/****************************************************************************** * Copyright (c) 2004, 2008 IBM Corporation * All rights reserved. * This program and the accompanying materials * are made available under the terms of the BSD License * which accompanies this distribution, and is available at * http://www.opensource.org/licenses/bsd-license.php * * Contributors: * IBM Corporation - initial implementation *****************************************************************************/ // // Copyright 2002,2003,2004 Segher Boessenkool // #define NEXT00 goto *cfa->a #define NEXT0 cfa = ip->a; NEXT00 #define NEXT ip++; NEXT0 #define PRIM(name) code_##name: { \ asm volatile ("#### " #name : : : "memory"); \ void *w = (cfa = (++ip)->a)->a; #define MIRP goto *w; } // start interpreting NEXT0; // These macros could be replaced to allow for TOS caching etc. #define TOS (*dp) #define NOS (*(dp-1)) #define POP dp-- #define PUSH dp++ #define RTOS (*rp) #define RNOS (*(rp-1)) #define RPOP rp-- #define RPUSH rp++ // For terminal input. PRIM(TIB) PUSH; TOS.a = the_tib; MIRP // For pockets (temporary string buffers). PRIM(POCKETS) PUSH; TOS.a = the_pockets; MIRP // exception register area PRIM(EREGS) PUSH; TOS.a = the_exception_frame; MIRP // client register area PRIM(CIREGS) PUSH; TOS.a = the_client_frame; MIRP // Client stack // (According to the PowerPC ABI the stack-pointer points to the // lowest **USED** value. // I.e. it is decremented before a new element is stored on the // stack.) PRIM(CISTACK) PUSH; TOS.a = the_client_stack + (sizeof(the_client_stack) / CELLSIZE); MIRP // compile-in-interpret buffer PRIM(COMP_X2d_BUFFER) PUSH; TOS.a = the_comp_buffer; MIRP // Paflof base address PRIM(PAFLOF_X2d_START) PUSH; TOS.a = _start_OF; MIRP // Heap pointers PRIM(HEAP_X2d_START) PUSH; TOS.a = the_heap_start; MIRP PRIM(HEAP_X2d_END) PUSH; TOS.a = the_heap_end; MIRP // FDT pointer PRIM(FDT_X2d_START) PUSH; TOS.u = fdt_start; MIRP // romfs-base PRIM(ROMFS_X2d_BASE) PUSH; TOS.u = romfs_base; MIRP // if the low level firmware is epapr compliant it will put the // epapr magic into r6 before starting paflof // epapr-magic is a copy of r6 PRIM(EPAPR_X2d_MAGIC) PUSH; TOS.u = epapr_magic; MIRP // Initially mapped area size (for ePAPR compliant LLFW) PRIM(EPAPR_X2d_IMA_X2d_SIZE) PUSH; TOS.u = epapr_ima_size; MIRP // Codefields. code_DOCOL: { RPUSH; RTOS.a = ip; ip = cfa; NEXT; } code_DODOES: { RPUSH; RTOS.a = ip; ip = (cfa + 1)->a; PUSH; TOS.a = cfa + 2; NEXT0; } code_DODEFER: { cfa = (cfa + 1)->a; NEXT00; } code_DOALIAS: { cfa = (cfa + 1)->a; NEXT00; } code_DOCON: { PUSH; TOS = *(cfa + 1); NEXT; } code_DOVAL: { PUSH; TOS = *(cfa + 1); NEXT; } code_DOFIELD: { dp->n += (cfa + 1)->n; NEXT; } code_DOVAR: { (++dp)->a = cfa + 1; NEXT; } code_DOBUFFER_X3a: { (++dp)->a = cfa + 1; NEXT; } // branching code_BRANCH: { type_n dis = (++ip)->n; ip = (cell *)((type_u)ip + dis); NEXT; } code_0BRANCH: { type_n dis = (++ip)->n; if (TOS.u == 0) ip = (cell *)((type_u)ip + dis); POP; NEXT; } // Jump to "defer BP" code_BREAKPOINT: { RPUSH; RTOS.a = ip; ip = (cell * ) xt_BP+2; NEXT; } // literals code_LIT: { PUSH; TOS = *++ip; NEXT; } code_DOTICK: { PUSH; TOS = *++ip; NEXT; } // 1.1 PRIM(DUP) cell x = TOS; PUSH; TOS = x; MIRP PRIM(OVER) cell x = NOS; PUSH; TOS = x; MIRP PRIM(PICK) TOS = *(dp - TOS.n - 1); MIRP // 1.2 PRIM(DROP) POP; MIRP // 1.3 PRIM(SWAP) cell x = NOS; NOS = TOS; TOS = x; MIRP // 1.4 PRIM(_X3e_R) RPUSH; RTOS = TOS; POP; MIRP PRIM(R_X3e) PUSH; TOS = RTOS; RPOP; MIRP PRIM(R_X40) PUSH; TOS = RTOS; MIRP // 1.5 PRIM(DEPTH) PUSH; TOS.u = dp - the_data_stack; MIRP PRIM(DEPTH_X21) dp = the_data_stack + TOS.u - 1; MIRP PRIM(RDEPTH) PUSH; TOS.u = rp - the_return_stack + 1; MIRP PRIM(RDEPTH_X21) rp = the_return_stack + TOS.u - 1; POP; MIRP PRIM(RPICK) TOS = *(rp - TOS.n); MIRP // 2.1 PRIM(_X2b) NOS.u += TOS.u; POP; MIRP PRIM(_X2d) NOS.u -= TOS.u; POP; MIRP PRIM(_X2a) NOS.u *= TOS.u; POP; MIRP // 2.2 PRIM(LSHIFT) NOS.u <<= TOS.u; POP; MIRP PRIM(RSHIFT) NOS.u >>= TOS.u; POP; MIRP PRIM(ASHIFT) NOS.n >>= TOS.u; POP; MIRP PRIM(AND) NOS.u &= TOS.u; POP; MIRP PRIM(OR) NOS.u |= TOS.u; POP; MIRP PRIM(XOR) NOS.u ^= TOS.u; POP; MIRP // 3.1 #define GET_TYPE1(t) { \ t *restrict a = (t *restrict)(TOS.a); \ t b; #define GET_TYPE2(t) \ b = *a; #define GET_TYPE3(t) \ TOS.u = b; \ } #define PUT_TYPE1(t) { \ t *restrict a = TOS.a; \ t b = NOS.u; \ POP; \ POP; #define PUT_TYPE2(t) \ *a = b; \ } #define GET_CELL1 GET_TYPE1(type_u) #define PUT_CELL1 PUT_TYPE1(type_u) #define GET_CHAR1 GET_TYPE1(type_c) #define PUT_CHAR1 PUT_TYPE1(type_c) #define GET_WORD1 GET_TYPE1(type_w) #define PUT_WORD1 PUT_TYPE1(type_w) #define GET_LONG1 GET_TYPE1(type_l) #define PUT_LONG1 PUT_TYPE1(type_l) #define GET_XONG1 GET_TYPE1(type_u) #define PUT_XONG1 PUT_TYPE1(type_u) #define GET_CELL2 GET_TYPE2(type_u) #define PUT_CELL2 PUT_TYPE2(type_u) #define GET_CHAR2 GET_TYPE2(type_c) #define PUT_CHAR2 PUT_TYPE2(type_c) #define GET_WORD2 GET_TYPE2(type_w) #define PUT_WORD2 PUT_TYPE2(type_w) #define GET_LONG2 GET_TYPE2(type_l) #define PUT_LONG2 PUT_TYPE2(type_l) #define GET_XONG2 GET_TYPE2(type_u) #define PUT_XONG2 PUT_TYPE2(type_u) #define GET_CELL3 GET_TYPE3(type_u) #define GET_CHAR3 GET_TYPE3(type_c) #define GET_WORD3 GET_TYPE3(type_w) #define GET_LONG3 GET_TYPE3(type_l) #define GET_XONG3 GET_TYPE3(type_u) #define GET_CELL GET_CELL1 GET_CELL2 GET_CELL3 #define PUT_CELL PUT_CELL1 PUT_CELL2 #define GET_CHAR GET_CHAR1 GET_CHAR2 GET_CHAR3 #define PUT_CHAR PUT_CHAR1 PUT_CHAR2 #define GET_WORD GET_WORD1 GET_WORD2 GET_WORD3 #define PUT_WORD PUT_WORD1 PUT_WORD2 #define GET_LONG GET_LONG1 GET_LONG2 GET_LONG3 #define PUT_LONG PUT_LONG1 PUT_LONG2 #define GET_XONG GET_XONG1 GET_XONG2 GET_XONG3 #define PUT_XONG PUT_XONG1 PUT_XONG2 PRIM(_X40) GET_CELL; MIRP PRIM(_X21) PUT_CELL; MIRP PRIM(C_X40) GET_CHAR; MIRP PRIM(C_X21) PUT_CHAR; MIRP PRIM(W_X40) GET_WORD; MIRP PRIM(W_X21) PUT_WORD; MIRP PRIM(L_X40) GET_LONG; MIRP PRIM(L_X21) PUT_LONG; MIRP PRIM(X_X40) GET_XONG; MIRP PRIM(X_X21) PUT_XONG; MIRP #define UGET_TYPE1(t) { \ type_c *restrict a = (type_c *restrict)(TOS.a); \ t b; \ type_c *restrict c = (type_c *restrict)&b; #define UGET_TYPE2(t) \ *c++ = *a++; \ *c++ = *a++; #define UGET_TYPE3(t) \ TOS.u = b; \ } #define UPUT_TYPE1(t) { \ type_c *restrict a = (type_c *restrict)(TOS.a); \ t b = NOS.u; \ type_c *restrict c = (type_c *restrict)&b; \ POP; \ POP; #define UPUT_TYPE2(t) \ *a++ = *c++; \ *a++ = *c++; #define UPUT_TYPE3(t) } #define UGET_WORD1 UGET_TYPE1(type_w) #define UPUT_WORD1 UPUT_TYPE1(type_w) #define UGET_WORD2 UGET_TYPE2(type_w) #define UPUT_WORD2 UPUT_TYPE2(type_w) #define UGET_WORD3 UGET_TYPE3(type_w) #define UPUT_WORD3 UPUT_TYPE3(type_w) #define UGET_LONG1 UGET_TYPE1(type_l) #define UPUT_LONG1 UPUT_TYPE1(type_l) #define UGET_LONG2 UGET_TYPE2(type_l) #define UPUT_LONG2 UPUT_TYPE2(type_l) #define UGET_LONG3 UGET_TYPE3(type_l) #define UPUT_LONG3 UPUT_TYPE3(type_l) #define UGET_WORD UGET_WORD1 UGET_WORD2 UGET_WORD3 #define UPUT_WORD UPUT_WORD1 UPUT_WORD2 UPUT_WORD3 #define UGET_LONG UGET_LONG1 UGET_LONG2 UGET_LONG2 UGET_LONG3 #define UPUT_LONG UPUT_LONG1 UPUT_LONG2 UPUT_LONG2 UPUT_LONG3 PRIM(UNALIGNED_X2d_W_X40) UGET_WORD; MIRP PRIM(UNALIGNED_X2d_W_X21) UPUT_WORD; MIRP PRIM(UNALIGNED_X2d_L_X40) UGET_LONG; MIRP PRIM(UNALIGNED_X2d_L_X21) UPUT_LONG; MIRP // 6 PRIM(_X3c) NOS.n = -(NOS.n < TOS.n); POP; MIRP PRIM(U_X3c) NOS.n = -(NOS.u < TOS.u); POP; MIRP PRIM(0_X3c) TOS.n = -(TOS.n < 0); MIRP PRIM(_X3d) NOS.n = -(NOS.u == TOS.u); POP; MIRP PRIM(0_X3d) TOS.n = -(TOS.u == 0); MIRP // 8.4 PRIM(DODO) RPUSH; RTOS = NOS; RPUSH; RTOS = TOS; POP; POP; MIRP code_DO_X3f_DO: { cell i = *dp--; cell n = *dp--; type_n dis = (++ip)->n; if (i.n == n.n) ip = (cell *restrict)((type_c *restrict)ip + dis); else { *(rp + 1) = n; *(rp += 2) = i; } NEXT; } code_DOLOOP: { type_n dis = (++ip)->n; rp->n++; if (rp->n == (rp - 1)->n) rp -= 2; else ip = (cell *restrict)((type_c *restrict)ip + dis); NEXT; } code_DO_X2b_LOOP: { type_u lo, hi; type_n inc; type_n dis = (++ip)->n; lo = rp->u; inc = (dp--)->n; rp->n += inc; if (inc >= 0) hi = rp->u; else { hi = lo; lo = rp->u; } if ((type_u)((rp - 1)->n - 1 - lo) < hi - lo) rp -= 2; else ip = (cell *restrict)((type_c *restrict)ip + dis); NEXT; } code_DOLEAVE: { type_n dis = (++ip)->n; rp -= 2; ip = (cell *restrict)((type_c *restrict)ip + dis); NEXT; } code_DO_X3f_LEAVE: { type_n dis = (++ip)->n; if ((dp--)->n) { rp -= 2; ip = (cell *restrict)((type_c *restrict)ip + dis); } NEXT; } // 8.5 code_EXIT: { ip = (rp--)->a; NEXT; } code_SEMICOLON: { ip = (rp--)->a; NEXT; } code_EXECUTE: // don't need this as prim { cfa = (dp--)->a; NEXT00; } PRIM(MOVE) type_u n = TOS.u; POP; unsigned char *q = TOS.a; POP; unsigned char *p = TOS.a; POP; _FASTMOVE(p, q, n); MIRP code_FILL: { unsigned char c = (dp--)->u; type_n size = ((dp--)->n); unsigned char *d = (unsigned char *)((dp--)->u); type_u fill_v=c | c <<8; fill_v |= fill_v << 16; switch (((type_u)d | (type_u)size) & (sizeof(type_u)-1)) { case 0: { type_u *up = (type_u *)d; #if (__LONG_MAX__ > 2147483647L) fill_v |= fill_v << 32; #endif while ((size-=sizeof(type_u)) >= 0) *up++ = fill_v; } case sizeof(type_l): { type_l *lp = (type_l *)d; while ((size-=sizeof(type_l)) >= 0) *lp++ = (type_l)fill_v; } case sizeof(type_w): { type_w *wp = (type_w *)d; while ((size-=sizeof(type_w)) >= 0) *wp++ = (type_w)fill_v; } default: while (size-- > 0) *d++ = (unsigned char)c; } NEXT; } code_COMP: { type_n len = ((dp--)->n); unsigned char *addr2 = (unsigned char *)((dp--)->u); unsigned char *addr1 = (unsigned char *)((dp--)->u); while (len-- > 0) { if (*addr1 > *addr2) { (++dp)->n = 1; NEXT; } else if (*addr1 < *addr2) { (++dp)->n = -1; NEXT; } addr1 += 1; addr2 += 1; } (++dp)->n = 0; NEXT; } PRIM(RMOVE) type_u size = ((dp--)->u); type_u *d = (type_u *)((dp--)->u); type_u *s = (type_u *)((dp--)->u); _FASTRMOVE(s, d, size); MIRP // String compare, case insensitive: // : string=ci ( str1 len1 str2 len2 -- equal? ) PRIM(STRING_X3d_CI) type_u l2 = TOS.u; POP; unsigned char *p2 = TOS.a; POP; type_u l1 = TOS.u; POP; unsigned char *p1 = TOS.a; if (l1 == l2) { TOS.n = -1; /* Default to TRUE */ while (l1 > 0) { if (toupper(*p1) != toupper(*p2)) { TOS.n = 0; break; } ++p1; ++p2; --l1; } } else { TOS.n = 0; } MIRP // bool dependend pick // ?PICK ( v1 v2 bool -- v1|v2 ) PRIM(_X3f_PICK) type_u b = TOS.u; POP; if (b) { NOS = TOS; } POP; MIRP /* zcount ( zstr -- str len ) */ PRIM(ZCOUNT) type_u len = strlen(TOS.a); PUSH; TOS.u = len; MIRP PRIM(CLEAN_X2d_HASH) memset(hash_table, 0, sizeof(hash_table)); MIRP PRIM(HASH_X2d_TABLE) PUSH; TOS.a = hash_table; MIRP /* hash ( str len -- hash ) * this word is used in find-hash.fs to create * a hash to accelerate word lookup */ PRIM(HASH) type_u len = TOS.u; POP; unsigned char *str = TOS.a; type_u tmp = len; type_u hash = 0; while(len--) { hash <<= 1; hash ^= tolower(*str); hash ^= tmp; str++; } /* we only want hash values which size is smaller * than HASHSIZE */ hash &= HASHSIZE - 1; /* access the hash table in steps of CELLSIZE */ hash *= CELLSIZE; /* return a pointer for this hash in the hash table */ TOS.a = hash_table + hash; MIRP