doc/uImage.FIT/overlay-fdt-boot.txt - u-boot-mtk - Git at Google

 U-Boot FDT Overlay FIT usage
 ============================

 Introduction
 ------------
 In many cases it is desirable to have a single FIT image support a multitude
 of similar boards and their expansion options. The same kernel on DT enabled
 platforms can support this easily enough by providing a DT blob upon boot
 that matches the desired configuration.

 This document focuses on specifically using overlays as part of a FIT image.
 General information regarding overlays including its syntax and building it
 can be found in doc/README.fdt-overlays

 Configuration without overlays
 ------------------------------

 Take a hypothetical board named 'foo' where there are different supported
 revisions, reva and revb. Assume that both board revisions can use add a bar
 add-on board, while only the revb board can use a baz add-on board.

 Without using overlays the configuration would be as follows for every case.

 	/dts-v1/;
 	/ {
 		images {
 			kernel {
 				data = /incbin/("./zImage");
 				type = "kernel";
 				arch = "arm";
 				os = "linux";
 				load = <0x82000000>;
 				entry = <0x82000000>;
 			};
 			fdt-1 {
 				data = /incbin/("./foo-reva.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 			fdt-2 {
 				data = /incbin/("./foo-revb.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 			fdt-3 {
 				data = /incbin/("./foo-reva-bar.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 			fdt-4 {
 				data = /incbin/("./foo-revb-bar.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 			fdt-5 {
 				data = /incbin/("./foo-revb-baz.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 			fdt-6 {
 				data = /incbin/("./foo-revb-bar-baz.dtb");
 				type = "flat_dt";
 				arch = "arm";
 			};
 		};

 		configurations {
 			default = "foo-reva.dtb;
 			foo-reva.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1";
 			};
 			foo-revb.dtb {
 				kernel = "kernel";
 				fdt = "fdt-2";
 			};
 			foo-reva-bar.dtb {
 				kernel = "kernel";
 				fdt = "fdt-3";
 			};
 			foo-revb-bar.dtb {
 				kernel = "kernel";
 				fdt = "fdt-4";
 			};
 			foo-revb-baz.dtb {
 				kernel = "kernel";
 				fdt = "fdt-5";
 			};
 			foo-revb-bar-baz.dtb {
 				kernel = "kernel";
 				fdt = "fdt-6";
 			};
 		};
 	};

 Note the blob needs to be compiled for each case and the combinatorial explosion of
 configurations. A typical device tree blob is in the low hunderds of kbytes so a
 multitude of configuration grows the image quite a bit.

 Booting this image is done by using

 	# bootm <addr>#<config>

 Where config is one of:
 	foo-reva.dtb, foo-revb.dtb, foo-reva-bar.dtb, foo-revb-bar.dtb,
 	foo-revb-baz.dtb, foo-revb-bar-baz.dtb

 This selects the DTB to use when booting.

 Configuration using overlays
 ----------------------------

 Device tree overlays can be applied to a base DT and result in the same blob
 being passed to the booting kernel. This saves on space and avoid the combinatorial
 explosion problem.

 	/dts-v1/;
 	/ {
 		images {
 			kernel {
 				data = /incbin/("./zImage");
 				type = "kernel";
 				arch = "arm";
 				os = "linux";
 				load = <0x82000000>;
 				entry = <0x82000000>;
 			};
 			fdt-1 {
 				data = /incbin/("./foo.dtb");
 				type = "flat_dt";
 				arch = "arm";
 				load = <0x87f00000>;
 			};
 			fdt-2 {
 				data = /incbin/("./reva.dtbo");
 				type = "flat_dt";
 				arch = "arm";
 				load = <0x87fc0000>;
 			};
 			fdt-3 {
 				data = /incbin/("./revb.dtbo");
 				type = "flat_dt";
 				arch = "arm";
 				load = <0x87fc0000>;
 			};
 			fdt-4 {
 				data = /incbin/("./bar.dtbo");
 				type = "flat_dt";
 				arch = "arm";
 				load = <0x87fc0000>;
 			};
 			fdt-5 {
 				data = /incbin/("./baz.dtbo");
 				type = "flat_dt";
 				arch = "arm";
 				load = <0x87fc0000>;
 			};
 		};

 		configurations {
 			default = "foo-reva.dtb;
 			foo-reva.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-2";
 			};
 			foo-revb.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-3";
 			};
 			foo-reva-bar.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-2", "fdt-4";
 			};
 			foo-revb-bar.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-3", "fdt-4";
 			};
 			foo-revb-baz.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-3", "fdt-5";
 			};
 			foo-revb-bar-baz.dtb {
 				kernel = "kernel";
 				fdt = "fdt-1", "fdt-3", "fdt-4", "fdt-5";
 			};
 			bar {
 				fdt = "fdt-4";
 			};
 			baz {
 				fdt = "fdt-5";
 			};
 		};
 	};

 Booting this image is exactly the same as the non-overlay example.
 u-boot will retrieve the base blob and apply the overlays in sequence as
 they are declared in the configuration.

 Note the minimum amount of different DT blobs, as well as the requirement for
 the DT blobs to have a load address; the overlay application requires the blobs
 to be writeable.

 Configuration using overlays and feature selection
 --------------------------------------------------

 Although the configuration in the previous section works is a bit inflexible
 since it requires all possible configuration options to be laid out before
 hand in the FIT image. For the add-on boards the extra config selection method
 might make sense.

 Note the two bar & baz configuration nodes. To boot a reva board with
 the bar add-on board enabled simply use:

 	# bootm <addr>#foo-reva.dtb#bar

 While booting a revb with bar and baz is as follows:

 	# bootm <addr>#foo-revb.dtb#bar#baz

 The limitation for a feature selection configuration node is that a single
 fdt option is currently supported.

 Pantelis Antoniou
 pantelis.antoniou@konsulko.com
 12/6/2017
	U-Boot FDT Overlay FIT usage
	============================

	Introduction
	------------
	In many cases it is desirable to have a single FIT image support a multitude
	of similar boards and their expansion options. The same kernel on DT enabled
	platforms can support this easily enough by providing a DT blob upon boot
	that matches the desired configuration.

	This document focuses on specifically using overlays as part of a FIT image.
	General information regarding overlays including its syntax and building it
	can be found in doc/README.fdt-overlays

	Configuration without overlays
	------------------------------

	Take a hypothetical board named 'foo' where there are different supported
	revisions, reva and revb. Assume that both board revisions can use add a bar
	add-on board, while only the revb board can use a baz add-on board.

	Without using overlays the configuration would be as follows for every case.

	/dts-v1/;
	/ {
	images {
	kernel {
	data = /incbin/("./zImage");
	type = "kernel";
	arch = "arm";
	os = "linux";
	load = <0x82000000>;
	entry = <0x82000000>;
	};
	fdt-1 {
	data = /incbin/("./foo-reva.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	fdt-2 {
	data = /incbin/("./foo-revb.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	fdt-3 {
	data = /incbin/("./foo-reva-bar.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	fdt-4 {
	data = /incbin/("./foo-revb-bar.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	fdt-5 {
	data = /incbin/("./foo-revb-baz.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	fdt-6 {
	data = /incbin/("./foo-revb-bar-baz.dtb");
	type = "flat_dt";
	arch = "arm";
	};
	};

	configurations {
	default = "foo-reva.dtb;
	foo-reva.dtb {
	kernel = "kernel";
	fdt = "fdt-1";
	};
	foo-revb.dtb {
	kernel = "kernel";
	fdt = "fdt-2";
	};
	foo-reva-bar.dtb {
	kernel = "kernel";
	fdt = "fdt-3";
	};
	foo-revb-bar.dtb {
	kernel = "kernel";
	fdt = "fdt-4";
	};
	foo-revb-baz.dtb {
	kernel = "kernel";
	fdt = "fdt-5";
	};
	foo-revb-bar-baz.dtb {
	kernel = "kernel";
	fdt = "fdt-6";
	};
	};
	};

	Note the blob needs to be compiled for each case and the combinatorial explosion of
	configurations. A typical device tree blob is in the low hunderds of kbytes so a
	multitude of configuration grows the image quite a bit.

	Booting this image is done by using

	# bootm <addr>#<config>

	Where config is one of:
	foo-reva.dtb, foo-revb.dtb, foo-reva-bar.dtb, foo-revb-bar.dtb,
	foo-revb-baz.dtb, foo-revb-bar-baz.dtb

	This selects the DTB to use when booting.

	Configuration using overlays
	----------------------------

	Device tree overlays can be applied to a base DT and result in the same blob
	being passed to the booting kernel. This saves on space and avoid the combinatorial
	explosion problem.

	/dts-v1/;
	/ {
	images {
	kernel {
	data = /incbin/("./zImage");
	type = "kernel";
	arch = "arm";
	os = "linux";
	load = <0x82000000>;
	entry = <0x82000000>;
	};
	fdt-1 {
	data = /incbin/("./foo.dtb");
	type = "flat_dt";
	arch = "arm";
	load = <0x87f00000>;
	};
	fdt-2 {
	data = /incbin/("./reva.dtbo");
	type = "flat_dt";
	arch = "arm";
	load = <0x87fc0000>;
	};
	fdt-3 {
	data = /incbin/("./revb.dtbo");
	type = "flat_dt";
	arch = "arm";
	load = <0x87fc0000>;
	};
	fdt-4 {
	data = /incbin/("./bar.dtbo");
	type = "flat_dt";
	arch = "arm";
	load = <0x87fc0000>;
	};
	fdt-5 {
	data = /incbin/("./baz.dtbo");
	type = "flat_dt";
	arch = "arm";
	load = <0x87fc0000>;
	};
	};

	configurations {
	default = "foo-reva.dtb;
	foo-reva.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-2";
	};
	foo-revb.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-3";
	};
	foo-reva-bar.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-2", "fdt-4";
	};
	foo-revb-bar.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-3", "fdt-4";
	};
	foo-revb-baz.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-3", "fdt-5";
	};
	foo-revb-bar-baz.dtb {
	kernel = "kernel";
	fdt = "fdt-1", "fdt-3", "fdt-4", "fdt-5";
	};
	bar {
	fdt = "fdt-4";
	};
	baz {
	fdt = "fdt-5";
	};
	};
	};

	Booting this image is exactly the same as the non-overlay example.
	u-boot will retrieve the base blob and apply the overlays in sequence as
	they are declared in the configuration.

	Note the minimum amount of different DT blobs, as well as the requirement for
	the DT blobs to have a load address; the overlay application requires the blobs
	to be writeable.

	Configuration using overlays and feature selection
	--------------------------------------------------

	Although the configuration in the previous section works is a bit inflexible
	since it requires all possible configuration options to be laid out before
	hand in the FIT image. For the add-on boards the extra config selection method
	might make sense.

	Note the two bar & baz configuration nodes. To boot a reva board with
	the bar add-on board enabled simply use:

	# bootm <addr>#foo-reva.dtb#bar

	While booting a revb with bar and baz is as follows:

	# bootm <addr>#foo-revb.dtb#bar#baz

	The limitation for a feature selection configuration node is that a single
	fdt option is currently supported.

	Pantelis Antoniou
	pantelis.antoniou@konsulko.com
	12/6/2017