this hart. These
	ISA strings are defined by the RISC-V ISA manual.

	Example: SiFive Freedom U540G Development Kit
	---------------------------------------------

	This system contains two harts: a hart marked as disabled that's used for
	low-level system tasks and should be ignored by Linux, and a second hart that
	Linux is allowed to run on.

	cpus {
	#address-cells = <1>;
	#size-cells = <0>;
	timebase-frequency = <1000000>;
	cpu@0 {
	clock-frequency = <1600000000>;
	compatible = "sifive,rocket0", "riscv";
	device_type = "cpu";
	i-cache-block-size = <64>;
	i-cache-sets = <128>;
	i-cache-size = <16384>;
	next-level-cache = <&L15 &L0>;
	reg = <0>;
	riscv,isa = "rv64imac";
	status = "disabled";
	L10: interrupt-controller {
	#interrupt-cells = <1>;
	compatible = "riscv,cpu-intc";
	interrupt-controller;
	};
	};
	cpu@1 {
	clock-frequency = <1600000000>;
	compatible = "sifive,rocket0", "riscv";
	d-cache-block-size = <64>;
	d-cache-sets = <64>;
	d-cache-size = <32768>;
	d-tlb-sets = <1>;
	d-tlb-size = <32>;
	device_type = "cpu";
	i-cache-block-size = <64>;
	i-cache-sets = <64>;
	i-cache-size = <32768>;
	i-tlb-sets = <1>;
	i-tlb-size = <32>;
	mmu-type = "riscv,sv39";
	next-level-cache = <&L15 &L0>;
	reg = <1>;
	riscv,isa = "rv64imafdc";
	status = "okay";
	tlb-split;
	L13: interrupt-controller {
	#interrupt-cells = <1>;
	compatible = "riscv,cpu-intc";
	interrupt-controller;
	};
	};
	};

	Example: Spike ISA Simulator with 1 Hart
	----------------------------------------

	This device tree matches the Spike ISA golden model as run with `spike -p1`.

	cpus {
	cpu@0 {
	device_type = "cpu";
	reg = <0x00000000>;
	status = "okay";
	compatible = "riscv";
	riscv,isa = "rv64imafdc";
	mmu-type = "riscv,sv48";
	clock-frequency = <0x3b9aca00>;
	interrupt-controller {
	#interrupt-cells = <0x00000001>;
	interrupt-controller;
	compatible = "riscv,cpu-intc";
	}
	}
	}