suzanne.soy/fpgatools
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
59649ea0a3
fpgatools/model.h
Wolfgang Spraul 59649ea0a3 minor floorplan fixes
2012-08-25 12:21:36 +02:00

663 lines
22 KiB
C
Raw Blame History

//
// Author: Wolfgang Spraul
//
// This is free and unencumbered software released into the public domain.
// For details see the UNLICENSE file at the root of the source tree.
//
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdint.h>
#include <assert.h>
#include <errno.h>
#include <sys/stat.h>
#include "helper.h"
//
// columns
// 'L' = X+L logic block
// 'M' = X+M logic block
// 'B' = block ram
// 'D' = dsp (macc)
// 'R' = registers and center IO/logic column
//
// 'n' = noio - can follow L or M to designate a logic
// column without IO at top or bottom
// 'g' = gclk - can follow LlMmBD to designate exactly one
// place on the left and right side of the chip where
// the global clock is separated into left and right
// half (on each side of the chip, for a total of 4
// vertical clock separations).
//
// wiring on the left and right side is described with 16
// characters for each row, order is top-down
// 'W' = wired
// 'U' = unwired
//
#define XC6SLX9_ROWS 4
#define XC6SLX9_COLUMNS "M L Bg M L D M R M Ln M L Bg M L"
#define XC6SLX9_LEFT_WIRING \
/* row 3 */ "UWUWUWUW" "WWWWUUUU" \
/* row 2 */ "UUUUUUUU" "WWWWWWUU" \
/* row 1 */ "WWWUUWUU" "WUUWUUWU" \
/* row 0 */ "UWUUWUUW" "UUWWWWUU"
#define XC6SLX9_RIGHT_WIRING \
/* row 3 */ "UUWWUWUW" "WWWWUUUU" \
/* row 2 */ "UUUUUUUU" "WWWWWWUU" \
/* row 1 */ "WWWUUWUU" "WUUWUUWU" \
/* row 0 */ "UWUUWUUW" "UUWWWWUU"
#define LEFT_SIDE_MAJOR 1
struct fpga_model
{
int cfg_rows;
char cfg_columns[512];
char cfg_left_wiring[1024], cfg_right_wiring[1024];
int x_width, y_height;
int center_x;
int center_y;
// Left and right gclk separators will be located on
// the device column (+1 or +2) of the logic or dsp/macc
// column as indicated in the chip's cfg_columns with a 'g'.
int left_gclk_sep_x, right_gclk_sep_x;
// x_major is an array of column indices for each x coordinate,
// starting with column 1 for the left side, and incrementing
// through the configuration columns. This corresponds to the
// 'majors' in the bitstream.
int x_major[512];
struct fpga_tile* tiles;
struct hashed_strarray str;
int num_nets;
struct fpga_net* nets;
// tmp_str will be allocated to hold max(x_width, y_height)
// pointers, useful for string seeding when running wires.
const char** tmp_str;
};
enum fpga_tile_type
{
NA = 0,
ROUTING, ROUTING_BRK, ROUTING_VIA,
HCLK_ROUTING_XM, HCLK_ROUTING_XL, HCLK_LOGIC_XM, HCLK_LOGIC_XL,
LOGIC_XM, LOGIC_XL,
REGH_ROUTING_XM, REGH_ROUTING_XL, REGH_LOGIC_XM, REGH_LOGIC_XL,
BRAM_ROUTING, BRAM_ROUTING_BRK,
BRAM,
BRAM_ROUTING_TERM_T, BRAM_ROUTING_TERM_B, BRAM_ROUTING_VIA_TERM_T, BRAM_ROUTING_VIA_TERM_B,
BRAM_TERM_LT, BRAM_TERM_RT, BRAM_TERM_LB, BRAM_TERM_RB,
HCLK_BRAM_ROUTING, HCLK_BRAM_ROUTING_VIA, HCLK_BRAM,
REGH_BRAM_ROUTING, REGH_BRAM_ROUTING_VIA, REGH_BRAM_L, REGH_BRAM_R,
MACC,
HCLK_MACC_ROUTING, HCLK_MACC_ROUTING_VIA, HCLK_MACC,
REGH_MACC_ROUTING, REGH_MACC_ROUTING_VIA, REGH_MACC_L,
PLL_T, DCM_T, PLL_B, DCM_B, REG_T,
REG_TERM_T, REG_TERM_B, REG_B,
REGV_TERM_T, REGV_TERM_B,
HCLK_REGV,
REGV, REGV_BRK, REGV_T, REGV_B, REGV_MIDBUF_T, REGV_HCLKBUF_T, REGV_HCLKBUF_B, REGV_MIDBUF_B,
REGC_ROUTING, REGC_LOGIC, REGC_CMT,
CENTER, // unique center tile in the middle of the chip
IO_T, IO_B, IO_TERM_T, IO_TERM_B, IO_ROUTING, IO_LOGIC_TERM_T, IO_LOGIC_TERM_B,
IO_OUTER_T, IO_INNER_T, IO_OUTER_B, IO_INNER_B,
IO_BUFPLL_TERM_T, IO_LOGIC_REG_TERM_T, IO_BUFPLL_TERM_B, IO_LOGIC_REG_TERM_B,
LOGIC_ROUTING_TERM_B, LOGIC_NOIO_TERM_B,
MACC_ROUTING_TERM_T, MACC_ROUTING_TERM_B, MACC_VIA_TERM_T,
MACC_TERM_TL, MACC_TERM_TR, MACC_TERM_BL, MACC_TERM_BR,
ROUTING_VIA_REGC, ROUTING_VIA_IO, ROUTING_VIA_IO_DCM, ROUTING_VIA_CARRY,
CORNER_TERM_L, CORNER_TERM_R,
IO_TERM_L_UPPER_TOP, IO_TERM_L_UPPER_BOT, IO_TERM_L_LOWER_TOP, IO_TERM_L_LOWER_BOT,
IO_TERM_R_UPPER_TOP, IO_TERM_R_UPPER_BOT, IO_TERM_R_LOWER_TOP, IO_TERM_R_LOWER_BOT,
IO_TERM_L, IO_TERM_R,
HCLK_TERM_L, HCLK_TERM_R,
REGH_IO_TERM_L, REGH_IO_TERM_R,
REG_L, REG_R,
IO_PCI_L, IO_PCI_R, IO_RDY_L, IO_RDY_R,
IO_L, IO_R,
IO_PCI_CONN_L, IO_PCI_CONN_R,
CORNER_TERM_T, CORNER_TERM_B,
ROUTING_IO_L,
HCLK_ROUTING_IO_L, HCLK_ROUTING_IO_R, REGH_ROUTING_IO_L, REGH_ROUTING_IO_R,
ROUTING_IO_L_BRK, ROUTING_GCLK,
REGH_IO_L, REGH_IO_R, REGH_MCB, HCLK_MCB,
ROUTING_IO_VIA_L, ROUTING_IO_VIA_R, ROUTING_IO_PCI_CE_L, ROUTING_IO_PCI_CE_R,
CORNER_TL, CORNER_BL,
CORNER_TR_UPPER, CORNER_TR_LOWER, CORNER_BR_UPPER, CORNER_BR_LOWER,
HCLK_IO_TOP_UP_L, HCLK_IO_TOP_UP_R,
HCLK_IO_TOP_SPLIT_L, HCLK_IO_TOP_SPLIT_R,
HCLK_IO_TOP_DN_L, HCLK_IO_TOP_DN_R,
HCLK_IO_BOT_UP_L, HCLK_IO_BOT_UP_R,
HCLK_IO_BOT_SPLIT_L, HCLK_IO_BOT_SPLIT_R,
HCLK_IO_BOT_DN_L, HCLK_IO_BOT_DN_R,
};
// Some macros to make the code more readable
#define LEFT_OUTER_COL 0
#define LEFT_INNER_COL 1
#define LEFT_IO_ROUTING 2
#define LEFT_IO_DEVS 3
#define LEFT_MCB_COL 4
#define LEFT_SIDE_WIDTH 5
#define RIGHT_SIDE_WIDTH 5
#define LEFT_LOCAL_HEIGHT 1
#define RIGHT_LOCAL_HEIGHT 2
#define TOP_IO_TILES 2
#define TOPBOT_IO_ROWS 2 // OUTER and INNER IO
// todo: maybe rename TOP_OUTER_ROW to TOP_OUTER_TERM and
// TOP_INNER_ROW to TOP_INNER_TERM?
#define TOP_OUTER_ROW 0
#define TOP_INNER_ROW 1
#define TOP_OUTER_IO 2
#define TOP_INNER_IO 3
#define HALF_ROW 8
#define HCLK_POS 8 // hclk pos in row
#define LAST_POS_IN_ROW 16 // including hclk at 8
#define ROW_SIZE (HALF_ROW+1+HALF_ROW)
#define CENTER_TOP_IOB_O 3 // deduct from center_x
#define CENTER_BOT_IOB_O 1 // add to center_x
// Some offsets that are being deducted from their origin
#define BOT_IO_TILES 2
// todo: rename BOT_OUTER_ROW to BOT_OUTER_TERM and BOT_INNER_ROW
// to BOT_INNER_TERM?
#define BOT_OUTER_ROW 1
#define BOT_INNER_ROW 2
#define BOT_OUTER_IO 3
#define BOT_INNER_IO 4
#define RIGHT_OUTER_O 1
#define RIGHT_INNER_O 2
#define RIGHT_MCB_O 3
#define RIGHT_IO_DEVS_O 4
#define RIGHT_IO_ROUTING_O 5
#define CENTER_CMTPLL_O 1
#define CENTER_LOGIC_O 2
#define CENTER_ROUTING_O 3
#define YX_TILE(model, y, x) (&(model)->tiles[(y)*(model)->x_width+(x)])
// tile flags
#define TF_FABRIC_ROUTING_COL 0x00000001 // only set in y==0, not for left and right IO routing or center
#define TF_FABRIC_LOGIC_XM_COL 0x00000002 // only set in y==0
#define TF_FABRIC_LOGIC_XL_COL 0x00000004 // only set in y==0
#define TF_FABRIC_BRAM_VIA_COL 0x00000008 // only set in y==0
#define TF_FABRIC_MACC_VIA_COL 0x00000010 // only set in y==0
#define TF_FABRIC_BRAM_COL 0x00000020 // only set in y==0
#define TF_FABRIC_MACC_COL 0x00000040 // only set in y==0
// TF_ROUTING_NO_IO is only set in y==0 - automatically for BRAM and MACC
// routing, and manually for logic routing with the noio flag in the column
// configuration string
#define TF_ROUTING_NO_IO 0x00000080
#define TF_BRAM_DEV 0x00000100
#define TF_MACC_DEV 0x00000200
#define TF_LOGIC_XL_DEV 0x00000400
#define TF_LOGIC_XM_DEV 0x00000800
#define TF_IOLOGIC_DELAY_DEV 0x00001000
#define TF_DCM_DEV 0x00002000
#define TF_PLL_DEV 0x00004000
// TF_WIRED is only set for x==0 on the left side or x==x_width-1
// on the right side.
#define TF_WIRED 0x00008000
#define Y_INNER_TOP 0x0001
#define Y_INNER_BOTTOM 0x0002
#define Y_CHIP_HORIZ_REGS 0x0004
#define Y_ROW_HORIZ_AXSYMM 0x0008
#define Y_BOTTOM_OF_ROW 0x0010
#define Y_LEFT_WIRED 0x0020
#define Y_RIGHT_WIRED 0x0040
// Y_TOPBOT_IO_RANGE checks if y points to the top or bottom outer or
// inner rows.
#define Y_TOPBOT_IO_RANGE 0x0080
#define Y_TOP_OUTER_IO 0x0100
#define Y_TOP_INNER_IO 0x0200
#define Y_BOT_INNER_IO 0x0400
#define Y_BOT_OUTER_IO 0x0800
// multiple checks are combined with OR logic
int is_aty(int check, struct fpga_model* model, int y);
#define X_FABRIC_LOGIC_COL (X_FABRIC_LOGIC_XM_COL \
|X_FABRIC_LOGIC_XL_COL)
#define X_FABRIC_LOGIC_ROUTING_COL (X_FABRIC_LOGIC_XM_ROUTING_COL \
|X_FABRIC_LOGIC_XL_ROUTING_COL)
#define X_FABRIC_ROUTING_COL (X_FABRIC_LOGIC_XM_ROUTING_COL \
|X_FABRIC_LOGIC_XL_ROUTING_COL \
|X_FABRIC_BRAM_ROUTING_COL \
|X_FABRIC_MACC_ROUTING_COL)
#define X_ROUTING_COL (X_FABRIC_ROUTING_COL \
|X_CENTER_ROUTING_COL \
|X_LEFT_IO_ROUTING_COL \
|X_RIGHT_IO_ROUTING_COL)
// todo and realizations:
// * maybe the center_logic and routing cols can also be
// seen as just a regular xl logic and routing cols.
// * maybe the many special cases for bram are better
// tied to no-io columns
#define X_OUTER_LEFT 0x00000001
#define X_INNER_LEFT 0x00000002
#define X_INNER_RIGHT 0x00000004
#define X_OUTER_RIGHT 0x00000008
#define X_ROUTING_NO_IO 0x00000010
#define X_FABRIC_LOGIC_XM_ROUTING_COL 0x00000020 // logic-xm only
#define X_FABRIC_LOGIC_XL_ROUTING_COL 0x00000040 // logic-xl only
#define X_FABRIC_LOGIC_XM_COL 0x00000080
#define X_FABRIC_LOGIC_XL_COL 0x00000100
#define X_FABRIC_BRAM_ROUTING_COL 0x00000200 // BRAM only
#define X_FABRIC_MACC_ROUTING_COL 0x00000400 // MACC only
#define X_FABRIC_BRAM_VIA_COL 0x00000800 // second routing col for BRAM
#define X_FABRIC_MACC_VIA_COL 0x00001000 // second routing col for MACC
#define X_FABRIC_BRAM_COL 0x00002000
#define X_FABRIC_MACC_COL 0x00004000
#define X_CENTER_ROUTING_COL 0x00008000
#define X_CENTER_LOGIC_COL 0x00010000
#define X_CENTER_CMTPLL_COL 0x00020000
#define X_CENTER_REGS_COL 0x00040000
#define X_LEFT_IO_ROUTING_COL 0x00080000
#define X_LEFT_IO_DEVS_COL 0x00100000
#define X_RIGHT_IO_ROUTING_COL 0x00200000
#define X_RIGHT_IO_DEVS_COL 0x00400000
#define X_LEFT_SIDE 0x00800000 // true for anything left of the center (not including center)
#define X_LEFT_MCB 0x01000000
#define X_RIGHT_MCB 0x02000000
#define IS_TOP_ROW(row, model) ((row) == (model)->cfg_rows-1)
#define IS_BOTTOM_ROW(row, model) ((row) == 0)
#define IS_CENTER_Y(row, model) ((row) == (model)->center_y)
#define BOT_TERM(model) ((model)->y_height-BOT_INNER_ROW)
#define TOP_TERM(model) (TOP_INNER_ROW)
// multiple checks are combined with OR logic
int is_atx(int check, struct fpga_model* model, int x);
// True for all tiles that are in the regular 0..15 row tiles of a routing col
#define YX_ROUTING_TILE 0x0001
#define YX_IO_ROUTING 0x0002
#define YX_ROUTING_TO_FABLOGIC 0x0004 // left of a regular fabric logic device
#define YX_DEV_ILOGIC 0x0008
#define YX_DEV_OLOGIC 0x0010
#define YX_DEV_LOGIC 0x0020
int is_atyx(int check, struct fpga_model* model, int y, int x);
// if not in row, both return values (if given) will
// be set to -1. the row_pos is 0..7 for the upper half,
// 8 for the hclk, and 9..16 for the lower half.
void is_in_row(const struct fpga_model* model, int y,
int* row_num, int* row_pos);
// which_row() and pos_in_row() return -1 if y is outside of a row
int which_row(int y, struct fpga_model* model);
int pos_in_row(int y, struct fpga_model* model);
const char* logicin_s(int wire, int routing_io);
enum fpgadev_type
{ DEV_NONE = 0,
DEV_LOGIC, DEV_TIEOFF, DEV_MACC, DEV_IOB,
DEV_ILOGIC, DEV_OLOGIC, DEV_IODELAY, DEV_BRAM16, DEV_BRAM8,
DEV_BUFH, DEV_BUFIO, DEV_BUFIO_FB, DEV_BUFPLL, DEV_BUFPLL_MCB,
DEV_BUFGMUX, DEV_BSCAN, DEV_DCM, DEV_PLL, DEV_ICAP,
DEV_POST_CRC_INTERNAL, DEV_STARTUP, DEV_SLAVE_SPI,
DEV_SUSPEND_SYNC, DEV_OCT_CALIBRATE, DEV_SPI_ACCESS };
#define FPGA_DEV_STR \
{ 0, \
"LOGIC", "TIEOFF", "MACC", "IOB", \
"ILOGIC", "OLOGIC", "IODELAY", "BRAM16", "BRAM8", \
"BUFH", "BUFIO", "BUFIO_FB", "BUFPLL", "BUFPLL_MCB", \
"BUFGMUX", "BSCAN", "DCM", "PLL", "ICAP", \
"POST_CRC_INTERNAL", "STARTUP", "SLAVE_SPI", \
"SUSPEND_SYNC", "OCT_CALIBRATE", "SPI_ACCESS" }
// We use two types of device indices, one is a flat index
// into the tile->devs array (dev_idx_t), the other
// one counts up from 0 through devices of one particular
// type in the tile. The first logic device has type_idx == 0,
// the second logic device has type_idx == 1, etc, no matter
// at which index they are in the device array. The type indices
// are used in the floorplan, the flat array indices internally
// in memory.
typedef int dev_idx_t;
typedef int dev_type_idx_t;
#define NO_DEV -1
#define FPGA_DEV(model, y, x, dev_idx) (&YX_TILE(model, y, x)->devs[dev_idx])
// M and L device is always at type index 0, X device
// is always at type index 1.
#define DEV_LOGM 0
#define DEV_LOGL 0
#define DEV_LOGX 1
// All device configuration is structured so that the value
// 0 is never a valid configured setting. That way all config
// data can safely be initialized to 0 meaning unconfigured.
enum { LOGIC_M = 1, LOGIC_L, LOGIC_X };
// All LOGICIN_IN A..D sequences must be exactly sequential as
// here to match initialization in model_device:init_logic().
enum { // input:
LOGIC_IN_A1 = 0,
LOGIC_IN_A2, LOGIC_IN_A3, LOGIC_IN_A4, LOGIC_IN_A5, LOGIC_IN_A6,
LOGIC_IN_B1, LOGIC_IN_B2, LOGIC_IN_B3, LOGIC_IN_B4, LOGIC_IN_B5,
LOGIC_IN_B6,
LOGIC_IN_C1, LOGIC_IN_C2, LOGIC_IN_C3, LOGIC_IN_C4, LOGIC_IN_C5,
LOGIC_IN_C6,
LOGIC_IN_D1, LOGIC_IN_D2, LOGIC_IN_D3, LOGIC_IN_D4, LOGIC_IN_D5,
LOGIC_IN_D6,
LOGIC_IN_AX, LOGIC_IN_BX, LOGIC_IN_CX, LOGIC_IN_DX,
LOGIC_IN_CLK, LOGIC_IN_CE, LOGIC_IN_SR,
// only for L and M:
LOGIC_IN_CIN, // only some L and M devs have this
// only for M:
LOGIC_IN_WE, LOGIC_IN_AI, LOGIC_IN_BI, LOGIC_IN_CI, LOGIC_IN_DI,
// output:
LOGIC_OUT_A, LOGIC_OUT_B, LOGIC_OUT_C, LOGIC_OUT_D,
LOGIC_OUT_AMUX, LOGIC_OUT_BMUX, LOGIC_OUT_CMUX, LOGIC_OUT_DMUX,
LOGIC_OUT_AQ, LOGIC_OUT_BQ, LOGIC_OUT_CQ, LOGIC_OUT_DQ,
LOGIC_OUT_COUT }; // only some L and M devs have this
#define LOGIC_LAST_INPUT_PINW LOGIC_IN_DI
#define LOGIC_LAST_OUTPUT_PINW LOGIC_OUT_COUT
#define LOGIC_PINW_STR \
{ "A1", "A2", "A3", "A4", "A5", "A6", \
"B1", "B2", "B3", "B4", "B5", "B6", \
"C1", "C2", "C3", "C4", "C5", "C6", \
"D1", "D2", "D3", "D4", "D5", "D6", \
"AX", "BX", "CX", "DX", \
"CLK", "CE", "SR", \
"CIN", \
"WE", "AI", "BI", "CI", "DI", \
"A", "B", "C", "D", \
"AMUX", "BMUX", "CMUX", "DMUX", \
"AQ", "BQ", "CQ", "DQ", \
"COUT" }
struct fpgadev_logic
{
int subtype; // LOGIC_M, LOGIC_L or LOGIC_X
int A_used, B_used, C_used, D_used;
char* A6_lut, *B6_lut, *C6_lut, *D6_lut;
};
enum { IOBM = 1, IOBS };
typedef char IOSTANDARD[32];
#define IO_LVCMOS33 "LVCMOS33"
enum { BYPASS_MUX_I = 1, BYPASS_MUX_O, BYPASS_MUX_T };
enum { IMUX_I_B = 1, IMUX_I };
enum { SLEW_SLOW = 1, SLEW_FAST, SLEW_QUIETIO };
enum { SUSP_LAST_VAL = 1, SUSP_3STATE, SUSP_3STATE_PULLUP,
SUSP_3STATE_PULLDOWN, SUSP_3STATE_KEEPER, SUSP_3STATE_OCT_ON };
enum { ITERM_NONE = 1, ITERM_UNTUNED_25, ITERM_UNTUNED_50,
ITERM_UNTUNED_75 };
enum { OTERM_NONE = 1, OTERM_UNTUNED_25, OTERM_UNTUNED_50,
OTERM_UNTUNED_75 };
enum { // input:
IOB_IN_O = 0, IOB_IN_T, IOB_IN_DIFFI_IN, IOB_IN_DIFFO_IN,
// output:
IOB_OUT_I, IOB_OUT_PADOUT, IOB_OUT_PCI_RDY, IOB_OUT_DIFFO_OUT };
#define IOB_LAST_INPUT_PINW IOB_IN_DIFFO_IN
#define IOB_LAST_OUTPUT_PINW IOB_OUT_DIFFO_OUT
#define IOB_PINW_STR \
{ "O", "T", "DIFFI_IN", "DIFFO_IN", \
"I", "PADOUT", "PCI_RDY", "DIFFO_OUT" }
struct fpgadev_iob
{
int subtype; // IOBM or IOBS
IOSTANDARD istandard;
IOSTANDARD ostandard;
int bypass_mux;
int I_mux;
int drive_strength; // supports 2,4,6,8,12,16 and 24
int slew;
int O_used;
int suspend;
int in_term;
int out_term;
};
typedef int pinw_idx_t; // index into pinw array
struct fpga_device
{
enum fpgadev_type type;
int instantiated;
// A bram dev has about 190 pinwires (input and output
// combined), macc about 350, mcb about 1200.
int num_pinw_total, num_pinw_in;
// The array holds first the input wires, then the output wires.
// Unused members are set to STRIDX_NO_ENTRY.
str16_t* pinw;
union {
struct fpgadev_logic logic;
struct fpgadev_iob iob;
};
};
#define SWITCH_USED 0x80000000
#define SWITCH_BIDIRECTIONAL 0x40000000
#define SWITCH_MAX_CONNPT_O 0x7FFF // 15 bits
#define SW_FROM_I(u32) (((u32) >> 15) & SWITCH_MAX_CONNPT_O)
#define SW_TO_I(u32) ((u32) & SWITCH_MAX_CONNPT_O)
#define SW_I(u32, from_to) ((from_to) ? SW_FROM_I(u32) : SW_TO_I(u32))
// SW_FROM and SW_TO values are chosen such that ! inverts them,
// and swf() assumes that SW_FROM is positive.
#define SW_FROM 1
#define SW_TO 0
#define NO_SWITCH -1
#define NO_CONN -1
struct fpga_tile
{
enum fpga_tile_type type;
int flags;
// expect up to 64 devices per tile
int num_devs;
struct fpga_device* devs;
// expect up to 5k connection point names per tile
// 2*16 bit per entry
// - index into conn_point_dests (not multiplied by 3) (16bit)
// - hashed string array index (16 bit)
// each conn point name exists only once in the array
int num_conn_point_names; // conn_point_names is 2*num_conn_point_names 16-bit words
uint16_t* conn_point_names; // num_conn_point_names*2 16-bit-words: 16(conn)-16(str)
// expect up to 28k connection point destinations to other tiles per tile
// 3*16 bit per destination:
// - x coordinate of other tile (16bit)
// - y coordinate of other tile (16bit)
// - hashed string array index for conn_point_names name in other tile (16bit)
int num_conn_point_dests; // conn_point_dests array is 3*num_conn_point_dests 16-bit words
uint16_t* conn_point_dests; // num_conn_point_dests*3 16-bit words: 16(x)-16(y)-16(conn_name)
// expect up to 4k switches per tile
// 32bit: 31 off: no connection on: connected
// 30 off: unidirectional on: bidirectional
// 29:15 from, index into conn_point_names (not yet *2)
// 14:0 to, index into conn_point_names (not yet *2)
int num_switches;
uint32_t* switches;
};
int fpga_build_model(struct fpga_model* model,
int fpga_rows, const char* columns,
const char* left_wiring, const char* right_wiring);
void fpga_free_model(struct fpga_model* model);
const char* fpga_tiletype_str(enum fpga_tile_type type);
int init_tiles(struct fpga_model* model);
int init_devices(struct fpga_model* model);
void free_devices(struct fpga_model* model);
const char* fpgadev_str(enum fpgadev_type type);
#define PINW_NO_IDX -1
pinw_idx_t fpgadev_pinw_str2idx(int devtype, const char* str);
// returns 0 when idx not found for the given devtype
const char* fpgadev_pinw_idx2str(int devtype, pinw_idx_t idx);
int init_ports(struct fpga_model* model, int dup_warn);
int init_conns(struct fpga_model* model);
int init_switches(struct fpga_model* model, int routing_sw);
// replicate_routing_switches() is a high-speed optimized way to
// initialize the routing switches, will only work before ports,
// connections or other switches.
int replicate_routing_switches(struct fpga_model* model);
const char* pf(const char* fmt, ...);
const char* wpref(struct fpga_model* model, int y, int x, const char* wire_name);
char next_non_whitespace(const char* s);
char last_major(const char* str, int cur_o);
int has_connpt(struct fpga_model* model, int y, int x, const char* name);
// add_connpt_name(): name_i and conn_point_o can be 0
int add_connpt_name(struct fpga_model* model, int y, int x,
const char* connpt_name, int warn_if_duplicate, uint16_t* name_i,
int* conn_point_o);
int has_device(struct fpga_model* model, int y, int x, int dev);
int has_device_type(struct fpga_model* model, int y, int x, int dev, int subtype);
int add_connpt_2(struct fpga_model* model, int y, int x,
const char* connpt_name, const char* suffix1, const char* suffix2,
int dup_warn);
typedef int (*add_conn_f)(struct fpga_model* model,
int y1, int x1, const char* name1,
int y2, int x2, const char* name2);
#define NOPREF_BI_F add_conn_bi
#define PREF_BI_F add_conn_bi_pref
#define NOPREF_UNI_F add_conn_uni
#define PREF_UNI_F add_conn_uni_pref
int add_conn_uni(struct fpga_model* model,
int y1, int x1, const char* name1,
int y2, int x2, const char* name2);
int add_conn_uni_pref(struct fpga_model* model,
int y1, int x1, const char* name1,
int y2, int x2, const char* name2);
int add_conn_bi(struct fpga_model* model,
int y1, int x1, const char* name1,
int y2, int x2, const char* name2);
int add_conn_bi_pref(struct fpga_model* model,
int y1, int x1, const char* name1,
int y2, int x2, const char* name2);
int add_conn_range(struct fpga_model* model, add_conn_f add_conn_func,
int y1, int x1, const char* name1, int start1, int last1,
int y2, int x2, const char* name2, int start2);
// COUNT_DOWN can be OR'ed to start_count to make
// the enumerated wires count from start_count down.
#define COUNT_DOWN 0x100
#define COUNT_MASK 0xFF
struct w_point // wire point
{
const char* name;
int start_count; // if there is a %i in the name, this is the start number
int y, x;
};
#define NO_INCREMENT 0
struct w_net
{
// if !last_inc, no incrementing will happen (NO_INCREMENT)
// if last_inc > 0, incrementing will happen to
// the %i in the name from 0:last_inc, for a total
// of last_inc+1 wires.
int last_inc;
struct w_point pts[40];
};
int add_conn_net(struct fpga_model* model, add_conn_f add_conn_func, struct w_net* net);
int add_switch(struct fpga_model* model, int y, int x, const char* from,
const char* to, int is_bidirectional);
int add_switch_set(struct fpga_model* model, int y, int x, const char* prefix,
const char** pairs, int suffix_inc);
// This will replicate the entire conn_point_names and switches arrays
// from one tile to another, assuming that all of conn_point_names,
// switches and conn_point_dests in the destination tile are empty.
int replicate_switches_and_names(struct fpga_model* model,
int y_from, int x_from, int y_to, int x_to);
struct seed_data
{
int x_flags;
const char* str;
};
void seed_strx(struct fpga_model* model, struct seed_data* data);
// The LWF flags are OR'ed into the logic_wire enum
#define LWF_SOUTH0 0x0100
#define LWF_NORTH3 0x0200
#define LWF_BIDIR 0x0400
#define LWF_FAN_B 0x0800
#define LWF_WIRE_MASK 0x00FF // namespace for the enums
enum logicin_wire {
/* 0 */ X_A1 = 0,
X_A2, X_A3, X_A4, X_A5, X_A6, X_AX,
/* 7 */ X_B1, X_B2, X_B3, X_B4, X_B5, X_B6, X_BX,
/* 14 */ X_C1, X_C2, X_C3, X_C4, X_C5, X_C6, X_CE, X_CX,
/* 22 */ X_D1, X_D2, X_D3, X_D4, X_D5, X_D6, X_DX,
/* 29 */ M_A1, M_A2, M_A3, M_A4, M_A5, M_A6, M_AX, M_AI,
/* 37 */ M_B1, M_B2, M_B3, M_B4, M_B5, M_B6, M_BX, M_BI,
/* 45 */ M_C1, M_C2, M_C3, M_C4, M_C5, M_C6, M_CE, M_CX, M_CI,
/* 54 */ M_D1, M_D2, M_D3, M_D4, M_D5, M_D6, M_DX, M_DI,
/* 62 */ M_WE
};
enum logicout_wire {
/* 0 */ X_A = 0,
X_AMUX, X_AQ, X_B, X_BMUX, X_BQ,
/* 6 */ X_C, X_CMUX, X_CQ, X_D, X_DMUX, X_DQ,
/* 12 */ M_A, M_AMUX, M_AQ, M_B, M_BMUX, M_BQ,
/* 18 */ M_C, M_CMUX, M_CQ, M_D, M_DMUX, M_DQ
};
const char* logicin_str(enum logicin_wire w);
const char* logicout_str(enum logicout_wire w);
// The extra wires must not overlap with logicin_wire or logicout_wire
// namespaces so that they can be combined with either of them.
enum extra_wires {
UNDEF = 100,
FAN_B,
GFAN0,
GFAN1,
LOGICIN20,
LOGICIN21,
LOGICIN44,
LOGICIN52,
LOGICIN_N21,
LOGICIN_N28,
LOGICIN_N52,
LOGICIN_N60,
LOGICIN_S20,
LOGICIN_S36,
LOGICIN_S44,
LOGICIN_S62
};
Reference in New Issue View Git Blame Copy Permalink