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#pragma once
/**
* @file Implementation of Profiles.
*
* See the manual for additional information.
*/
#include "types.hh"
#include "pathlocks.hh"
#include <time.h>
namespace nix {
class StorePath;
/**
* A positive number identifying a generation for a given profile.
*
* Generation numbers are assigned sequentially. Each new generation is
* assigned 1 + the current highest generation number.
*/
typedef uint64_t GenerationNumber;
/**
* A generation is a revision of a profile.
*
* Each generation is a mapping (key-value pair) from an identifier
* (`number`) to a store object (specified by `path`).
*/
struct Generation
{
/**
* The number of a generation is its unique identifier within the
* profile.
*/
GenerationNumber number;
/**
* The store path identifies the store object that is the contents
* of the generation.
*
* These store paths / objects are not unique to the generation
* within a profile. Nix tries to ensure successive generations have
* distinct contents to avoid bloat, but nothing stops two
* non-adjacent generations from having the same contents.
*
* @todo Use `StorePath` instead of `Path`?
*/
Path path;
/**
* When the generation was created. This is extra metadata about the
* generation used to make garbage collecting old generations more
* convenient.
*/
time_t creationTime;
};
/**
* All the generations of a profile
*/
typedef std::list<Generation> Generations;
/**
* Find all generations for the given profile.
*
* @param profile A profile specified by its name and location combined
* into a path. E.g. if "foo" is the name of the profile, and "/bar/baz"
* is the directory it is in, then the path "/bar/baz/foo" would be the
* argument for this parameter.
*
* @return The pair of:
*
* - The list of currently present generations for the specified profile,
* sorted by ascending generation number.
*
* - The number of the current/active generation.
*
* Note that the current/active generation need not be the latest one.
*/
std::pair<Generations, std::optional<GenerationNumber>> findGenerations(Path profile);
class LocalFSStore;
/**
* Create a new generation of the given profile
*
* If the previous generation (not the currently active one!) has a
* distinct store object, a fresh generation number is mapped to the
* given store object, referenced by path. Otherwise, the previous
* generation is assumed.
*
* The behavior of reusing existing generations like this makes this
* procedure idempotent. It also avoids clutter.
*/
Path createGeneration(LocalFSStore & store, Path profile, StorePath outPath);
/**
* Unconditionally delete a generation
*
* @param profile A profile specified by its name and location combined into a path.
*
* @param gen The generation number specifying exactly which generation
* to delete.
*
* Because there is no check of whether the generation to delete is
* active, this is somewhat unsafe.
*
* @todo Should we expose this at all?
*/
void deleteGeneration(const Path & profile, GenerationNumber gen);
/**
* Delete the given set of generations.
*
* @param profile The profile, specified by its name and location combined into a path, whose generations we want to delete.
*
* @param gensToDelete The generations to delete, specified by a set of
* numbers.
*
* @param dryRun Log what would be deleted instead of actually doing
* so.
*
* Trying to delete the currently active generation will fail, and cause
* no generations to be deleted.
*/
void deleteGenerations(const Path & profile, const std::set<GenerationNumber> & gensToDelete, bool dryRun);
/**
* Delete generations older than `max` passed the current generation.
*
* @param profile The profile, specified by its name and location combined into a path, whose generations we want to delete.
*
* @param max How many generations to keep up to the current one. Must
* be at least 1 so we don't delete the current one.
*
* @param dryRun Log what would be deleted instead of actually doing
* so.
*/
void deleteGenerationsGreaterThan(const Path & profile, GenerationNumber max, bool dryRun);
/**
* Delete all generations other than the current one
*
* @param profile The profile, specified by its name and location combined into a path, whose generations we want to delete.
*
* @param dryRun Log what would be deleted instead of actually doing
* so.
*/
void deleteOldGenerations(const Path & profile, bool dryRun);
/**
* Delete generations older than `t`, except for the most recent one
* older than `t`.
*
* @param profile The profile, specified by its name and location combined into a path, whose generations we want to delete.
*
* @param dryRun Log what would be deleted instead of actually doing
* so.
*/
void deleteGenerationsOlderThan(const Path & profile, time_t t, bool dryRun);
/**
* Parse a temp spec intended for `deleteGenerationsOlderThan()`.
*
* Throws an exception if `timeSpec` fails to parse.
*/
time_t parseOlderThanTimeSpec(std::string_view timeSpec);
/**
* Smaller wrapper around `replaceSymlink` for replacing the current
* generation of a profile. Does not enforce proper structure.
*
* @todo Always use `switchGeneration()` instead, and delete this.
*/
void switchLink(Path link, Path target);
/**
* Roll back a profile to the specified generation, or to the most
* recent one older than the current.
*/
void switchGeneration(
const Path & profile,
std::optional<GenerationNumber> dstGen,
bool dryRun);
/**
* Ensure exclusive access to a profile. Any command that modifies
* the profile first acquires this lock.
*/
void lockProfile(PathLocks & lock, const Path & profile);
/**
* Optimistic locking is used by long-running operations like `nix-env
* -i'. Instead of acquiring the exclusive lock for the entire
* duration of the operation, we just perform the operation
* optimistically (without an exclusive lock), and check at the end
* whether the profile changed while we were busy (i.e., the symlink
* target changed). If so, the operation is restarted. Restarting is
* generally cheap, since the build results are still in the Nix
* store. Most of the time, only the user environment has to be
* rebuilt.
*/
std::string optimisticLockProfile(const Path & profile);
/**
* Create and return the path to a directory suitable for storing the user’s
* profiles.
*/
Path profilesDir();
/**
* Return the path to the profile directory for root (but don't try creating it)
*/
Path rootProfilesDir();
/**
* Create and return the path to the file used for storing the users's channels
*/
Path defaultChannelsDir();
/**
* Return the path to the channel directory for root (but don't try creating it)
*/
Path rootChannelsDir();
/**
* Resolve the default profile (~/.nix-profile by default,
* $XDG_STATE_HOME/nix/profile if XDG Base Directory Support is enabled),
* and create if doesn't exist
*/
Path getDefaultProfile();
}
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