// The MLAB // -------- // In addition to Logic Array Blocks (LABs) that contain ten Adaptive Logic // Modules (ALMs, see alm_sim.v), the Cyclone V also contains // Memory/Logic Array Blocks (MLABs) that can act as either ten ALMs, or utilise // the memory the ALM uses to store the look-up table data for general usage, // producing a 32 address by 20-bit block of memory. MLABs are spread out // around the chip, so they can be placed near where they are needed, rather than // being comparatively limited in placement for a deep but narrow memory such as // the M10K memory block. // // MLABs are used mainly for shallow but wide memories, such as CPU register // files (which have perhaps 32 registers that are comparatively wide (16/32-bit)) // or shift registers (by using the output of the Nth bit as input for the N+1th // bit). // // For historical reasons a MISTRAL_MLAB cell represents a 32 address by 1-bit cell, // and 20 of them represent a physical MLAB. // // How the MLAB works // ------------------ // MLABs are poorly documented, so the following information is based mainly // on the simulation model and my knowledge of how memories like these work. // Additionally, note that the ports of MISTRAL_MLAB are the ones auto-generated // by the Yosys `memory_bram` pass, and it doesn't make sense to me to use // `techmap` just for the sake of renaming the cell ports. // // The MLAB can be initialised to any value. // // The MLAB takes in data from A1DATA at the rising edge of CLK1, and if A1EN // is high, writes it to the address in A1ADDR. A1EN can therefore be used to // conditionally write data to the MLAB. // // Simultaneously, the MLAB reads data from B1ADDR, and outputs it to B1DATA, // asynchronous to CLK1 and ignoring A1EN. If a synchronous read is needed // then the output can be fed to embedded flops. // The vendor sim model outputs 'x for a very short period (a few // combinational delta cycles) after each write. This has been omitted from // the following model because it's very difficult to trigger this in practice // as clock cycles will be much longer than any potential blip of 'x, so the // model can be treated as always returning a defined result. (* abc9_box, lib_whitebox *) module MISTRAL_MLAB(input [4:0] A1ADDR, input A1DATA, A1EN, (* clkbuf_sink *) input CLK1, input [4:0] B1ADDR, output B1DATA); reg [31:0] mem = 32'b0; `ifdef cyclonev specify $setup(A1ADDR, posedge CLK1, 86); $setup(A1DATA, posedge CLK1, 86); $setup(A1EN, posedge CLK1, 86); (B1ADDR[0] => B1DATA) = 487; (B1ADDR[1] => B1DATA) = 475; (B1ADDR[2] => B1DATA) = 382; (B1ADDR[3] => B1DATA) = 284; (B1ADDR[4] => B1DATA) = 96; endspecify `endif always @(posedge CLK1) if (A1EN) mem[A1ADDR] <= A1DATA; assign B1DATA = mem[B1ADDR]; endmodule // The M10K // -------- // TODO module MISTRAL_M10K(CLK1, A1ADDR, A1DATA, A1EN, B1ADDR, B1DATA, B1EN); parameter INIT = 0; parameter CFG_ABITS = 10; parameter CFG_DBITS = 10; (* clkbuf_sink *) input CLK1; input [CFG_ABITS-1:0] A1ADDR, B1ADDR; input [CFG_DBITS-1:0] A1DATA; input A1EN, B1EN; output reg [CFG_DBITS-1:0] B1DATA; reg [2**CFG_ABITS * CFG_DBITS - 1 : 0] mem = INIT; `ifdef cyclonev specify $setup(A1ADDR, posedge CLK1, 125); $setup(A1DATA, posedge CLK1, 97); $setup(A1EN, posedge CLK1, 140); $setup(B1ADDR, posedge CLK1, 125); $setup(B1EN, posedge CLK1, 161); if (B1EN) (posedge CLK1 => (B1DATA : A1DATA)) = 1004; endspecify `endif always @(posedge CLK1) begin if (!A1EN) mem[(A1ADDR + 1) * CFG_DBITS - 1 : A1ADDR * CFG_DBITS] <= A1DATA; if (B1EN) B1DATA <= mem[(B1ADDR + 1) * CFG_DBITS - 1 : B1ADDR * CFG_DBITS]; end endmodule