of_unittest.txt 7.5 KB

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  1. Open Firmware Device Tree Unittest
  2. ----------------------------------
  3. Author: Gaurav Minocha <gaurav.minocha.os@gmail.com>
  4. 1. Introduction
  5. This document explains how the test data required for executing OF unittest
  6. is attached to the live tree dynamically, independent of the machine's
  7. architecture.
  8. It is recommended to read the following documents before moving ahead.
  9. [1] Documentation/devicetree/usage-model.txt
  10. [2] http://www.devicetree.org/Device_Tree_Usage
  11. OF Selftest has been designed to test the interface (include/linux/of.h)
  12. provided to device driver developers to fetch the device information..etc.
  13. from the unflattened device tree data structure. This interface is used by
  14. most of the device drivers in various use cases.
  15. 2. Test-data
  16. The Device Tree Source file (drivers/of/unittest-data/testcases.dts) contains
  17. the test data required for executing the unit tests automated in
  18. drivers/of/unittest.c. Currently, following Device Tree Source Include files
  19. (.dtsi) are included in testcases.dts:
  20. drivers/of/unittest-data/tests-interrupts.dtsi
  21. drivers/of/unittest-data/tests-platform.dtsi
  22. drivers/of/unittest-data/tests-phandle.dtsi
  23. drivers/of/unittest-data/tests-match.dtsi
  24. When the kernel is build with OF_SELFTEST enabled, then the following make rule
  25. $(obj)/%.dtb: $(src)/%.dts FORCE
  26. $(call if_changed_dep, dtc)
  27. is used to compile the DT source file (testcases.dts) into a binary blob
  28. (testcases.dtb), also referred as flattened DT.
  29. After that, using the following rule the binary blob above is wrapped as an
  30. assembly file (testcases.dtb.S).
  31. $(obj)/%.dtb.S: $(obj)/%.dtb
  32. $(call cmd, dt_S_dtb)
  33. The assembly file is compiled into an object file (testcases.dtb.o), and is
  34. linked into the kernel image.
  35. 2.1. Adding the test data
  36. Un-flattened device tree structure:
  37. Un-flattened device tree consists of connected device_node(s) in form of a tree
  38. structure described below.
  39. // following struct members are used to construct the tree
  40. struct device_node {
  41. ...
  42. struct device_node *parent;
  43. struct device_node *child;
  44. struct device_node *sibling;
  45. ...
  46. };
  47. Figure 1, describes a generic structure of machine's un-flattened device tree
  48. considering only child and sibling pointers. There exists another pointer,
  49. *parent, that is used to traverse the tree in the reverse direction. So, at
  50. a particular level the child node and all the sibling nodes will have a parent
  51. pointer pointing to a common node (e.g. child1, sibling2, sibling3, sibling4's
  52. parent points to root node)
  53. root ('/')
  54. |
  55. child1 -> sibling2 -> sibling3 -> sibling4 -> null
  56. | | | |
  57. | | | null
  58. | | |
  59. | | child31 -> sibling32 -> null
  60. | | | |
  61. | | null null
  62. | |
  63. | child21 -> sibling22 -> sibling23 -> null
  64. | | | |
  65. | null null null
  66. |
  67. child11 -> sibling12 -> sibling13 -> sibling14 -> null
  68. | | | |
  69. | | | null
  70. | | |
  71. null null child131 -> null
  72. |
  73. null
  74. Figure 1: Generic structure of un-flattened device tree
  75. Before executing OF unittest, it is required to attach the test data to
  76. machine's device tree (if present). So, when selftest_data_add() is called,
  77. at first it reads the flattened device tree data linked into the kernel image
  78. via the following kernel symbols:
  79. __dtb_testcases_begin - address marking the start of test data blob
  80. __dtb_testcases_end - address marking the end of test data blob
  81. Secondly, it calls of_fdt_unflatten_tree() to unflatten the flattened
  82. blob. And finally, if the machine's device tree (i.e live tree) is present,
  83. then it attaches the unflattened test data tree to the live tree, else it
  84. attaches itself as a live device tree.
  85. attach_node_and_children() uses of_attach_node() to attach the nodes into the
  86. live tree as explained below. To explain the same, the test data tree described
  87. in Figure 2 is attached to the live tree described in Figure 1.
  88. root ('/')
  89. |
  90. testcase-data
  91. |
  92. test-child0 -> test-sibling1 -> test-sibling2 -> test-sibling3 -> null
  93. | | | |
  94. test-child01 null null null
  95. Figure 2: Example test data tree to be attached to live tree.
  96. According to the scenario above, the live tree is already present so it isn't
  97. required to attach the root('/') node. All other nodes are attached by calling
  98. of_attach_node() on each node.
  99. In the function of_attach_node(), the new node is attached as the child of the
  100. given parent in live tree. But, if parent already has a child then the new node
  101. replaces the current child and turns it into its sibling. So, when the testcase
  102. data node is attached to the live tree above (Figure 1), the final structure is
  103. as shown in Figure 3.
  104. root ('/')
  105. |
  106. testcase-data -> child1 -> sibling2 -> sibling3 -> sibling4 -> null
  107. | | | | |
  108. (...) | | | null
  109. | | child31 -> sibling32 -> null
  110. | | | |
  111. | | null null
  112. | |
  113. | child21 -> sibling22 -> sibling23 -> null
  114. | | | |
  115. | null null null
  116. |
  117. child11 -> sibling12 -> sibling13 -> sibling14 -> null
  118. | | | |
  119. null null | null
  120. |
  121. child131 -> null
  122. |
  123. null
  124. -----------------------------------------------------------------------
  125. root ('/')
  126. |
  127. testcase-data -> child1 -> sibling2 -> sibling3 -> sibling4 -> null
  128. | | | | |
  129. | (...) (...) (...) null
  130. |
  131. test-sibling3 -> test-sibling2 -> test-sibling1 -> test-child0 -> null
  132. | | | |
  133. null null null test-child01
  134. Figure 3: Live device tree structure after attaching the testcase-data.
  135. Astute readers would have noticed that test-child0 node becomes the last
  136. sibling compared to the earlier structure (Figure 2). After attaching first
  137. test-child0 the test-sibling1 is attached that pushes the child node
  138. (i.e. test-child0) to become a sibling and makes itself a child node,
  139. as mentioned above.
  140. If a duplicate node is found (i.e. if a node with same full_name property is
  141. already present in the live tree), then the node isn't attached rather its
  142. properties are updated to the live tree's node by calling the function
  143. update_node_properties().
  144. 2.2. Removing the test data
  145. Once the test case execution is complete, selftest_data_remove is called in
  146. order to remove the device nodes attached initially (first the leaf nodes are
  147. detached and then moving up the parent nodes are removed, and eventually the
  148. whole tree). selftest_data_remove() calls detach_node_and_children() that uses
  149. of_detach_node() to detach the nodes from the live device tree.
  150. To detach a node, of_detach_node() either updates the child pointer of given
  151. node's parent to its sibling or attaches the previous sibling to the given
  152. node's sibling, as appropriate. That is it :)