package dotty.tools.dotc.core
import Contexts._
/** Periods are the central "clock" of the compiler.
* A period consists of a run id and a phase id.
* run ids represent compiler runs
* phase ids represent compiler phases
*/
abstract class Periods extends DotClass { self: Context =>
import Periods._
/** The current phase identifier */
def phaseId: Int = period.phaseId
/** The current run identifier */
def runId: Int = period.runId
/** Execute `op` at given period */
def atPeriod[T](pd: Period)(op: Context => T): T =
op(ctx.fresh.withPeriod(pd))
/** Execute `op` at given phase id */
def atPhase[T](pid: PhaseId)(op: Context => T): T =
op(ctx.fresh.withPhase(pid))
/** The period containing the current period where denotations do not change.
* We compute this by taking as first phase the first phase less or equal to
* the current phase that has the same "nextTransformer". As last phase
* we take the phaseId of the nextTransformer - 1. This has the advantage that
* it works even if no transformer is installed other than the sentinel
* NoTransformer, which is always installed automatically.
*/
def stablePeriod = {
var first = phaseId
val transformers = base.symTransformers
val nxTrans = transformers.nextTransformer(first)
while (first - 1 > NoPhaseId &&
(transformers.nextTransformer(first - 1) eq nxTrans)) {
first -= 1
}
Period(runId, first, nxTrans.phaseId - 1)
}
}
object Periods {
/** A period is a contiguous sequence of phase ids in some run.
* It is coded as follows:
*
* sign, always 0 1 bit
* runid 21 bits
* last phase id: 5 bits
* #phases before last: 5 bits
*/
class Period(val code: Int) extends AnyVal {
/** The run identifier of this period. */
def runId: Int = code >>> (PhaseWidth * 2)
/** The phase identifier of this single-phase period. */
def phaseId: Int = (code >>> PhaseWidth) & PhaseMask
/** The last phase of this period */
def lastPhaseId: Int =
(code >>> PhaseWidth) & PhaseMask
/** The first phase of this period */
def firstPhaseId = lastPhaseId - (code & PhaseMask)
/** Does this period contain given period? */
def contains(that: Period): Boolean = {
// Let this = (r1, l1, d1), that = (r2, l2, d2)
// where r = runid, l = last phase, d = duration - 1
// Then seen as intervals:
//
// this = r1 / (l1 - d1) .. l1
// that = r2 / (l2 - d2) .. l2
//
// Let's compute:
//
// lastDiff = X * 2^5 + (l1 - l2) mod 2^5
// where X >= 0, X == 0 iff r1 == r2 & l1 - l2 >= 0
// result = lastDiff + d2 <= d1
// We have:
// lastDiff + d2 <= d1
// iff X == 0 && l1 - l2 >= 0 && l1 - l2 + d2 <= d1
// iff r1 == r2 & l1 >= l2 && l1 - d1 <= l2 - d2
// q.e.d
val lastDiff = (code - that.code) >>> PhaseWidth
lastDiff + (that.code & PhaseMask ) <= (this.code & PhaseMask)
}
/** Does this period overlap with given period? */
def overlaps(that: Period): Boolean =
this.runId == that.runId &&
this.firstPhaseId <= that.lastPhaseId &&
that.firstPhaseId <= this.lastPhaseId
/** The intersection of two periods */
def & (that: Period): Period =
if (this overlaps that)
Period(
this.runId,
this.firstPhaseId max that.firstPhaseId,
this.lastPhaseId min that.lastPhaseId)
else
Nowhere
override def toString = s"Period($firstPhaseId..$lastPhaseId, run = $runId)"
}
object Period {
/** The single-phase period consisting of given run id and phase id */
def apply(rid: RunId, pid: PhaseId): Period =
new Period(((rid << PhaseWidth) | pid) << PhaseWidth)
/** The period consisting of given run id, and lo/hi phase ids */
def apply(rid: RunId, loPid: PhaseId, hiPid: PhaseId): Period =
new Period(((rid << PhaseWidth) | hiPid) << PhaseWidth | (hiPid - loPid))
/** The interval consisting of all periods of given run id */
def allInRun(rid: RunId) =
apply(rid, 0, PhaseMask)
}
final val Nowhere = new Period(0)
final val InitialPeriod = Period(InitialRunId, FirstPhaseId, FirstPhaseId)
/** An ordinal number for compiler runs. First run has number 1. */
type RunId = Int
final val NoRunId = 0
final val InitialRunId = 1
/** An ordinal number for phases. First phase has number 1. */
type PhaseId = Int
final val NoPhaseId = 0
final val FirstPhaseId = 1
/** The number of bits needed to encode a phase identifier. */
final val PhaseWidth = 5
final val PhaseMask = (1 << PhaseWidth) - 1
final val MaxPossiblePhaseId = PhaseMask
}