A thread can be at a safepoint or not be at a safepoint. When at a safepoint, the thread's representation of it's Java machine state is well described, and can be safely manipulated and observed by other threads in the JVM. When not at a safepoint, the thread's representation of the java machine state will NOT be manipulated by other threads in the JVM. [Note that other threads do not manipulate a thread's actual logical machine state, just it's representation of that state. A simple example of changing the representation of machine state is changing the virtual addresss that a java reference stack variable points to as a result of relocating that object. The logical state of the reference variable is not affected by this change, as the reference still refers to the same object, and two references variable referring to the same object will still be logically equal to each other even if they temporarily point to different virtual addresses].
"Being at a safepoint" does not mean "being blocked" (e.g. JNI code runs at a safepoint), but "being blocked" always happens at a safepoint.
The JVM may choose to reach a global safepoint (aka Stop-The-World), where all threads are at a safepoint and can't leave the safe point until the JVM decides to let it do so. This is useful for doing all sorts of work (like certain GC operations, deoptimization during class loading, etc.) that require ALL threads to be at a well described state.
Some JVMs can bring individual threads to safepoint without requiring a global safepoint. E.g. Zing uses the term Checkpoint (first published in [1]) to describe a JVM mechanism that individually passes threads through thread-specidfic safepoints to perform certain very short operations on individual thread state without requiring a Stop-The-Wolrd pause.
When you write Unsafe java code, you must assume that a safepoint MAY occur between any two bytecodes.
Unsafe calls are not required to have safepoints within them (and many/most don't), but they MAY include one or more safepoints. E.g. an unsafe memoryCopy MAY include a periodic safepoint opportunities (e.g. take a safepoint every 16KB). Zing sure does, as we do a lot of under the hood work to keep TTSP in check.
All [practical] JVMs apply some highly efficient mechanism for frequently crossing safepoint opportunities, where the thread does not actually enter a safepoint unless someone else indicates the need to do so. E.g. most call sites and loop backedges in generated code will include some sort of safepoint polling sequence that amounts to "do I need to go to a safepoint now?". Many HotSpot variants (OpenJDK and Oracle JDK) currently use a simple global "go to safepoint" indicator in the form of a page that is protected when a safepoint is needed, and unprotected otherwise. The safepoint polling for this mechanism amounts to a load from a fixed address in that page. If the load traps with a SEGV, the thread knows it needs to go to enter a safepoint. Zing uses a different, per-thread go-to-safepoint indicator of similar efficiency.
All JNI code executes at a safepoint. No Java machine state of the executing thread can be changed or observed by it's JNI code while at a safepoint. Any manipulation or observation of Java state done by JNI code is achieved via JNI API calls that leave the safepoint for the duration of the API call, and then enter a safepoint again before returning to the calling JNI code. This "crossing of the JNI line" is where most of the JNI call and API overhead lies, but it's fairly quick (entering and leaving safepoint normally amounts to some CAS operations).
【背景】
看到JVM的 STW(stop the world)时候 遇到了safepoint 。
【参考文档】
A thread can be at a safepoint or not be at a safepoint. When at a safepoint, the thread's representation of it's Java machine state is well described, and can be safely manipulated and observed by other threads in the JVM. When not at a safepoint, the thread's representation of the java machine state will NOT be manipulated by other threads in the JVM. [Note that other threads do not manipulate a thread's actual logical machine state, just it's representation of that state. A simple example of changing the representation of machine state is changing the virtual addresss that a java reference stack variable points to as a result of relocating that object. The logical state of the reference variable is not affected by this change, as the reference still refers to the same object, and two references variable referring to the same object will still be logically equal to each other even if they temporarily point to different virtual addresses].
"Being at a safepoint" does not mean "being blocked" (e.g. JNI code runs at a safepoint), but "being blocked" always happens at a safepoint.
The JVM may choose to reach a global safepoint (aka Stop-The-World), where all threads are at a safepoint and can't leave the safe point until the JVM decides to let it do so. This is useful for doing all sorts of work (like certain GC operations, deoptimization during class loading, etc.) that require ALL threads to be at a well described state.
Some JVMs can bring individual threads to safepoint without requiring a global safepoint. E.g. Zing uses the term Checkpoint (first published in [1]) to describe a JVM mechanism that individually passes threads through thread-specidfic safepoints to perform certain very short operations on individual thread state without requiring a Stop-The-Wolrd pause.
When you write Unsafe java code, you must assume that a safepoint MAY occur between any two bytecodes.
Unsafe calls are not required to have safepoints within them (and many/most don't), but they MAY include one or more safepoints. E.g. an unsafe memoryCopy MAY include a periodic safepoint opportunities (e.g. take a safepoint every 16KB). Zing sure does, as we do a lot of under the hood work to keep TTSP in check.
All [practical] JVMs apply some highly efficient mechanism for frequently crossing safepoint opportunities, where the thread does not actually enter a safepoint unless someone else indicates the need to do so. E.g. most call sites and loop backedges in generated code will include some sort of safepoint polling sequence that amounts to "do I need to go to a safepoint now?". Many HotSpot variants (OpenJDK and Oracle JDK) currently use a simple global "go to safepoint" indicator in the form of a page that is protected when a safepoint is needed, and unprotected otherwise. The safepoint polling for this mechanism amounts to a load from a fixed address in that page. If the load traps with a SEGV, the thread knows it needs to go to enter a safepoint. Zing uses a different, per-thread go-to-safepoint indicator of similar efficiency.
All JNI code executes at a safepoint. No Java machine state of the executing thread can be changed or observed by it's JNI code while at a safepoint. Any manipulation or observation of Java state done by JNI code is achieved via JNI API calls that leave the safepoint for the duration of the API call, and then enter a safepoint again before returning to the calling JNI code. This "crossing of the JNI line" is where most of the JNI call and API overhead lies, but it's fairly quick (entering and leaving safepoint normally amounts to some CAS operations).