/* * VHDL code generation for LPM devices. * * Copyright (C) 2008-2009 Nick Gasson (nick@nickg.me.uk) * * This program is free software; you can redistribute it and/or modify * it 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "vhdl_target.h" #include "state.hh" #include #include /* * Return the base of a part select. */ static vhdl_expr *part_select_base(vhdl_scope *scope, ivl_lpm_t lpm) { vhdl_expr *off; ivl_nexus_t base = ivl_lpm_data(lpm, 1); if (base != NULL) off = readable_ref(scope, base); else off = new vhdl_const_int(ivl_lpm_base(lpm)); // Array indexes must be integers vhdl_type integer(VHDL_TYPE_INTEGER); return off->cast(&integer); } static vhdl_expr *binop_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm, vhdl_binop_t op) { unsigned out_width = ivl_lpm_width(lpm); vhdl_type *result_type = vhdl_type::type_for(out_width, ivl_lpm_signed(lpm) != 0); vhdl_binop_expr *expr = new vhdl_binop_expr(op, result_type); for (unsigned i = 0; i < ivl_lpm_size(lpm); i++) { vhdl_expr *e = readable_ref(scope, ivl_lpm_data(lpm, i)); if (NULL == e) return NULL; // It's possible that the inputs are a mixture of signed and unsigned // in which case we must cast them to the output type e = e->cast(vhdl_type::type_for(e->get_type()->get_width(), ivl_lpm_signed(lpm) != 0)); // Bit of a hack: the LPM inputs are in the wrong order for concatenation if (op == VHDL_BINOP_CONCAT) expr->add_expr_front(e); else expr->add_expr(e); } if (op == VHDL_BINOP_MULT) { // Need to resize the output to the desired size, // as this does not happen automatically in VHDL vhdl_fcall *resize = new vhdl_fcall("Resize", vhdl_type::nsigned(out_width)); resize->add_expr(expr); resize->add_expr(new vhdl_const_int(out_width)); return resize; } else return expr; } static vhdl_expr *rel_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm, vhdl_binop_t op) { vhdl_binop_expr *expr = new vhdl_binop_expr(op, vhdl_type::boolean()); vhdl_expr *lhs = readable_ref(scope, ivl_lpm_data(lpm, 0)); if (NULL == lhs) return NULL; vhdl_expr *rhs = readable_ref(scope, ivl_lpm_data(lpm, 1)); if (NULL == rhs) { delete lhs; return NULL; } // Ensure LHS and RHS are the same type if (lhs->get_type() != rhs->get_type()) rhs = rhs->cast(lhs->get_type()); expr->add_expr(lhs); expr->add_expr(rhs); return expr; } static vhdl_expr *part_select_vp_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { vhdl_var_ref *selfrom = readable_ref(scope, ivl_lpm_data(lpm, 0)); if (NULL == selfrom) return NULL; vhdl_expr *off = part_select_base(scope, lpm);; if (NULL == off) return NULL; if (selfrom->get_type()->get_width() > 1) selfrom->set_slice(off, ivl_lpm_width(lpm) - 1); return selfrom; } static vhdl_expr *part_select_pv_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { return readable_ref(scope, ivl_lpm_data(lpm, 0)); } static vhdl_expr *ufunc_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { ivl_scope_t f_scope = ivl_lpm_define(lpm); vhdl_fcall *fcall = new vhdl_fcall(ivl_scope_basename(f_scope), NULL); for (unsigned i = 0; i < ivl_lpm_size(lpm); i++) { vhdl_var_ref *ref = readable_ref(scope, ivl_lpm_data(lpm, i)); if (NULL == ref) { delete fcall; return NULL; } fcall->add_expr(ref); } return fcall; } static vhdl_expr *reduction_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm, support_function_t f, bool invert) { vhdl_var_ref *ref = readable_ref(scope, ivl_lpm_data(lpm, 0)); if (NULL == ref) return NULL; vhdl_expr *result; if (ref->get_type()->get_name() == VHDL_TYPE_STD_LOGIC) result = ref; else { require_support_function(f); vhdl_fcall *fcall = new vhdl_fcall(support_function::function_name(f), vhdl_type::std_logic()); vhdl_type std_logic_vector(VHDL_TYPE_STD_LOGIC_VECTOR); fcall->add_expr(ref->cast(&std_logic_vector)); result = fcall; } if (invert) return new vhdl_unaryop_expr (VHDL_UNARYOP_NOT, result, vhdl_type::std_logic()); else return result; } static vhdl_expr *sign_extend_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { vhdl_expr *ref = readable_ref(scope, ivl_lpm_data(lpm, 0)); if (ref) return ref->resize(ivl_lpm_width(lpm)); else return NULL; } static vhdl_expr *array_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { ivl_signal_t array = ivl_lpm_array(lpm); if (!seen_signal_before(array)) return NULL; const char *renamed = get_renamed_signal(array).c_str(); vhdl_decl *adecl = scope->get_decl(renamed); assert(adecl); vhdl_type *atype = new vhdl_type(*adecl->get_type()); vhdl_expr *select = readable_ref(scope, ivl_lpm_select(lpm)); if (NULL == select) { delete atype; return NULL; } vhdl_var_ref *ref = new vhdl_var_ref(renamed, atype); vhdl_type integer(VHDL_TYPE_INTEGER); ref->set_slice(select->cast(&integer)); return ref; } static vhdl_expr *shift_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm, vhdl_binop_t shift_op) { vhdl_expr *lhs = readable_ref(scope, ivl_lpm_data(lpm, 0)); vhdl_expr *rhs = readable_ref(scope, ivl_lpm_data(lpm, 1)); if (!lhs || !rhs) return NULL; // The RHS must be an integer vhdl_type integer(VHDL_TYPE_INTEGER); vhdl_expr *r_cast = rhs->cast(&integer); vhdl_type *rtype = new vhdl_type(*lhs->get_type()); return new vhdl_binop_expr(lhs, shift_op, r_cast, rtype); } static vhdl_expr *repeat_lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { vhdl_expr *in = readable_ref(scope, ivl_lpm_data(lpm, 0)); return new vhdl_bit_spec_expr(NULL, in); } static vhdl_expr *lpm_to_expr(vhdl_scope *scope, ivl_lpm_t lpm) { switch (ivl_lpm_type(lpm)) { case IVL_LPM_ADD: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_ADD); case IVL_LPM_SUB: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_SUB); case IVL_LPM_MULT: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_MULT); case IVL_LPM_DIVIDE: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_DIV); case IVL_LPM_MOD: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_MOD); case IVL_LPM_CONCAT: return binop_lpm_to_expr(scope, lpm, VHDL_BINOP_CONCAT); case IVL_LPM_CMP_GE: return rel_lpm_to_expr(scope, lpm, VHDL_BINOP_GEQ); case IVL_LPM_CMP_GT: return rel_lpm_to_expr(scope, lpm, VHDL_BINOP_GT); case IVL_LPM_CMP_NE: case IVL_LPM_CMP_NEE: return rel_lpm_to_expr(scope, lpm, VHDL_BINOP_NEQ); case IVL_LPM_CMP_EQ: case IVL_LPM_CMP_EEQ: return rel_lpm_to_expr(scope, lpm, VHDL_BINOP_EQ); case IVL_LPM_PART_VP: return part_select_vp_lpm_to_expr(scope, lpm); case IVL_LPM_PART_PV: return part_select_pv_lpm_to_expr(scope, lpm); case IVL_LPM_UFUNC: return ufunc_lpm_to_expr(scope, lpm); case IVL_LPM_RE_AND: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_AND, false); case IVL_LPM_RE_NAND: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_AND, true); case IVL_LPM_RE_NOR: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_OR, true); case IVL_LPM_RE_OR: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_OR, false); case IVL_LPM_RE_XOR: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_XOR, false); case IVL_LPM_RE_XNOR: return reduction_lpm_to_expr(scope, lpm, SF_REDUCE_XNOR, true); case IVL_LPM_SIGN_EXT: return sign_extend_lpm_to_expr(scope, lpm); case IVL_LPM_ARRAY: return array_lpm_to_expr(scope, lpm); case IVL_LPM_SHIFTL: return shift_lpm_to_expr(scope, lpm, VHDL_BINOP_SL); case IVL_LPM_SHIFTR: return shift_lpm_to_expr(scope, lpm, VHDL_BINOP_SR); case IVL_LPM_REPEAT: return repeat_lpm_to_expr(scope, lpm); default: error("Unsupported LPM type: %d", ivl_lpm_type(lpm)); return NULL; } } static int draw_mux_lpm(vhdl_arch *arch, ivl_lpm_t lpm) { int nselects = ivl_lpm_selects(lpm); if (nselects > 1) { error("Only 1 LPM select bit supported at the moment"); return 1; } vhdl_scope *scope = arch->get_scope(); vhdl_expr *s0 = readable_ref(scope, ivl_lpm_data(lpm, 0)); vhdl_expr *s1 = readable_ref(scope, ivl_lpm_data(lpm, 1)); vhdl_expr *sel = readable_ref(scope, ivl_lpm_select(lpm)); vhdl_expr *b1 = new vhdl_const_bit('1'); vhdl_expr *t1 = new vhdl_binop_expr(sel, VHDL_BINOP_EQ, b1, vhdl_type::boolean()); vhdl_var_ref *out = nexus_to_var_ref(scope, ivl_lpm_q(lpm)); // Make sure s0 and s1 have the same type as the output s0 = s0->cast(out->get_type()); s1 = s1->cast(out->get_type()); vhdl_cassign_stmt *s = new vhdl_cassign_stmt(out, s0); s->add_condition(s1, t1); arch->add_stmt(s); return 0; } int draw_lpm(vhdl_arch *arch, ivl_lpm_t lpm) { if (ivl_lpm_type(lpm) == IVL_LPM_MUX) return draw_mux_lpm(arch, lpm); vhdl_expr *f = lpm_to_expr(arch->get_scope(), lpm); if (NULL == f) return 1; vhdl_var_ref *out = nexus_to_var_ref(arch->get_scope(), ivl_lpm_q(lpm)); if (ivl_lpm_type(lpm) == IVL_LPM_PART_PV) { vhdl_expr *off = part_select_base(arch->get_scope(), lpm); assert(off); out->set_slice(off, ivl_lpm_width(lpm) - 1); } // Converting from Boolean to std_logic is a common case so should be // replaced by an idiomatic VHDL construct rather than a call to a // conversion function bool bool_to_logic = out->get_type()->get_name() == VHDL_TYPE_STD_LOGIC && f->get_type()->get_name() == VHDL_TYPE_BOOLEAN; if (bool_to_logic) { vhdl_cassign_stmt* s = new vhdl_cassign_stmt(out, new vhdl_const_bit('0')); s->add_condition(new vhdl_const_bit('1'), f); arch->add_stmt(s); } else arch->add_stmt(new vhdl_cassign_stmt(out, f->cast(out->get_type()))); return 0; }