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cmpsc_2012.c
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cmpsc_2012.c
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/* CMPSC_2012.C (C) Copyright "Fish" (David B. Trout), 2012-2019 */
/* (c) Bernard van der Helm, 2000-2012 */
/* S/390 Compression Call Instruction Functions */
/* */
/* Released under "The Q Public License Version 1" */
/* (http://www.hercules-390.org/herclic.html) as modifications to */
/* Hercules. */
/*-------------------------------------------------------------------*/
/* This module implements ESA/390 Compression Call instruction as */
/* described in SA22-7832-08 zArchitecture Principles of Operation */
/* and in great detail by "SA22-7208-01 ESA/390 Data Compression". */
/* Please also note that it was designed as written for use by both */
/* the primary Hercules instruction engine as well as by a separate */
/* stand alone testing tool utility from outside of Hercules. */
/*-------------------------------------------------------------------*/
/*-------------------------------------------------------------------*/
/* Additional credits and copyrights: */
/* */
/* The technique of expanding symbols until CBN# zero is reached */
/* and then expanding 8 symbols at a time was borrowed from the */
/* previous version of Hercules and is thus Bernard van der Helm's */
/* idea and not mine. Bernard gets all the credit for this technique */
/* and not me. The technique of using a cache of previously expanded */
/* symbols is not my own. It is the exact same technique that the */
/* previous version of Hercules was using and thus was Bernard's */
/* idea as well and not my own. Bernard gets all the credit for this */
/* technique as well. Both techniques are copyrighted by him. */
/* */
/* The basic compression/expansion algorithms which are implemented */
/* however, are the exact algorithms documented by IBM in the manual */
/* SA22-7832-08 zArchitecture Principles of Operation. */
/* */
/* All *OTHER* techniques (bit extraction macros, the index get/put */
/* functions, the dictionary extraction functions and their accom- */
/* panying memory access functions to save a call to MADDR) are all */
/* techniques copyrighted by me and licensed to Hercules. */
/* */
/* -- Fish (David B. Trout), Feb. 2012 */
/*-------------------------------------------------------------------*/
#include "hstdinc.h" // (MUST be first #include in EVERY source file)
DISABLE_GCC_UNUSED_FUNCTION_WARNING;
#define _CMPSC_C_
#define _HENGINE_DLL_
#if !defined( NOT_HERC ) // (building Hercules?)
#include "hercules.h"
#include "opcode.h"
#include "inline.h"
#endif
#include "cmpsc.h" // (Master header for both)
#if defined( FEATURE_CMPSC )
///////////////////////////////////////////////////////////////////////////////
// Symbols Cache Control Entry
#ifndef EXP_ONCE // (we only need to define these once)
#define EXP_ONCE // (we only need to define these once)
#ifdef CMPSC_SYMCACHE // (Symbol caching option)
struct SYMCTL // Symbol Cache Control Entry
{
U16 idx; // Cache index (sym's pos in cache)
U16 len; // Symbol length (sym's expanded len)
};
typedef struct SYMCTL SYMCTL;
#endif // CMPSC_SYMCACHE // (we only need to define this once)
///////////////////////////////////////////////////////////////////////////////
// EXPAND Index Symbol parameters block
struct EXPBLK // EXPAND Index Symbol parameters block
{
#ifdef CMPSC_SYMCACHE // (Symbol caching option)
SYMCTL symcctl[ MAX_DICT_ENTRIES ]; // Symbols cache control entries
U8 symcache[ CMPSC_SYMCACHE_SIZE ]; // Previously expanded symbols
U16 symindex; // Next available cache location
#endif // CMPSC_SYMCACHE // (Symbol caching option)
DCTBLK dctblk; // GetDCT parameters block
ECEBLK eceblk; // GetECE parameters block
MEMBLK op1blk; // Operand-1 memory access control block
MEMBLK op2blk; // Operand-2 memory access control block
ECE ece; // Expansion Character Entry data
U16 symlen; // Working symbol length value
U16 index; // SRC Index value
U8 SRC_bytes; // Number of bytes to adjust the SRC ptr/len by
U8 rc; // TRUE == success (cc), FALSE == failure (pic)
};
typedef struct EXPBLK EXPBLK;
#endif // EXP_ONCE // (we only need to define these once)
///////////////////////////////////////////////////////////////////////////////
// ZeroPadOp1 only if facility was enabled for this build architecture...
#if defined( FEATURE_047_CMPSC_ENH_FACILITY )
#undef ZERO_PAD_OP1
#define ZERO_PAD_OP1( pCMPSCBLK, pOp1MemBlk ) \
if (pCMPSCBLK->zp) /* (do zero padding?) */ \
ARCH_DEP( ZeroPadOp1 )( pCMPSCBLK, pOp1MemBlk );
#else // !defined( FEATURE_047_CMPSC_ENH_FACILITY )
#undef ZERO_PAD_OP1
#define ZERO_PAD_OP1( pCMPSCBLK, pOp1MemBlk ) \
UNREFERENCED( pOp1MemBlk );
#endif // defined( FEATURE_047_CMPSC_ENH_FACILITY )
///////////////////////////////////////////////////////////////////////////////
// Zero-padding
#if defined( FEATURE_047_CMPSC_ENH_FACILITY )
static CMPSC_INLINE void (CMPSC_FASTCALL ARCH_DEP( ZeroPadOp1 ))( CMPSCBLK* pCMPSCBLK, MEMBLK* pOp1MemBlk )
{
U64 pOp1 = pCMPSCBLK->pOp1; // (operand-1 output)
U64 nLen1 = pCMPSCBLK->nLen1; // (operand-1 length)
if (1
&& !(pCMPSCBLK->regs->GR_L(0) & 0x100) // (compression?)
&& pCMPSCBLK->cbn // (partial byte?)
&& nLen1 // (rem >= 1 byte?)
)
{
pOp1++; // (skip past byte)
nLen1--; // (length remaining)
}
pOp1 &= ADDRESS_MAXWRAP( pCMPSCBLK->regs ); // (wrap if needed)
MEMBLK_BUMP( pOp1MemBlk, pOp1 ); // (bump if needed)
if (pOp1 & CMPSC_ZP_MASK) // (is padding needed?)
{
U16 nPadAmt = ((U16)CMPSC_ZP_BYTES - (U16)(pOp1 & CMPSC_ZP_MASK));
if (nLen1 >= (U64) nPadAmt) // (enough room for pad?)
{
static U8 zeroes[ (1 << MAX_CMPSC_ZP_BITS) ] = {0};
store_op_str( zeroes, nPadAmt-1, pOp1, pOp1MemBlk );
}
}
}
#endif // defined( FEATURE_047_CMPSC_ENH_FACILITY )
///////////////////////////////////////////////////////////////////////////////
// Separate return functions for easier debugging... (it's much easier to
// set a breakpoint here and then examine the stack to see where you came
// from than it is to set breakpoints everywhere each function is called)
#if !defined( NOT_HERC ) // (building Hercules?)
#undef CMPSC_RETFUNCS // (rebuild each time)
#endif // (else do only once)
#ifndef CMPSC_RETFUNCS // (one time if Utility, each time if Herc)
#define CMPSC_RETFUNCS // (one time if Utility, each time if Herc)
PUSH_GCC_WARNINGS()
DISABLE_GCC_UNUSED_FUNCTION_WARNING;
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( ERR ))( CMPSCBLK* pCMPSCBLK, MEMBLK* pOp1MemBlk )
{
UNREFERENCED( pOp1MemBlk );
pCMPSCBLK->pic = 7;
return FALSE;
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( CC3 ))( CMPSCBLK* pCMPSCBLK, MEMBLK* pOp1MemBlk )
{
ZERO_PAD_OP1( pCMPSCBLK, pOp1MemBlk );
pCMPSCBLK->pic = 0;
pCMPSCBLK->cc = 3;
return TRUE;
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( CC1 ))( CMPSCBLK* pCMPSCBLK, MEMBLK* pOp1MemBlk )
{
ZERO_PAD_OP1( pCMPSCBLK, pOp1MemBlk );
pCMPSCBLK->pic = 0;
pCMPSCBLK->cc = 1;
return TRUE;
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( CC0 ))( CMPSCBLK* pCMPSCBLK, MEMBLK* pOp1MemBlk )
{
ZERO_PAD_OP1( pCMPSCBLK, pOp1MemBlk );
pCMPSCBLK->pic = 0;
pCMPSCBLK->cc = 0;
return TRUE;
}
//-----------------------------------------------------------------------------
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( EXPOK ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
UNREFERENCED( pCMPSCBLK );
UNREFERENCED( pEXPBLK );
return TRUE; // (success; keep going)
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( EXPERR ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
pEXPBLK->rc = ARCH_DEP( ERR )( pCMPSCBLK, &pEXPBLK->op1blk ); return FALSE; // (break)
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( EXPCC3 ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
pEXPBLK->rc = ARCH_DEP( CC3 )( pCMPSCBLK, &pEXPBLK->op1blk ); return FALSE; // (break)
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( EXPCC1 ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
pEXPBLK->rc = ARCH_DEP( CC1 )( pCMPSCBLK, &pEXPBLK->op1blk ); return FALSE; // (break)
}
static CMPSC_INLINE U8 (CMPSC_FASTCALL ARCH_DEP( EXPCC0 ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
pEXPBLK->rc = ARCH_DEP( CC0 )( pCMPSCBLK, &pEXPBLK->op1blk ); return FALSE; // (break)
}
POP_GCC_WARNINGS()
//-----------------------------------------------------------------------------
// (define simpler macros to make calling the return functions much easier)
#undef RETERR
#undef RETCC3
#undef RETCC1
#undef RETCC0
#undef EXP_RETOK
#undef EXP_RETERR
#undef EXP_RETCC3
#undef EXP_RETCC1
#undef EXP_RETCC0
#define RETERR( pOp1MemBlk ) return ARCH_DEP( ERR )( pCMPSCBLK, pOp1MemBlk ) // (failure)
#define RETCC3( pOp1MemBlk ) return ARCH_DEP( CC3 )( pCMPSCBLK, pOp1MemBlk ) // (stop)
#define RETCC1( pOp1MemBlk ) return ARCH_DEP( CC1 )( pCMPSCBLK, pOp1MemBlk ) // (stop)
#define RETCC0( pOp1MemBlk ) return ARCH_DEP( CC0 )( pCMPSCBLK, pOp1MemBlk ) // (stop)
#define EXP_RETOK() return ARCH_DEP( EXPOK )( pCMPSCBLK, pEXPBLK ) // (success; keep going)
#define EXP_RETERR() return ARCH_DEP( EXPERR )( pCMPSCBLK, pEXPBLK ) // (break)
#define EXP_RETCC3() return ARCH_DEP( EXPCC3 )( pCMPSCBLK, pEXPBLK ) // (break)
#define EXP_RETCC1() return ARCH_DEP( EXPCC1 )( pCMPSCBLK, pEXPBLK ) // (break)
#define EXP_RETCC0() return ARCH_DEP( EXPCC0 )( pCMPSCBLK, pEXPBLK ) // (break)
#endif // CMPSC_RETFUNCS
///////////////////////////////////////////////////////////////////////////////
// EXPAND Index Symbol; TRUE == success, FALSE == error; rc == return code
U8 (CMPSC_FASTCALL ARCH_DEP( cmpsc_Expand_Index ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK );
///////////////////////////////////////////////////////////////////////////////
// EXPANSION: TRUE == success (cc), FALSE == failure (pic)
U8 (CMPSC_FASTCALL ARCH_DEP( cmpsc_Expand ))( CMPSCBLK* pCMPSCBLK )
{
U64 nCPUAmt; // CPU determined processing limit
GetIndex** ppGetIndex; // Ptr to GetNextIndex table for this CDSS-1
GetIndex* pGetIndex; // Ptr to GetNextIndex function for this CBN
GIBLK giblk; // GetIndex parameters block
EXPBLK expblk; // EXPAND Index Symbol parameters block
U16 index[8]; // SRC Index values
U8 bits; // Number of bits per index
nCPUAmt = 0;
ppGetIndex = ARCH_DEP( GetIndexCDSSTab )[ pCMPSCBLK->cdss - 1 ];
pGetIndex = ppGetIndex [ pCMPSCBLK->cbn ];
bits = pCMPSCBLK->cdss + 8;
// Initialize GetIndex parameters block
memset( &giblk, 0, sizeof( giblk ));
giblk.pCMPSCBLK = pCMPSCBLK;
giblk.pMEMBLK = &expblk.op2blk; // (we get indexes from op-2)
giblk.pIndex = &index[0];
giblk.ppGetIndex = (void**) &pGetIndex;
// Initialize EXPAND Index Symbol parameters block
memset( &expblk, 0, sizeof( expblk ));
expblk.dctblk.regs = pCMPSCBLK->regs;
expblk.dctblk.arn = pCMPSCBLK->r2;
expblk.dctblk.pkey = pCMPSCBLK->regs->psw.pkey;
expblk.dctblk.pDict = pCMPSCBLK->pDict;
expblk.eceblk.pDCTBLK = &expblk.dctblk;
expblk.eceblk.max_index = 0xFFFF >> (16 - bits);
expblk.eceblk.pECE = &expblk.ece;
expblk.op1blk.arn = pCMPSCBLK->r1;
expblk.op1blk.regs = pCMPSCBLK->regs;
expblk.op1blk.pkey = pCMPSCBLK->regs->psw.pkey;
expblk.op2blk.arn = pCMPSCBLK->r2;
expblk.op2blk.regs = pCMPSCBLK->regs;
expblk.op2blk.pkey = pCMPSCBLK->regs->psw.pkey;
#ifdef CMPSC_EXPAND8
// Expand individual index symbols until CBN==0...
if ((pCMPSCBLK->cbn & 7) != 0)
{
while (nCPUAmt < (U64) pCMPSCBLK->nCPUAmt && (pCMPSCBLK->cbn & 7) != 0)
{
// Get index symbol...
if (unlikely( !(expblk.SRC_bytes = pGetIndex( &giblk ))))
RETCC0( &expblk.op1blk );
// Expand it...
expblk.index = index[0];
if (unlikely( !ARCH_DEP( cmpsc_Expand_Index )( pCMPSCBLK, &expblk )))
return expblk.rc;
// Bump source...
nCPUAmt += expblk.SRC_bytes;
pCMPSCBLK->pOp2 += expblk.SRC_bytes;
pCMPSCBLK->nLen2 -= expblk.SRC_bytes;
pCMPSCBLK->cbn += bits;
MEMBLK_BUMP( &expblk.op2blk, pCMPSCBLK->pOp2 );
// Bump destination...
pCMPSCBLK->pOp1 += expblk.symlen;
pCMPSCBLK->nLen1 -= expblk.symlen;
MEMBLK_BUMP( &expblk.op1blk, pCMPSCBLK->pOp1 );
}
}
// Now expand eight (8) index symbols at a time...
if ((pCMPSCBLK->cbn & 7) == 0)
{
GetIndex** ppGet8Index; // Ptr to GetNext8Index table for this CDSS-1
GetIndex* pGet8Index; // Ptr to GetNext8Index function for this CBN
CMPSCBLK save_cmpsc; // Work context
MEMBLK save_op1blk; // Work context
MEMBLK save_op2blk; // Work context
U8 i; // (work)
ppGet8Index = ARCH_DEP( Get8IndexCDSSTab )[ pCMPSCBLK->cdss - 1 ];
pGet8Index = ppGet8Index[ 0 ]; // (always CBN==0)
// Save context
memcpy( &save_cmpsc, pCMPSCBLK, sizeof( CMPSCBLK ));
memcpy( &save_op1blk, &expblk.op1blk, sizeof( MEMBLK ));
memcpy( &save_op2blk, &expblk.op2blk, sizeof( MEMBLK ));
while (nCPUAmt < (U64) pCMPSCBLK->nCPUAmt)
{
// Retrieve 8 index symbols from operand-2...
if (unlikely( !(expblk.SRC_bytes = pGet8Index( &giblk ))))
break;
// Bump source...
nCPUAmt += expblk.SRC_bytes;
pCMPSCBLK->pOp2 += expblk.SRC_bytes;
pCMPSCBLK->nLen2 -= expblk.SRC_bytes;
MEMBLK_BUMP( &expblk.op2blk, pCMPSCBLK->pOp2 );
// Expand each of the 8 individually into operand-1...
for (i=0; i < 8; i++)
{
expblk.index = index[i];
if (unlikely( !ARCH_DEP( cmpsc_Expand_Index )( pCMPSCBLK, &expblk )))
{
// Restore context
memcpy( pCMPSCBLK, &save_cmpsc, sizeof( CMPSCBLK ));
memcpy( &expblk.op1blk, &save_op1blk, sizeof( MEMBLK ));
memcpy( &expblk.op2blk, &save_op2blk, sizeof( MEMBLK ));
break; // (i < 8)
}
// Bump destination...
pCMPSCBLK->pOp1 += expblk.symlen;
pCMPSCBLK->nLen1 -= expblk.symlen;
// pCMPSCBLK->cbn += bits;
MEMBLK_BUMP( &expblk.op1blk, pCMPSCBLK->pOp1 );
}
if (i < 8)
break;
// Save context
memcpy( &save_cmpsc, pCMPSCBLK, sizeof( CMPSCBLK ));
memcpy( &save_op1blk, &expblk.op1blk, sizeof( MEMBLK ));
memcpy( &save_op2blk, &expblk.op2blk, sizeof( MEMBLK ));
}
}
#endif // CMPSC_EXPAND8
// Finish up any remainder...
while (nCPUAmt < (U64) pCMPSCBLK->nCPUAmt)
{
// Get index symbol...
if (unlikely( !(expblk.SRC_bytes = pGetIndex( &giblk ))))
RETCC0( &expblk.op1blk );
// Expand it...
expblk.index = index[0];
if (unlikely( !ARCH_DEP( cmpsc_Expand_Index )( pCMPSCBLK, &expblk )))
return expblk.rc;
// Bump source...
nCPUAmt += expblk.SRC_bytes;
pCMPSCBLK->pOp2 += expblk.SRC_bytes;
pCMPSCBLK->nLen2 -= expblk.SRC_bytes;
pCMPSCBLK->cbn += bits;
MEMBLK_BUMP( &expblk.op2blk, pCMPSCBLK->pOp2 );
// Bump destination...
pCMPSCBLK->pOp1 += expblk.symlen;
pCMPSCBLK->nLen1 -= expblk.symlen;
MEMBLK_BUMP( &expblk.op1blk, pCMPSCBLK->pOp1 );
}
RETCC3( &expblk.op1blk );
}
///////////////////////////////////////////////////////////////////////////////
// EXPAND Index Symbol; TRUE == success, FALSE == error; rc == return code
U8 (CMPSC_FASTCALL ARCH_DEP( cmpsc_Expand_Index ))( CMPSCBLK* pCMPSCBLK, EXPBLK* pEXPBLK )
{
U8 dicts; // Counts dictionary entries processed
if (unlikely( !pCMPSCBLK->nLen1 ))
EXP_RETCC1();
if (likely( pEXPBLK->index >= 256 ))
{
#ifdef CMPSC_SYMCACHE
// Check our cache of previously expanded index symbols
// to see if we've already expanded this symbol before
// and if we have room in the o/p buffer to expand it.
if (1
&& (pEXPBLK->symlen = pEXPBLK->symcctl[ pEXPBLK->index ].len) > 0
&& pEXPBLK->symlen <= pCMPSCBLK->nLen1
)
{
store_op_str( &pEXPBLK->symcache[ pEXPBLK->symcctl[ pEXPBLK->index ].idx ], pEXPBLK->symlen-1, pCMPSCBLK->pOp1, &pEXPBLK->op1blk );
}
else
#endif // CMPSC_SYMCACHE
{
// We need to expand this index symbol: fetch the ECE...
if (unlikely( !ARCH_DEP( GetECE )( pEXPBLK->index, &pEXPBLK->eceblk )))
EXP_RETERR();
if (pEXPBLK->ece.psl)
{
// Preceded (i.e. partial symbol)...
// Do we have room for the complete symbol?
if (unlikely( pCMPSCBLK->nLen1 < (pEXPBLK->symlen = pEXPBLK->ece.psl + pEXPBLK->ece.ofst)))
EXP_RETCC1();
dicts = 1;
do
{
// Expand this partial ("preceded") chunk of this index symbol...
store_op_str( pEXPBLK->ece.ec, pEXPBLK->ece.psl-1, pCMPSCBLK->pOp1 + pEXPBLK->ece.ofst, &pEXPBLK->op1blk );
// Get the ECE for the next chunk...
if (unlikely( !ARCH_DEP( GetECE )( pEXPBLK->ece.pptr, &pEXPBLK->eceblk )))
EXP_RETERR();
if (unlikely( ++dicts > 127 ))
EXP_RETERR();
}
while (pEXPBLK->ece.psl);
// we're done with the partial ("preceded") part of this
// symbol's expansion. Fall through to the "complete" symbol
// expansion logic to finish up this symbol's expansion...
}
else
{
// Unpreceded (i.e. complete symbol)...
// Do we have room for the complete symbol?
if (unlikely( pCMPSCBLK->nLen1 < (pEXPBLK->symlen = pEXPBLK->ece.csl)))
EXP_RETCC1();
}
// Complete the expansion of this index symbol...
store_op_str( pEXPBLK->ece.ec, pEXPBLK->ece.csl-1, pCMPSCBLK->pOp1, &pEXPBLK->op1blk );
#ifdef CMPSC_SYMCACHE
// If there's room for it, add this symbol to our expanded symbols cache
if (pEXPBLK->symlen <= (sizeof( pEXPBLK->symcache ) - pEXPBLK->symindex))
{
pEXPBLK->symcctl[ pEXPBLK->index ].len = pEXPBLK->symlen;
pEXPBLK->symcctl[ pEXPBLK->index ].idx = pEXPBLK->symindex;
// (add this symbol to our previously expanded symbols cache)
fetch_op_str( &pEXPBLK->symcache[ pEXPBLK->symindex ], pEXPBLK->symlen-1, pCMPSCBLK->pOp1, &pEXPBLK->op1blk );
pEXPBLK->symindex += pEXPBLK->symlen;
}
#endif // CMPSC_SYMCACHE
}
}
else // (pEXPBLK->index < 256)
{
// The index symbol is an alphabet entry (i.e. an index symbol
// corresponding to a one-byte symbol). The expanded symbol it
// represents is the value of the alphabet index symbol itself.
store_op_b( (U8)pEXPBLK->index, pCMPSCBLK->pOp1, &pEXPBLK->op1blk );
pEXPBLK->symlen = 1;
}
EXP_RETOK();
}
///////////////////////////////////////////////////////////////////////////////
// COMPRESSION: TRUE == success (cc), FALSE == failure (pgmck).
U8 (CMPSC_FASTCALL ARCH_DEP( cmpsc_Compress ))( CMPSCBLK* pCMPSCBLK )
{
U64 nCPUAmt; // CPU determined processing limit
U64 pBegOp2; // Ptr to beginning of operand-2
PutGetCBN* pPutGetCBN; // Ptr to PutGetCBN function for this CDSS-1
PutIndex** ppPutIndex; // Ptr to PutNextIndex table for this CDSS-1
PutIndex* pPutIndex; // Ptr to PutNextIndex function for this CBN
U64 pSymTab; // Symbol-Translation Table
GETSD* pGetSD; // Pointer to Get-Sibling-Descriptor function
CCE parent; // Parent Compression Character Entry data
CCE child; // Child Compression Character Entry data
SDE sibling; // Sibling Descriptor Entry data
MEMBLK op1blk; // Operand-1 memory access control block
MEMBLK op2blk; // Operand-2 memory access control block
DCTBLK dctblk; // GetDCT parameters block (cmp dict)
DCTBLK dctblk2; // GetDCT parameters block (exp dict)
CCEBLK cceblk; // GetCCE parameters block
SDEBLK sdeblk; // GetSDn parameters block
PIBLK piblk; // PutIndex parameters block
U16 parent_index; // Parent's CE Index value
U16 child_index; // Child's CE Index value
U16 sibling_index; // Sibling's SDE Index value
U16 max_index; // Maximum Index value
U16 children; // Counts children
U8 ccnum, scnum, byt; // (work variables)
U8 eodst, flag; // (work flags)
U8 bits; // Number of bits per index
U8 wrk[ MAX_SYMLEN ]; // (work buffer)
bits = 8 + pCMPSCBLK->cdss;
max_index = (0xFFFF >> (16 - bits));
pPutGetCBN = ARCH_DEP( PutGetCBNTab )[ pCMPSCBLK->cdss - 1 ];
ppPutIndex = ARCH_DEP( PutIndexCDSSTab )[ pCMPSCBLK->cdss - 1 ];
pPutIndex = ppPutIndex[ pCMPSCBLK->cbn ];
pSymTab = pCMPSCBLK->st ? pCMPSCBLK->pDict + ((U32)pCMPSCBLK->stt << 7) : 0;
pGetSD = pCMPSCBLK->f1 ? ARCH_DEP( GetSD1 ) : ARCH_DEP( GetSD0 );
#define PUTSETCBN() pCMPSCBLK->cbn = pPutGetCBN( pPutIndex )
memset( &dctblk, 0, sizeof( dctblk ) );
memset( &dctblk2, 0, sizeof( dctblk ) );
dctblk.regs = pCMPSCBLK->regs;
dctblk.arn = pCMPSCBLK->r2;
dctblk.pkey = pCMPSCBLK->regs->psw.pkey;
dctblk.pDict = pCMPSCBLK->pDict;
dctblk2.regs = pCMPSCBLK->regs;
dctblk2.arn = pCMPSCBLK->r2;
dctblk2.pkey = pCMPSCBLK->regs->psw.pkey;
dctblk2.pDict = pCMPSCBLK->pDict + g_nDictSize[ pCMPSCBLK->cdss - 1 ];
cceblk.pDCTBLK = &dctblk;
cceblk.max_index = max_index;
cceblk.pCCE = NULL; // (filled in before each call)
memset( &cceblk.cce, 0, sizeof( cceblk.cce ) );
sdeblk.pDCTBLK = &dctblk;
sdeblk.pDCTBLK2 = &dctblk2;
sdeblk.pSDE = &sibling;
sdeblk.pCCE = NULL; // (depends if first sibling)
memset( &sdeblk.sde, 0, sizeof( sdeblk.sde ) );
piblk.ppPutIndex = (void**) &pPutIndex;
piblk.pCMPSCBLK = pCMPSCBLK;
piblk.pMEMBLK = &op1blk; // (we put indexes into op-1)
piblk.index = 0; // (filled in before each call)
op1blk.arn = pCMPSCBLK->r1;
op1blk.regs = pCMPSCBLK->regs;
op1blk.pkey = pCMPSCBLK->regs->psw.pkey;
op1blk.vpagebeg = 0;
op1blk.maddr[0] = 0;
op1blk.maddr[1] = 0;
op2blk.arn = pCMPSCBLK->r2;
op2blk.regs = pCMPSCBLK->regs;
op2blk.pkey = pCMPSCBLK->regs->psw.pkey;
op2blk.vpagebeg = 0;
op2blk.maddr[0] = 0;
op2blk.maddr[1] = 0;
// GET STARTED...
pBegOp2 = pCMPSCBLK->pOp2;
eodst = (pCMPSCBLK->nLen1 < (2 + ((pCMPSCBLK->cbn > (16 - bits)) ? 1 : 0)))
? TRUE : FALSE;
nCPUAmt = 0;
//-------------------------------------------------------------------------
// PROGRAMMING NOTE: the following compression algorithm follows exactly
// the algorithm documented by IBM in their Principles of Operation manual.
// Most labels and all primary comments match the algorithm's flowchart.
//-------------------------------------------------------------------------
cmp1:
// Another SRC char exists?
// No, set CC0 and endop.
if (unlikely( !pCMPSCBLK->nLen2 ))
{
PUTSETCBN();
RETCC0( &op1blk );
}
cmp2:
// Another DST index position exists?
// No, set CC1 and endop.
if (unlikely( eodst ))
{
PUTSETCBN();
RETCC1( &op1blk );
}
if (unlikely( nCPUAmt >= (U64) pCMPSCBLK->nCPUAmt )) // (max bytes processed?)
{
PUTSETCBN();
RETCC3( &op1blk ); // (return cc3 to caller)
}
children = 0;
// Use next SRC char as index of alphabet entry.
// Call this entry the parent.
// Advance 1 byte in SRC.
parent_index = (U16) fetch_op_b( pCMPSCBLK->pOp2, &op2blk );
cceblk.pCCE = &parent;
if (unlikely( !ARCH_DEP( GetCCE )( parent_index, &cceblk )))
{
PUTSETCBN();
RETERR( &op1blk );
}
nCPUAmt++;
pCMPSCBLK->pOp2++;
pCMPSCBLK->nLen2--;
cmp3:
MEMBLK_BUMP( &op1blk, pCMPSCBLK->pOp1 );
MEMBLK_BUMP( &op2blk, pCMPSCBLK->pOp2 );
// CCT=0?
// Yes, goto cmp9;
if (!parent.cct)
goto cmp9;
//cmp4:
ccnum = 0;
// Set flag=1.
flag = TRUE;
// Another SRC char exists?
// No, goto cmp13;
if (unlikely( !pCMPSCBLK->nLen2 ))
goto cmp13;
// (REPEAT FOR EACH CC)...
cmp5:
// ---------------- UNROLL #1 ----------------
// Next SRC char = CC?
// Yes, goto cmp10;
byt = fetch_op_b( pCMPSCBLK->pOp2, &op2blk );
if (byt == parent.cc[ ccnum ])
goto cmp10;
// Set flag=0;
flag = FALSE;
// Another CC?
// Yes, goto cmp5;
if (++ccnum >= parent.cct)
goto cmp5E;
// ---------------- UNROLL #2 ----------------
// Next SRC char = CC?
// Yes, goto cmp10;
if (byt == parent.cc[ ccnum ])
goto cmp10;
// Set flag=0;
// flag = FALSE; // (already done by UNROLL #1)
// Another CC?
// Yes, goto cmp5;
if (++ccnum >= parent.cct)
goto cmp5E;
// ---------------- UNROLL #3 ----------------
// Next SRC char = CC?
// Yes, goto cmp10;
if (byt == parent.cc[ ccnum ])
goto cmp10;
// Set flag=0;
// flag = FALSE; // (already done by UNROLL #1)
// Another CC?
// Yes, goto cmp5;
if (++ccnum >= parent.cct)
goto cmp5E;
// ---------------- UNROLL #4 ----------------
// Next SRC char = CC?
// Yes, goto cmp10;
if (byt == parent.cc[ ccnum ])
goto cmp10;
// Set flag=0;
// flag = FALSE; // (already done by UNROLL #1)
// Another CC?
// Yes, goto cmp5;
if (++ccnum >= parent.cct)
goto cmp5E;
// ---------------- UNROLL #5 ----------------
// Next SRC char = CC?
// Yes, goto cmp10;
if (byt == parent.cc[ ccnum ])
goto cmp10;
// Set flag=0;
// flag = FALSE; // (already done by UNROLL #1)
// Another CC?
// Yes, goto cmp5;
if (++ccnum < parent.cct) // (** last UNROLL **)
goto cmp5;
cmp5E:
// CCT indicates more children?
// No, goto cmp8;
if (!parent.mc)
goto cmp8;
//cmp6:
// Set SD index = CPTR + #of CC's.
sibling_index = (parent.cptr + parent.cct);
sdeblk.pCCE = &parent;
if (unlikely( !pGetSD( sibling_index, &sdeblk )))
{
PUTSETCBN();
RETERR( &op1blk );
}
scnum = 0;
// (REPEAT FOR EACH SC IN SD)...
cmp7:
// ---------------- UNROLL #1 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
byt = fetch_op_b( pCMPSCBLK->pOp2, &op2blk );
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #2 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #3 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #4 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #5 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #6 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum >= sibling.sct)
goto cmp7E;
// ---------------- UNROLL #7 ----------------
// Next SRC char = SC?
// Yes, goto cmp12;
if (byt == sibling.sc[ scnum ])
goto cmp12;
// Another SC?
// Yes, goto cmp7;
if (++scnum < sibling.sct) // (** last UNROLL **)
goto cmp7;
cmp7E:
// SCT indicates more children?
// No, goto cmp8;
if (!sibling.ms)
goto cmp8;
// Set SD index = current SD index + #of SC's + 1.
sibling_index += sibling.sct + 1;
sdeblk.pCCE = NULL;
if (unlikely( !pGetSD( sibling_index, &sdeblk )))
{
PUTSETCBN();
RETERR( &op1blk );
}
scnum = 0;
// goto cmp7;
goto cmp7;
cmp8:
// Store parent index in DST.
// Advance 1 index in DST.
// goto cmp2;
if (unlikely( (pCMPSCBLK->pOp2 - pBegOp2) > MAX_SYMLEN ))
{
PUTSETCBN();
RETERR( &op1blk );
}
pBegOp2 = pCMPSCBLK->pOp2;
piblk.index = (!pCMPSCBLK->st) ? parent_index
: fetch_dct_hw( pSymTab + (parent_index << 1), pCMPSCBLK );
eodst = pPutIndex( &piblk );
goto cmp2;
cmp9:
// Store parent index in DST.
// Advance 1 index in DST.
// goto cmp1;
if (unlikely( (pCMPSCBLK->pOp2 - pBegOp2) > MAX_SYMLEN ))
{
PUTSETCBN();
RETERR( &op1blk );
}
pBegOp2 = pCMPSCBLK->pOp2;
piblk.index = (!pCMPSCBLK->st) ? parent_index
: fetch_dct_hw( pSymTab + (parent_index << 1), pCMPSCBLK );
eodst = pPutIndex( &piblk );