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assist.c
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assist.c
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/* ASSIST.C (C) Copyright Roger Bowler, 1999-2012 */
/* (C) Copyright Jan Jaeger, 1999-2012 */
/* (C) and others 2013-2023 */
/* ESA/390 MVS Assist Routines */
/* */
/* Released under "The Q Public License Version 1" */
/* (http://www.hercules-390.org/herclic.html) as modifications to */
/* Hercules. */
/* z/Architecture support - (C) Copyright Jan Jaeger, 1999-2012 */
/*-------------------------------------------------------------------*/
/* This module contains routines which process the MVS Assist */
/* instructions described in the manual GA22-7079-01. */
/*-------------------------------------------------------------------*/
/* Instruction decode rework - Jan Jaeger */
/* Correct address wraparound - Jan Jaeger */
/* Add dummy assist instruction - Jay Maynard, */
/* suggested by Brandon Hill */
#include "hstdinc.h"
#define _ASSIST_C_
#define _HENGINE_DLL_
#include "hercules.h"
#include "opcode.h"
#include "inline.h"
#include "ecpsvm.h"
DISABLE_GCC_UNUSED_SET_WARNING;
#if !defined(_ASSIST_C)
#define _ASSIST_C
/*-------------------------------------------------------------------*/
/* Control block offsets fixed by architecture */
/*-------------------------------------------------------------------*/
/* Prefixed storage area offsets */
#define PSALCPUA 0x2F4 /* Logical CPU address */
#define PSAHLHI 0x2F8 /* Locks held indicators */
/* Bit settings for PSAHLHI */
#define PSACMSLI 0x00000002 /* CMS lock held indicator */
#define PSALCLLI 0x00000001 /* Local lock held indicator */
#define PSACSTK 0x380 /* Ptr to FRR stack */
#define PSALSFCC 0x3F4 /* Branch addr if stack full */
#define PSAXMFLG 0x49C /* Cross Memory Flags */
/* Bit settings for PSAXMFLG */
#define PSAXMODE 0x40 /* 0=Primary, 1=Secondary */
#define PSAXMCR3 0x5C4 /* CR3 & CR4 in PSA */
/* Address space control block offsets */
#define ASCBLOCK 0x080 /* Local lock */
#define ASCBLSWQ 0x084 /* Local lock suspend queue */
/* Lock interface table offsets */
#define LITOLOC (-16) /* Obtain local error exit */
#define LITRLOC (-12) /* Release local error exit */
#define LITOCMS (-8) /* Obtain CMS error exit */
#define LITRCMS (-4) /* Release CMS error exit */
#endif /*!defined(_ASSIST_C)*/
/* The macro below allows each assist instruction to execute in a virtual
machine. Per GA22-7072-0, these assist instructions must co-exist with
ECPS:VM if present (whether enabled or disabled), so that MVS running
as a guest of VM can use these assists. This is the "Virtual Machine
Extended Facility Assist" feature, also known as "370E" in VM. The macro
will allow execution of these privileged assist instructions when the
real PSW is in the problem state -- if and only if the guest virtual
machine PSW is in the virtual supervisor state (ECPSVM_CR6_VIRTPROB=0)
and the 370E feature is enabled (ECPS_CR6_VMMVSAS=1). Otherwise, the
PRIV_CHECK macro is invoked to cause a privileged operation exception.
*/
#define GUEST_CHECK( ) \
if (PROBSTATE( ®s->psw )) \
{ \
if ((regs->CR_L(6) & (ECPSVM_CR6_VIRTPROB + ECPSVM_CR6_VMMVSAS)) != ECPSVM_CR6_VMMVSAS) \
PRIV_CHECK( regs ); \
}
#if !defined( FEATURE_S390_DAT ) && !defined( FEATURE_001_ZARCH_INSTALLED_FACILITY )
/*-------------------------------------------------------------------*/
/* E502 - Page Fix [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(fix_page)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
RADR mplp;
#define MPLPFAL 0x34
SSE( inst, regs, b1, effective_addr1, b2, effective_addr2 );
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK();
/* The Page Fix assist cannot return via the PTT_ERR( ) method as used
in most of the other assists here. Per GA22-7079-1 "IBM System/370
Assists for MVS", this assist must NOT exit to the next sequential
instruction. Instead, we follow the "simplified execution path"
described on page 3 of that documentation for Fix Page.
*/
regs->GR_L(14) = PSW_IA_FROM_IP(regs, 0);
mplp = ARCH_DEP( vfetch4 )( (effective_addr2 & ADDRESS_MAXWRAP( regs )),
USE_INST_SPACE, regs );
regs->GR_L(15) = ARCH_DEP( vfetch4 )( (( mplp+MPLPFAL ) & ADDRESS_MAXWRAP( regs )),
USE_INST_SPACE, regs );
SET_PSW_IA_AND_MAYBE_IP( regs, regs->GR_L(15) );
}
#endif /* !defined( FEATURE_S390_DAT ) && !defined( FEATURE_001_ZARCH_INSTALLED_FACILITY ) */
/*-------------------------------------------------------------------*/
/* E503 - SVC assist [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(svc_assist)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
PTT_ERR( "*E503 SVCA", effective_addr1, effective_addr2, regs->psw.IA_L );
/*INCOMPLETE: NO ACTION IS TAKEN, THE SVC IS UNASSISTED
AND MVS WILL HAVE TO HANDLE THE SITUATION*/
}
/*-------------------------------------------------------------------*/
/* E504 - Obtain Local Lock [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(obtain_local_lock)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
VADR ascb_addr; /* Virtual address of ASCB */
U32 hlhi_word; /* Highest lock held word */
VADR lit_addr; /* Virtual address of lock
interface table */
U32 lcpa; /* Logical CPU address */
VADR newia; /* Unsuccessful branch addr */
BYTE *mainstor; /* mainstor address */
U32 old; /* old value */
U32 new; /* new value */
int acc_mode = 0; /* access mode to use */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PERFORM_SERIALIZATION(regs);
/* MAINLOCK may be required if cmpxchg assists unavailable */
OBTAIN_MAINLOCK(regs);
{
if (ACCESS_REGISTER_MODE(®s->psw))
acc_mode = USE_PRIMARY_SPACE;
/* Load ASCB address from first operand location */
ascb_addr = ARCH_DEP(vfetch4) ( effective_addr1, acc_mode, regs );
/* Load locks held bits from second operand location */
hlhi_word = ARCH_DEP(vfetch4) ( effective_addr2, acc_mode, regs );
/* Fetch our logical CPU address from PSALCPUA */
lcpa = ARCH_DEP(vfetch4) ( effective_addr2 - 4, acc_mode, regs );
/* Get mainstor address of ASCBLOCK word */
mainstor = MADDRL (ascb_addr + ASCBLOCK, 4, b2, regs, ACCTYPE_WRITE, regs->psw.pkey);
/* The lock word should contain 0; use this as our compare value.
Swap in the CPU address in lpca */
old = 0;
new = CSWAP32(lcpa);
/* Try exchanging values; cmpxchg4 returns 0=success, !0=failure */
if (!cmpxchg4( &old, new, mainstor ))
{
/* Store the unchanged value into the second operand to
ensure suppression in the event of an access exception */
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set the local lock held bit in the second operand */
hlhi_word |= PSALCLLI;
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set register 13 to zero to indicate lock obtained */
regs->GR_L(13) = 0;
}
else
{
/* Fetch the lock interface table address from the
second word of the second operand, and load the
new instruction address and amode from LITOLOC */
lit_addr = ARCH_DEP(vfetch4) ( effective_addr2 + 4, acc_mode, regs ) + LITOLOC;
lit_addr &= ADDRESS_MAXWRAP(regs);
newia = ARCH_DEP(vfetch4) ( lit_addr, acc_mode, regs );
/* Save the link information in register 12 */
regs->GR_L(12) = PSW_IA_FROM_IP(regs, 0);
/* Copy LITOLOC into register 13 to signify obtain failure */
regs->GR_L(13) = newia;
/* Update the PSW instruction address */
SET_PSW_IA_AND_MAYBE_IP(regs, newia);
}
}
RELEASE_MAINLOCK(regs);
PERFORM_SERIALIZATION(regs);
} /* end function obtain_local_lock */
/*-------------------------------------------------------------------*/
/* E505 - Release Local Lock [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(release_local_lock)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
VADR ascb_addr; /* Virtual address of ASCB */
VADR lock_addr; /* Virtual addr of ASCBLOCK */
VADR susp_addr; /* Virtual addr of ASCBLSWQ */
U32 hlhi_word; /* Highest lock held word */
VADR lit_addr; /* Virtual address of lock
interface table */
U32 lock; /* Lock value */
U32 susp; /* Lock suspend queue */
U32 lcpa; /* Logical CPU address */
VADR newia; /* Unsuccessful branch addr */
int acc_mode = 0; /* access mode to use */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
/* Obtain main-storage access lock */
OBTAIN_MAINLOCK_UNCONDITIONAL(regs);
if (ACCESS_REGISTER_MODE(®s->psw))
acc_mode = USE_PRIMARY_SPACE;
/* Load ASCB address from first operand location */
ascb_addr = ARCH_DEP(vfetch4) ( effective_addr1, acc_mode, regs );
/* Load locks held bits from second operand location */
hlhi_word = ARCH_DEP(vfetch4) ( effective_addr2, acc_mode, regs );
/* Fetch our logical CPU address from PSALCPUA */
lcpa = ARCH_DEP(vfetch4) ( effective_addr2 - 4, acc_mode, regs );
/* Fetch the local lock and the suspend queue from the ASCB */
lock_addr = (ascb_addr + ASCBLOCK) & ADDRESS_MAXWRAP(regs);
susp_addr = (ascb_addr + ASCBLSWQ) & ADDRESS_MAXWRAP(regs);
lock = ARCH_DEP(vfetch4) ( lock_addr, acc_mode, regs );
susp = ARCH_DEP(vfetch4) ( susp_addr, acc_mode, regs );
/* Test if this CPU holds the local lock, and does not hold
any CMS lock, and the local lock suspend queue is empty */
if (lock == lcpa
&& (hlhi_word & (PSALCLLI | PSACMSLI)) == PSALCLLI
&& susp == 0)
{
/* Store the unchanged value into the second operand to
ensure suppression in the event of an access exception */
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Clear the local lock held bit in the second operand */
hlhi_word &= ~PSALCLLI;
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set the local lock to zero */
ARCH_DEP(vstore4) ( 0, lock_addr, acc_mode, regs );
/* Set register 13 to zero to indicate lock released */
regs->GR_L(13) = 0;
}
else
{
/* Fetch the lock interface table address from the
second word of the second operand, and load the
new instruction address and amode from LITRLOC */
lit_addr = ARCH_DEP(vfetch4) ( effective_addr2 + 4, acc_mode, regs ) + LITRLOC;
lit_addr &= ADDRESS_MAXWRAP(regs);
newia = ARCH_DEP(vfetch4) ( lit_addr, acc_mode, regs );
/* Save the link information in register 12 */
regs->GR_L(12) = PSW_IA_FROM_IP(regs, 0);
/* Copy LITRLOC into register 13 to signify release failure */
regs->GR_L(13) = newia;
/* Update the PSW instruction address */
SET_PSW_IA_AND_MAYBE_IP(regs, newia);
}
/* Release main-storage access lock */
RELEASE_MAINLOCK_UNCONDITIONAL(regs);
} /* end function release_local_lock */
/*-------------------------------------------------------------------*/
/* E506 - Obtain CMS Lock [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(obtain_cms_lock)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
VADR ascb_addr; /* Virtual address of ASCB */
U32 hlhi_word; /* Highest lock held word */
VADR lit_addr; /* Virtual address of lock
interface table */
VADR lock_addr; /* Lock address */
int lock_arn; /* Lock access register */
U32 lock; /* Lock value */
VADR newia; /* Unsuccessful branch addr */
BYTE *mainstor; /* mainstor address */
U32 old; /* old value */
U32 new; /* new value */
U32 locked = 0; /* status of cmpxchg4 result */
int acc_mode = 0; /* access mode to use */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PERFORM_SERIALIZATION(regs);
/* General register 11 contains the lock address */
lock_addr = regs->GR_L(11) & ADDRESS_MAXWRAP(regs);
lock_arn = 11;
/* MAINLOCK may be required if cmpxchg assists unavailable */
OBTAIN_MAINLOCK(regs);
{
if (ACCESS_REGISTER_MODE(®s->psw))
acc_mode = USE_PRIMARY_SPACE;
/* Load ASCB address from first operand location */
ascb_addr = ARCH_DEP(vfetch4) ( effective_addr1, acc_mode, regs );
/* Load locks held bits from second operand location */
hlhi_word = ARCH_DEP(vfetch4) ( effective_addr2, acc_mode, regs );
/* Fetch the lock addressed by general register 11 */
lock = ARCH_DEP(vfetch4) ( lock_addr, acc_mode, regs );
/* Validate that the address space meets criteria to obtain the CMS lock:
the target lock word pointed to by GR11 must be 0,
the LOCAL lock *must* be held on this CPU,
and the CMS lock must *not* be held on this CPU. */
if (lock == 0
&& (hlhi_word & (PSALCLLI | PSACMSLI)) == PSALCLLI)
{
/* Get mainstor address of lock word */
mainstor = MADDRL (lock_addr, 4, b2, regs, ACCTYPE_WRITE, regs->psw.pkey);
/* The lock word should contain 0; use this as our compare value.
Swap in the ASCB address from instruction operand 1 */
old = 0;
new = CSWAP32(ascb_addr);
/* Try exchanging values; cmpxchg4 returns 0=success, !0=failure */
locked = !cmpxchg4( &old, new, mainstor );
}
if (locked)
{
/* Store the unchanged value into the second operand to
ensure suppression in the event of an access exception */
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set the CMS lock held bit in the second operand */
hlhi_word |= PSACMSLI;
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set register 13 to zero to indicate lock obtained */
regs->GR_L(13) = 0;
}
else
{
/* Fetch the lock interface table address from the
second word of the second operand, and load the
new instruction address and amode from LITOCMS */
lit_addr = ARCH_DEP(vfetch4) ( effective_addr2 + 4, acc_mode, regs ) + LITOCMS;
lit_addr &= ADDRESS_MAXWRAP(regs);
newia = ARCH_DEP(vfetch4) ( lit_addr, acc_mode, regs );
/* Save the link information in register 12 */
regs->GR_L(12) = PSW_IA_FROM_IP(regs, 0);
/* Copy LITOCMS into register 13 to signify obtain failure */
regs->GR_L(13) = newia;
/* Update the PSW instruction address */
SET_PSW_IA_AND_MAYBE_IP(regs, newia);
}
}
RELEASE_MAINLOCK(regs);
PERFORM_SERIALIZATION(regs);
} /* end function obtain_cms_lock */
/*-------------------------------------------------------------------*/
/* E507 - Release CMS Lock [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(release_cms_lock)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
VADR ascb_addr; /* Virtual address of ASCB */
U32 hlhi_word; /* Highest lock held word */
VADR lit_addr; /* Virtual address of lock
interface table */
VADR lock_addr; /* Lock address */
int lock_arn; /* Lock access register */
U32 lock; /* Lock value */
U32 susp; /* Lock suspend queue */
VADR newia; /* Unsuccessful branch addr */
int acc_mode = 0; /* access mode to use */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
/* General register 11 contains the lock address */
lock_addr = regs->GR_L(11) & ADDRESS_MAXWRAP(regs);
lock_arn = 11;
/* Obtain main-storage access lock */
OBTAIN_MAINLOCK_UNCONDITIONAL(regs);
if (ACCESS_REGISTER_MODE(®s->psw))
acc_mode = USE_PRIMARY_SPACE;
/* Load ASCB address from first operand location */
ascb_addr = ARCH_DEP(vfetch4) ( effective_addr1, acc_mode, regs );
/* Load locks held bits from second operand location */
hlhi_word = ARCH_DEP(vfetch4) ( effective_addr2, acc_mode, regs );
/* Fetch the CMS lock and the suspend queue word */
lock = ARCH_DEP(vfetch4) ( lock_addr, acc_mode, regs );
susp = ARCH_DEP(vfetch4) ( lock_addr + 4, acc_mode, regs );
/* Test if current ASCB holds this lock, the locks held indicators
show a CMS lock is held, and the lock suspend queue is empty */
if (lock == ascb_addr
&& (hlhi_word & PSACMSLI)
&& susp == 0)
{
/* Store the unchanged value into the second operand to
ensure suppression in the event of an access exception */
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Clear the CMS lock held bit in the second operand */
hlhi_word &= ~PSACMSLI;
ARCH_DEP(vstore4) ( hlhi_word, effective_addr2, acc_mode, regs );
/* Set the CMS lock to zero */
ARCH_DEP(vstore4) ( 0, lock_addr, acc_mode, regs );
/* Set register 13 to zero to indicate lock released */
regs->GR_L(13) = 0;
}
else
{
/* Fetch the lock interface table address from the
second word of the second operand, and load the
new instruction address and amode from LITRCMS */
lit_addr = ARCH_DEP(vfetch4) ( effective_addr2 + 4, acc_mode, regs ) + LITRCMS;
lit_addr &= ADDRESS_MAXWRAP(regs);
newia = ARCH_DEP(vfetch4) ( lit_addr, acc_mode, regs );
/* Save the link information in register 12 */
regs->GR_L(12) = PSW_IA_FROM_IP(regs, 0);
/* Copy LITRCMS into register 13 to signify release failure */
regs->GR_L(13) = newia;
/* Update the PSW instruction address */
SET_PSW_IA_AND_MAYBE_IP(regs, newia);
}
/* Release main-storage access lock */
RELEASE_MAINLOCK_UNCONDITIONAL(regs);
} /* end function release_cms_lock */
#if !defined(FEATURE_TRACING)
/*-------------------------------------------------------------------*/
/* E508 - Trace SVC Interruption [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_svc_interruption)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E508 TRSVC",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
/*-------------------------------------------------------------------*/
/* E509 - Trace Program Interruption [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_program_interruption)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E509 TRPGM",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
/*-------------------------------------------------------------------*/
/* E50A - Trace Initial SRB Dispatch [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_initial_srb_dispatch)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E50A TRSRB",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
/*-------------------------------------------------------------------*/
/* E50B - Trace I/O Interruption [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_io_interruption)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E50B TRIO",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
/*-------------------------------------------------------------------*/
/* E50C - Trace Task Dispatch [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_task_dispatch)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E50C TRTSK",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
/*-------------------------------------------------------------------*/
/* E50D - Trace SVC Return [SSE] */
/*-------------------------------------------------------------------*/
DEF_INST(trace_svc_return)
{
int b1, b2; /* Values of base field */
VADR effective_addr1,
effective_addr2; /* Effective addresses */
SSE(inst, regs, b1, effective_addr1, b2, effective_addr2);
PER_ZEROADDR_XCHECK2( regs, b1, b2 );
GUEST_CHECK( );
/* Specification exception if operands are not on word boundary */
if ((effective_addr1 & 0x00000003) || (effective_addr2 & 0x00000003))
ARCH_DEP(program_interrupt) (regs, PGM_SPECIFICATION_EXCEPTION);
PTT_ERR("*E50D TRRTN",effective_addr1,effective_addr2,regs->psw.IA_L);
/*INCOMPLETE: NO TRACE ENTRY IS GENERATED*/
}
#endif /*!defined(FEATURE_TRACING)*/
/*-------------------------------------------------------------------*/
/* B242 - Add FRR [RRE] */
/*-------------------------------------------------------------------*/
DEF_INST( add_frr )
{
/* ADDFRR
Add new Functional-Recovery-Routine Stack entry
What little documentation that exists for this feature can be found
on page 9 of IBM System/370 Assists for MVS, GA22-7079-1 (the text
of which is copied verbatim further below), which can be found on
Bitsavers at:
* https://bitsavers.org/pdf/ibm/370/MVS/GA22-7079-1_IBM_System_370_Assists_for_MVS_2nd_ed_198110.pdf
The rest of the documentation regarding how it works is found in the
way MVS itself manages the FRR stack. The assist feature is part of
the 3033 Extensions.
r1 contains an entry value designating the type of FRR and action to
take by this assist. r2 contains the address of the FRR to be added.
*/
/* ADDFRR
"A new entry is added to the top of the current functional-
recovery-routine (FRR) stack. The entry is initialized with
values provided in general registers and with the PSW S bit
(bit 16)."
"Optionally, the contents of control registers 3 and 4 are
saved in an entry in a separate table."
"The general register designated by the r2 field provides the
logical address of the FRR entry point."
"Before instruction execution, the general register designated
by the r1 field provides three bytes that are stored in the
FRR entry and whose value determines if control registers 3
and 4 are to be stored as well. When instruction execution is
completed, the register designated by r1 contains the logical
address of the six-word work area within the new, current
FRR-stack entry."
"Logical location 380 hex contains the logical address of the
stack-table header. The stack-table header contains (1) a logical
address which is 32 less than the address of the first dynamic
entry in the stack table, (2) the logical address of the last
entry in the stack table, and (3) the logical address of the
current stack-table entry."
"At an offset from the beginning of the stack-table header is
found a table of stack-entry-extension entries. Optionally,
the contents of control registers 3 and 4 are saved in an
extension entry. One extension entry corresponds to each entry
in the stack table. The offset to the table of extension entries,
and the encoded length of an extension entry, are found in the
word at logical location BA8 hex."
Condition Code: The code remains unchanged.
Program Exceptions:
Access (storage operands)
Operation (when the instruction is not installed)
Privileged operation
Specification
*/
int r1, r2;
VADR frrstak;
VADR frrparm;
VADR frrlast;
U32 frrsize;
VADR frrcurr;
VADR frrnext;
VADR newia;
VADR cr_ptr;
BYTE entrycode;
U32 size, len;
VADR clear_vaddr;
static const BYTE zeros[256] = {0};
#define FRRSPARM 0x08
/* Entry code bits in r1 */
#define EUT 0x80
#define FULLXM 0x08
#define PRIMARY 0x04
#define LOCAL 0x02
#define GLOBAL 0x01
#define HOME 0x00
RRE( inst, regs, r1, r2 );
PRIV_CHECK( regs );
/* Obtain needed values from the FRR stack pointers */
frrstak = ARCH_DEP( vfetch4 )( PSACSTK, USE_PRIMARY_SPACE, regs ) & ADDRESS_MAXWRAP( regs );
frrparm = ARCH_DEP( vfetch4 )( (frrstak + 0), USE_PRIMARY_SPACE, regs ) & ADDRESS_MAXWRAP( regs );
frrlast = ARCH_DEP( vfetch4 )( (frrstak + 4) & ADDRESS_MAXWRAP( regs ), USE_PRIMARY_SPACE, regs ) & ADDRESS_MAXWRAP( regs );
frrsize = ARCH_DEP( vfetch4 )( (frrstak + 8) & ADDRESS_MAXWRAP( regs ), USE_PRIMARY_SPACE, regs );
frrcurr = ARCH_DEP( vfetch4 )( (frrstak + 12) & ADDRESS_MAXWRAP( regs ), USE_PRIMARY_SPACE, regs ) & ADDRESS_MAXWRAP( regs );
frrnext = (frrcurr + frrsize) & ADDRESS_MAXWRAP( regs );
/* Determine if FRR stack is full. If yes, then
branch to the system supplied code at PSALFSCC
*/
if (frrnext > frrlast)
{
newia = ARCH_DEP( vfetch4 )( PSALSFCC, USE_PRIMARY_SPACE, regs ) & ADDRESS_MAXWRAP( regs );
SET_PSW_IA_AND_MAYBE_IP( regs, newia );
return;
}
/* Perform exactly one of the following three functions based on the entry code from r1 */
entrycode = regs->GR_LHLCL( r1 );
/* 1. SETFRR A,MODE=HOME (no LOCAL/GLOBAL or EUT specification) */
if (entrycode == HOME)
{
/* Set the FRR entry point from r2 in the stack */
ARCH_DEP( vstore4 )( regs->GR_L(r2), frrnext, USE_PRIMARY_SPACE, regs );
}
/* 2. SETFRR A,MODE=(HOME, with any combination of LOCAL or GLOBAL or EUT=YES. */
else if ((!(entrycode & (FULLXM + PRIMARY))) && (entrycode & (EUT + GLOBAL + LOCAL)))
{
/* Set the FRR entry point from r2 in the stack */
ARCH_DEP( vstore4 )( regs->GR_L(r2) | 0x00000001, frrnext, USE_PRIMARY_SPACE, regs );
/* The entry code is stored in the FRR stack */
ARCH_DEP( vstoreb )( entrycode, (frrnext + 7) & ADDRESS_MAXWRAP( regs ), USE_PRIMARY_SPACE, regs );
}
/* 3. SETFRR A,MODE=(FULLXM | PRIMARY, with any or no combination of LOCAL or GLOBAL or EUT=YES. */
else
{
BYTE cr34[8]; // CR3 and CR4
/* Set the FRR entry point from r2 in the stack */
ARCH_DEP( vstore4 )( regs->GR_L(r2) | 0x00000001, frrnext, USE_PRIMARY_SPACE, regs );
/* Check if in secondary access mode; if yes turn on secondary bit in the entry code */
if (ARCH_DEP( vfetchb )( (PSAXMFLG & ADDRESS_MAXWRAP( regs )), USE_PRIMARY_SPACE, regs ) & PSAXMODE)
entrycode |= PSAXMODE; // indicate to FRR in secondary mode
/* The entry code is stored in the FRR stack */
ARCH_DEP( vstoreb )( entrycode, ((frrnext + 7) & ADDRESS_MAXWRAP( regs )), USE_PRIMARY_SPACE, regs );
/* Compute the address of the FRR area where CR3 and CR4 are copied from the PSA */
cr_ptr = frrnext - frrparm;
cr_ptr = cr_ptr >> 2;
cr_ptr = (frrstak + cr_ptr + 120) & ADDRESS_MAXWRAP( regs );
/* Copy CR3 and CR4 values from PSA to computed FRR area */
ARCH_DEP( vfetchc )( cr34, 8-1, PSAXMCR3, USE_PRIMARY_SPACE, regs );
ARCH_DEP( vstorec )( cr34, 8-1, cr_ptr, 0, regs );
}
/* Update the FRR stack pointers to point to the newly added FRR */
ARCH_DEP( vstore4 )( frrnext, (frrstak + 12) & ADDRESS_MAXWRAP( regs ), USE_PRIMARY_SPACE, regs );
/* Return with the FRRSPARM area address in r1 per the assist documentation */
regs->GR_L(r1) = (frrnext + FRRSPARM) & ADDRESS_MAXWRAP( regs );
/* Initialize (clear) the rest of the FRR stack */
clear_vaddr = (frrnext + 8) & ADDRESS_MAXWRAP( regs );
len = 256;
size = frrsize;
while (size)
{
if (len > size) len = size;
ARCH_DEP( vstorec )( zeros, len-1, clear_vaddr, 0, regs );
size -= len;
clear_vaddr += len;
clear_vaddr &= ADDRESS_MAXWRAP( regs );
}
}
#if !defined(_GEN_ARCH)
#if defined(_ARCH_NUM_1)
#define _GEN_ARCH _ARCH_NUM_1
#include "assist.c"
#endif
#if defined(_ARCH_NUM_2)
#undef _GEN_ARCH
#define _GEN_ARCH _ARCH_NUM_2
#include "assist.c"
#endif
#endif /*!defined(_GEN_ARCH)*/