Because the total amount of file data cached includes the system working set, modified page list, and standby list—the sizes of which are all controlled by the memory manager—it is in a sense the real cache manager. The cache manager subsystem simply provides convenient interfaces for accessing file data through the memory manager. It also plays an important role with its read-ahead and write-behind policies in influencing what data the memory manager keeps present in physical memory, as well as with managing system virtual address views of the space.
To try to accurately reflect the total amount of file data that’s cached on a system, Task Manager shows a value named Cache in its performance view that reflects the combined size of the system working set, standby list, and modified page list. Process Explorer, on the other hand, breaks up these values into Cache WS (system cache working set), Standby, and Modified. Figure 11-4 shows the system information view in Process Explorer and the Cache WS value in the Physical Memory area in the lower left of the figure, as well as the size of the standby and modified lists in the Paging Lists area near the middle of the figure. Note that the Cache value in Task Manager also includes the Paged WS, Kernel WS, and Driver WS values shown in Process Explorer. When these values were chosen, the vast majority of System WS came from the Cache WS. This is no longer the case today, but the anachronism remains in Task Manager.
Cache Data Structures
The cache manager uses the following data structures to keep track of cached files:
Each 256-KB slot in the system cache is described by a VACB.
Each separately opened cached file has a private cache map, which contains information used to control read-ahead (discussed later in the chapter).
Each cached file has a single shared cache map structure, which points to slots in the system cache that contain mapped views of the file.
These structures and their relationships are described in the next sections.
Systemwide Cache Data Structures
As previously described, the cache manager keeps track of the state of the views in the system cache by using an array of data structures called
Additionally, each VACB array is composed of two kinds of VACB:
As you can see in Figure 11-6, the first field in a VACB is the virtual address of the data in the system cache. The second field is a pointer to the shared cache map structure, which identifies which file is cached. The third field identifies the offset within the file at which the view begins (always based on 256-KB granularity). Given this granularity, the bottom 16 bits of the file offset will always be zero, so those bits are reused to store the number of references to the view—that is, how many active reads or writes are accessing the view. The fourth field links the VACB into a list of least-recently-used (LRU) VACBs when the cache manager frees the VACB; the cache manager first checks this list when allocating a new VACB. Finally, the fifth field links this VACB to the VACB array header representing the array in which the VACB is stored.
