# Terraform Core Architecture Summary This document is a summary of the main components of Terraform Core and how data and requests flow between these components. It's intended as a primer to help navigate the codebase to dig into more details. We assume some familiarity with user-facing Terraform concepts like configuration, state, CLI workflow, etc. The Terraform website has documentation on these ideas. ## Terraform Request Flow The following diagram shows an approximation of how a user command is executed in Terraform: ![Terraform Architecture Diagram, described in text below](./images/architecture-overview.png) Each of the different subsystems (solid boxes) in this diagram is described in more detail in a corresponding section below. ## CLI (`command` package) Each time a user runs the `terraform` program, aside from some initial bootstrapping in the root package (not shown in the diagram) execution transfers immediately into one of the "command" implementations in [the `command` package](https://pkg.go.dev/github.com/hashicorp/terraform/internal/command). The mapping between the user-facing command names and their corresponding `command` package types can be found in the `commands.go` file in the root of the repository. The full flow illustrated above does not actually apply to _all_ commands, but it applies to the main Terraform workflow commands `terraform plan` and `terraform apply`, along with a few others. For these commands, the role of the command implementation is to read and parse any command line arguments, command line options, and environment variables that are needed for the given command and use them to produce a [`backend.Operation`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/backend#Operation) object that describes an action to be taken. An _operation_ consists of: * The action to be taken (e.g. "plan", "apply"). * The name of the [workspace](https://www.terraform.io/docs/state/workspaces.html) where the action will be taken. * Root module input variables to use for the action. * For the "plan" operation, a path to the directory containing the configuration's root module. * For the "apply" operation, the plan to apply. * Various other less-common options/settings such as `-target` addresses, the "force" flag, etc. The operation is then passed to the currently-selected [backend](https://www.terraform.io/docs/backends/index.html). Each backend name corresponds to an implementation of [`backend.Backend`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/backend#Backend), using a mapping table in [the `backend/init` package](https://pkg.go.dev/github.com/hashicorp/terraform/internal/backend/init). Backends that are able to execute operations additionally implement [`backend.Enhanced`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/backend#Enhanced); the command-handling code calls `Operation` with the operation it has constructed, and then the backend is responsible for executing that action. Backends that execute operations, however, do so as an architectural implementation detail and not a general feature of backends. That is, the term 'backend' as a Terraform feature is used to refer to a plugin that determines where Terraform stores its state snapshots - only the default `local` backend and Terraform Cloud's backends (`remote`, `cloud`) perform operations. Thus, most backends do _not_ implement this interface, and so the `command` package wraps these backends in an instance of [`local.Local`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/backend/local#Local), causing the operation to be executed locally within the `terraform` process itself. ## Backends A _backend_ determines where Terraform should store its state snapshots. As described above, the `local` backend also executes operations on behalf of most other backends. It uses a _state manager_ (either [`statemgr.Filesystem`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states/statemgr#Filesystem) if the local backend is being used directly, or an implementation provided by whatever backend is being wrapped) to retrieve the current state for the workspace specified in the operation, then uses the _config loader_ to load and do initial processing/validation of the configuration specified in the operation. It then uses these, along with the other settings given in the operation, to construct a [`terraform.Context`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#Context), which is the main object that actually performs Terraform operations. The `local` backend finally calls an appropriate method on that context to begin execution of the relevant command, such as [`Plan`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#Context.Plan) or [`Apply`](), which in turn constructs a graph using a _graph builder_, described in a later section. ## Configuration Loader The top-level configuration structure is represented by model types in [package `configs`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/configs). A whole configuration (the root module plus all of its descendent modules) is represented by [`configs.Config`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/configs#Config). The `configs` package contains some low-level functionality for constructing configuration objects, but the main entry point is in the sub-package [`configload`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/configs/configload]), via [`configload.Loader`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/configs/configload#Loader). A loader deals with all of the details of installing child modules (during `terraform init`) and then locating those modules again when a configuration is loaded by a backend. It takes the path to a root module and recursively loads all of the child modules to produce a single [`configs.Config`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/configs#Config) representing the entire configuration. Terraform expects configuration files written in the Terraform language, which is a DSL built on top of [HCL](https://github.com/hashicorp/hcl). Some parts of the configuration cannot be interpreted until we build and walk the graph, since they depend on the outcome of other parts of the configuration, and so these parts of the configuration remain represented as the low-level HCL types [`hcl.Body`](https://pkg.go.dev/github.com/hashicorp/hcl/v2/#Body) and [`hcl.Expression`](https://pkg.go.dev/github.com/hashicorp/hcl/v2/#Expression), allowing Terraform to interpret them at a more appropriate time. ## State Manager A _state manager_ is responsible for storing and retrieving snapshots of the [Terraform state](https://www.terraform.io/docs/language/state/index.html) for a particular workspace. Each manager is an implementation of some combination of interfaces in [the `statemgr` package](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states/statemgr), with most practical managers implementing the full set of operations described by [`statemgr.Full`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states/statemgr#Full) provided by a _backend_. The smaller interfaces exist primarily for use in other function signatures to be explicit about what actions the function might take on the state manager; there is little reason to write a state manager that does not implement all of `statemgr.Full`. The implementation [`statemgr.Filesystem`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states/statemgr#Filesystem) is used by default (by the `local` backend) and is responsible for the familiar `terraform.tfstate` local file that most Terraform users start with, before they switch to [remote state](https://www.terraform.io/docs/language/state/remote.html). Other implementations of `statemgr.Full` are used to implement remote state. Each of these saves and retrieves state via a remote network service appropriate to the backend that creates it. A state manager accepts and returns a state snapshot as a [`states.State`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states#State) object. The state manager is responsible for exactly how that object is serialized and stored, but all state managers at the time of writing use the same JSON serialization format, storing the resulting JSON bytes in some kind of arbitrary blob store. ## Graph Builder A _graph builder_ is called by a [`terraform.Context`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#Context) method (e.g. `Plan` or `Apply`) to produce the graph that will be used to represent the necessary steps for that operation and the dependency relationships between them. In most cases, the [vertices](https://en.wikipedia.org/wiki/Vertex_(graph_theory)) of Terraform's graphs each represent a specific object in the configuration, or something derived from those configuration objects. For example, each `resource` block in the configuration has one corresponding [`GraphNodeConfigResource`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#GraphNodeConfigResource) vertex representing it in the "plan" graph. (Terraform Core uses terminology inconsistently, describing graph _vertices_ also as graph _nodes_ in various places. These both describe the same concept.) The [edges](https://en.wikipedia.org/wiki/Glossary_of_graph_theory_terms#edge) in the graph represent "must happen after" relationships. These define the order in which the vertices are evaluated, ensuring that e.g. one resource is created before another resource that depends on it. Each operation has its own graph builder, because the graph building process is different for each. For example, a "plan" operation needs a graph built directly from the configuration, but an "apply" operation instead builds its graph from the set of changes described in the plan that is being applied. The graph builders all work in terms of a sequence of _transforms_, which are implementations of [`terraform.GraphTransformer`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#GraphTransformer). Implementations of this interface just take a graph and mutate it in any way needed, and so the set of available transforms is quite varied. Some important examples include: * [`ConfigTransformer`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#ConfigTransformer), which creates a graph vertex for each `resource` block in the configuration. * [`StateTransformer`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#StateTransformer), which creates a graph vertex for each resource instance currently tracked in the state. * [`ReferenceTransformer`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#ReferenceTransformer), which analyses the configuration to find dependencies between resources and other objects and creates any necessary "happens after" edges for these. * [`ProviderTransformer`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#ProviderTransformer), which associates each resource or resource instance with exactly one provider configuration (implementing [the inheritance rules](https://www.terraform.io/docs/language/modules/develop/providers.html)) and then creates "happens after" edges to ensure that the providers are initialized before taking any actions with the resources that belong to them. There are many more different graph transforms, which can be discovered by reading the source code for the different graph builders. Each graph builder uses a different subset of these depending on the needs of the operation that is being performed. The result of graph building is a [`terraform.Graph`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#Graph), which can then be processed using a _graph walker_. ## Graph Walk The process of walking the graph visits each vertex of that graph in a way which respects the "happens after" edges in the graph. The walk algorithm itself is implemented in [the low-level `dag` package](https://pkg.go.dev/github.com/hashicorp/terraform/internal/dag#AcyclicGraph.Walk) (where "DAG" is short for [_Directed Acyclic Graph_](https://en.wikipedia.org/wiki/Directed_acyclic_graph)), in [`AcyclicGraph.Walk`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/dag#AcyclicGraph.Walk). However, the "interesting" Terraform walk functionality is implemented in [`terraform.ContextGraphWalker`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#ContextGraphWalker), which implements a small set of higher-level operations that are performed during the graph walk: * `EnterPath` is called once for each module in the configuration, taking a module address and returning a [`terraform.EvalContext`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#EvalContext) that tracks objects within that module. `terraform.Context` is the _global_ context for the entire operation, while `terraform.EvalContext` is a context for processing within a single module, and is the primary means by which the namespaces in each module are kept separate. Each vertex in the graph is evaluated, in an order that guarantees that the "happens after" edges will be respected. If possible, the graph walk algorithm will evaluate multiple vertices concurrently. Vertex evaluation code must therefore make careful use of concurrency primitives such as mutexes in order to coordinate access to shared objects such as the `states.State` object. In most cases, we use the helper wrapper [`states.SyncState`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/states#SyncState) to safely implement concurrent reads and writes from the shared state. ## Vertex Evaluation The action taken for each vertex during the graph walk is called _execution_. Execution runs a sequence of arbitrary actions that make sense for a particular vertex type. For example, evaluation of a vertex representing a resource instance during a plan operation would include the following high-level steps: * Retrieve the resource's associated provider from the `EvalContext`. This should already be initialized earlier by the provider's own graph vertex, due to the "happens after" edge between the resource node and the provider node. * Retrieve from the state the portion relevant to the specific resource instance being evaluated. * Evaluate the attribute expressions given for the resource in configuration. This often involves retrieving the state of _other_ resource instances so that their values can be copied or transformed into the current instance's attributes, which is coordinated by the `EvalContext`. * Pass the current instance state and the resource configuration to the provider, asking the provider to produce an _instance diff_ representing the differences between the state and the configuration. * Save the instance diff as part of the plan that is being constructed by this operation. Each execution step for a vertex is an implementation of [`terraform.Execute`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/erraform#Execute). As with graph transforms, the behavior of these implementations varies widely: whereas graph transforms can take any action against the graph, an `Execute` implementation can take any action against the `EvalContext`. The implementation of `terraform.EvalContext` used in real processing (as opposed to testing) is [`terraform.BuiltinEvalContext`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#BuiltinEvalContext). It provides coordinated access to plugins, the current state, and the current plan via the `EvalContext` interface methods. In order to be executed, a vertex must implement [`terraform.GraphNodeExecutable`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#GraphNodeExecutable), which has a single `Execute` method that handles. There are numerous `Execute` implementations with different behaviors, but some prominent examples are: * [NodePlannableResource.Execute](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#NodePlannableResourceInstance.Execute), which handles the `plan` operation. * [`NodeApplyableResourceInstance.Execute`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#NodeApplyableResourceInstance.Execute), which handles the main `apply` operation. * [`NodeDestroyResourceInstance.Execute`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#EvalWriteState), which handles the main `destroy` operation. A vertex must complete successfully before the graph walk will begin evaluation for other vertices that have "happens after" edges. Evaluation can fail with one or more errors, in which case the graph walk is halted and the errors are returned to the user. ### Expression Evaluation An important part of vertex evaluation for most vertex types is evaluating any expressions in the configuration block associated with the vertex. This completes the processing of the portions of the configuration that were not processed by the configuration loader. The high-level process for expression evaluation is: 1. Analyze the configuration expressions to see which other objects they refer to. For example, the expression `aws_instance.example[1]` refers to one of the instances created by a `resource "aws_instance" "example"` block in configuration. This analysis is performed by [`lang.References`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#References), or more often one of the helper wrappers around it: [`lang.ReferencesInBlock`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#ReferencesInBlock) or [`lang.ReferencesInExpr`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#ReferencesInExpr) 1. Retrieve from the state the data for the objects that are referred to and create a lookup table of the values from these objects that the HCL evaluation code can refer to. 1. Prepare the table of built-in functions so that HCL evaluation can refer to them. 1. Ask HCL to evaluate each attribute's expression (a [`hcl.Expression`](https://pkg.go.dev/github.com/hashicorp/hcl/v2/#Expression) object) against the data and function lookup tables. In practice, steps 2 through 4 are usually run all together using one of the methods on [`lang.Scope`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#Scope); most commonly, [`lang.EvalBlock`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#Scope.EvalBlock) or [`lang.EvalExpr`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/lang#Scope.EvalExpr). Expression evaluation produces a dynamic value represented as a [`cty.Value`](https://pkg.go.dev/github.com/zclconf/go-cty/cty#Value). This Go type represents values from the Terraform language and such values are eventually passed to provider plugins. ### Sub-graphs Some vertices have a special additional behavior that happens after their evaluation steps are complete, where the vertex implementation is given the opportunity to build another separate graph which will be walked as part of the evaluation of the vertex. The main example of this is when a `resource` block has the `count` argument set. In that case, the plan graph initially contains one vertex for each `resource` block, but that graph then _dynamically expands_ to have a sub-graph containing one vertex for each instance requested by the count. That is, the sub-graph of `aws_instance.example` might contain vertices for `aws_instance.example[0]`, `aws_instance.example[1]`, etc. This is necessary because the `count` argument may refer to other objects whose values are not known when the main graph is constructed, but become known while evaluating other vertices in the main graph. This special behavior applies to vertex objects that implement [`terraform.GraphNodeDynamicExpandable`](https://pkg.go.dev/github.com/hashicorp/terraform/internal/terraform#GraphNodeDynamicExpandable). Such vertices have their own nested _graph builder_, _graph walk_, and _vertex evaluation_ steps, with the same behaviors as described in these sections for the main graph. The difference is in which graph transforms are used to construct the graph and in which evaluation steps apply to the nodes in that sub-graph.