This change makes workspace file naming a little more consistent with respect
to Mufile naming. Instead of having a .mu/ directory, under which a workspace.yaml
and/or a stacks directory might exist, we now have a Muspace.yaml (or .json) file,
and a .Mudeps/ directory. This has nicer symmetric with respect to Mu.yaml files.
This change completes the implementation of dependency and type binding.
The top-level change here is that, during the first semantic analysis AST walk,
we gather up all unknown dependencies. Then the compiler resolves them, caching
the lookups to ensure that we don't load the same stack twice. Finally, during
the second and final semantic analysis AST walk, we populate the bound nodes
by looking up what the compiler resolved for us.
This change implements dependency versions, including semantic analysis, per the
checkin 83030685c3.
There's quite a bit in here but at a top-level this parses and validates dependency
references of the form
[[proto://]base.url]namespace/.../name[@version]
and verifies that the components are correct, as well as binding them to symbols.
These references can appear in two places at the moment:
* Service types.
* Cluster dependencies.
As part of this change, a number of supporting changes have been made:
* Parse Workspaces using a full-blown parser, parser analysis, and semantic analysis.
This allows us to share logic around the validation of common AST types. This also
moves some of the logic around loading workspace.yaml files back to the parser, where
it can be unified with the way we load Mu.yaml files.
* New ast.Version and ast.VersionSpec types. The former represents a precise version
-- either a specific semantic version or a short or long Git SHA hash -- and the
latter represents a range -- either a Version, "latest", or a semantic range.
* New ast.Ref and ast.RefParts types. The former is an unparsed string that is
thought to contain a Ref, while the latter is a validated Ref that has been parsed
into its components (Proto, Base, Name, and Version).
* Added some type assertions to ensure certain structs implement certain interfaces,
to speed up finding errors. (And remove the coercions that zero-fill vtbl slots.)
* Be consistent about prefixing error types with Error or Warning.
* Organize the core compiler driver's logic into three methods, FE, sema, and BE.
* A bunch of tests for some of the above ... more to come in an upcoming change.
This change adds support for Workspaces, a convenient way of sharing settings
among many Stacks, like default cluster targets, configuration settings, and the
like, which are not meant to be distributed as part of the Stack itself.
The following things are included in this checkin:
* At workspace initialization time, detect and parse the .mu/workspace.yaml
file. This is pretty rudimentary right now and contains just the default
cluster targets. The results are stored in a new ast.Workspace type.
* Rename "target" to "cluster". This impacts many things, including ast.Target
being changed to ast.Cluster, and all related fields, the command line --target
being changed to --cluster, various internal helper functions, and so on. This
helps to reinforce the desired mental model.
* Eliminate the ast.Metadata type. Instead, the metadata moves directly onto
the Stack. This reflects the decision to make Stacks "the thing" that is
distributed, versioned, and is the granularity of dependency.
* During cluster targeting, add the workspace settings into the probing logic.
We still search in the same order: CLI > Stack > Workspace.
This change includes logic to resolve dependencies declared by stacks. The design
is described in https://github.com/marapongo/mu/blob/master/docs/deps.md.
In summary, each stack may declare dependencies, which are name/semver pairs. A
new structure has been introduced, ast.Ref, to distinguish between ast.Names and
dependency names. An ast.Ref includes a protocol, base part, and a name part (the
latter being an ast.Name); for example, in "https://hub.mu.com/mu/container/",
"https://" is the protocol, "hub.mu.com/" is the base, and "mu/container" is the
name. This is used to resolve URL-like names to package manager-like artifacts.
The dependency resolution phase happens after parsing, but before semantic analysis.
This is because dependencies are "source-like" in that we must load and parse all
dependency metadata files. We stick the full transitive closure of dependencies
into a map attached to the compiler to avoid loading dependencies multiple times.
Note that, although dependencies prohibit cycles, this forms a DAG, meaning multiple
inbound edges to a single stack may come from multiple places.
From there, we rely on ordinary visitation to deal with dependencies further.
This includes inserting symbol entries into the symbol table, mapping names to the
loaded stacks, during the first phase of binding so that they may be found
subsequently when typechecking during the second phase and beyond.
This change introduces a Workspace interface that can be used as a first
class object. We will embellish this as we start binding to dependencies,
which requires us to search multiple paths. This change also introduces a
workspace.InstallRoot() function to fetch the Mu install path.
This adds some tests around cloud targeting, in addition to enabling builds
to use in-memory Mufiles (mostly to make testing simpler, but this is a
generally useful capability to have when hosting the compiler API).
This change implements most of the cloud target and architecture detection
logic, along with associated verification and a bunch of new error messages.
There are two settings for picking a cloud destination:
* Architecture: this specifies the combination of cloud (e.g., AWS, GCP, etc)
plus scheduler (e.g., none, Swarm, ECS, etc).
* Target: a named, preconfigured entity that includes both an Architecture and
an assortment of extra default configuration options.
The general idea here is that you can preconfigure a set of Targets for
named environments like "prod", "stage", etc. Those can either exist in a
single Mufile, or the Mucluster file if they are shared amongst multiple
Mufiles. This can be specified at the command line as such:
$ mu build --target=stage
Furthermore, a given environment may be annointed the default, so that
$ mu build
selects that environment without needing to say so explicitly.
It is also possible to specify an architecture at the command line for
scenarios where you aren't intending to target an existing named environment.
This is good for "anonymous" testing scenarios or even just running locally:
$ mu build --arch=aws
$ mu build --arch=aws:ecs
$ mu build --arch=local:kubernetes
$ .. and so on ..
This change does little more than plumb these settings around, verify them,
etc., however it sets us up to actually start dispating to the right backend.
This change adds a few more compiler tests and rearranges some bits and pieces
that came up while doing so. For example, we now issue warnings for incorrect
casing and/or extensions of the Mufile (and test these conditions). As part of
doing that, it became clear the layering between the mu/compiler and mu/workspace
packages wasn't quite right, so some logic got moved around; additionally, the
separation of concerns between mu/workspace and mu/schema wasn't quite right, so
this has been fixed also (workspace just understands Mufile related things while
schema understands how to unmarshal the specific supported extensions).
This adds a bunch of general scaffolding and the beginning of a `build` command.
The general engineering scaffolding includes:
* Glide for dependency management.
* A Makefile that runs govet and golint during builds.
* Google's Glog library for logging.
* Cobra for command line functionality.
The Mu-specific scaffolding includes some packages:
* mu/pkg/diag: A package for compiler-like diagnostics. It's fairly barebones
at the moment, however we can embellish this over time.
* mu/pkg/errors: A package containing Mu's predefined set of errors.
* mu/pkg/workspace: A package containing workspace-related convenience helpers.
in addition to a main entrypoint that simply wires up and invokes the CLI. From
there, the mu/cmd package takes over, with the Cobra-defined CLI commands.
Finally, the mu/pkg/compiler package actually implements the compiler behavior.
Or, it will. For now, it simply parses a JSON or YAML Mufile into the core
mu/pkg/api types, and prints out the result.
