/* * Copyright (c) 2001 Stephen Williams (steve@icarus.com) * * This source code is free software; you can redistribute it * and/or modify it in source code form under the terms of the GNU * General Public License as published by the Free Software * Foundation; either version 2 of the License, or (at your option) * any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ #if !defined(WINNT) #ident "$Id: vpi_signal.cc,v 1.22 2001/08/08 01:05:06 steve Exp $" #endif /* * vpiReg handles are handled here. These objects represent vectors of * .var objects that can be manipulated by the VPI module. */ # include "vpi_priv.h" # include "functor.h" # include # include # include # include /* * Hex digits that represent 4-value bits of Verilog are not as * trivially obvious to display as if the bits were the usual 2-value * bits. So, although it is possible to write a function that * generates a correct character for 4*4-value bits, it is easier to * just perform the lookup in a table. This only takes 256 bytes, * which is not many executable instructions:-) * * The table is calculated as compile time, therefore, by the * draw_tt.c program. */ extern const char hex_digits[256]; extern const char oct_digits[256]; /* * implement vpi_get for vpiReg objects. */ static int signal_get(int code, vpiHandle ref) { assert((ref->vpi_type->type_code==vpiNet) || (ref->vpi_type->type_code==vpiReg)); struct __vpiSignal*rfp = (struct __vpiSignal*)ref; switch (code) { case vpiSigned: return rfp->signed_flag != 0; case vpiSize: if (rfp->msb >= rfp->lsb) return rfp->msb - rfp->lsb + 1; else return rfp->lsb - rfp->msb + 1; default: return 0; } } static char* signal_get_str(int code, vpiHandle ref) { assert((ref->vpi_type->type_code==vpiNet) || (ref->vpi_type->type_code==vpiReg)); struct __vpiSignal*rfp = (struct __vpiSignal*)ref; static char full_name[4096]; switch (code) { case vpiFullName: strcpy(full_name, vpi_get_str(vpiFullName, &rfp->scope->base)); strcat(full_name, "."); strcat(full_name, rfp->name); return full_name; case vpiName: return (char*)rfp->name; } return 0; } static char buf[4096]; static void signal_vpiDecStrVal(struct __vpiSignal*rfp, s_vpi_value*vp) { unsigned wid = (rfp->msb >= rfp->lsb) ? (rfp->msb - rfp->lsb + 1) : (rfp->lsb - rfp->msb + 1); unsigned long val = 0; unsigned count_x = 0, count_z = 0; for (unsigned idx = 0 ; idx < wid ; idx += 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, wid-idx-1); val *= 2; switch (functor_oval(fptr)) { case 0: break; case 1: val += 1; break; case 2: count_x += 1; break; case 3: count_z += 1; break; } } if (count_x == wid) { buf[0] = 'x'; buf[1] = 0; return; } if (count_x > 0) { buf[0] = 'X'; buf[1] = 0; return; } if (count_z == wid) { buf[0] = 'z'; buf[1] = 0; return; } if (count_z > 0) { buf[0] = 'Z'; buf[1] = 0; return; } if (rfp->signed_flag) { long tmp; assert(sizeof(tmp) == sizeof(val)); if (val & (1<<(wid-1)) && wid < 8*sizeof(tmp)) { tmp = -1; tmp <<= wid; tmp |= val; } else { tmp = val; } sprintf(buf, "%ld", tmp); } else { sprintf(buf, "%lu", val); } } static void signal_vpiStringVal(struct __vpiSignal*rfp, s_vpi_value*vp) { char*cp; unsigned idx; unsigned wid = (rfp->msb >= rfp->lsb) ? (rfp->msb - rfp->lsb + 1) : (rfp->lsb - rfp->msb + 1); assert(wid % 8 == 0); cp = buf; for (idx = wid ; idx >= 8 ; idx -= 8) { char tmp = 0; unsigned bdx; for (bdx = 8 ; bdx > 0 ; bdx -= 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, idx-8+bdx-1); tmp <<= 1; switch (functor_oval(fptr)) { case 0: break; case 1: tmp |= 1; break; default: break; } } *cp++ = tmp? tmp : ' '; } *cp++ = 0; } /* * The get_value method reads the values of the functors and returns * the vector to the caller. This causes no side-effect, and reads the * variables like a %load would. */ static void signal_get_value(vpiHandle ref, s_vpi_value*vp) { assert((ref->vpi_type->type_code==vpiNet) || (ref->vpi_type->type_code==vpiReg)); struct __vpiSignal*rfp = (struct __vpiSignal*)ref; unsigned wid = (rfp->msb >= rfp->lsb) ? (rfp->msb - rfp->lsb + 1) : (rfp->lsb - rfp->msb + 1); switch (vp->format) { case vpiIntVal: assert(wid <= 8 * sizeof vp->value.integer); vp->value.integer = 0; for (unsigned idx = 0 ; idx < wid ; idx += 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, idx); switch (functor_oval(fptr)) { case 0: break; case 1: vp->value.integer |= 1<value.integer = 0; break; } } break; case vpiBinStrVal: for (unsigned idx = 0 ; idx < wid ; idx += 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, idx); buf[wid-idx-1] = "01xz"[functor_oval(fptr)]; } buf[wid] = 0; vp->value.str = buf; break; case vpiHexStrVal: { unsigned hval, hwid; hwid = (wid + 3) / 4; buf[hwid] = 0; hval = 0; for (unsigned idx = 0 ; idx < wid ; idx += 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, idx); hval = hval | (functor_oval(fptr) << 2*(idx % 4)); if (idx%4 == 3) { hwid -= 1; buf[hwid] = hex_digits[hval]; hval = 0; } } if (hwid > 0) { hwid -= 1; buf[hwid] = hex_digits[hval]; unsigned padd = 0; switch(buf[hwid]) { case 'X': padd = 2; break; case 'Z': padd = 3; break; } if (padd) { for (unsigned idx = wid % 4; idx < 4; idx += 1) { hval = hval | padd << 2*idx; } buf[hwid] = hex_digits[hval]; } } vp->value.str = buf; break; } case vpiOctStrVal: { unsigned hval, hwid; hwid = (wid + 2) / 3; buf[hwid] = 0; hval = 0; for (unsigned idx = 0 ; idx < wid ; idx += 1) { vvp_ipoint_t fptr = vvp_fvector_get(rfp->bits, idx); hval = hval | (functor_oval(fptr) << 2*(idx % 3)); if (idx%3 == 2) { hwid -= 1; buf[hwid] = oct_digits[hval]; hval = 0; } } if (hwid > 0) { hwid -= 1; buf[hwid] = oct_digits[hval]; unsigned padd = 0; switch(buf[hwid]) { case 'X': padd = 2; break; case 'Z': padd = 3; break; } if (padd) { for (unsigned idx = wid % 3; idx < 3; idx += 1) { hval = hval | padd << 2*idx; } buf[hwid] = oct_digits[hval]; } } vp->value.str = buf; break; } case vpiDecStrVal: signal_vpiDecStrVal(rfp, vp); vp->value.str = buf; break; case vpiStringVal: signal_vpiStringVal(rfp, vp); vp->value.str = buf; break; default: fprintf(stderr, "vvp internal error: signal_get_value: " "value type %u not implemented.\n", vp->format); assert(0); } } /* * The put_value method writes the value into the vector, and returns * the affected ref. This operation works much like the %set or * %assign instructions and causes all the side-effects that the * equivilent instruction would cause. */ static vpiHandle signal_put_value(vpiHandle ref, s_vpi_value*vp, p_vpi_time when, int flags) { unsigned wid; struct __vpiSignal*rfp; assert((ref->vpi_type->type_code==vpiNet) || (ref->vpi_type->type_code==vpiReg)); rfp = (struct __vpiSignal*)ref; /* XXXX delays are not yet supported. */ assert(flags == vpiNoDelay); wid = (rfp->msb >= rfp->lsb) ? (rfp->msb - rfp->lsb + 1) : (rfp->lsb - rfp->msb + 1); switch (vp->format) { case vpiIntVal: { if (wid > 8*sizeof(long)) { fprintf(stderr, "internal error: wid(%u) " "too large.\n", wid); assert(0); } long val = vp->value.integer; for (unsigned idx = 0 ; idx < wid ; idx += 1) { functor_set(vvp_fvector_get(rfp->bits,idx), val&1, (val&1)? St1 : St0, true); val >>= 1; } break; } case vpiScalarVal: switch (vp->value.scalar) { case vpi0: functor_set(vvp_fvector_get(rfp->bits,0), 0, St0, true); break; case vpi1: functor_set(vvp_fvector_get(rfp->bits,0), 1, St1, true); break; case vpiX: functor_set(vvp_fvector_get(rfp->bits,0), 2, StX, true); break; case vpiZ: functor_set(vvp_fvector_get(rfp->bits,0), 3, HiZ, true); break; default: assert(0); } break; case vpiVectorVal: { assert(wid <= sizeof (unsigned long)); unsigned long aval = vp->value.vector->aval; unsigned long bval = vp->value.vector->bval; for (unsigned idx = 0 ; idx < wid ; idx += 1) { int bit = (aval&1) | ((bval<<1)&2); switch (bit) { case 0: /* zero */ functor_set(vvp_fvector_get(rfp->bits,idx), 0, St0, true); break; case 1: /* one */ functor_set(vvp_fvector_get(rfp->bits,idx), 1, St1, true); break; case 2: /* z */ functor_set(vvp_fvector_get(rfp->bits,idx), 3, HiZ, true); break; case 3: /* x */ functor_set(vvp_fvector_get(rfp->bits,idx), 2, StX, true); break; } aval >>= 1; bval >>= 1; } break; } default: assert(0); } return ref; } static const struct __vpirt vpip_reg_rt = { vpiReg, signal_get, signal_get_str, signal_get_value, signal_put_value, 0, 0 }; static const struct __vpirt vpip_net_rt = { vpiNet, signal_get, signal_get_str, signal_get_value, signal_put_value, 0, 0 }; /* * Construct a vpiReg object. It's like a net, except for the type. */ vpiHandle vpip_make_reg(char*name, int msb, int lsb, bool signed_flag, vvp_fvector_t vec) { vpiHandle obj = vpip_make_net(name, msb,lsb, signed_flag, vec); obj->vpi_type = &vpip_reg_rt; return obj; } /* * Construct a vpiNet object. Give the object specified dimensions, * and point to the specified functor for the lsb. */ vpiHandle vpip_make_net(char*name, int msb, int lsb, bool signed_flag, vvp_fvector_t vec) { struct __vpiSignal*obj = (struct __vpiSignal*) malloc(sizeof(struct __vpiSignal)); obj->base.vpi_type = &vpip_net_rt; obj->name = name; obj->msb = msb; obj->lsb = lsb; obj->signed_flag = signed_flag? 1 : 0; obj->bits = vec; obj->callback = 0; obj->scope = vpip_peek_current_scope(); return &obj->base; } /* * $Log: vpi_signal.cc,v $ * Revision 1.22 2001/08/08 01:05:06 steve * Initial implementation of vvp_fvectors. * (Stephan Boettcher) * * Revision 1.21 2001/07/24 01:34:56 steve * Implement string value for signals. * * Revision 1.20 2001/07/16 18:48:07 steve * Properly pad unknow values. (Stephan Boettcher) * * Revision 1.19 2001/07/13 03:02:34 steve * Rewire signal callback support for fast lookup. (Stephan Boettcher) * * Revision 1.18 2001/06/29 00:44:56 steve * Properly support signal full names. * * Revision 1.17 2001/06/21 23:05:08 steve * Some documentation of callback behavior. * * Revision 1.16 2001/06/21 22:54:12 steve * Support cbValueChange callbacks. * * Revision 1.15 2001/05/30 03:02:35 steve * Propagate strength-values instead of drive strengths. * * Revision 1.14 2001/05/22 04:08:49 steve * correctly interpret signed decimal values. * * Revision 1.13 2001/05/15 15:09:08 steve * Add the glossary file. * * Revision 1.12 2001/05/14 00:42:32 steve * test width of target with bit size of long. * * Revision 1.11 2001/05/09 04:23:19 steve * Now that the interactive debugger exists, * there is no use for the output dump. * * Revision 1.10 2001/05/08 23:32:26 steve * Add to the debugger the ability to view and * break on functors. * * Add strengths to functors at compile time, * and Make functors pass their strengths as they * propagate their output. */