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Upgrading Privileged-Code Applications on OpenVMS Alpha and OpenVMS I64 Systems

Upgrading Privileged-Code Applications on OpenVMS Alpha and OpenVMS I64 Systems


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B.5 EXE_STD$MODIFY, EXE_STD$READ, EXE_STD$WRITE

The routines EXE_STD$MODIFY, EXE_STD$READ, and EXE_STD$WRITE are upper-level FDT routines, so their interfaces remain unchanged:


int exe_std$modify (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb) 
int exe_std$read   (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb) 
int exe_std$write  (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb) 

These routines obtain the address of the caller's buffer from irp->irp$l_qio_p1 . These routines have been modified to obtain the full 64-bit buffer address from irp->irp$q_qio_p1 and pass it to EXE_STD$READLOCK or EXE_STD$WRITELOCK. Note, however, that the buffer size remains a longword and is obtained from irp->irp$l_qio_p2 without checking the upper 32-bits.

B.6 EXE_STD$MODIFYLOCK, EXE_STD$READLOCK, EXE_STD$WRITELOCK

The routines EXE_STD$MODIFYLOCK, EXE_STD$READLOCK, and EXE_STD$WRITELOCK are FDT support routines that:

If an error is encountered, an optional error callback routine is invoked and the I/O request is aborted. If the entire buffer is not resident then the I/O request is backed out and a special status is returned to request a pagefault of the needed page.

In releases prior to OpenVMS Alpha Version 7.0, the interfaces for these routines were:


int exe_std$modifylock (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        void *buf, int bufsiz, void (*err_rout)(...)) 
int exe_std$readlock   (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        void *buf, int bufsiz, void (*err_rout)(...)) 
int exe_std$writelock  (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        void *buf, int bufsiz, void (*err_rout)(...)) 

The new interfaces for these routines are:


int exe_std$modifylock (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        VOID_PQ buf, int bufsiz [, void (*err_rout)(...)] ) 
int exe_std$readlock   (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        VOID_PQ buf, int bufsiz [, void (*err_rout)(...)] ) 
int exe_std$writelock  (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb, 
                        VOID_PQ buf, int bufsiz [, void (*err_rout)(...)] ) 

There are two differences in the new OpenVMS Alpha Version 7.0 interfaces:

  1. These functions now use the full 64-bits of the buffer address buf that is passed by value.
    Previously, the buffer address was a 32-bit value that was sign-extended into a 64-bit parameter value.
  2. It is possible to omit the err_rout parameter. Currently, one can pass in the value 0 to specify that there is no error routine.
    The new interface supports either method of specifying that there is no error routine. Because many callers do not require an error routine, this allows them to call these routines more efficiently with six parameters.

Both of these interface changes are upwardly compatible.

B.6.1 CALL_xLOCK and CALL_xLOCK_ERR Macros

There are six MACRO-32 macros that facilitate the use of the routines described in Section B.6 by code that was originally written to use the JSB-interface counterparts for these routines. These macros have implicit register inputs and outputs that correspond to the register inputs and outputs of the JSB-interface routines.

The CALL_MODIFYLOCK, CALL_READLOCK, and CALL_WRITELOCK macros have been modified to pass the full 64-bits of R0 as the buffer address and to omit the optional error routine parameter instead of passing the value 0.

The CALL_MODIFYLOCK_ERR, CALL_READLOCK_ERR, and CALL_WRITELOCK_ERR macros have been modified to pass the full 64-bits of R0 as the buffer address.

This is an upwardly compatible change to the implementation of these macros. This change is transparent to users prior to OpenVMS Alpha Version 7.0, because R0 currently contains the 32-bit buffer address sign-extended to 64-bits.

B.7 EXE_STD$READCHK and EXE_STD$WRITECHK

The routines EXE_STD$READCHK and EXE_STD$WRITECHK probe the accessibility of a specified buffer by the mode contained in irp->irp$b_mode .

In releases prior to OpenVMS Alpha Version 7.0, the interfaces for these routines were:


int exe_std$readchk  (IRP *irp, PCB *pcb, UCB *ucb, void *buf, int bufsiz) 
int exe_std$writechk (IRP *irp, PCB *pcb, UCB *ucb, void *buf, int bufsiz) 

As of OpenVMS Alpha Version 7.0, the new interfaces for these routines are:


int exe_std$readchk  (IRP *irp, PCB *pcb, UCB *ucb, VOID_PQ buf, int bufsiz) 
int exe_std$writechk (IRP *irp, PCB *pcb, UCB *ucb, VOID_PQ buf, int bufsiz) 

The only difference in the new interface is that these functions now use the full 64-bits of the buffer address buf that is passed by value. Previously, the buffer address was a 32-bit value sign-extended into a 64-bit parameter value. Thus, this is an upward compatible change to the interface.

B.7.1 CALL_xCHK and CALL_xCHKR Macros

The CALL_READCHK, CALL_READCHKR, CALL_WRITECHK, and CALL_WRITECHKR MACRO-32 macros have been modified to pass the full 64-bits of the buffer address in a similar fashion as described in Section B.6.1.

B.8 EXE_STD$SETCHAR and EXE_STD$SETMODE

The routines EXE_STD$SETCHAR and EXE_STD$SETMODE are upper-level FDT routines, thus their interfaces remain unchanged:


int exe_std$setchar (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb) 
int exe_std$setmode (IRP *irp, PCB *pcb, UCB *ucb, CCB *ccb) 

Both of these routines use the local routine CHECK_SET to obtain and validate a pointer to the caller's buffer from irp->irp$l_qio_p1 . The routine CHECK_SET has been modified to obtain the full 64-bit buffer address from irp->irp$q_qio_p1 . Routines EXE_STD$SETCHAR and EXE_STD$SETMODE has been modified to use the 64-bit pointer returned by CHECK_SET when loading the UCB characteristics from the caller's buffer.

B.9 IOC_STD$CREATE_DIOBM

Routine IOC_STD$CREATE_DIOBM is a new routine that is used to derive a 32-bit system virtual address for a specific number of PTEs that are pointed to by a 64-bit process virtual address. This routine allocates a "primary" DIOBM structure of sufficient size for its needs and returns a pointer to it. When the derived 32-bit system virtual address is no longer required the DIOBM must be released by calling the IOC_STD$RELEASE_DIOBM routine.

The algorithm used by this routine is very similar to the one used by IOC_STD$FILL_DIOBM as described in Section B.10. The significant difference is that IOC_STD$CREATE_DIOBM allocates a sufficiently sized primary DIOBM structure for its needs and does not depend on a preallocated fixed-size DIOBM. This routine is designed for previous users of the MMG$IOLOCK routine that do not have an embedded DIOBM to work with, but can maintain a single pointer to the external DIOBM structure that is returned by IOC_STD$CREATE_DIOBM.

The interface for IOC_STD$CREATE_DIOBM is:


int ioc_std$create_diobm (const PTE_PQ va_pte, const uint32 pte_count, 
                          const uint32 flags, 
                          PTE **svapte_p, DIOBM **diobm_p) 

Table B-7 summarizes the use of the arguments.

Table B-7 IOC_STD$CREATE_DIOBM Arguments
Argument Type Access Description
va_pte PTE_PQ Input A 64-bit pointer to the first PTE that maps the user buffer.
pte_count uint32 Input Number of PTEs that are required to map the entire buffer.
svapte_p PTE ** Output Pointer to a 32-bit PTE address that is returned. The returned address is always a 32-bit system virtual address.
flags uint32 Input Option flags. The following bit mask values can be set:

DIOBM$M_NORESWAIT - Disable resource wait.

All other option bits must be zero.

diobm_p DIOBM ** Output Pointer to DIOBM address that is returned.

This routine requires system resources, nonpaged pool and possibly SPTEs. If there are insufficient resources, this routine will, by default, place the process (kernel thread) in a kernel mode wait state for nonpaged pool and try again until it succeeds. In this case, the return value of this routine is always SS$_NORMAL because it will not return until it can do so successfully.

However, the caller can inhibit this resource wait by setting the DIOBM$M_NORESWAIT option in the flags parameter. When this is done an error status is returned to the caller if there are insufficient system resources. This capability is intended to be used in contexts where either a resource wait in kernel mode is not acceptable or the caller can readily put the process into a wait state in the requestor's mode.

This routine must be called in process context and assumes that it was called at IPL 2, or minimally, that it can lower IPL to 2.


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