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  1. [role="xpack"]
    2. 

  2. [[data-tiers]]
    3. 

  3. == Data tiers
    4. 

  4. 

  5. A _data tier_ is a collection of nodes with the same data role that
    6. 

  6. typically share the same hardware profile:
    7. 

  7. 

  8. * <<content-tier, Content tier>> nodes handle the indexing and query load for content such as a product catalog.
    9. 

  9. * <<hot-tier, Hot tier>> nodes handle the indexing load for time series data such as logs or metrics
    10. 

  10. and hold your most recent, most-frequently-accessed data.
    11. 

  11. * <<warm-tier, Warm tier>> nodes hold time series data that is accessed less-frequently
    12. 

  12. and rarely needs to be updated.
    13. 

  13. * <<cold-tier, Cold tier>> nodes hold time series data that is accessed infrequently and not normally updated.
    14. 

  14. * <<frozen-tier, Frozen tier>> nodes hold time series data that is accessed rarely and never updated, kept in searchable snapshots.
    15. 

  15. 

  16. When you index documents directly to a specific index, they remain on content tier nodes indefinitely.
    17. 

  17. 

  18. When you index documents to a data stream, they initially reside on hot tier nodes.
    19. 

  19. You can configure <<index-lifecycle-management, {ilm}>> ({ilm-init}) policies
    20. 

  20. to automatically transition your time series data through the hot, warm, and cold tiers
    21. 

  21. according to your performance, resiliency and data retention requirements.
    22. 

  22. 

  23. A node's <<data-node, data role>> is configured in `elasticsearch.yml`.
    24. 

  24. For example, the highest-performance nodes in a cluster might be assigned to both the hot and content tiers:
    25. 

  25. 

  26. [source,yaml]
    27. 

  27. --------------------------------------------------
    28. 

  28. node.roles: ["data_hot", "data_content"]
    29. 

  29. --------------------------------------------------
    30. 

  30. 

  31. [discrete]
    32. 

  32. [[content-tier]]
    33. 

  33. === Content tier
    34. 

  34. 

  35. Data stored in the content tier is generally a collection of items such as a product catalog or article archive.
    36. 

  36. Unlike time series data, the value of the content remains relatively constant over time,
    37. 

  37. so it doesn't make sense to move it to a tier with different performance characteristics as it ages.
    38. 

  38. Content data typically has long data retention requirements, and you want to be able to retrieve
    39. 

  39. items quickly regardless of how old they are.
    40. 

  40. 

  41. Content tier nodes are usually optimized for query performance--they prioritize processing power over IO throughput
    42. 

  42. so they can process complex searches and aggregations and return results quickly.
    43. 

  43. While they are also responsible for indexing, content data is generally not ingested at as high a rate
    44. 

  44. as time series data such as logs and metrics. From a resiliency perspective the indices in this
    45. 

  45. tier should be configured to use one or more replicas.
    46. 

  46. 

  47. The content tier is required. System indices and other indices that aren't part
    48. 

  48. of a data stream are automatically allocated to the content tier.
    49. 

  49. 

  50. [discrete]
    51. 

  51. [[hot-tier]]
    52. 

  52. === Hot tier
    53. 

  53. 

  54. The hot tier is the {es} entry point for time series data and holds your most-recent,
    55. 

  55. most-frequently-searched time series data.
    56. 

  56. Nodes in the hot tier need to be fast for both reads and writes,
    57. 

  57. which requires more hardware resources and faster storage (SSDs).
    58. 

  58. For resiliency, indices in the hot tier should be configured to use one or more replicas.
    59. 

  59. 

  60. The hot tier is required. New indices that are part of a <<data-streams,
    61. 

  61. data stream>> are automatically allocated to the hot tier.
    62. 

  62. 

  63. [discrete]
    64. 

  64. [[warm-tier]]
    65. 

  65. === Warm tier
    66. 

  66. 

  67. Time series data can move to the warm tier once it is being queried less frequently
    68. 

  68. than the recently-indexed data in the hot tier.
    69. 

  69. The warm tier typically holds data from recent weeks.
    70. 

  70. Updates are still allowed, but likely infrequent.
    71. 

  71. Nodes in the warm tier generally don't need to be as fast as those in the hot tier.
    72. 

  72. For resiliency, indices in the warm tier should be configured to use one or more replicas.
    73. 

  73. 

  74. [discrete]
    75. 

  75. [[cold-tier]]
    76. 

  76. === Cold tier
    77. 

  77. 

  78. When data is no longer being updated, it can move from the warm tier to the cold
    79. 

  79. tier where it stays while being queried infrequently. As data transitions into
    80. 

  80. the cold tier, it can be compressed and shrunken. Instead of using replicas, the
    81. 

  81. cold tier can use <<fully-mounted,fully mounted indices>> of
    82. 

  82. <<ilm-searchable-snapshot,{search-snaps}>> for resiliency, eliminating the need
    83. 

  83. for replicas. The cold tier is still a responsive query tier, but data becomes
    84. 

  84. read-only.
    85. 

  85. 

  86. [discrete]
    87. 

  87. [[frozen-tier]]
    88. 

  88. === Frozen tier
    89. 

  89. 

  90. Once data is no longer being queried, or being queried rarely, it may move from
    91. 

  91. the cold tier to the frozen tier where it stays for the rest of its life.
    92. 

  92. 

  93. The frozen tier uses <<partially-mounted,partially mounted indices>> to store
    94. 

  94. and load data from a snapshot repository. This reduces local storage and
    95. 

  95. operating costs while still letting you search frozen data. Because {es} must
    96. 

  96. sometimes fetch frozen data from the snapshot repository, searches on the frozen
    97. 

  97. tier are typically slower than on the cold tier.
    98. 

  98. 

  99. NOTE: We recommend you use <<data-frozen-node,dedicated nodes>> in the frozen
    100. 

  100. tier.
    101. 

  101. 

  102. [discrete]
    103. 

  103. [[data-tier-allocation]]
    104. 

  104. === Data tier index allocation
    105. 

  105. 

  106. When you create an index, by default {es} sets
    107. 

  107. <<tier-preference-allocation-filter, `index.routing.allocation.include._tier_preference`>>
    108. 

  108. to `data_content` to automatically allocate the index shards to the content tier.
    109. 

  109. 

  110. When {es} creates an index as part of a <<data-streams, data stream>>,
    111. 

  111. by default {es} sets
    112. 

  112. <<tier-preference-allocation-filter, `index.routing.allocation.include._tier_preference`>>
    113. 

  113. to `data_hot` to automatically allocate the index shards to the hot tier.
    114. 

  114. 

  115. You can override the automatic tier-based allocation by specifying
    116. 

  116. <<shard-allocation-filtering, shard allocation filtering>>
    117. 

  117. settings in the create index request or index template that matches the new index.
    118. 

  118. 

  119. You can also explicitly set `index.routing.allocation.include._tier_preference`
    120. 

  120. to opt out of the default tier-based allocation.
    121. 

  121. If you set the tier preference to `null`, {es} ignores the data tier roles during allocation.
    122. 

  122. 

  123. [discrete]
    124. 

  124. [[data-tier-migration]]
    125. 

  125. === Automatic data tier migration
    126. 

  126. 

  127. {ilm-init} automatically transitions managed
    128. 

  128. indices through the available data tiers using the <<ilm-migrate, migrate>> action.
    129. 

  129. By default, this action is automatically injected in every phase.
    130. 

  130. You can explicitly specify the migrate action to override the default behavior,
    131. 

  131. or use the <<ilm-allocate, allocate action>> to manually specify allocation rules.
    132.