1 * ARM Secure world bindings
3 ARM CPUs with TrustZone support have two distinct address spaces,
4 "Normal" and "Secure". Most devicetree consumers (including the Linux
5 kernel) are not TrustZone aware and run entirely in either the Normal
6 world or the Secure world. However some devicetree consumers are
7 TrustZone aware and need to be able to determine whether devices are
8 visible only in the Secure address space, only in the Normal address
9 space, or visible in both. (One example of that situation would be a
10 virtual machine which boots Secure firmware and wants to tell the
11 firmware about the layout of the machine via devicetree.)
13 The general principle of the naming scheme for Secure world bindings
14 is that any property that needs a different value in the Secure world
15 can be supported by prefixing the property name with "secure-". So for
16 instance "secure-foo" would override "foo". For property names with
17 a vendor prefix, the Secure variant of "vendor,foo" would be
18 "vendor,secure-foo". If there is no "secure-" property then the Secure
19 world value is the same as specified for the Normal world by the
20 non-prefixed property. However, only the properties listed below may
21 validly have "secure-" versions; this list will be enlarged on a
24 Defining the bindings in this way means that a device tree which has
25 been annotated to indicate the presence of Secure-only devices can
26 still be processed unmodified by existing Non-secure software (and in
27 particular by the kernel).
29 Note that it is still valid for bindings intended for purely Secure
30 world consumers (like kernels that run entirely in Secure) to simply
31 describe the view of Secure world using the standard bindings. These
32 secure- bindings only need to be used where both the Secure and Normal
33 world views need to be described in a single device tree.
35 Valid Secure world properties
36 -----------------------------
38 - secure-status : specifies whether the device is present and usable
39 in the secure world. The combination of this with "status" allows
40 the various possible combinations of device visibility to be
41 specified. If "secure-status" is not specified it defaults to the
42 same value as "status"; if "status" is not specified either then
43 both default to "okay". This means the following combinations are
46 /* Neither specified: default to visible in both S and NS */
47 secure-status = "okay"; /* visible in both */
48 status = "okay"; /* visible in both */
49 status = "okay"; secure-status = "okay"; /* visible in both */
50 secure-status = "disabled"; /* NS-only */
51 status = "okay"; secure-status = "disabled"; /* NS-only */
52 status = "disabled"; secure-status = "okay"; /* S-only */
53 status = "disabled"; /* disabled in both */
54 status = "disabled"; secure-status = "disabled"; /* disabled in both */
56 The secure-chosen node
57 ----------------------
59 Similar to the /chosen node which serves as a place for passing data
60 between firmware and the operating system, the /secure-chosen node may
61 be used to pass data to the Secure OS. Only the properties defined
62 below may appear in the /secure-chosen node.
64 - stdout-path : specifies the device to be used by the Secure OS for
65 its console output. The syntax is the same as for /chosen/stdout-path.
66 If the /secure-chosen node exists but the stdout-path property is not
67 present, the Secure OS should not perform any console output. If
68 /secure-chosen does not exist, the Secure OS should use the value of
69 /chosen/stdout-path instead (that is, use the same device as the
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