/* ----------------------------------------------------------------------------- * * (c) The University of Glasgow 2004-2013 * * This file is included at the top of all .cmm source files (and * *only* .cmm files). It defines a collection of useful macros for * making .cmm code a bit less error-prone to write, and a bit easier * on the eye for the reader. * * For the syntax of .cmm files, see the parser in ghc/compiler/cmm/CmmParse.y. * * Accessing fields of structures defined in the RTS header files is * done via automatically-generated macros in DerivedConstants.h. For * example, where previously we used * * CurrentTSO->what_next = x * * in C-- we now use * * StgTSO_what_next(CurrentTSO) = x * * where the StgTSO_what_next() macro is automatically generated by * mkDerivedConstants.c. If you need to access a field that doesn't * already have a macro, edit that file (it's pretty self-explanatory). * * -------------------------------------------------------------------------- */ #ifndef CMM_H #define CMM_H /* * In files that are included into both C and C-- (and perhaps * Haskell) sources, we sometimes need to conditionally compile bits * depending on the language. CMINUSMINUS==1 in .cmm sources: */ #define CMINUSMINUS 1 #include "ghcconfig.h" /* ----------------------------------------------------------------------------- Types The following synonyms for C-- types are declared here: I8, I16, I32, I64 MachRep-style names for convenience W_ is shorthand for the word type (== StgWord) F_ shorthand for float (F_ == StgFloat == C's float) D_ shorthand for double (D_ == StgDouble == C's double) CInt has the same size as an int in C on this platform CLong has the same size as a long in C on this platform --------------------------------------------------------------------------- */ #define I8 bits8 #define I16 bits16 #define I32 bits32 #define I64 bits64 #define P_ gcptr #if SIZEOF_VOID_P == 4 #define W_ bits32 /* Maybe it's better to include MachDeps.h */ #define TAG_BITS 2 #elif SIZEOF_VOID_P == 8 #define W_ bits64 /* Maybe it's better to include MachDeps.h */ #define TAG_BITS 3 #else #error Unknown word size #endif /* * The RTS must sometimes UNTAG a pointer before dereferencing it. * See the wiki page Commentary/Rts/HaskellExecution/PointerTagging */ #define TAG_MASK ((1 << TAG_BITS) - 1) #define UNTAG(p) (p & ~TAG_MASK) #define GETTAG(p) (p & TAG_MASK) #if SIZEOF_INT == 4 #define CInt bits32 #elif SIZEOF_INT == 8 #define CInt bits64 #else #error Unknown int size #endif #if SIZEOF_LONG == 4 #define CLong bits32 #elif SIZEOF_LONG == 8 #define CLong bits64 #else #error Unknown long size #endif #define F_ float32 #define D_ float64 #define L_ bits64 #define V16_ bits128 #define V32_ bits256 #define V64_ bits512 #define SIZEOF_StgDouble 8 #define SIZEOF_StgWord64 8 /* ----------------------------------------------------------------------------- Misc useful stuff -------------------------------------------------------------------------- */ #define ccall foreign "C" #define NULL (0::W_) #define STRING(name,str) \ section "rodata" { \ name : bits8[] str; \ } \ #ifdef TABLES_NEXT_TO_CODE #define RET_LBL(f) f##_info #else #define RET_LBL(f) f##_ret #endif #ifdef TABLES_NEXT_TO_CODE #define ENTRY_LBL(f) f##_info #else #define ENTRY_LBL(f) f##_entry #endif /* ----------------------------------------------------------------------------- Byte/word macros Everything in C-- is in byte offsets (well, most things). We use some macros to allow us to express offsets in words and to try to avoid byte/word confusion. -------------------------------------------------------------------------- */ #define SIZEOF_W SIZEOF_VOID_P #define W_MASK (SIZEOF_W-1) #if SIZEOF_W == 4 #define W_SHIFT 2 #elif SIZEOF_W == 8 #define W_SHIFT 3 #endif /* Converting quantities of words to bytes */ #define WDS(n) ((n)*SIZEOF_W) /* * Converting quantities of bytes to words * NB. these work on *unsigned* values only */ #define BYTES_TO_WDS(n) ((n) / SIZEOF_W) #define ROUNDUP_BYTES_TO_WDS(n) (((n) + SIZEOF_W - 1) / SIZEOF_W) /* TO_W_(n) converts n to W_ type from a smaller type */ #if SIZEOF_W == 4 #define TO_W_(x) %sx32(x) #define HALF_W_(x) %lobits16(x) #elif SIZEOF_W == 8 #define TO_W_(x) %sx64(x) #define HALF_W_(x) %lobits32(x) #endif #if SIZEOF_INT == 4 && SIZEOF_W == 8 #define W_TO_INT(x) %lobits32(x) #elif SIZEOF_INT == SIZEOF_W #define W_TO_INT(x) (x) #endif #if SIZEOF_LONG == 4 && SIZEOF_W == 8 #define W_TO_LONG(x) %lobits32(x) #elif SIZEOF_LONG == SIZEOF_W #define W_TO_LONG(x) (x) #endif /* ----------------------------------------------------------------------------- Heap/stack access, and adjusting the heap/stack pointers. -------------------------------------------------------------------------- */ #define Sp(n) W_[Sp + WDS(n)] #define Hp(n) W_[Hp + WDS(n)] #define Sp_adj(n) Sp = Sp + WDS(n) /* pronounced "spadge" */ #define Hp_adj(n) Hp = Hp + WDS(n) /* ----------------------------------------------------------------------------- Assertions and Debuggery -------------------------------------------------------------------------- */ #ifdef DEBUG #define ASSERT(predicate) \ if (predicate) { \ /*null*/; \ } else { \ foreign "C" _assertFail(NULL, __LINE__) never returns; \ } #else #define ASSERT(p) /* nothing */ #endif #ifdef DEBUG #define DEBUG_ONLY(s) s #else #define DEBUG_ONLY(s) /* nothing */ #endif /* * The IF_DEBUG macro is useful for debug messages that depend on one * of the RTS debug options. For example: * * IF_DEBUG(RtsFlags_DebugFlags_apply, * foreign "C" fprintf(stderr, stg_ap_0_ret_str)); * * Note the syntax is slightly different to the C version of this macro. */ #ifdef DEBUG #define IF_DEBUG(c,s) if (RtsFlags_DebugFlags_##c(RtsFlags) != 0::I32) { s; } #else #define IF_DEBUG(c,s) /* nothing */ #endif /* ----------------------------------------------------------------------------- Entering It isn't safe to "enter" every closure. Functions in particular have no entry code as such; their entry point contains the code to apply the function. ToDo: range should end in N_CLOSURE_TYPES-1, not N_CLOSURE_TYPES, but switch doesn't allow us to use exprs there yet. If R1 points to a tagged object it points either to * A constructor. * A function with arity <= TAG_MASK. In both cases the right thing to do is to return. Note: it is rather lucky that we can use the tag bits to do this for both objects. Maybe it points to a brittle design? Indirections can contain tagged pointers, so their tag is checked. -------------------------------------------------------------------------- */ #ifdef PROFILING // When profiling, we cannot shortcut ENTER() by checking the tag, // because LDV profiling relies on entering closures to mark them as // "used". #define LOAD_INFO(ret,x) \ info = %INFO_PTR(UNTAG(x)); #define UNTAG_IF_PROF(x) UNTAG(x) #else #define LOAD_INFO(ret,x) \ if (GETTAG(x) != 0) { \ ret(x); \ } \ info = %INFO_PTR(x); #define UNTAG_IF_PROF(x) (x) /* already untagged */ #endif // We need two versions of ENTER(): // - ENTER(x) takes the closure as an argument and uses return(), // for use in civilized code where the stack is handled by GHC // // - ENTER_NOSTACK() where the closure is in R1, and returns are // explicit jumps, for use when we are doing the stack management // ourselves. #define ENTER(x) ENTER_(return,x) #define ENTER_R1() ENTER_(RET_R1,R1) #define RET_R1(x) jump %ENTRY_CODE(Sp(0)) [R1] #define ENTER_(ret,x) \ again: \ W_ info; \ LOAD_INFO(ret,x) \ switch [INVALID_OBJECT .. N_CLOSURE_TYPES] \ (TO_W_( %INFO_TYPE(%STD_INFO(info)) )) { \ case \ IND, \ IND_PERM, \ IND_STATIC: \ { \ x = StgInd_indirectee(x); \ goto again; \ } \ case \ FUN, \ FUN_1_0, \ FUN_0_1, \ FUN_2_0, \ FUN_1_1, \ FUN_0_2, \ FUN_STATIC, \ BCO, \ PAP: \ { \ ret(x); \ } \ default: \ { \ x = UNTAG_IF_PROF(x); \ jump %ENTRY_CODE(info) (x); \ } \ } // The FUN cases almost never happen: a pointer to a non-static FUN // should always be tagged. This unfortunately isn't true for the // interpreter right now, which leaves untagged FUNs on the stack. /* ----------------------------------------------------------------------------- Constants. -------------------------------------------------------------------------- */ #include "rts/Constants.h" #include "DerivedConstants.h" #include "rts/storage/ClosureTypes.h" #include "rts/storage/FunTypes.h" #include "rts/storage/SMPClosureOps.h" #include "rts/OSThreads.h" /* * Need MachRegs, because some of the RTS code is conditionally * compiled based on REG_R1, REG_R2, etc. */ #include "stg/RtsMachRegs.h" #include "rts/prof/LDV.h" #undef BLOCK_SIZE #undef MBLOCK_SIZE #include "rts/storage/Block.h" /* For Bdescr() */ #define MyCapability() (BaseReg - OFFSET_Capability_r) /* ------------------------------------------------------------------------- Info tables ------------------------------------------------------------------------- */ #if defined(PROFILING) #define PROF_HDR_FIELDS(w_,hdr1,hdr2) \ w_ hdr1, \ w_ hdr2, #else #define PROF_HDR_FIELDS(w_,hdr1,hdr2) /* nothing */ #endif /* ------------------------------------------------------------------------- Allocation and garbage collection ------------------------------------------------------------------------- */ /* * ALLOC_PRIM is for allocating memory on the heap for a primitive * object. It is used all over PrimOps.cmm. * * We make the simplifying assumption that the "admin" part of a * primitive closure is just the header when calculating sizes for * ticky-ticky. It's not clear whether eg. the size field of an array * should be counted as "admin", or the various fields of a BCO. */ #define ALLOC_PRIM(bytes) \ HP_CHK_GEN_TICKY(bytes); \ TICK_ALLOC_PRIM(SIZEOF_StgHeader,bytes-SIZEOF_StgHeader,0); \ CCCS_ALLOC(bytes); #define HEAP_CHECK(bytes,failure) \ TICK_BUMP(HEAP_CHK_ctr); \ Hp = Hp + (bytes); \ if (Hp > HpLim) { HpAlloc = (bytes); failure; } \ TICK_ALLOC_HEAP_NOCTR(bytes); #define ALLOC_PRIM_WITH_CUSTOM_FAILURE(bytes,failure) \ HEAP_CHECK(bytes,failure) \ TICK_ALLOC_PRIM(SIZEOF_StgHeader,bytes-SIZEOF_StgHeader,0); \ CCCS_ALLOC(bytes); #define ALLOC_PRIM_(bytes,fun) \ ALLOC_PRIM_WITH_CUSTOM_FAILURE(bytes,GC_PRIM(fun)); #define ALLOC_PRIM_P(bytes,fun,arg) \ ALLOC_PRIM_WITH_CUSTOM_FAILURE(bytes,GC_PRIM_P(fun,arg)); #define ALLOC_PRIM_N(bytes,fun,arg) \ ALLOC_PRIM_WITH_CUSTOM_FAILURE(bytes,GC_PRIM_N(fun,arg)); /* CCS_ALLOC wants the size in words, because ccs->mem_alloc is in words */ #define CCCS_ALLOC(__alloc) CCS_ALLOC(BYTES_TO_WDS(__alloc), CCCS) #define HP_CHK_GEN_TICKY(bytes) \ HP_CHK_GEN(bytes); \ TICK_ALLOC_HEAP_NOCTR(bytes); #define HP_CHK_P(bytes, fun, arg) \ HEAP_CHECK(bytes, GC_PRIM_P(fun,arg)) // TODO I'm not seeing where ALLOC_P_TICKY is used; can it be removed? // -NSF March 2013 #define ALLOC_P_TICKY(bytes, fun, arg) \ HP_CHK_P(bytes); \ TICK_ALLOC_HEAP_NOCTR(bytes); #define CHECK_GC() \ (bdescr_link(CurrentNursery) == NULL || \ generation_n_new_large_words(W_[g0]) >= TO_W_(CLong[large_alloc_lim])) // allocate() allocates from the nursery, so we check to see // whether the nursery is nearly empty in any function that uses // allocate() - this includes many of the primops. // // HACK alert: the __L__ stuff is here to coax the common-block // eliminator into commoning up the call stg_gc_noregs() with the same // code that gets generated by a STK_CHK_GEN() in the same proc. We // also need an if (0) { goto __L__; } so that the __L__ label isn't // optimised away by the control-flow optimiser prior to common-block // elimination (it will be optimised away later). // // This saves some code in gmp-wrappers.cmm where we have lots of // MAYBE_GC() in the same proc as STK_CHK_GEN(). // #define MAYBE_GC(retry) \ if (CHECK_GC()) { \ HpAlloc = 0; \ goto __L__; \ __L__: \ call stg_gc_noregs(); \ goto retry; \ } \ if (0) { goto __L__; } #define GC_PRIM(fun) \ jump stg_gc_prim(fun); // Version of GC_PRIM for use in low-level Cmm. We can call // stg_gc_prim, because it takes one argument and therefore has a // platform-independent calling convention (Note [Syntax of .cmm // files] in CmmParse.y). #define GC_PRIM_LL(fun) \ R1 = fun; \ jump stg_gc_prim [R1]; // We pass the fun as the second argument, because the arg is // usually already in the first argument position (R1), so this // avoids moving it to a different register / stack slot. #define GC_PRIM_N(fun,arg) \ jump stg_gc_prim_n(arg,fun); #define GC_PRIM_P(fun,arg) \ jump stg_gc_prim_p(arg,fun); #define GC_PRIM_P_LL(fun,arg) \ R1 = arg; \ R2 = fun; \ jump stg_gc_prim_p_ll [R1,R2]; #define GC_PRIM_PP(fun,arg1,arg2) \ jump stg_gc_prim_pp(arg1,arg2,fun); #define MAYBE_GC_(fun) \ if (CHECK_GC()) { \ HpAlloc = 0; \ GC_PRIM(fun) \ } #define MAYBE_GC_N(fun,arg) \ if (CHECK_GC()) { \ HpAlloc = 0; \ GC_PRIM_N(fun,arg) \ } #define MAYBE_GC_P(fun,arg) \ if (CHECK_GC()) { \ HpAlloc = 0; \ GC_PRIM_P(fun,arg) \ } #define MAYBE_GC_PP(fun,arg1,arg2) \ if (CHECK_GC()) { \ HpAlloc = 0; \ GC_PRIM_PP(fun,arg1,arg2) \ } #define STK_CHK_LL(n, fun) \ TICK_BUMP(STK_CHK_ctr); \ if (Sp - (n) < SpLim) { \ GC_PRIM_LL(fun) \ } #define STK_CHK_P_LL(n, fun, arg) \ TICK_BUMP(STK_CHK_ctr); \ if (Sp - (n) < SpLim) { \ GC_PRIM_P_LL(fun,arg) \ } #define STK_CHK_PP(n, fun, arg1, arg2) \ TICK_BUMP(STK_CHK_ctr); \ if (Sp - (n) < SpLim) { \ GC_PRIM_PP(fun,arg1,arg2) \ } #define STK_CHK_ENTER(n, closure) \ TICK_BUMP(STK_CHK_ctr); \ if (Sp - (n) < SpLim) { \ jump __stg_gc_enter_1(closure); \ } // A funky heap check used by AutoApply.cmm #define HP_CHK_NP_ASSIGN_SP0(size,f) \ HEAP_CHECK(size, Sp(0) = f; jump __stg_gc_enter_1 [R1];) /* ----------------------------------------------------------------------------- Closure headers -------------------------------------------------------------------------- */ /* * This is really ugly, since we don't do the rest of StgHeader this * way. The problem is that values from DerivedConstants.h cannot be * dependent on the way (SMP, PROF etc.). For SIZEOF_StgHeader we get * the value from GHC, but it seems like too much trouble to do that * for StgThunkHeader. */ #define SIZEOF_StgThunkHeader SIZEOF_StgHeader+SIZEOF_StgSMPThunkHeader #define StgThunk_payload(__ptr__,__ix__) \ W_[__ptr__+SIZEOF_StgThunkHeader+ WDS(__ix__)] /* ----------------------------------------------------------------------------- Closures -------------------------------------------------------------------------- */ /* The offset of the payload of an array */ #define BYTE_ARR_CTS(arr) ((arr) + SIZEOF_StgArrWords) /* The number of words allocated in an array payload */ #define BYTE_ARR_WDS(arr) ROUNDUP_BYTES_TO_WDS(StgArrWords_bytes(arr)) /* Getting/setting the info pointer of a closure */ #define SET_INFO(p,info) StgHeader_info(p) = info #define GET_INFO(p) StgHeader_info(p) /* Determine the size of an ordinary closure from its info table */ #define sizeW_fromITBL(itbl) \ SIZEOF_StgHeader + WDS(%INFO_PTRS(itbl)) + WDS(%INFO_NPTRS(itbl)) /* NB. duplicated from InfoTables.h! */ #define BITMAP_SIZE(bitmap) ((bitmap) & BITMAP_SIZE_MASK) #define BITMAP_BITS(bitmap) ((bitmap) >> BITMAP_BITS_SHIFT) /* Debugging macros */ #define LOOKS_LIKE_INFO_PTR(p) \ ((p) != NULL && \ LOOKS_LIKE_INFO_PTR_NOT_NULL(p)) #define LOOKS_LIKE_INFO_PTR_NOT_NULL(p) \ ( (TO_W_(%INFO_TYPE(%STD_INFO(p))) != INVALID_OBJECT) && \ (TO_W_(%INFO_TYPE(%STD_INFO(p))) < N_CLOSURE_TYPES)) #define LOOKS_LIKE_CLOSURE_PTR(p) (LOOKS_LIKE_INFO_PTR(GET_INFO(UNTAG(p)))) /* * The layout of the StgFunInfoExtra part of an info table changes * depending on TABLES_NEXT_TO_CODE. So we define field access * macros which use the appropriate version here: */ #ifdef TABLES_NEXT_TO_CODE /* * when TABLES_NEXT_TO_CODE, slow_apply is stored as an offset * instead of the normal pointer. */ #define StgFunInfoExtra_slow_apply(fun_info) \ (TO_W_(StgFunInfoExtraRev_slow_apply_offset(fun_info)) \ + (fun_info) + SIZEOF_StgFunInfoExtraRev + SIZEOF_StgInfoTable) #define StgFunInfoExtra_fun_type(i) StgFunInfoExtraRev_fun_type(i) #define StgFunInfoExtra_arity(i) StgFunInfoExtraRev_arity(i) #define StgFunInfoExtra_bitmap(i) StgFunInfoExtraRev_bitmap(i) #else #define StgFunInfoExtra_slow_apply(i) StgFunInfoExtraFwd_slow_apply(i) #define StgFunInfoExtra_fun_type(i) StgFunInfoExtraFwd_fun_type(i) #define StgFunInfoExtra_arity(i) StgFunInfoExtraFwd_arity(i) #define StgFunInfoExtra_bitmap(i) StgFunInfoExtraFwd_bitmap(i) #endif #define mutArrCardMask ((1 << MUT_ARR_PTRS_CARD_BITS) - 1) #define mutArrPtrCardDown(i) ((i) >> MUT_ARR_PTRS_CARD_BITS) #define mutArrPtrCardUp(i) (((i) + mutArrCardMask) >> MUT_ARR_PTRS_CARD_BITS) #define mutArrPtrsCardWords(n) ROUNDUP_BYTES_TO_WDS(mutArrPtrCardUp(n)) #if defined(PROFILING) || (!defined(THREADED_RTS) && defined(DEBUG)) #define OVERWRITING_CLOSURE(c) foreign "C" overwritingClosure(c "ptr") #define OVERWRITING_CLOSURE_OFS(c,n) \ foreign "C" overwritingClosureOfs(c "ptr", n) #else #define OVERWRITING_CLOSURE(c) /* nothing */ #define OVERWRITING_CLOSURE_OFS(c,n) /* nothing */ #endif #ifdef THREADED_RTS #define prim_write_barrier prim %write_barrier() #else #define prim_write_barrier /* nothing */ #endif /* ----------------------------------------------------------------------------- Ticky macros -------------------------------------------------------------------------- */ #ifdef TICKY_TICKY #define TICK_BUMP_BY(ctr,n) CLong[ctr] = CLong[ctr] + n #else #define TICK_BUMP_BY(ctr,n) /* nothing */ #endif #define TICK_BUMP(ctr) TICK_BUMP_BY(ctr,1) #define TICK_ENT_DYN_IND() TICK_BUMP(ENT_DYN_IND_ctr) #define TICK_ENT_DYN_THK() TICK_BUMP(ENT_DYN_THK_ctr) #define TICK_ENT_VIA_NODE() TICK_BUMP(ENT_VIA_NODE_ctr) #define TICK_ENT_STATIC_IND() TICK_BUMP(ENT_STATIC_IND_ctr) #define TICK_ENT_PERM_IND() TICK_BUMP(ENT_PERM_IND_ctr) #define TICK_ENT_PAP() TICK_BUMP(ENT_PAP_ctr) #define TICK_ENT_AP() TICK_BUMP(ENT_AP_ctr) #define TICK_ENT_AP_STACK() TICK_BUMP(ENT_AP_STACK_ctr) #define TICK_ENT_BH() TICK_BUMP(ENT_BH_ctr) #define TICK_ENT_LNE() TICK_BUMP(ENT_LNE_ctr) #define TICK_UNKNOWN_CALL() TICK_BUMP(UNKNOWN_CALL_ctr) #define TICK_UPDF_PUSHED() TICK_BUMP(UPDF_PUSHED_ctr) #define TICK_CATCHF_PUSHED() TICK_BUMP(CATCHF_PUSHED_ctr) #define TICK_UPDF_OMITTED() TICK_BUMP(UPDF_OMITTED_ctr) #define TICK_UPD_NEW_IND() TICK_BUMP(UPD_NEW_IND_ctr) #define TICK_UPD_NEW_PERM_IND() TICK_BUMP(UPD_NEW_PERM_IND_ctr) #define TICK_UPD_OLD_IND() TICK_BUMP(UPD_OLD_IND_ctr) #define TICK_UPD_OLD_PERM_IND() TICK_BUMP(UPD_OLD_PERM_IND_ctr) #define TICK_SLOW_CALL_FUN_TOO_FEW() TICK_BUMP(SLOW_CALL_FUN_TOO_FEW_ctr) #define TICK_SLOW_CALL_FUN_CORRECT() TICK_BUMP(SLOW_CALL_FUN_CORRECT_ctr) #define TICK_SLOW_CALL_FUN_TOO_MANY() TICK_BUMP(SLOW_CALL_FUN_TOO_MANY_ctr) #define TICK_SLOW_CALL_PAP_TOO_FEW() TICK_BUMP(SLOW_CALL_PAP_TOO_FEW_ctr) #define TICK_SLOW_CALL_PAP_CORRECT() TICK_BUMP(SLOW_CALL_PAP_CORRECT_ctr) #define TICK_SLOW_CALL_PAP_TOO_MANY() TICK_BUMP(SLOW_CALL_PAP_TOO_MANY_ctr) #define TICK_SLOW_CALL_fast_v16() TICK_BUMP(SLOW_CALL_fast_v16_ctr) #define TICK_SLOW_CALL_fast_v() TICK_BUMP(SLOW_CALL_fast_v_ctr) #define TICK_SLOW_CALL_fast_p() TICK_BUMP(SLOW_CALL_fast_p_ctr) #define TICK_SLOW_CALL_fast_pv() TICK_BUMP(SLOW_CALL_fast_pv_ctr) #define TICK_SLOW_CALL_fast_pp() TICK_BUMP(SLOW_CALL_fast_pp_ctr) #define TICK_SLOW_CALL_fast_ppv() TICK_BUMP(SLOW_CALL_fast_ppv_ctr) #define TICK_SLOW_CALL_fast_ppp() TICK_BUMP(SLOW_CALL_fast_ppp_ctr) #define TICK_SLOW_CALL_fast_pppv() TICK_BUMP(SLOW_CALL_fast_pppv_ctr) #define TICK_SLOW_CALL_fast_pppp() TICK_BUMP(SLOW_CALL_fast_pppp_ctr) #define TICK_SLOW_CALL_fast_ppppp() TICK_BUMP(SLOW_CALL_fast_ppppp_ctr) #define TICK_SLOW_CALL_fast_pppppp() TICK_BUMP(SLOW_CALL_fast_pppppp_ctr) #define TICK_VERY_SLOW_CALL() TICK_BUMP(VERY_SLOW_CALL_ctr) /* NOTE: TICK_HISTO_BY and TICK_HISTO currently have no effect. The old code for it didn't typecheck and I just commented it out to get ticky to work. - krc 1/2007 */ #define TICK_HISTO_BY(histo,n,i) /* nothing */ #define TICK_HISTO(histo,n) TICK_HISTO_BY(histo,n,1) /* An unboxed tuple with n components. */ #define TICK_RET_UNBOXED_TUP(n) \ TICK_BUMP(RET_UNBOXED_TUP_ctr++); \ TICK_HISTO(RET_UNBOXED_TUP,n) /* * A slow call with n arguments. In the unevald case, this call has * already been counted once, so don't count it again. */ #define TICK_SLOW_CALL(n) \ TICK_BUMP(SLOW_CALL_ctr); \ TICK_HISTO(SLOW_CALL,n) /* * This slow call was found to be to an unevaluated function; undo the * ticks we did in TICK_SLOW_CALL. */ #define TICK_SLOW_CALL_UNEVALD(n) \ TICK_BUMP(SLOW_CALL_UNEVALD_ctr); \ TICK_BUMP_BY(SLOW_CALL_ctr,-1); \ TICK_HISTO_BY(SLOW_CALL,n,-1); /* Updating a closure with a new CON */ #define TICK_UPD_CON_IN_NEW(n) \ TICK_BUMP(UPD_CON_IN_NEW_ctr); \ TICK_HISTO(UPD_CON_IN_NEW,n) #define TICK_ALLOC_HEAP_NOCTR(bytes) \ TICK_BUMP(ALLOC_RTS_ctr); \ TICK_BUMP_BY(ALLOC_RTS_tot,bytes) /* ----------------------------------------------------------------------------- Saving and restoring STG registers STG registers must be saved around a C call, just in case the STG register is mapped to a caller-saves machine register. Normally we don't need to worry about this the code generator has already loaded any live STG registers into variables for us, but in hand-written low-level Cmm code where we don't know which registers are live, we might have to save them all. -------------------------------------------------------------------------- */ #define SAVE_STGREGS \ W_ r1, r2, r3, r4, r5, r6, r7, r8; \ F_ f1, f2, f3, f4, f5, f6; \ D_ d1, d2, d3, d4, d5, d6; \ L_ l1; \ \ r1 = R1; \ r2 = R2; \ r3 = R3; \ r4 = R4; \ r5 = R5; \ r6 = R6; \ r7 = R7; \ r8 = R8; \ \ f1 = F1; \ f2 = F2; \ f3 = F3; \ f4 = F4; \ f5 = F5; \ f6 = F6; \ \ d1 = D1; \ d2 = D2; \ d3 = D3; \ d4 = D4; \ d5 = D5; \ d6 = D6; \ \ l1 = L1; #define RESTORE_STGREGS \ R1 = r1; \ R2 = r2; \ R3 = r3; \ R4 = r4; \ R5 = r5; \ R6 = r6; \ R7 = r7; \ R8 = r8; \ \ F1 = f1; \ F2 = f2; \ F3 = f3; \ F4 = f4; \ F5 = f5; \ F6 = f6; \ \ D1 = d1; \ D2 = d2; \ D3 = d3; \ D4 = d4; \ D5 = d5; \ D6 = d6; \ \ L1 = l1; /* ----------------------------------------------------------------------------- Misc junk -------------------------------------------------------------------------- */ #define NO_TREC stg_NO_TREC_closure #define END_TSO_QUEUE stg_END_TSO_QUEUE_closure #define STM_AWOKEN stg_STM_AWOKEN_closure #define END_INVARIANT_CHECK_QUEUE stg_END_INVARIANT_CHECK_QUEUE_closure #define recordMutableCap(p, gen) \ W_ __bd; \ W_ mut_list; \ mut_list = Capability_mut_lists(MyCapability()) + WDS(gen); \ __bd = W_[mut_list]; \ if (bdescr_free(__bd) >= bdescr_start(__bd) + BLOCK_SIZE) { \ W_ __new_bd; \ ("ptr" __new_bd) = foreign "C" allocBlock_lock(); \ bdescr_link(__new_bd) = __bd; \ __bd = __new_bd; \ W_[mut_list] = __bd; \ } \ W_ free; \ free = bdescr_free(__bd); \ W_[free] = p; \ bdescr_free(__bd) = free + WDS(1); #define recordMutable(p) \ P_ __p; \ W_ __bd; \ W_ __gen; \ __p = p; \ __bd = Bdescr(__p); \ __gen = TO_W_(bdescr_gen_no(__bd)); \ if (__gen > 0) { recordMutableCap(__p, __gen); } /* ----------------------------------------------------------------------------- Arrays -------------------------------------------------------------------------- */ /* Complete function body for the clone family of (mutable) array ops. Defined as a macro to avoid function call overhead or code duplication. */ #define cloneArray(info, src, offset, n) \ W_ words, size; \ gcptr dst, dst_p, src_p; \ \ again: MAYBE_GC(again); \ \ size = n + mutArrPtrsCardWords(n); \ words = BYTES_TO_WDS(SIZEOF_StgMutArrPtrs) + size; \ ("ptr" dst) = ccall allocate(MyCapability() "ptr", words); \ TICK_ALLOC_PRIM(SIZEOF_StgMutArrPtrs, WDS(size), 0); \ \ SET_HDR(dst, info, CCCS); \ StgMutArrPtrs_ptrs(dst) = n; \ StgMutArrPtrs_size(dst) = size; \ \ dst_p = dst + SIZEOF_StgMutArrPtrs; \ src_p = src + SIZEOF_StgMutArrPtrs + WDS(offset); \ while: \ if (n != 0) { \ n = n - 1; \ W_[dst_p] = W_[src_p]; \ dst_p = dst_p + WDS(1); \ src_p = src_p + WDS(1); \ goto while; \ } \ \ return (dst); #define copyArray(src, src_off, dst, dst_off, n) \ W_ dst_elems_p, dst_p, src_p, dst_cards_p, bytes; \ \ if ((n) != 0) { \ SET_HDR(dst, stg_MUT_ARR_PTRS_DIRTY_info, CCCS); \ \ dst_elems_p = (dst) + SIZEOF_StgMutArrPtrs; \ dst_p = dst_elems_p + WDS(dst_off); \ src_p = (src) + SIZEOF_StgMutArrPtrs + WDS(src_off); \ bytes = WDS(n); \ \ prim %memcpy(dst_p, src_p, bytes, WDS(1)); \ \ dst_cards_p = dst_elems_p + WDS(StgMutArrPtrs_ptrs(dst)); \ setCards(dst_cards_p, dst_off, n); \ } \ \ return (); #define copyMutableArray(src, src_off, dst, dst_off, n) \ W_ dst_elems_p, dst_p, src_p, dst_cards_p, bytes; \ \ if ((n) != 0) { \ SET_HDR(dst, stg_MUT_ARR_PTRS_DIRTY_info, CCCS); \ \ dst_elems_p = (dst) + SIZEOF_StgMutArrPtrs; \ dst_p = dst_elems_p + WDS(dst_off); \ src_p = (src) + SIZEOF_StgMutArrPtrs + WDS(src_off); \ bytes = WDS(n); \ \ if ((src) == (dst)) { \ prim %memmove(dst_p, src_p, bytes, WDS(1)); \ } else { \ prim %memcpy(dst_p, src_p, bytes, WDS(1)); \ } \ \ dst_cards_p = dst_elems_p + WDS(StgMutArrPtrs_ptrs(dst)); \ setCards(dst_cards_p, dst_off, n); \ } \ \ return (); /* * Set the cards in the cards table pointed to by dst_cards_p for an * update to n elements, starting at element dst_off. */ #define setCards(dst_cards_p, dst_off, n) \ W_ __start_card, __end_card, __cards; \ __start_card = mutArrPtrCardDown(dst_off); \ __end_card = mutArrPtrCardDown((dst_off) + (n) - 1); \ __cards = __end_card - __start_card + 1; \ prim %memset((dst_cards_p) + __start_card, 1, __cards, 1); /* Complete function body for the clone family of small (mutable) array ops. Defined as a macro to avoid function call overhead or code duplication. */ #define cloneSmallArray(info, src, offset, n) \ W_ words, size; \ gcptr dst, dst_p, src_p; \ \ again: MAYBE_GC(again); \ \ words = BYTES_TO_WDS(SIZEOF_StgSmallMutArrPtrs) + n; \ ("ptr" dst) = ccall allocate(MyCapability() "ptr", words); \ TICK_ALLOC_PRIM(SIZEOF_StgSmallMutArrPtrs, WDS(n), 0); \ \ SET_HDR(dst, info, CCCS); \ StgSmallMutArrPtrs_ptrs(dst) = n; \ \ dst_p = dst + SIZEOF_StgSmallMutArrPtrs; \ src_p = src + SIZEOF_StgSmallMutArrPtrs + WDS(offset); \ while: \ if (n != 0) { \ n = n - 1; \ W_[dst_p] = W_[src_p]; \ dst_p = dst_p + WDS(1); \ src_p = src_p + WDS(1); \ goto while; \ } \ \ return (dst); #endif /* CMM_H */