Document revision date: 19 July 1999 | |
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This standard states that a standard call may be accomplished in any way that presents the called routine with the required environment (see Section 1.4). However, typically, most standard-conforming external calls are implemented with a common sequence of instructions and conventions. Since a common set of call conventions is so pervasive, these conventions are included for reference as part of this standard.
One important feature of the calling standard is that the same
instruction sequence can be used to call each of the different types of
procedure. Specifically, the caller does not have to know which type of
procedure is being called.
3.7.1 Call Conventions
The call conventions describe the rules and methods used to communicate certain information between the caller and the called procedure during invocation and return. For a standard call, these conventions include the following:
Figure 3-11 Argument Information Register (R25) Format
Field Name | Contents | ||||||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
AI$B_ARG_COUNT | Unsigned byte <7:0> that specifies the number of 64-bit argument items in the argument list (known as the "argument count"). | ||||||||||||||||||||||||
AI$V_ARG_REG_INFO |
An 18-bit vector field <25:8> divided into six groups of three
bits that correspond to the six arguments passed in registers. These
groups describe how each of the first six arguments are passed in
registers with the first group <10:8> describing the first
argument. The encoding for each group for the argument register usage
follows:
|
||||||||||||||||||||||||
Bits 26--63 | Reserved and must be 0. |
One implication of the stack alignment requirement is that low-level interrupt and exception-fielding software must be prepared to handle and correct the alignment before calling handler routines, in case the stack pointer is not octaword aligned at the time of an interrupt or exception. |
Because the Alpha hardware architecture has the property of instructions that cannot contain full virtual addresses, it is sometimes referred to as a base register architecture. In a base register architecture, normal memory references within a limited range from a given address are expressed by using displacements relative to the contents of a register containing that address (base register). Base registers for external program segments, either data or code, are usually loaded indirectly through a program segment of address constants.
The fundamental program section containing address constants that a procedure uses to access other static storage, external procedures, and variables is termed a linkage section. Any register used to access the contents of the linkage section is termed a linkage pointer.
A procedure's linkage section includes the procedure descriptor for the procedure, addresses of all external variables and procedures referenced by the procedure, and other constants a compiler may choose to reference using a linkage pointer.
When a standard procedure is called, the caller must provide the procedure value for that procedure in R27. Static procedure values are defined to be the address of the procedure's descriptor. Since the procedure descriptor is part of the linkage section, calling this type of procedure value provides a pointer into the linkage section for that procedure in R27. This linkage pointer can then be used by the called procedure as a base register to address locations in its linkage section. For this reason, most compilers generate references to items in the linkage section as offsets from a pointer to the procedure's descriptor.
Compilers usually arrange (as part of the environment setup) to have the environment setup code (for bound procedures) load R27 with the address of the procedure's descriptor so it can be used as a linkage pointer as previously described. For an example, see Section 3.7.4.
Although not required, linkages to external procedures are typically represented in the calling procedure's linkage section as a linkage pair. As shown in Figure 3-12 and described in Table 3-12, a linkage pair (LKP) block with two fields should be octaword aligned and defined by LKP$K_SIZE as 16 bytes.
Figure 3-12 Linkage Pair Block Format
Field Name | Contents |
---|---|
LKP$Q_ENTRY | Absolute address of the first instruction of the called procedure's entry code sequence. |
LKP$Q_PROC_VALUE | Contains the procedure value of the procedure to be called. Normally, this field is the absolute address of a procedure descriptor for the procedure to be called, but in certain cases, it could be a bound procedure value (such as for procedures that are called through certain types of transfer vectors). |
In general, an object module contains a procedure descriptor for each entry point in the module. The descriptors are allocated in a linkage section. For each external procedure Q that is referenced in a module, the module's linkage section also contains a linkage pair denoting Q (which is a pointer to Q's procedure descriptor and entry code address).
The following code example calls an external procedure Q as represented by a linkage pair. In this example, R4 is the register that currently contains the address of the current procedure's descriptor.
LDQ R26,Q_DESC-MY_DESC(R4) ;Q's entry address into R26 LDQ R27,Q_DESC-MY_DESC+8(R4) ;Q's procedure value into R27 MOVQ #AI_LITERAL,R25 ;Load Argument Information register JSR R26,(R26) ;Call to Q. Return address in R26 |
Because Q's procedure descriptor (statically defined procedure value)
is in Q's linkage section, Q can use the value in R27 as a base address
for accessing data in its linkage section. Q accesses external
procedures and data in other program sections through pointers in its
linkage section. Therefore, R27 serves as the root pointer through
which all data can be referenced.
3.7.3 Calling Computed Addresses
Most calls are made to a fixed address whose value is determined by the time the program starts execution. However, certain cases are possible that cause the exact address to be unknown until the code is finally executed. In this case, the procedure value representing the procedure to be called is computed in a register.
The following code example illustrates a call to a computed procedure value (simple or bound) that is contained in R4:
LDQ R26,8(R4) ;Entry address to scratch register MOV R4,R27 ;Procedure value to R27 MOVQ #AI_LITERAL,R25 ;Load Argument Information register JSR R26,(R26) ;Call entry address. |
If interoperation with translated images must be considered, the procedure value (in this example, in R4) might be the address of a VAX entry point rather than the address of an Alpha procedure descriptor. A VAX entry point can be dynamically distinguished from an Alpha procedure descriptor by examining bits 12 and 13 of a VAX entry call mask, which are required to be 0 by the VAX architecture. For an Alpha procedure, bit 12 corresponds to the PDSC$V_NATIVE flag, which is required to be set in all Alpha procedure descriptors. Bit 13 corresponds to the PDSC$V_NO_JACKET flag, which is currently required to be set but reserved for enhancements to this standard in all Alpha procedure descriptors.
If the procedure value is determined to correspond to an Alpha procedure, then the call can be completed as discussed. If the procedure value is determined to correspond to a VAX procedure, then the call must be completed using system facilities that will effect the transition into and out of the code of the translated image. Example 3-1 illustrates a code sequence for examining the procedure value.
Example 3-1 Code for Examining the Procedure Value |
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LDL R28,0(R4) ;Load the flags field of the target PDSC MOVQ #AI_LITERAL,R25 ;Load Argument Information register SRL R28,#PDSC$V_NO_JACKET,R26 ;Position jacket flag BLBC R26,CALL_JACKET ;If clear then jacket needed LDQ R26,8(R4) ;Entry address to scratch register MOV R4,R27 ;Procedure value to R27 JSR R26,(R26) ;Call entry address. back_in_line: ... ;Rest of procedure code goes here TRANSLATED: ;Generated out of line, R2 contains a LDQ R26,N_TO_T_LKP(R2) ;Entry address to scratch register LDQ R27,N_TO_T_LKP+8(R2) ;Load procedure value MOV R4,R23 ;Address of routine to call to R23 JSR R26,(R26) ;Call jacket routine BR back_in_line ;Return to normal code path CALL_JACKET: ; SRL R28,#PDSC$V_NATIVE,R28;Jacketing for translated or native? LDA R24,PSIG_OUT(R2) ;Pass address of our argument ; signature information in R24 BLBC R28,TRANSLATED ;If clear, then translated jacketing (Native Jacketing Reserved for Future Use) BR back_in_line ;Return to normal code path |
In Example 3-1, jacketing functionality is provided by the
SYS$NATIVE_TO_TRANSLATED routine. This system procedure is called with
the actual arguments for the target procedure in their normal locations
(as though the target procedure were an Alpha procedure) and with two
additional, nonstandard arguments in registers R23 and R24. R23
contains the procedure value for the target VAX procedure, and R24
contains the address of a procedure signature block for this call as
described in Section 3.5.
3.7.4 Bound Procedure Descriptors
Bound procedure descriptors provide a mechanism to interpose special processing between a call and the called routine without modifying either. The descriptor may contain (or reference) data used as part of that processing. Between native and translated images, the OpenVMS Alpha operating system uses linker and image-activator created bound procedure descriptors to mediate the handling of parameter and result passing (see Section 3.5). Language processors on OpenVMS Alpha systems use bound procedure descriptors to implement bound procedure values (see Section 3.7.4.1). Other uses are possible.
The minimum size of the descriptor is 24 bytes (defined by PDSC$K_MIN_BOUND_SIZE). An optional PDSC extension in 8-byte increments provides the specific environment values as defined by the implementation.
The fields defined in the bound procedure descriptor are illustrated in Figure 3-13 and described in Table 3-13.
Figure 3-13 Bound Procedure Descriptor (PDSC)
Field Name | Contents | ||
---|---|---|---|
PDSC$W_FLAGS |
Vector of flag bits <15:0> that must be a copy of the flag bits
(except for KIND bits) contained in the quadword pointed to by
PDSC$Q_PROC_VALUE.
|
||
PDSC$V_FUNC_RETURN |
A 4-bit field <11:8> that describes which registers are used for
the function value return (if there is one) and what format is used for
those registers.
PDSC$V_FUNC_RETURN in a bound procedure descriptor must be the same as the PDSC$V_FUNC_RETURN of the procedure descriptor for the procedure for which the environment is established. Table 3-7 lists and describes the possible encoding values of PDSC$V_FUNC_RETURN. |
||
Bits 12--15 | Reserved and must be 0. | ||
PDSC$W_SIGNATURE_OFFSET |
A 16-bit signed byte offset from the start of the procedure descriptor.
This offset designates the start of the procedure signature block (if
any). In a bound procedure, a 0 in this field indicates the actual
signature block must be sought in the procedure descriptor indicated by
the PDSC$Q_PROC_VALUE field. A 1 in this field indicates a standard
default signature. (An offset value of 1 is not a valid offset because
both procedure descriptors and signature blocks must be quadword
aligned. See Section 3.5 for details of the procedure signature
block.)
Note that a nonzero signature offset in a bound procedure value normally occurs only in the case of bound procedures used as part of the implementation of calls from native OpenVMS Alpha code to translated OpenVMS VAX images. In any case, if a nonzero offset is present, it takes precedence over signature information that might occur in any related procedure descriptor. |
||
PDSC$Q_ENTRY | Address of the transfer code sequence. | ||
PDSC$Q_PROC_VALUE | Value of the procedure to be called by the transfer code. The value can be either the address of a procedure descriptor for the procedure or possibly another bound procedure value. | ||
PDSC$Q_ENVIRONMENT | An environment value to pass to the procedure. The choice of environment value is system implementation specific. For more information, see Section 3.7.4.1. |
There are two distinct classes of procedures:
A simple procedure is a procedure that does not need direct access to the stack of its execution environment. A bound procedure is a procedure that does need direct access to the stack of its execution environment, typically to reference an up-level variable or to perform a nonlocal GOTO operation. Both a simple procedure and a bound procedure have an associated procedure descriptor, as described in previous sections.
When a bound procedure is called, the caller must pass some kind of pointer to the called code that allows it to reference its up-level environment. Typically, this pointer is the frame pointer for that environment, but many variations are possible. When the caller is executing its program within that outer environment, it can usually make such a call directly to the code for the nested procedure without recourse to any additional procedure descriptors. However, when a procedure value for the nested procedure must be passed outside of that environment to a call site that has no knowledge of the target procedure, a bound procedure descriptor is created so that the nested procedure can be called just like a simple procedure.
Bound procedure values, as defined by this standard, are designed for multilanguage use and utilize the properties of procedure descriptors to allow callers of procedures to use common code to call both bound and simple procedures.
The procedure value for a bound procedure is a pointer to a bound procedure descriptor that, like all other procedure descriptors, contains the address to which the calling procedure must transfer control at offset 8 (see Figure 3-13). This transfer code is responsible for setting up the dynamic environment needed by the target nested procedure and then completing the transfer of control to the code for that procedure. The transfer code receives in R27 a pointer to its corresponding bound procedure descriptor and thus can fetch any required environment information from that descriptor. A bound procedure descriptor also contains a procedure value for the target procedure that is used to complete the transfer of control.
When the transfer code sequence addressed by PDSC$Q_ENTRY of a bound procedure descriptor is called (by a call sequence such as the one given in Section 3.7.3), the procedure value will be in R27, and the transfer code must finish setting up the environment for the target procedure. The preferred location for this transfer code is directly preceding the code for the target procedure. This saves a memory fetch and a branching instruction and optimizes instruction caches and paging.
The following is an example of such a transfer code sequence. It is an example of a target procedure Q that expects the environment value to be passed in R1 and a linkage pointer in R27.
Q_TRANSFER: LDQ R1,24(R27) ;Environment value to R1 LDQ R27,16(R27) ;Procedure descriptor address to R27 Q_ENTRY:: ;Normal procedure entry code starts here |
After the transfer code has been executed and control is transferred to Q's entry address, R27 contains the address of Q's procedure descriptor, R26 (unmodified by transfer code) contains the return address, and R1 contains the environment value.
When a bound procedure value such as this is needed, the bound procedure descriptor is usually allocated on the parent procedure's stack.
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