scrub.c 6.3 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /*
  3. * The generic EDAC scrub driver controls the memory scrubbers in the
  4. * system. The common sysfs scrub interface abstracts the control of
  5. * various arbitrary scrubbing functionalities into a unified set of
  6. * functions.
  7. *
  8. * Copyright (c) 2024-2025 HiSilicon Limited.
  9. */
  10. #include <linux/edac.h>
  11. enum edac_scrub_attributes {
  12. SCRUB_ADDRESS,
  13. SCRUB_SIZE,
  14. SCRUB_ENABLE_BACKGROUND,
  15. SCRUB_MIN_CYCLE_DURATION,
  16. SCRUB_MAX_CYCLE_DURATION,
  17. SCRUB_CUR_CYCLE_DURATION,
  18. SCRUB_MAX_ATTRS
  19. };
  20. struct edac_scrub_dev_attr {
  21. struct device_attribute dev_attr;
  22. u8 instance;
  23. };
  24. struct edac_scrub_context {
  25. char name[EDAC_FEAT_NAME_LEN];
  26. struct edac_scrub_dev_attr scrub_dev_attr[SCRUB_MAX_ATTRS];
  27. struct attribute *scrub_attrs[SCRUB_MAX_ATTRS + 1];
  28. struct attribute_group group;
  29. };
  30. #define TO_SCRUB_DEV_ATTR(_dev_attr) \
  31. container_of(_dev_attr, struct edac_scrub_dev_attr, dev_attr)
  32. #define EDAC_SCRUB_ATTR_SHOW(attrib, cb, type, format) \
  33. static ssize_t attrib##_show(struct device *ras_feat_dev, \
  34. struct device_attribute *attr, char *buf) \
  35. { \
  36. u8 inst = TO_SCRUB_DEV_ATTR(attr)->instance; \
  37. struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev); \
  38. const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops; \
  39. type data; \
  40. int ret; \
  41. \
  42. ret = ops->cb(ras_feat_dev->parent, ctx->scrub[inst].private, &data); \
  43. if (ret) \
  44. return ret; \
  45. \
  46. return sysfs_emit(buf, format, data); \
  47. }
  48. EDAC_SCRUB_ATTR_SHOW(addr, read_addr, u64, "0x%llx\n")
  49. EDAC_SCRUB_ATTR_SHOW(size, read_size, u64, "0x%llx\n")
  50. EDAC_SCRUB_ATTR_SHOW(enable_background, get_enabled_bg, bool, "%u\n")
  51. EDAC_SCRUB_ATTR_SHOW(min_cycle_duration, get_min_cycle, u32, "%u\n")
  52. EDAC_SCRUB_ATTR_SHOW(max_cycle_duration, get_max_cycle, u32, "%u\n")
  53. EDAC_SCRUB_ATTR_SHOW(current_cycle_duration, get_cycle_duration, u32, "%u\n")
  54. #define EDAC_SCRUB_ATTR_STORE(attrib, cb, type, conv_func) \
  55. static ssize_t attrib##_store(struct device *ras_feat_dev, \
  56. struct device_attribute *attr, \
  57. const char *buf, size_t len) \
  58. { \
  59. u8 inst = TO_SCRUB_DEV_ATTR(attr)->instance; \
  60. struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev); \
  61. const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops; \
  62. type data; \
  63. int ret; \
  64. \
  65. ret = conv_func(buf, 0, &data); \
  66. if (ret < 0) \
  67. return ret; \
  68. \
  69. ret = ops->cb(ras_feat_dev->parent, ctx->scrub[inst].private, data); \
  70. if (ret) \
  71. return ret; \
  72. \
  73. return len; \
  74. }
  75. EDAC_SCRUB_ATTR_STORE(addr, write_addr, u64, kstrtou64)
  76. EDAC_SCRUB_ATTR_STORE(size, write_size, u64, kstrtou64)
  77. EDAC_SCRUB_ATTR_STORE(enable_background, set_enabled_bg, unsigned long, kstrtoul)
  78. EDAC_SCRUB_ATTR_STORE(current_cycle_duration, set_cycle_duration, unsigned long, kstrtoul)
  79. static umode_t scrub_attr_visible(struct kobject *kobj, struct attribute *a, int attr_id)
  80. {
  81. struct device *ras_feat_dev = kobj_to_dev(kobj);
  82. struct device_attribute *dev_attr = container_of(a, struct device_attribute, attr);
  83. u8 inst = TO_SCRUB_DEV_ATTR(dev_attr)->instance;
  84. struct edac_dev_feat_ctx *ctx = dev_get_drvdata(ras_feat_dev);
  85. const struct edac_scrub_ops *ops = ctx->scrub[inst].scrub_ops;
  86. switch (attr_id) {
  87. case SCRUB_ADDRESS:
  88. if (ops->read_addr) {
  89. if (ops->write_addr)
  90. return a->mode;
  91. else
  92. return 0444;
  93. }
  94. break;
  95. case SCRUB_SIZE:
  96. if (ops->read_size) {
  97. if (ops->write_size)
  98. return a->mode;
  99. else
  100. return 0444;
  101. }
  102. break;
  103. case SCRUB_ENABLE_BACKGROUND:
  104. if (ops->get_enabled_bg) {
  105. if (ops->set_enabled_bg)
  106. return a->mode;
  107. else
  108. return 0444;
  109. }
  110. break;
  111. case SCRUB_MIN_CYCLE_DURATION:
  112. if (ops->get_min_cycle)
  113. return a->mode;
  114. break;
  115. case SCRUB_MAX_CYCLE_DURATION:
  116. if (ops->get_max_cycle)
  117. return a->mode;
  118. break;
  119. case SCRUB_CUR_CYCLE_DURATION:
  120. if (ops->get_cycle_duration) {
  121. if (ops->set_cycle_duration)
  122. return a->mode;
  123. else
  124. return 0444;
  125. }
  126. break;
  127. default:
  128. break;
  129. }
  130. return 0;
  131. }
  132. #define EDAC_SCRUB_ATTR_RO(_name, _instance) \
  133. ((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_RO(_name), \
  134. .instance = _instance })
  135. #define EDAC_SCRUB_ATTR_WO(_name, _instance) \
  136. ((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_WO(_name), \
  137. .instance = _instance })
  138. #define EDAC_SCRUB_ATTR_RW(_name, _instance) \
  139. ((struct edac_scrub_dev_attr) { .dev_attr = __ATTR_RW(_name), \
  140. .instance = _instance })
  141. static int scrub_create_desc(struct device *scrub_dev,
  142. const struct attribute_group **attr_groups, u8 instance)
  143. {
  144. struct edac_scrub_context *scrub_ctx;
  145. struct attribute_group *group;
  146. int i;
  147. struct edac_scrub_dev_attr dev_attr[] = {
  148. [SCRUB_ADDRESS] = EDAC_SCRUB_ATTR_RW(addr, instance),
  149. [SCRUB_SIZE] = EDAC_SCRUB_ATTR_RW(size, instance),
  150. [SCRUB_ENABLE_BACKGROUND] = EDAC_SCRUB_ATTR_RW(enable_background, instance),
  151. [SCRUB_MIN_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RO(min_cycle_duration, instance),
  152. [SCRUB_MAX_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RO(max_cycle_duration, instance),
  153. [SCRUB_CUR_CYCLE_DURATION] = EDAC_SCRUB_ATTR_RW(current_cycle_duration, instance)
  154. };
  155. scrub_ctx = devm_kzalloc(scrub_dev, sizeof(*scrub_ctx), GFP_KERNEL);
  156. if (!scrub_ctx)
  157. return -ENOMEM;
  158. group = &scrub_ctx->group;
  159. for (i = 0; i < SCRUB_MAX_ATTRS; i++) {
  160. memcpy(&scrub_ctx->scrub_dev_attr[i], &dev_attr[i], sizeof(dev_attr[i]));
  161. sysfs_attr_init(&scrub_ctx->scrub_dev_attr[i].dev_attr.attr);
  162. scrub_ctx->scrub_attrs[i] = &scrub_ctx->scrub_dev_attr[i].dev_attr.attr;
  163. }
  164. sprintf(scrub_ctx->name, "%s%d", "scrub", instance);
  165. group->name = scrub_ctx->name;
  166. group->attrs = scrub_ctx->scrub_attrs;
  167. group->is_visible = scrub_attr_visible;
  168. attr_groups[0] = group;
  169. return 0;
  170. }
  171. /**
  172. * edac_scrub_get_desc - get EDAC scrub descriptors
  173. * @scrub_dev: client device, with scrub support
  174. * @attr_groups: pointer to attribute group container
  175. * @instance: device's scrub instance number.
  176. *
  177. * Return:
  178. * * %0 - Success.
  179. * * %-EINVAL - Invalid parameters passed.
  180. * * %-ENOMEM - Dynamic memory allocation failed.
  181. */
  182. int edac_scrub_get_desc(struct device *scrub_dev,
  183. const struct attribute_group **attr_groups, u8 instance)
  184. {
  185. if (!scrub_dev || !attr_groups)
  186. return -EINVAL;
  187. return scrub_create_desc(scrub_dev, attr_groups, instance);
  188. }