From: Marcelina Koƛcielnicka Date: Wed, 8 Apr 2020 19:42:50 +0000 (+0200) Subject: Add new builtin FF types X-Git-Tag: working-ls180~453^2~4 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=b0bee396a8edec360616b68e97a3bd373b700b26;p=yosys.git Add new builtin FF types The new types include: - FFs with async reset and enable (`$adffe`, `$_DFFE_[NP][NP][01][NP]_`) - FFs with sync reset (`$sdff`, `$_SDFF_[NP][NP][01]_`) - FFs with sync reset and enable, reset priority (`$sdffs`, `$_SDFFE_[NP][NP][01][NP]_`) - FFs with sync reset and enable, enable priority (`$sdffce`, `$_SDFFCE_[NP][NP][01][NP]_`) - FFs with async reset, set, and enable (`$dffsre`, `$_DFFSRE_[NP][NP][NP][NP]_`) - latches with reset or set (`$adlatch`, `$_DLATCH_[NP][NP][01]_`) The new FF types are not actually used anywhere yet (this is left for future commits). --- diff --git a/kernel/celltypes.h b/kernel/celltypes.h index db54436cb..12dea93b8 100644 --- a/kernel/celltypes.h +++ b/kernel/celltypes.h @@ -139,8 +139,14 @@ struct CellTypes setup_type(ID($dff), {ID::CLK, ID::D}, {ID::Q}); setup_type(ID($dffe), {ID::CLK, ID::EN, ID::D}, {ID::Q}); setup_type(ID($dffsr), {ID::CLK, ID::SET, ID::CLR, ID::D}, {ID::Q}); + setup_type(ID($dffsre), {ID::CLK, ID::SET, ID::CLR, ID::D, ID::E}, {ID::Q}); setup_type(ID($adff), {ID::CLK, ID::ARST, ID::D}, {ID::Q}); + setup_type(ID($adffe), {ID::CLK, ID::ARST, ID::D, ID::E}, {ID::Q}); + setup_type(ID($sdff), {ID::CLK, ID::SRST, ID::D}, {ID::Q}); + setup_type(ID($sdffe), {ID::CLK, ID::SRST, ID::D, ID::E}, {ID::Q}); + setup_type(ID($sdffce), {ID::CLK, ID::SRST, ID::D, ID::E}, {ID::Q}); setup_type(ID($dlatch), {ID::EN, ID::D}, {ID::Q}); + setup_type(ID($adlatch), {ID::EN, ID::D, ID::ARST}, {ID::Q}); setup_type(ID($dlatchsr), {ID::EN, ID::SET, ID::CLR, ID::D}, {ID::Q}); } @@ -208,14 +214,48 @@ struct CellTypes for (auto c3 : list_01) setup_type(stringf("$_DFF_%c%c%c_", c1, c2, c3), {ID::C, ID::R, ID::D}, {ID::Q}); + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_01) + for (auto c4 : list_np) + setup_type(stringf("$_DFFE_%c%c%c%c_", c1, c2, c3, c4), {ID::C, ID::R, ID::D, ID::E}, {ID::Q}); + for (auto c1 : list_np) for (auto c2 : list_np) for (auto c3 : list_np) setup_type(stringf("$_DFFSR_%c%c%c_", c1, c2, c3), {ID::C, ID::S, ID::R, ID::D}, {ID::Q}); + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_np) + for (auto c4 : list_np) + setup_type(stringf("$_DFFSRE_%c%c%c%c_", c1, c2, c3, c4), {ID::C, ID::S, ID::R, ID::D, ID::E}, {ID::Q}); + + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_01) + setup_type(stringf("$_SDFF_%c%c%c_", c1, c2, c3), {ID::C, ID::R, ID::D}, {ID::Q}); + + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_01) + for (auto c4 : list_np) + setup_type(stringf("$_SDFFE_%c%c%c%c_", c1, c2, c3, c4), {ID::C, ID::R, ID::D, ID::E}, {ID::Q}); + + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_01) + for (auto c4 : list_np) + setup_type(stringf("$_SDFFCE_%c%c%c%c_", c1, c2, c3, c4), {ID::C, ID::R, ID::D, ID::E}, {ID::Q}); + for (auto c1 : list_np) setup_type(stringf("$_DLATCH_%c_", c1), {ID::E, ID::D}, {ID::Q}); + for (auto c1 : list_np) + for (auto c2 : list_np) + for (auto c3 : list_01) + setup_type(stringf("$_DLATCH_%c%c%c_", c1, c2, c3), {ID::E, ID::R, ID::D}, {ID::Q}); + for (auto c1 : list_np) for (auto c2 : list_np) for (auto c3 : list_np) diff --git a/kernel/constids.inc b/kernel/constids.inc index 383d7c615..69bc06d2c 100644 --- a/kernel/constids.inc +++ b/kernel/constids.inc @@ -158,6 +158,9 @@ X(SRC_EN) X(SRC_PEN) X(SRC_POL) X(SRC_WIDTH) +X(SRST) +X(SRST_POLARITY) +X(SRST_VALUE) X(STATE_BITS) X(STATE_NUM) X(STATE_NUM_LOG2) diff --git a/kernel/rtlil.cc b/kernel/rtlil.cc index ef81cac01..7e71adbb0 100644 --- a/kernel/rtlil.cc +++ b/kernel/rtlil.cc @@ -54,8 +54,14 @@ const pool &RTLIL::builtin_ff_cell_types() { ID($dff), ID($dffe), ID($dffsr), + ID($dffsre), ID($adff), + ID($adffe), + ID($sdff), + ID($sdffe), + ID($sdffce), ID($dlatch), + ID($adlatch), ID($dlatchsr), ID($_DFFE_NN_), ID($_DFFE_NP_), @@ -69,16 +75,102 @@ const pool &RTLIL::builtin_ff_cell_types() { ID($_DFFSR_PNP_), ID($_DFFSR_PPN_), ID($_DFFSR_PPP_), + ID($_DFFSRE_NNNN_), + ID($_DFFSRE_NNNP_), + ID($_DFFSRE_NNPN_), + ID($_DFFSRE_NNPP_), + ID($_DFFSRE_NPNN_), + ID($_DFFSRE_NPNP_), + ID($_DFFSRE_NPPN_), + ID($_DFFSRE_NPPP_), + ID($_DFFSRE_PNNN_), + ID($_DFFSRE_PNNP_), + ID($_DFFSRE_PNPN_), + ID($_DFFSRE_PNPP_), + ID($_DFFSRE_PPNN_), + ID($_DFFSRE_PPNP_), + ID($_DFFSRE_PPPN_), + ID($_DFFSRE_PPPP_), + ID($_DFF_N_), + ID($_DFF_P_), ID($_DFF_NN0_), ID($_DFF_NN1_), ID($_DFF_NP0_), ID($_DFF_NP1_), - ID($_DFF_N_), ID($_DFF_PN0_), ID($_DFF_PN1_), ID($_DFF_PP0_), ID($_DFF_PP1_), - ID($_DFF_P_), + ID($_DFFE_NN0N_), + ID($_DFFE_NN0P_), + ID($_DFFE_NN1N_), + ID($_DFFE_NN1P_), + ID($_DFFE_NP0N_), + ID($_DFFE_NP0P_), + ID($_DFFE_NP1N_), + ID($_DFFE_NP1P_), + ID($_DFFE_PN0N_), + ID($_DFFE_PN0P_), + ID($_DFFE_PN1N_), + ID($_DFFE_PN1P_), + ID($_DFFE_PP0N_), + ID($_DFFE_PP0P_), + ID($_DFFE_PP1N_), + ID($_DFFE_PP1P_), + ID($_SDFF_NN0_), + ID($_SDFF_NN1_), + ID($_SDFF_NP0_), + ID($_SDFF_NP1_), + ID($_SDFF_PN0_), + ID($_SDFF_PN1_), + ID($_SDFF_PP0_), + ID($_SDFF_PP1_), + ID($_SDFFE_NN0N_), + ID($_SDFFE_NN0P_), + ID($_SDFFE_NN1N_), + ID($_SDFFE_NN1P_), + ID($_SDFFE_NP0N_), + ID($_SDFFE_NP0P_), + ID($_SDFFE_NP1N_), + ID($_SDFFE_NP1P_), + ID($_SDFFE_PN0N_), + ID($_SDFFE_PN0P_), + ID($_SDFFE_PN1N_), + ID($_SDFFE_PN1P_), + ID($_SDFFE_PP0N_), + ID($_SDFFE_PP0P_), + ID($_SDFFE_PP1N_), + ID($_SDFFE_PP1P_), + ID($_SDFFCE_NN0N_), + ID($_SDFFCE_NN0P_), + ID($_SDFFCE_NN1N_), + ID($_SDFFCE_NN1P_), + ID($_SDFFCE_NP0N_), + ID($_SDFFCE_NP0P_), + ID($_SDFFCE_NP1N_), + ID($_SDFFCE_NP1P_), + ID($_SDFFCE_PN0N_), + ID($_SDFFCE_PN0P_), + ID($_SDFFCE_PN1N_), + ID($_SDFFCE_PN1P_), + ID($_SDFFCE_PP0N_), + ID($_SDFFCE_PP0P_), + ID($_SDFFCE_PP1N_), + ID($_SDFFCE_PP1P_), + ID($_SR_NN_), + ID($_SR_NP_), + ID($_SR_PN_), + ID($_SR_PP_), + ID($_DLATCH_N_), + ID($_DLATCH_P_), + ID($_DLATCH_NN0_), + ID($_DLATCH_NN1_), + ID($_DLATCH_NP0_), + ID($_DLATCH_NP1_), + ID($_DLATCH_PN0_), + ID($_DLATCH_PN1_), + ID($_DLATCH_PP0_), + ID($_DLATCH_PP1_), ID($_DLATCHSR_NNN_), ID($_DLATCHSR_NNP_), ID($_DLATCHSR_NPN_), @@ -87,8 +179,6 @@ const pool &RTLIL::builtin_ff_cell_types() { ID($_DLATCHSR_PNP_), ID($_DLATCHSR_PPN_), ID($_DLATCHSR_PPP_), - ID($_DLATCH_N_), - ID($_DLATCH_P_), ID($_FF_), }; return res; @@ -1139,6 +1229,21 @@ namespace { return; } + if (cell->type == ID($dffsre)) { + param_bool(ID::CLK_POLARITY); + param_bool(ID::SET_POLARITY); + param_bool(ID::CLR_POLARITY); + param_bool(ID::EN_POLARITY); + port(ID::CLK, 1); + port(ID::EN, 1); + port(ID::SET, param(ID::WIDTH)); + port(ID::CLR, param(ID::WIDTH)); + port(ID::D, param(ID::WIDTH)); + port(ID::Q, param(ID::WIDTH)); + check_expected(); + return; + } + if (cell->type == ID($adff)) { param_bool(ID::CLK_POLARITY); param_bool(ID::ARST_POLARITY); @@ -1151,6 +1256,46 @@ namespace { return; } + if (cell->type == ID($sdff)) { + param_bool(ID::CLK_POLARITY); + param_bool(ID::SRST_POLARITY); + param_bits(ID::SRST_VALUE, param(ID::WIDTH)); + port(ID::CLK, 1); + port(ID::SRST, 1); + port(ID::D, param(ID::WIDTH)); + port(ID::Q, param(ID::WIDTH)); + check_expected(); + return; + } + + if (cell->type.in(ID($sdffe), ID($sdffce))) { + param_bool(ID::CLK_POLARITY); + param_bool(ID::EN_POLARITY); + param_bool(ID::SRST_POLARITY); + param_bits(ID::SRST_VALUE, param(ID::WIDTH)); + port(ID::CLK, 1); + port(ID::EN, 1); + port(ID::SRST, 1); + port(ID::D, param(ID::WIDTH)); + port(ID::Q, param(ID::WIDTH)); + check_expected(); + return; + } + + if (cell->type == ID($adffe)) { + param_bool(ID::CLK_POLARITY); + param_bool(ID::EN_POLARITY); + param_bool(ID::ARST_POLARITY); + param_bits(ID::ARST_VALUE, param(ID::WIDTH)); + port(ID::CLK, 1); + port(ID::EN, 1); + port(ID::ARST, 1); + port(ID::D, param(ID::WIDTH)); + port(ID::Q, param(ID::WIDTH)); + check_expected(); + return; + } + if (cell->type == ID($dlatch)) { param_bool(ID::EN_POLARITY); port(ID::EN, 1); @@ -1160,6 +1305,18 @@ namespace { return; } + if (cell->type == ID($adlatch)) { + param_bool(ID::EN_POLARITY); + param_bool(ID::ARST_POLARITY); + param_bits(ID::ARST_VALUE, param(ID::WIDTH)); + port(ID::EN, 1); + port(ID::ARST, 1); + port(ID::D, param(ID::WIDTH)); + port(ID::Q, param(ID::WIDTH)); + check_expected(); + return; + } + if (cell->type == ID($dlatchsr)) { param_bool(ID::EN_POLARITY); param_bool(ID::SET_POLARITY); @@ -1351,49 +1508,69 @@ namespace { if (cell->type == ID($_MUX8_)) { port(ID::A,1); port(ID::B,1); port(ID::C,1); port(ID::D,1); port(ID::E,1); port(ID::F,1); port(ID::G,1); port(ID::H,1); port(ID::S,1); port(ID::T,1); port(ID::U,1); port(ID::Y,1); check_expected(); return; } if (cell->type == ID($_MUX16_)) { port(ID::A,1); port(ID::B,1); port(ID::C,1); port(ID::D,1); port(ID::E,1); port(ID::F,1); port(ID::G,1); port(ID::H,1); port(ID::I,1); port(ID::J,1); port(ID::K,1); port(ID::L,1); port(ID::M,1); port(ID::N,1); port(ID::O,1); port(ID::P,1); port(ID::S,1); port(ID::T,1); port(ID::U,1); port(ID::V,1); port(ID::Y,1); check_expected(); return; } - if (cell->type == ID($_SR_NN_)) { port(ID::S,1); port(ID::R,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_SR_NP_)) { port(ID::S,1); port(ID::R,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_SR_PN_)) { port(ID::S,1); port(ID::R,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_SR_PP_)) { port(ID::S,1); port(ID::R,1); port(ID::Q,1); check_expected(); return; } - - if (cell->type == ID($_FF_)) { port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFF_N_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); check_expected(); return; } - if (cell->type == ID($_DFF_P_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); check_expected(); return; } - - if (cell->type == ID($_DFFE_NN_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::E,1); check_expected(); return; } - if (cell->type == ID($_DFFE_NP_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::E,1); check_expected(); return; } - if (cell->type == ID($_DFFE_PN_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::E,1); check_expected(); return; } - if (cell->type == ID($_DFFE_PP_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::E,1); check_expected(); return; } - - if (cell->type == ID($_DFF_NN0_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_NN1_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_NP0_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_NP1_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_PN0_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_PN1_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_PP0_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - if (cell->type == ID($_DFF_PP1_)) { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } - - if (cell->type == ID($_DFFSR_NNN_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_NNP_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_NPN_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_NPP_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_PNN_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_PNP_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_PPN_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DFFSR_PPP_)) { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - - if (cell->type == ID($_DLATCH_N_)) { port(ID::E,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCH_P_)) { port(ID::E,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - - if (cell->type == ID($_DLATCHSR_NNN_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_NNP_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_NPN_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_NPP_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_PNN_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_PNP_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_PPN_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } - if (cell->type == ID($_DLATCHSR_PPP_)) { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } + if (cell->type.in(ID($_SR_NN_), ID($_SR_NP_), ID($_SR_PN_), ID($_SR_PP_))) + { port(ID::S,1); port(ID::R,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type == ID($_FF_)) { port(ID::D,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type.in(ID($_DFF_N_), ID($_DFF_P_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); check_expected(); return; } + + if (cell->type.in(ID($_DFFE_NN_), ID($_DFFE_NP_), ID($_DFFE_PN_), ID($_DFFE_PP_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::E,1); check_expected(); return; } + + if (cell->type.in( + ID($_DFF_NN0_), ID($_DFF_NN1_), ID($_DFF_NP0_), ID($_DFF_NP1_), + ID($_DFF_PN0_), ID($_DFF_PN1_), ID($_DFF_PP0_), ID($_DFF_PP1_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } + + if (cell->type.in( + ID($_DFFE_NN0N_), ID($_DFFE_NN0P_), ID($_DFFE_NN1N_), ID($_DFFE_NN1P_), + ID($_DFFE_NP0N_), ID($_DFFE_NP0P_), ID($_DFFE_NP1N_), ID($_DFFE_NP1P_), + ID($_DFFE_PN0N_), ID($_DFFE_PN0P_), ID($_DFFE_PN1N_), ID($_DFFE_PN1P_), + ID($_DFFE_PP0N_), ID($_DFFE_PP0P_), ID($_DFFE_PP1N_), ID($_DFFE_PP1P_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); port(ID::E,1); check_expected(); return; } + + if (cell->type.in( + ID($_DFFSR_NNN_), ID($_DFFSR_NNP_), ID($_DFFSR_NPN_), ID($_DFFSR_NPP_), + ID($_DFFSR_PNN_), ID($_DFFSR_PNP_), ID($_DFFSR_PPN_), ID($_DFFSR_PPP_))) + { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type.in( + ID($_DFFSRE_NNNN_), ID($_DFFSRE_NNNP_), ID($_DFFSRE_NNPN_), ID($_DFFSRE_NNPP_), + ID($_DFFSRE_NPNN_), ID($_DFFSRE_NPNP_), ID($_DFFSRE_NPPN_), ID($_DFFSRE_NPPP_), + ID($_DFFSRE_PNNN_), ID($_DFFSRE_PNNP_), ID($_DFFSRE_PNPN_), ID($_DFFSRE_PNPP_), + ID($_DFFSRE_PPNN_), ID($_DFFSRE_PPNP_), ID($_DFFSRE_PPPN_), ID($_DFFSRE_PPPP_))) + { port(ID::C,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::E,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type.in( + ID($_SDFF_NN0_), ID($_SDFF_NN1_), ID($_SDFF_NP0_), ID($_SDFF_NP1_), + ID($_SDFF_PN0_), ID($_SDFF_PN1_), ID($_SDFF_PP0_), ID($_SDFF_PP1_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); check_expected(); return; } + + if (cell->type.in( + ID($_SDFFE_NN0N_), ID($_SDFFE_NN0P_), ID($_SDFFE_NN1N_), ID($_SDFFE_NN1P_), + ID($_SDFFE_NP0N_), ID($_SDFFE_NP0P_), ID($_SDFFE_NP1N_), ID($_SDFFE_NP1P_), + ID($_SDFFE_PN0N_), ID($_SDFFE_PN0P_), ID($_SDFFE_PN1N_), ID($_SDFFE_PN1P_), + ID($_SDFFE_PP0N_), ID($_SDFFE_PP0P_), ID($_SDFFE_PP1N_), ID($_SDFFE_PP1P_), + ID($_SDFFCE_NN0N_), ID($_SDFFCE_NN0P_), ID($_SDFFCE_NN1N_), ID($_SDFFCE_NN1P_), + ID($_SDFFCE_NP0N_), ID($_SDFFCE_NP0P_), ID($_SDFFCE_NP1N_), ID($_SDFFCE_NP1P_), + ID($_SDFFCE_PN0N_), ID($_SDFFCE_PN0P_), ID($_SDFFCE_PN1N_), ID($_SDFFCE_PN1P_), + ID($_SDFFCE_PP0N_), ID($_SDFFCE_PP0P_), ID($_SDFFCE_PP1N_), ID($_SDFFCE_PP1P_))) + { port(ID::D,1); port(ID::Q,1); port(ID::C,1); port(ID::R,1); port(ID::E,1); check_expected(); return; } + + if (cell->type.in(ID($_DLATCH_N_), ID($_DLATCH_P_))) + { port(ID::E,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type.in( + ID($_DLATCH_NN0_), ID($_DLATCH_NN1_), ID($_DLATCH_NP0_), ID($_DLATCH_NP1_), + ID($_DLATCH_PN0_), ID($_DLATCH_PN1_), ID($_DLATCH_PP0_), ID($_DLATCH_PP1_))) + { port(ID::E,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } + + if (cell->type.in( + ID($_DLATCHSR_NNN_), ID($_DLATCHSR_NNP_), ID($_DLATCHSR_NPN_), ID($_DLATCHSR_NPP_), + ID($_DLATCHSR_PNN_), ID($_DLATCHSR_PNP_), ID($_DLATCHSR_PPN_), ID($_DLATCHSR_PPP_))) + { port(ID::E,1); port(ID::S,1); port(ID::R,1); port(ID::D,1); port(ID::Q,1); check_expected(); return; } error(__LINE__); } diff --git a/manual/CHAPTER_CellLib.tex b/manual/CHAPTER_CellLib.tex index 32c530582..25adcda86 100644 --- a/manual/CHAPTER_CellLib.tex +++ b/manual/CHAPTER_CellLib.tex @@ -234,16 +234,6 @@ Clock is active on the positive edge if this parameter has the value {\tt 1'b1} edge if this parameter is {\tt 1'b0}. \end{itemize} -D-type flip-flops with enable are represented by {\tt \$dffe} cells. As the {\tt \$dff} -cells they have \B{CLK}, \B{D} and \B{Q} ports. In addition they also have a single-bit \B{EN} -input port for the enable pin and the following parameter: - -\begin{itemize} -\item \B{EN\_POLARITY} \\ -The enable input is active-high if this parameter has the value {\tt 1'b1} and active-low -if this parameter is {\tt 1'b0}. -\end{itemize} - D-type flip-flops with asynchronous reset are represented by {\tt \$adff} cells. As the {\tt \$dff} cells they have \B{CLK}, \B{D} and \B{Q} ports. In addition they also have a single-bit \B{ARST} input port for the reset pin and the following additional two parameters: @@ -257,13 +247,26 @@ if this parameter is {\tt 1'b0}. The state of \B{Q} will be set to this value when the reset is active. \end{itemize} -Note that the {\tt \$adff} cell can only be used when the reset value is constant. - \begin{sloppypar} Usually these cells are generated by the {\tt proc} pass using the information in the designs RTLIL::Process objects. \end{sloppypar} +D-type flip-flops with synchronous reset are represented by {\tt \$sdff} cells. As the {\tt \$dff} +cells they have \B{CLK}, \B{D} and \B{Q} ports. In addition they also have a single-bit \B{SRST} +input port for the reset pin and the following additional two parameters: + +\begin{itemize} +\item \B{SRST\_POLARITY} \\ +The synchronous reset is active-high if this parameter has the value {\tt 1'b1} and active-low +if this parameter is {\tt 1'b0}. + +\item \B{SRST\_VALUE} \\ +The state of \B{Q} will be set to this value when the reset is active. +\end{itemize} + +Note that the {\tt \$adff} and {\tt \$sdff} cells can only be used when the reset value is constant. + D-type flip-flops with asynchronous set and reset are represented by {\tt \$dffsr} cells. As the {\tt \$dff} cells they have \B{CLK}, \B{D} and \B{Q} ports. In addition they also have a single-bit \B{SET} input port for the set pin, a single-bit \B{CLR} input port for the reset pin, @@ -282,9 +285,21 @@ if this parameter is {\tt 1'b0}. When both the set and reset inputs of a {\tt \$dffsr} cell are active, the reset input takes precedence. +D-type flip-flops with enable are represented by {\tt \$dffe}, {\tt \$adffe}, {\tt \$dffsre}, +{\tt \$sdffe}, and {\tt \$sdffce} cells, which are enhanced variants of {\tt \$dff}, {\tt \$adff}, {\tt \$dffsr}, +{\tt \$sdff} (with reset over enable) and {\tt \$sdff} (with enable over reset) +cells, respectively. They have the same ports and parameters as their base cell. +In addition they also have a single-bit \B{EN} input port for the enable pin and the following parameter: + +\begin{itemize} +\item \B{EN\_POLARITY} \\ +The enable input is active-high if this parameter has the value {\tt 1'b1} and active-low +if this parameter is {\tt 1'b0}. +\end{itemize} + \begin{fixme} Add information about {\tt \$sr} cells (set-reset flip-flops), {\tt \$dlatch} cells (d-type latches), -and {\tt \$dlatchsr} cells (d-type latches with set/reset). +{\tt \$adlatch} and {\tt \$dlatchsr} cells (d-type latches with set/reset). \end{fixme} \subsection{Memories} @@ -490,20 +505,29 @@ Verilog & Cell Type \\ \lstinline[language=Verilog]; always @(negedge C) Q <= D; & {\tt \$\_DFF\_N\_} \\ \lstinline[language=Verilog]; always @(posedge C) Q <= D; & {\tt \$\_DFF\_P\_} \\ \end{tabular} +\caption{Cell types for gate level logic networks (main list)} +\label{tab:CellLib_gates} +\end{table} + +\begin{table}[t] \hfil \begin{tabular}[t]{llll} $ClkEdge$ & $RstLvl$ & $RstVal$ & Cell Type \\ \hline -\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_NN0\_} \\ -\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_NN1\_} \\ -\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_NP0\_} \\ -\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_NP1\_} \\ -\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_PN0\_} \\ -\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_PN1\_} \\ -\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_PP0\_} \\ -\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_PP1\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_NN0\_}, {\tt \$\_SDFF\_NN0\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_NN1\_}, {\tt \$\_SDFF\_NN1\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_NP0\_}, {\tt \$\_SDFF\_NP0\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_NP1\_}, {\tt \$\_SDFF\_NP1\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_PN0\_}, {\tt \$\_SDFF\_PN0\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_PN1\_}, {\tt \$\_SDFF\_PN1\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFF\_PP0\_}, {\tt \$\_SDFF\_PP0\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFF\_PP1\_}, {\tt \$\_SDFF\_PP1\_} \\ \end{tabular} -% FIXME: the layout of this is broken and I have no idea how to fix it +\caption{Cell types for gate level logic networks (FFs with reset)} +\label{tab:CellLib_gates_adff} +\end{table} + +\begin{table}[t] \hfil \begin{tabular}[t]{lll} $ClkEdge$ & $EnLvl$ & Cell Type \\ @@ -513,7 +537,36 @@ $ClkEdge$ & $EnLvl$ & Cell Type \\ \lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_PN\_} \\ \lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_PP\_} \\ \end{tabular} -% FIXME: the layout of this is broken too +\caption{Cell types for gate level logic networks (FFs with enable)} +\label{tab:CellLib_gates_dffe} +\end{table} + +\begin{table}[t] +\begin{tabular}[t]{lllll} +$ClkEdge$ & $RstLvl$ & $RstVal$ & $EnLvl$ & Cell Type \\ +\hline +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_NN0N\_}, {\tt \$\_SDFFE\_NN0N\_}, {\tt \$\_SDFFCE\_NN0N\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_NN0P\_}, {\tt \$\_SDFFE\_NN0P\_}, {\tt \$\_SDFFCE\_NN0P\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_NN1N\_}, {\tt \$\_SDFFE\_NN1N\_}, {\tt \$\_SDFFCE\_NN1N\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_NN1P\_}, {\tt \$\_SDFFE\_NN1P\_}, {\tt \$\_SDFFCE\_NN1P\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_NP0N\_}, {\tt \$\_SDFFE\_NP0N\_}, {\tt \$\_SDFFCE\_NP0N\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_NP0P\_}, {\tt \$\_SDFFE\_NP0P\_}, {\tt \$\_SDFFCE\_NP0P\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_NP1N\_}, {\tt \$\_SDFFE\_NP1N\_}, {\tt \$\_SDFFCE\_NP1N\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_NP1P\_}, {\tt \$\_SDFFE\_NP1P\_}, {\tt \$\_SDFFCE\_NP1P\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_PN0N\_}, {\tt \$\_SDFFE\_PN0N\_}, {\tt \$\_SDFFCE\_PN0N\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_PN0P\_}, {\tt \$\_SDFFE\_PN0P\_}, {\tt \$\_SDFFCE\_PN0P\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_PN1N\_}, {\tt \$\_SDFFE\_PN1N\_}, {\tt \$\_SDFFCE\_PN1N\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_PN1P\_}, {\tt \$\_SDFFE\_PN1P\_}, {\tt \$\_SDFFCE\_PN1P\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_PP0N\_}, {\tt \$\_SDFFE\_PP0N\_}, {\tt \$\_SDFFCE\_PP0N\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_PP0P\_}, {\tt \$\_SDFFE\_PP0P\_}, {\tt \$\_SDFFCE\_PP0P\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFE\_PP1N\_}, {\tt \$\_SDFFE\_PP1N\_}, {\tt \$\_SDFFCE\_PP1N\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFE\_PP1P\_}, {\tt \$\_SDFFE\_PP1P\_}, {\tt \$\_SDFFCE\_PP1P\_} \\ +\end{tabular} +\caption{Cell types for gate level logic networks (FFs with reset and enable)} +\label{tab:CellLib_gates_adffe} +\end{table} + +\begin{table}[t] \hfil \begin{tabular}[t]{llll} $ClkEdge$ & $SetLvl$ & $RstLvl$ & Cell Type \\ @@ -527,11 +580,37 @@ $ClkEdge$ & $SetLvl$ & $RstLvl$ & Cell Type \\ \lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSR\_PPN\_} \\ \lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSR\_PPP\_} \\ \end{tabular} -\caption{Cell types for gate level logic networks} -\label{tab:CellLib_gates} +\caption{Cell types for gate level logic networks (FFs with set and reset)} +\label{tab:CellLib_gates_dffsr} +\end{table} + +\begin{table}[t] +\hfil +\begin{tabular}[t]{lllll} +$ClkEdge$ & $SetLvl$ & $RstLvl$ & $EnLvl$ & Cell Type \\ +\hline +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_NNNN\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_NNNP\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_NNPN\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_NNPP\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_NPNN\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_NPNP\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_NPPN\_} \\ +\lstinline[language=Verilog];negedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_NPPP\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_PNNN\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_PNNP\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_PNPN\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_PNPP\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_PPNN\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_PPNP\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];0; & {\tt \$\_DFFSRE\_PPPN\_} \\ +\lstinline[language=Verilog];posedge; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & \lstinline[language=Verilog];1; & {\tt \$\_DFFSRE\_PPPP\_} \\ +\end{tabular} +\caption{Cell types for gate level logic networks (FFs with set and reset and enable)} +\label{tab:CellLib_gates_dffsre} \end{table} -Table~\ref{tab:CellLib_gates} lists all cell types used for gate level logic. The cell types +Tables~\ref{tab:CellLib_gates}, \ref{tab:CellLib_gates_dffe}, \ref{tab:CellLib_gates_adff}, \ref{tab:CellLib_gates_adffe}, \ref{tab:CellLib_gates_dffsr} and \ref{tab:CellLib_gates_dffsre} list all cell types used for gate level logic. The cell types {\tt \$\_NOT\_}, {\tt \$\_AND\_}, {\tt \$\_NAND\_}, {\tt \$\_ANDNOT\_}, {\tt \$\_OR\_}, {\tt \$\_NOR\_}, {\tt \$\_ORNOT\_}, {\tt \$\_XOR\_}, {\tt \$\_XNOR\_} and {\tt \$\_MUX\_} are used to model combinatorial logic. The cell type {\tt \$\_TBUF\_} is used to model tristate logic. @@ -563,8 +642,61 @@ otherwise. Q <= D; \end{lstlisting} -The cell types {\tt \$\_DFFSR\_NNN\_}, {\tt \$\_DFFSR\_NNP\_}, {\tt \$\_DFFSR\_NPN\_}, {\tt \$\_DFFSR\_NPP\_}, -{\tt \$\_DFFSR\_PNN\_}, {\tt \$\_DFFSR\_PNP\_}, {\tt \$\_DFFSR\_PPN\_} and {\tt \$\_DFFSR\_PPP\_} implement +The cell types {\tt \$\_SDFF\_NN0\_}, {\tt \$\_SDFF\_NN1\_}, {\tt \$\_SDFF\_NP0\_}, {\tt \$\_SDFF\_NP1\_}, +{\tt \$\_SDFF\_PN0\_}, {\tt \$\_SDFF\_PN1\_}, {\tt \$\_SDFF\_PP0\_} and {\tt \$\_SDFF\_PP1\_} implement +d-type flip-flops with synchronous reset. The values in the table for these cell types relate to the +following Verilog code template: + +\begin{lstlisting}[mathescape,language=Verilog] + always @($ClkEdge$ C) + if (R == $RstLvl$) + Q <= $RstVal$; + else + Q <= D; +\end{lstlisting} + +The cell types {\tt \$\_DFFE\_[NP][NP][01][NP]\_} implement +d-type flip-flops with asynchronous reset and enable. The values in the table for these cell types relate to the +following Verilog code template, where \lstinline[mathescape,language=Verilog];$RstEdge$; is \lstinline[language=Verilog];posedge; +if \lstinline[mathescape,language=Verilog];$RstLvl$; if \lstinline[language=Verilog];1;, and \lstinline[language=Verilog];negedge; +otherwise. + +\begin{lstlisting}[mathescape,language=Verilog] + always @($ClkEdge$ C, $RstEdge$ R) + if (R == $RstLvl$) + Q <= $RstVal$; + else if (EN == $EnLvl$) + Q <= D; +\end{lstlisting} + +The cell types {\tt \$\_SDFFE\_[NP][NP][01][NP]\_} implement d-type flip-flops +with synchronous reset and enable, with reset having priority over enable. +The values in the table for these cell types relate to the +following Verilog code template: + +\begin{lstlisting}[mathescape,language=Verilog] + always @($ClkEdge$ C) + if (R == $RstLvl$) + Q <= $RstVal$; + else if (EN == $EnLvl$) + Q <= D; +\end{lstlisting} + +The cell types {\tt \$\_SDFFCE\_[NP][NP][01][NP]\_} implement d-type flip-flops +with synchronous reset and enable, with enable having priority over reset. +The values in the table for these cell types relate to the +following Verilog code template: + +\begin{lstlisting}[mathescape,language=Verilog] + always @($ClkEdge$ C) + if (EN == $EnLvl$) + if (R == $RstLvl$) + Q <= $RstVal$; + else + Q <= D; +\end{lstlisting} + +The cell types {\tt \$\_DFFSR\_[NP][NP][NP]\_} implement d-type flip-flops with asynchronous set and reset. The values in the table for these cell types relate to the following Verilog code template, where \lstinline[mathescape,language=Verilog];$RstEdge$; is \lstinline[language=Verilog];posedge; if \lstinline[mathescape,language=Verilog];$RstLvl$; if \lstinline[language=Verilog];1;, \lstinline[language=Verilog];negedge; @@ -582,6 +714,24 @@ otherwise. Q <= D; \end{lstlisting} +The cell types {\tt \$\_DFFSRE\_[NP][NP][NP][NP]\_} implement +d-type flip-flops with asynchronous set and reset and enable. The values in the table for these cell types relate to the +following Verilog code template, where \lstinline[mathescape,language=Verilog];$RstEdge$; is \lstinline[language=Verilog];posedge; +if \lstinline[mathescape,language=Verilog];$RstLvl$; if \lstinline[language=Verilog];1;, \lstinline[language=Verilog];negedge; +otherwise, and \lstinline[mathescape,language=Verilog];$SetEdge$; is \lstinline[language=Verilog];posedge; +if \lstinline[mathescape,language=Verilog];$SetLvl$; if \lstinline[language=Verilog];1;, \lstinline[language=Verilog];negedge; +otherwise. + +\begin{lstlisting}[mathescape,language=Verilog] + always @($ClkEdge$ C, $RstEdge$ R, $SetEdge$ S) + if (R == $RstLvl$) + Q <= 0; + else if (S == $SetLvl$) + Q <= 1; + else if (E == $EnLvl$) + Q <= D; +\end{lstlisting} + In most cases gate level logic networks are created from RTL networks using the {\tt techmap} pass. The flip-flop cells from the gate level logic network can be mapped to physical flip-flop cells from a Liberty file using the {\tt dfflibmap} pass. The combinatorial logic cells can be mapped to physical cells from a Liberty file via ABC \citeweblink{ABC} diff --git a/passes/cmds/stat.cc b/passes/cmds/stat.cc index 6f2c2243e..ed51fdc24 100644 --- a/passes/cmds/stat.cc +++ b/passes/cmds/stat.cc @@ -117,7 +117,10 @@ struct statdata_t } else if (cell_type.in(ID($mux), ID($pmux))) cell_type = stringf("%s_%d", cell_type.c_str(), GetSize(cell->getPort(ID::Y))); - else if (cell_type.in(ID($sr), ID($dff), ID($dffsr), ID($adff), ID($dlatch), ID($dlatchsr))) + else if (cell_type.in( + ID($sr), ID($ff), ID($dff), ID($dffe), ID($dffsr), ID($dffsre), + ID($adff), ID($adffe), ID($sdff), ID($sdffe), ID($sdffce), + ID($dlatch), ID($adlatch), ID($dlatchsr))) cell_type = stringf("%s_%d", cell_type.c_str(), GetSize(cell->getPort(ID::Q))); } diff --git a/techlibs/common/gen_fine_ffs.py b/techlibs/common/gen_fine_ffs.py index 0abe48f61..e92d58f40 100644 --- a/techlibs/common/gen_fine_ffs.py +++ b/techlibs/common/gen_fine_ffs.py @@ -108,6 +108,31 @@ endmodule """ // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- +//- $_DFFE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q) +//- +//- A {C:negative|positive} edge D-type flip-flop with {R:negative|positive} polarity {V:reset|set} and {E:negative|positive} +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - {R:0|1} - | {V:0|1} +//- d {C:\\|/} - {E:0|1} | d +//- - - - - | q +//- +module \$_DFFE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @({C:neg|pos}edge C or {R:neg|pos}edge R) begin + if (R == {R:0|1}) + Q <= {V:0|1}; + else if (E == {E:0|1}) + Q <= D; +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- //- $_DFFSR_{C:N|P}{S:N|P}{R:N|P}_ (C, S, R, D, Q) //- //- A {C:negative|positive} edge D-type flip-flop with {S:negative|positive} polarity set and {R:negative|positive} @@ -136,6 +161,110 @@ endmodule """ // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- +//- $_DFFSRE_{C:N|P}{S:N|P}{R:N|P}{E:N|P}_ (C, S, R, E, D, Q) +//- +//- A {C:negative|positive} edge D-type flip-flop with {S:negative|positive} polarity set, {R:negative|positive} +//- polarity reset and {E:negative|positive} polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - {R:0|1} - - | 0 +//- - {S:0|1} - - - | 1 +//- {C:\\|/} - - {E:0|1} d | d +//- - - - - - | q +//- +module \$_DFFSRE_{C:N|P}{S:N|P}{R:N|P}{E:N|P}_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @({C:neg|pos}edge C, {S:neg|pos}edge S, {R:neg|pos}edge R) begin + if (R == {R:0|1}) + Q <= 0; + else if (S == {S:0|1}) + Q <= 1; + else if (E == {E:0|1}) + Q <= D; +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_{C:N|P}{R:N|P}{V:0|1}_ (D, C, R, Q) +//- +//- A {C:negative|positive} edge D-type flip-flop with {R:negative|positive} polarity synchronous {V:reset|set}. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - {C:\\|/} {R:0|1} | {V:0|1} +//- d {C:\\|/} - | d +//- - - - | q +//- +module \$_SDFF_{C:N|P}{R:N|P}{V:0|1}_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @({C:neg|pos}edge C) begin + if (R == {R:0|1}) + Q <= {V:0|1}; + else + Q <= D; +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q) +//- +//- A {C:negative|positive} edge D-type flip-flop with {R:negative|positive} polarity synchronous {V:reset|set} and {E:negative|positive} +//- polarity clock enable (with {V:reset|set} having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - {C:\\|/} {R:0|1} - | {V:0|1} +//- d {C:\\|/} - {E:0|1} | d +//- - - - - | q +//- +module \$_SDFFE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @({C:neg|pos}edge C) begin + if (R == {R:0|1}) + Q <= {V:0|1}; + else if (E == {E:0|1}) + Q <= D; +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q) +//- +//- A {C:negative|positive} edge D-type flip-flop with {R:negative|positive} polarity synchronous {V:reset|set} and {E:negative|positive} +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - {C:\\|/} {R:0|1} {E:0|1} | {V:0|1} +//- d {C:\\|/} - {E:0|1} | d +//- - - - - | q +//- +module \$_SDFFCE_{C:N|P}{R:N|P}{V:0|1}{E:N|P}_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @({C:neg|pos}edge C) begin + if (E == {E:0|1}) begin + if (R == {R:0|1}) + Q <= {V:0|1}; + else + Q <= D; + end +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- //- $_DLATCH_{E:N|P}_ (E, D, Q) //- //- A {E:negative|positive} enable D-type latch. @@ -157,6 +286,30 @@ endmodule """ // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- +//- $_DLATCH_{E:N|P}{R:N|P}{V:0|1}_ (E, R, D, Q) +//- +//- A {E:negative|positive} enable D-type latch with {R:negative|positive} polarity {V:reset|set}. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - {R:0|1} - | {V:0|1} +//- {E:0|1} - d | d +//- - - - | q +//- +module \$_DLATCH_{E:N|P}{R:N|P}{V:0|1}_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == {E:0|1}) + Q <= {V:0|1}; + else if (E == {E:0|1}) + Q <= D; +end +endmodule +""", +""" +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- //- $_DLATCHSR_{E:N|P}{S:N|P}{R:N|P}_ (E, S, R, D, Q) //- //- A {E:negative|positive} enable D-type latch with {S:negative|positive} polarity set and {R:negative|positive} diff --git a/techlibs/common/simcells.v b/techlibs/common/simcells.v index 157e8d23b..01b5bdfa6 100644 --- a/techlibs/common/simcells.v +++ b/techlibs/common/simcells.v @@ -870,256 +870,2240 @@ endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_NNN_ (C, S, R, D, Q) +//- $_DFFE_NN0N_ (D, C, R, E, Q) //- -//- A negative edge D-type flip-flop with negative polarity set and negative -//- polarity reset. +//- A negative edge D-type flip-flop with negative polarity reset and negative +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- //- - - 0 - | 0 -//- - 0 - - | 1 -//- \ - - d | d +//- d \ - 0 | d //- - - - - | q //- -module \$_DFFSR_NNN_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_NN0N_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(negedge C, negedge S, negedge R) begin +always @(negedge C or negedge R) begin if (R == 0) Q <= 0; - else if (S == 0) + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_NN0P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity reset and positive +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 0 - | 0 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_DFFE_NN0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C or negedge R) begin + if (R == 0) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_NN1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set and negative +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 0 - | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_DFFE_NN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C or negedge R) begin + if (R == 0) Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_NNP_ (C, S, R, D, Q) +//- $_DFFE_NN1P_ (D, C, R, E, Q) //- //- A negative edge D-type flip-flop with negative polarity set and positive -//- polarity reset. +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 0 - | 1 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_DFFE_NN1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C or negedge R) begin + if (R == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_NP0N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity reset and negative +//- polarity clock enable. +//- +//- Truth table: D C R E | Q //- ---------+--- //- - - 1 - | 0 -//- - 0 - - | 1 -//- \ - - d | d +//- d \ - 0 | d //- - - - - | q //- -module \$_DFFSR_NNP_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_NP0N_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(negedge C, negedge S, posedge R) begin +always @(negedge C or posedge R) begin if (R == 1) Q <= 0; - else if (S == 0) - Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_NPN_ (C, S, R, D, Q) +//- $_DFFE_NP0P_ (D, C, R, E, Q) //- -//- A negative edge D-type flip-flop with positive polarity set and negative -//- polarity reset. +//- A negative edge D-type flip-flop with positive polarity reset and positive +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- -//- - - 0 - | 0 -//- - 1 - - | 1 -//- \ - - d | d +//- - - 1 - | 0 +//- d \ - 1 | d //- - - - - | q //- -module \$_DFFSR_NPN_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_NP0P_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(negedge C, posedge S, negedge R) begin - if (R == 0) +always @(negedge C or posedge R) begin + if (R == 1) Q <= 0; - else if (S == 1) + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_NP1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set and negative +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 1 - | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_DFFE_NP1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C or posedge R) begin + if (R == 1) Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_NPP_ (C, S, R, D, Q) +//- $_DFFE_NP1P_ (D, C, R, E, Q) //- //- A negative edge D-type flip-flop with positive polarity set and positive -//- polarity reset. +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- -//- - - 1 - | 0 -//- - 1 - - | 1 -//- \ - - d | d +//- - - 1 - | 1 +//- d \ - 1 | d //- - - - - | q //- -module \$_DFFSR_NPP_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_NP1P_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(negedge C, posedge S, posedge R) begin +always @(negedge C or posedge R) begin if (R == 1) - Q <= 0; - else if (S == 1) Q <= 1; - else + else if (E == 1) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_PNN_ (C, S, R, D, Q) +//- $_DFFE_PN0N_ (D, C, R, E, Q) //- -//- A positive edge D-type flip-flop with negative polarity set and negative -//- polarity reset. +//- A positive edge D-type flip-flop with negative polarity reset and negative +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- //- - - 0 - | 0 -//- - 0 - - | 1 -//- / - - d | d +//- d / - 0 | d //- - - - - | q //- -module \$_DFFSR_PNN_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_PN0N_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(posedge C, negedge S, negedge R) begin +always @(posedge C or negedge R) begin if (R == 0) Q <= 0; - else if (S == 0) - Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_PNP_ (C, S, R, D, Q) +//- $_DFFE_PN0P_ (D, C, R, E, Q) //- -//- A positive edge D-type flip-flop with negative polarity set and positive -//- polarity reset. +//- A positive edge D-type flip-flop with negative polarity reset and positive +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- -//- - - 1 - | 0 -//- - 0 - - | 1 -//- / - - d | d +//- - - 0 - | 0 +//- d / - 1 | d //- - - - - | q //- -module \$_DFFSR_PNP_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_PN0P_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(posedge C, negedge S, posedge R) begin - if (R == 1) +always @(posedge C or negedge R) begin + if (R == 0) Q <= 0; - else if (S == 0) + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_PN1N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set and negative +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 0 - | 1 +//- d / - 0 | d +//- - - - - | q +//- +module \$_DFFE_PN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C or negedge R) begin + if (R == 0) Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_PPN_ (C, S, R, D, Q) +//- $_DFFE_PN1P_ (D, C, R, E, Q) //- -//- A positive edge D-type flip-flop with positive polarity set and negative -//- polarity reset. +//- A positive edge D-type flip-flop with negative polarity set and positive +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- -//- - - 0 - | 0 -//- - 1 - - | 1 -//- / - - d | d +//- - - 0 - | 1 +//- d / - 1 | d //- - - - - | q //- -module \$_DFFSR_PPN_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_PN1P_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(posedge C, posedge S, negedge R) begin +always @(posedge C or negedge R) begin if (R == 0) - Q <= 0; - else if (S == 1) Q <= 1; - else + else if (E == 1) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DFFSR_PPP_ (C, S, R, D, Q) +//- $_DFFE_PP0N_ (D, C, R, E, Q) //- -//- A positive edge D-type flip-flop with positive polarity set and positive -//- polarity reset. +//- A positive edge D-type flip-flop with positive polarity reset and negative +//- polarity clock enable. //- -//- Truth table: C S R D | Q +//- Truth table: D C R E | Q //- ---------+--- //- - - 1 - | 0 -//- - 1 - - | 1 -//- / - - d | d +//- d / - 0 | d //- - - - - | q //- -module \$_DFFSR_PPP_ (C, S, R, D, Q); -input C, S, R, D; +module \$_DFFE_PP0N_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @(posedge C, posedge S, posedge R) begin +always @(posedge C or posedge R) begin if (R == 1) Q <= 0; - else if (S == 1) - Q <= 1; - else + else if (E == 0) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DLATCH_N_ (E, D, Q) +//- $_DFFE_PP0P_ (D, C, R, E, Q) //- -//- A negative enable D-type latch. +//- A positive edge D-type flip-flop with positive polarity reset and positive +//- polarity clock enable. //- -//- Truth table: E D | Q -//- -----+--- -//- 0 d | d -//- - - | q +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 1 - | 0 +//- d / - 1 | d +//- - - - - | q //- -module \$_DLATCH_N_ (E, D, Q); -input E, D; +module \$_DFFE_PP0P_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @* begin - if (E == 0) +always @(posedge C or posedge R) begin + if (R == 1) + Q <= 0; + else if (E == 1) Q <= D; end endmodule // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| //- -//- $_DLATCH_P_ (E, D, Q) +//- $_DFFE_PP1N_ (D, C, R, E, Q) //- -//- A positive enable D-type latch. +//- A positive edge D-type flip-flop with positive polarity set and negative +//- polarity clock enable. //- -//- Truth table: E D | Q -//- -----+--- -//- 1 d | d -//- - - | q +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 1 - | 1 +//- d / - 0 | d +//- - - - - | q //- -module \$_DLATCH_P_ (E, D, Q); -input E, D; +module \$_DFFE_PP1N_ (D, C, R, E, Q); +input D, C, R, E; output reg Q; -always @* begin - if (E == 1) +always @(posedge C or posedge R) begin + if (R == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFE_PP1P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set and positive +//- polarity clock enable. +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - - 1 - | 1 +//- d / - 1 | d +//- - - - - | q +//- +module \$_DFFE_PP1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C or posedge R) begin + if (R == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_NNN_ (C, S, R, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set and negative +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 0 - | 0 +//- - 0 - - | 1 +//- \ - - d | d +//- - - - - | q +//- +module \$_DFFSR_NNN_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(negedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_NNP_ (C, S, R, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set and positive +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 1 - | 0 +//- - 0 - - | 1 +//- \ - - d | d +//- - - - - | q +//- +module \$_DFFSR_NNP_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(negedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_NPN_ (C, S, R, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set and negative +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 0 - | 0 +//- - 1 - - | 1 +//- \ - - d | d +//- - - - - | q +//- +module \$_DFFSR_NPN_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(negedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_NPP_ (C, S, R, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set and positive +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 1 - | 0 +//- - 1 - - | 1 +//- \ - - d | d +//- - - - - | q +//- +module \$_DFFSR_NPP_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(negedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_PNN_ (C, S, R, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set and negative +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 0 - | 0 +//- - 0 - - | 1 +//- / - - d | d +//- - - - - | q +//- +module \$_DFFSR_PNN_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(posedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_PNP_ (C, S, R, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set and positive +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 1 - | 0 +//- - 0 - - | 1 +//- / - - d | d +//- - - - - | q +//- +module \$_DFFSR_PNP_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(posedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_PPN_ (C, S, R, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set and negative +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 0 - | 0 +//- - 1 - - | 1 +//- / - - d | d +//- - - - - | q +//- +module \$_DFFSR_PPN_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(posedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSR_PPP_ (C, S, R, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set and positive +//- polarity reset. +//- +//- Truth table: C S R D | Q +//- ---------+--- +//- - - 1 - | 0 +//- - 1 - - | 1 +//- / - - d | d +//- - - - - | q +//- +module \$_DFFSR_PPP_ (C, S, R, D, Q); +input C, S, R, D; +output reg Q; +always @(posedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NNNN_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set, negative +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 0 - - - | 1 +//- \ - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NNNN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NNNP_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set, negative +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 0 - - - | 1 +//- \ - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NNNP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NNPN_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set, positive +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 0 - - - | 1 +//- \ - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NNPN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NNPP_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with negative polarity set, positive +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 0 - - - | 1 +//- \ - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NNPP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NPNN_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set, negative +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 1 - - - | 1 +//- \ - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NPNN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NPNP_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set, negative +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 1 - - - | 1 +//- \ - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NPNP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NPPN_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set, positive +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 1 - - - | 1 +//- \ - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NPPN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_NPPP_ (C, S, R, E, D, Q) +//- +//- A negative edge D-type flip-flop with positive polarity set, positive +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 1 - - - | 1 +//- \ - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_NPPP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(negedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PNNN_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set, negative +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 0 - - - | 1 +//- / - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PNNN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PNNP_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set, negative +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 0 - - - | 1 +//- / - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PNNP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, negedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PNPN_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set, positive +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 0 - - - | 1 +//- / - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PNPN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PNPP_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with negative polarity set, positive +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 0 - - - | 1 +//- / - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PNPP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, negedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PPNN_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set, negative +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 1 - - - | 1 +//- / - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PPNN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PPNP_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set, negative +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 0 - - | 0 +//- - 1 - - - | 1 +//- / - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PPNP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, posedge S, negedge R) begin + if (R == 0) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PPPN_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set, positive +//- polarity reset and negative polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 1 - - - | 1 +//- / - - 0 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PPPN_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DFFSRE_PPPP_ (C, S, R, E, D, Q) +//- +//- A positive edge D-type flip-flop with positive polarity set, positive +//- polarity reset and positive polarity clock enable. +//- +//- Truth table: C S R E D | Q +//- -----------+--- +//- - - 1 - - | 0 +//- - 1 - - - | 1 +//- / - - 1 d | d +//- - - - - - | q +//- +module \$_DFFSRE_PPPP_ (C, S, R, E, D, Q); +input C, S, R, E, D; +output reg Q; +always @(posedge C, posedge S, posedge R) begin + if (R == 1) + Q <= 0; + else if (S == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_NN0_ (D, C, R, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous reset. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - \ 0 | 0 +//- d \ - | d +//- - - - | q +//- +module \$_SDFF_NN0_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 0; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_NN1_ (D, C, R, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous set. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - \ 0 | 1 +//- d \ - | d +//- - - - | q +//- +module \$_SDFF_NN1_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_NP0_ (D, C, R, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous reset. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - \ 1 | 0 +//- d \ - | d +//- - - - | q +//- +module \$_SDFF_NP0_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 0; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_NP1_ (D, C, R, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous set. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - \ 1 | 1 +//- d \ - | d +//- - - - | q +//- +module \$_SDFF_NP1_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_PN0_ (D, C, R, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous reset. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - / 0 | 0 +//- d / - | d +//- - - - | q +//- +module \$_SDFF_PN0_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 0; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_PN1_ (D, C, R, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous set. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - / 0 | 1 +//- d / - | d +//- - - - | q +//- +module \$_SDFF_PN1_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_PP0_ (D, C, R, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous reset. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - / 1 | 0 +//- d / - | d +//- - - - | q +//- +module \$_SDFF_PP0_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 0; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFF_PP1_ (D, C, R, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous set. +//- +//- Truth table: D C R | Q +//- -------+--- +//- - / 1 | 1 +//- d / - | d +//- - - - | q +//- +module \$_SDFF_PP1_ (D, C, R, Q); +input D, C, R; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 1; + else + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NN0N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous reset and negative +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 - | 0 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFE_NN0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NN0P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous reset and positive +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 - | 0 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFE_NN0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NN1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous set and negative +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 - | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFE_NN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NN1P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous set and positive +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 - | 1 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFE_NN1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NP0N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous reset and negative +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 - | 0 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFE_NP0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NP0P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous reset and positive +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 - | 0 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFE_NP0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NP1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous set and negative +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 - | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFE_NP1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_NP1P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous set and positive +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 - | 1 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFE_NP1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (R == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PN0N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous reset and negative +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 - | 0 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFE_PN0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PN0P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous reset and positive +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 - | 0 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFE_PN0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PN1N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous set and negative +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 - | 1 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFE_PN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PN1P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous set and positive +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 - | 1 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFE_PN1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 0) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PP0N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous reset and negative +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 - | 0 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFE_PP0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PP0P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous reset and positive +//- polarity clock enable (with reset having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 - | 0 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFE_PP0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PP1N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous set and negative +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 - | 1 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFE_PP1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFE_PP1P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous set and positive +//- polarity clock enable (with set having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 - | 1 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFE_PP1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (R == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NN0N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous reset and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 0 | 0 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_NN0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 0) begin + if (R == 0) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NN0P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous reset and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 1 | 0 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_NN0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 1) begin + if (R == 0) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NN1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous set and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 0 | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_NN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 0) begin + if (R == 0) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NN1P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with negative polarity synchronous set and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 0 1 | 1 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_NN1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 1) begin + if (R == 0) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NP0N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous reset and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 0 | 0 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_NP0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 0) begin + if (R == 1) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NP0P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous reset and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 1 | 0 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_NP0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 1) begin + if (R == 1) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NP1N_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous set and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 0 | 1 +//- d \ - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_NP1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 0) begin + if (R == 1) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_NP1P_ (D, C, R, E, Q) +//- +//- A negative edge D-type flip-flop with positive polarity synchronous set and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - \ 1 1 | 1 +//- d \ - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_NP1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(negedge C) begin + if (E == 1) begin + if (R == 1) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PN0N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous reset and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 0 | 0 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_PN0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 0) begin + if (R == 0) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PN0P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous reset and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 1 | 0 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_PN0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 1) begin + if (R == 0) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PN1N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous set and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 0 | 1 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_PN1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 0) begin + if (R == 0) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PN1P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with negative polarity synchronous set and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 0 1 | 1 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_PN1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 1) begin + if (R == 0) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PP0N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous reset and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 0 | 0 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_PP0N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 0) begin + if (R == 1) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PP0P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous reset and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 1 | 0 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_PP0P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 1) begin + if (R == 1) + Q <= 0; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PP1N_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous set and negative +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 0 | 1 +//- d / - 0 | d +//- - - - - | q +//- +module \$_SDFFCE_PP1N_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 0) begin + if (R == 1) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_SDFFCE_PP1P_ (D, C, R, E, Q) +//- +//- A positive edge D-type flip-flop with positive polarity synchronous set and positive +//- polarity clock enable (with clock enable having priority). +//- +//- Truth table: D C R E | Q +//- ---------+--- +//- - / 1 1 | 1 +//- d / - 1 | d +//- - - - - | q +//- +module \$_SDFFCE_PP1P_ (D, C, R, E, Q); +input D, C, R, E; +output reg Q; +always @(posedge C) begin + if (E == 1) begin + if (R == 1) + Q <= 1; + else + Q <= D; + end +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_N_ (E, D, Q) +//- +//- A negative enable D-type latch. +//- +//- Truth table: E D | Q +//- -----+--- +//- 0 d | d +//- - - | q +//- +module \$_DLATCH_N_ (E, D, Q); +input E, D; +output reg Q; +always @* begin + if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_P_ (E, D, Q) +//- +//- A positive enable D-type latch. +//- +//- Truth table: E D | Q +//- -----+--- +//- 1 d | d +//- - - | q +//- +module \$_DLATCH_P_ (E, D, Q); +input E, D; +output reg Q; +always @* begin + if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_NN0_ (E, R, D, Q) +//- +//- A negative enable D-type latch with negative polarity reset. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 0 - | 0 +//- 0 - d | d +//- - - - | q +//- +module \$_DLATCH_NN0_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 0) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_NN1_ (E, R, D, Q) +//- +//- A negative enable D-type latch with negative polarity set. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 0 - | 1 +//- 0 - d | d +//- - - - | q +//- +module \$_DLATCH_NN1_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_NP0_ (E, R, D, Q) +//- +//- A negative enable D-type latch with positive polarity reset. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 1 - | 0 +//- 0 - d | d +//- - - - | q +//- +module \$_DLATCH_NP0_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 0) + Q <= 0; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_NP1_ (E, R, D, Q) +//- +//- A negative enable D-type latch with positive polarity set. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 1 - | 1 +//- 0 - d | d +//- - - - | q +//- +module \$_DLATCH_NP1_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 0) + Q <= 1; + else if (E == 0) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_PN0_ (E, R, D, Q) +//- +//- A positive enable D-type latch with negative polarity reset. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 0 - | 0 +//- 1 - d | d +//- - - - | q +//- +module \$_DLATCH_PN0_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 1) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_PN1_ (E, R, D, Q) +//- +//- A positive enable D-type latch with negative polarity set. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 0 - | 1 +//- 1 - d | d +//- - - - | q +//- +module \$_DLATCH_PN1_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 1) + Q <= 1; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_PP0_ (E, R, D, Q) +//- +//- A positive enable D-type latch with positive polarity reset. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 1 - | 0 +//- 1 - d | d +//- - - - | q +//- +module \$_DLATCH_PP0_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 1) + Q <= 0; + else if (E == 1) + Q <= D; +end +endmodule + +// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| +//- +//- $_DLATCH_PP1_ (E, R, D, Q) +//- +//- A positive enable D-type latch with positive polarity set. +//- +//- Truth table: E R D | Q +//- -------+--- +//- - 1 - | 1 +//- 1 - d | d +//- - - - | q +//- +module \$_DLATCH_PP1_ (E, R, D, Q); +input E, R, D; +output reg Q; +always @* begin + if (R == 1) + Q <= 1; + else if (E == 1) Q <= D; end endmodule diff --git a/techlibs/common/simlib.v b/techlibs/common/simlib.v index 125b8e013..2660e6f15 100644 --- a/techlibs/common/simlib.v +++ b/techlibs/common/simlib.v @@ -1822,6 +1822,39 @@ endgenerate endmodule +// -------------------------------------------------------- + +module \$dffsre (CLK, SET, CLR, EN, D, Q); + +parameter WIDTH = 0; +parameter CLK_POLARITY = 1'b1; +parameter SET_POLARITY = 1'b1; +parameter CLR_POLARITY = 1'b1; +parameter EN_POLARITY = 1'b1; + +input CLK, EN; +input [WIDTH-1:0] SET, CLR, D; +output reg [WIDTH-1:0] Q; + +wire pos_clk = CLK == CLK_POLARITY; +wire [WIDTH-1:0] pos_set = SET_POLARITY ? SET : ~SET; +wire [WIDTH-1:0] pos_clr = CLR_POLARITY ? CLR : ~CLR; + +genvar i; +generate + for (i = 0; i < WIDTH; i = i+1) begin:bitslices + always @(posedge pos_set[i], posedge pos_clr[i], posedge pos_clk) + if (pos_clr[i]) + Q[i] <= 0; + else if (pos_set[i]) + Q[i] <= 1; + else if (EN == EN_POLARITY) + Q[i] <= D[i]; + end +endgenerate + +endmodule + `endif // -------------------------------------------------------- @@ -1849,6 +1882,107 @@ endmodule // -------------------------------------------------------- +module \$sdff (CLK, SRST, D, Q); + +parameter WIDTH = 0; +parameter CLK_POLARITY = 1'b1; +parameter SRST_POLARITY = 1'b1; +parameter SRST_VALUE = 0; + +input CLK, SRST; +input [WIDTH-1:0] D; +output reg [WIDTH-1:0] Q; +wire pos_clk = CLK == CLK_POLARITY; +wire pos_srst = SRST == SRST_POLARITY; + +always @(posedge pos_clk) begin + if (pos_srst) + Q <= SRST_VALUE; + else + Q <= D; +end + +endmodule + +// -------------------------------------------------------- + +module \$adffe (CLK, ARST, EN, D, Q); + +parameter WIDTH = 0; +parameter CLK_POLARITY = 1'b1; +parameter EN_POLARITY = 1'b1; +parameter ARST_POLARITY = 1'b1; +parameter ARST_VALUE = 0; + +input CLK, ARST, EN; +input [WIDTH-1:0] D; +output reg [WIDTH-1:0] Q; +wire pos_clk = CLK == CLK_POLARITY; +wire pos_arst = ARST == ARST_POLARITY; + +always @(posedge pos_clk, posedge pos_arst) begin + if (pos_arst) + Q <= ARST_VALUE; + else if (EN == EN_POLARITY) + Q <= D; +end + +endmodule + +// -------------------------------------------------------- + +module \$sdffe (CLK, SRST, EN, D, Q); + +parameter WIDTH = 0; +parameter CLK_POLARITY = 1'b1; +parameter EN_POLARITY = 1'b1; +parameter SRST_POLARITY = 1'b1; +parameter SRST_VALUE = 0; + +input CLK, SRST, EN; +input [WIDTH-1:0] D; +output reg [WIDTH-1:0] Q; +wire pos_clk = CLK == CLK_POLARITY; +wire pos_srst = SRST == SRST_POLARITY; + +always @(posedge pos_clk) begin + if (pos_srst) + Q <= SRST_VALUE; + else if (EN == EN_POLARITY) + Q <= D; +end + +endmodule + +// -------------------------------------------------------- + +module \$sdffce (CLK, SRST, EN, D, Q); + +parameter WIDTH = 0; +parameter CLK_POLARITY = 1'b1; +parameter EN_POLARITY = 1'b1; +parameter SRST_POLARITY = 1'b1; +parameter SRST_VALUE = 0; + +input CLK, SRST, EN; +input [WIDTH-1:0] D; +output reg [WIDTH-1:0] Q; +wire pos_clk = CLK == CLK_POLARITY; +wire pos_srst = SRST == SRST_POLARITY; + +always @(posedge pos_clk) begin + if (EN == EN_POLARITY) begin + if (pos_srst) + Q <= SRST_VALUE; + else + Q <= D; + end +end + +endmodule + +// -------------------------------------------------------- + module \$dlatch (EN, D, Q); parameter WIDTH = 0; @@ -1865,6 +1999,28 @@ end endmodule +// -------------------------------------------------------- + +module \$adlatch (EN, ARST, D, Q); + +parameter WIDTH = 0; +parameter EN_POLARITY = 1'b1; +parameter ARST_POLARITY = 1'b1; +parameter ARST_VALUE = 0; + +input EN, ARST; +input [WIDTH-1:0] D; +output reg [WIDTH-1:0] Q; + +always @* begin + if (ARST == ARST_POLARITY) + Q = ARST_VALUE; + else if (EN == EN_POLARITY) + Q = D; +end + +endmodule + // -------------------------------------------------------- `ifndef SIMLIB_NOSR