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[/] [pci/] [trunk/] [apps/] [crt/] [syn/] [synplify/] [pci_crt.ucf] - Rev 154
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############################################### BASIC UCF SYNTAX EXAMPLES V2.1.6 ################################################# The "#" symbol is a comment character. To use this sample file, find the# specification necessary, remove the comment character (#) from the beginning# of the line, and modify the line (if necessary) to fit your design.## TIMING SPECIFICATIONS## Timing specifications can be applied to the entire device (global) or to# specific groups in your design (called "time groups'). The time groups are# declared in two basic ways.## Method 1: Based on a net name, where 'my_net' is a net that touches all the# logic to be grouped in to 'logic_grp'. Example:#NET my_net TNM_NET = logic_grp ;## Method 2: Group using the key word 'TIMEGRP' and declare using the names of# logic in your design. Example:#TIMEGRP group_name = FFS ("U1/*");# creates a group called 'group_name' for all flip-flops within# the hierarchical block called U1. Wildcards are valid.## Grouping is very important because it lets you tell the software which parts# of a design run at which speeds. For the majority of the designs with only# one clock, use simple global constraints.## The type of grouping constraint you use can vary depending on the synthesis# tools you are using. Foundation Express does better with Method 2.############################################################### Internal to the device clock speed specifications - Tsys ############################################################### data _________ /^^^^^\ _________ out# ----------| D Q |-----{ LOGIC } -----| D Q |------# | | \vvvvv/ | |# ---|> CLK | ---|> CLK |# clock | --------- | ---------# ------------------------------------## ---------------# Single Clock# ---------------## ----------------# PERIOD TIME-SPEC# ----------------# The PERIOD spec. covers all timing paths that start or end at a# register, latch, or synchronous RAM which are clocked by the reference# net (excluding pad destinations). Also covered is the setup# requirement of the synchronous element relative to other elements# (ex. flip flops, pads, etc...).# NOTE: The default unit for time is nanoseconds.##NET clock PERIOD = 50ns ;## -OR-## ------------------# FROM:TO TIME-SPECs# ------------------# FROM:TO style timespecs can be used to constrain paths between time# groups. NOTE: Keywords: RAMS, FFS, PADS, and LATCHES are predefined# time groups used to specify all elements of each type in a design.#TIMEGRP RFFS = RISING FFS ("*"); // creates a rising group called RFFS#TIMEGRP FFFS = FALLING FFS ("*"); // creates a falling group called FFFS#TIMESPEC TSF2F = FROM : FFS : TO : FFS : 50 ns; // Flip-flips with the same edge#TIMESPEC TSR2F = FROM : RFFS : TO : FFFS : 25 ns; // rising edge to falling edge#TIMESPEC TSF2R = FROM : FFFS : TO : RFFS : 25 ns; // falling edge to rising edge## ---------------# Multiple Clocks# ---------------# Requires a combination of the 'Period' and 'FROM:TO' type time specifications#NET clock1 TNM_NET = clk1_grp ;#NET clock2 TNM_NET = clk2_grp ;##TIMESPEC TS_clk1 = PERIOD : clk1_grp : 50 ;#TIMESPEC TS_clk2 = PERIOD : clk2_grp : 30 ;#TIMESPEC TS_ck1_2_ck2 = FROM : clk1_grp : TO : clk2_grp : 50 ;#TIMESPEC TS_ck2_2_ck1 = FROM : clk2_grp : TO : clk1_grp : 30 ;############################################################### CLOCK TO OUT specifications - Tco ############################################################### from _________ /^^^^^\ --------\# ----------| D Q |-----{ LOGIC } -----| Pad ># PLD | | \vvvvv/ --------/# ---|> CLK |# clock | ---------# --------## ----------------# OFFSET TIME-SPEC# ----------------# To automatically include clock buffer/routing delay in your# clock-to-out timing specifications, use OFFSET constraints .# For an output where the maximum clock-to-out (Tco) is 25 ns:##NET out_net_name OFFSET = OUT 25 AFTER clock_net_name ;## -OR-## ------------------# FROM:TO TIME-SPECs# ------------------#TIMESPEC TSF2P = FROM : FFS : TO : PADS : 25 ns;# Note that FROM: FFS : TO: PADS constraints start the delay analysis# at the flip flop itself, and not the clock input pin. The recommended# method to create a clock-to-out constraint is to use an OFFSET constraint.############################################################### Pad to Flip-Flop speed specifications - Tsu ############################################################### ------\ /^^^^^\ _________ into PLD# |pad >-------{ LOGIC } -----| D Q |------# ------/ \vvvvv/ | |# ---|> CLK |# clock | ---------# ----------------------------## ----------------# OFFSET TIME-SPEC# ----------------# To automatically account for clock delay in your input setup timing# specifications, use OFFSET constraints.# For an input where the maximum setup time is 25 ns:#NET in_net_name OFFSET = IN 25 BEFORE clock_net_name ;## -OR-## ------------------# FROM:TO TIME-SPECs# ------------------#TIMESPEC TSP2F = FROM : PADS : TO : FFS : 25 ns;# Note that FROM: PADS : TO: FFS constraints do not take into account any# delay for the clock path. The recommended method to create an input# setup time constraint is to use an OFFSET constraint.############################################################### Pad to Pad speed specifications - Tpd ############################################################### ------\ /^^^^^\ -------\# |pad >-------{ LOGIC } -----| pad ># ------/ \vvvvv/ -------/## ------------------# FROM:TO TIME-SPECs# ------------------#TIMESPEC TSP2P = FROM : PADS : TO : PADS : 125 ns;############################################################### Other timing specifications ############################################################### -------------# TIMING IGNORE# -------------# If you can ignore timing of paths, use Timing Ignore (TIG). NOTE: The# "*" character is a wild card, which can be used for bus names. A "?"# character can be used to wild-card one character.# Ignore timing of net reset_n:#NET : reset_n : TIG ;## Ignore data_reg(7:0) net in instance mux_mem:#NET : mux_mem/data_reg* : TIG ;## Ignore data_reg(7:0) net in instance mux_mem as related to a TIMESPEC# named TS01 only:#NET : mux_mem/data_reg* : TIG = TS01 ;## Ignore data1_sig and data2_sig nets:#NET : data?_sig : TIG ;## ---------------# PATH EXCEPTIONS# ---------------# If your design has outputs that can be slower than others, you can# create specific timespecs similar to this example for output nets# named out_data(7:0) and irq_n:#TIMEGRP slow_outs = PADS(out_data* : irq_n) ;#TIMEGRP fast_outs = PADS : EXCEPT : slow_outs ;#TIMESPEC TS08 = FROM : FFS : TO : fast_outs : 22 ;#TIMESPEC TS09 = FROM : FFS : TO : slow_outs : 75 ;## If you have multi-cycle FF to FF paths, you can create a time group# using either the TIMEGRP or TNM statements.## WARNING: Many VHDL/Verilog synthesizers do not predictably name flip# flop Q output nets. Most synthesizers do assign predictable instance# names to flip flops, however.## TIMEGRP example:#TIMEGRP slowffs = FFS(inst_path/ff_q_output_net1* :#inst_path/ff_q_output_net2*);## TNM attached to instance example:#INST inst_path/ff_instance_name1_reg* TNM = slowffs ;#INST inst_path/ff_instance_name2_reg* TNM = slowffs ;## If a FF clock-enable is used on all flip flops of a multi-cycle path,# you can attach TNM to the clock enable net. NOTE: TNM attached to a# net "forward traces" to any FF, LATCH, RAM, or PAD attached to the# net.#NET ff_clock_enable_net TNM = slowffs ;## Example of using "slowffs" timegroup, in a FROM:TO timespec, with# either of the three timegroup methods shown above:#TIMESPEC TS10 = FROM : slowffs : TO : FFS : 100 ;## Constrain the skew or delay associate with a net.#NET any_net_name MAXSKEW = 7 ;#NET any_net_name MAXDELAY = 20 ns;### Constraint priority in your .ucf file is as follows:## highest 1. Timing Ignore (TIG)# 2. FROM : THRU : TO specs# 3. FROM : TO specs# lowest 4. PERIOD specs## See the on-line "Library Reference Guide" document for# additional timespec features and more information.############################################################### ## LOCATION and ATTRIBUTE SPECIFICATIONS ## ############################################################## Pin and CLB location locking constraints ############################################################### -----------------------# Assign an IO pin number# -----------------------#INST io_buf_instance_name LOC = P110 ;#NET io_net_name LOC = P111 ;## -----------------------# Assign a signal to a range of I/O pins# -----------------------#NET "signal_name" LOC=P32, P33, P34;## -----------------------# Place a logic element(called a BEL) in a specific CLB location.# BEL = FF, LUT, RAM, etc...# -----------------------#INST instance_path/BEL_inst_name LOC = CLB_R17C36 ;## -----------------------# Place CLB in rectangular area from CLB R1C1 to CLB R5C7# -----------------------#INST /U1/U2/reg<0> LOC=clb_r1c1:clb_r5c7;## -----------------------# Place hierarchical logic block in rectangular area from CLB R1C1 to CLB R5C7# -----------------------#INST /U1* LOC=clb_r1c1:clb_r5c7;## -----------------------# Prohibit IO pin P26 or CLBR5C3 from being used:# -----------------------#CONFIG PROHIBIT = P26 ;#CONFIG PROHIBIT = CLB_R5C3 ;# Config Prohibit is very important for forcing the software to not use critical# configuration pins like INIT or DOUT on the FPGA. The Mode pins and JTAG# Pins require a special pad so they will not be available to this constraint## -----------------------# Assign an OBUF to be FAST or SLOW:# -----------------------#INST obuf_instance_name FAST ;#INST obuf_instance_name SLOW ;## -----------------------# FPGAs only: IOB input Flip-flop delay specification# -----------------------# Declare an IOB input FF delay (default = MAXDELAY).# NOTE: MEDDELAY/NODELAY can be attached to a CLB FF that is pushed# into an IOB by the "map -pr i" option.#INST input_ff_instance_name MEDDELAY ;#INST input_ff_instance_name NODELAY ;## -----------------------# Assign Global Clock Buffers Lower Left Right Side# -----------------------# INST gbuf1 LOC=SSW## ## define a group of metastable Flip-FlopsINST *sync_data_out* TNM = sync_ffs ;TIMESPEC TS_sync_flops = FROM : sync_ffs : TO : FFS : 15 ;INST *meta_q_o* TNM = meta_ffs ;TIMESPEC TS_meta_flops = FROM : meta_ffs : TO : FFS : 15 ;NET CLK TNM_NET = CLK_GRP ;NET CRT_CLK TNM_NET = CRT_CLK_GRP ;TIMESPEC TS_CLK_2_CRT_CLK = FROM : CLK_GRP : TO : CRT_CLK_GRP : 15 ;TIMESPEC TS_CRT_CLK_2_CLK = FROM : CRT_CLK_GRP : TO : CLK_GRP : 15 ;NET "AD0" IOSTANDARD = PCI33_5;NET "AD1" IOSTANDARD = PCI33_5;NET "AD2" IOSTANDARD = PCI33_5;NET "AD3" IOSTANDARD = PCI33_5;NET "AD4" IOSTANDARD = PCI33_5;NET "AD5" IOSTANDARD = PCI33_5;NET "AD6" IOSTANDARD = PCI33_5;NET "AD7" IOSTANDARD = PCI33_5;NET "AD8" IOSTANDARD = PCI33_5;NET "AD9" IOSTANDARD = PCI33_5;NET "AD10" IOSTANDARD = PCI33_5;NET "AD11" IOSTANDARD = PCI33_5;NET "AD12" IOSTANDARD = PCI33_5;NET "AD13" IOSTANDARD = PCI33_5;NET "AD14" IOSTANDARD = PCI33_5;NET "AD15" IOSTANDARD = PCI33_5;NET "AD16" IOSTANDARD = PCI33_5;NET "AD17" IOSTANDARD = PCI33_5;NET "AD18" IOSTANDARD = PCI33_5;NET "AD19" IOSTANDARD = PCI33_5;NET "AD20" IOSTANDARD = PCI33_5;NET "AD21" IOSTANDARD = PCI33_5;NET "AD22" IOSTANDARD = PCI33_5;NET "AD23" IOSTANDARD = PCI33_5;NET "AD24" IOSTANDARD = PCI33_5;NET "AD25" IOSTANDARD = PCI33_5;NET "AD26" IOSTANDARD = PCI33_5;NET "AD27" IOSTANDARD = PCI33_5;NET "AD28" IOSTANDARD = PCI33_5;NET "AD29" IOSTANDARD = PCI33_5;NET "AD30" IOSTANDARD = PCI33_5;NET "AD31" IOSTANDARD = PCI33_5;NET "CBE0" IOSTANDARD = PCI33_5;NET "CBE1" IOSTANDARD = PCI33_5;NET "CBE2" IOSTANDARD = PCI33_5;NET "CBE3" IOSTANDARD = PCI33_5;NET "DEVSEL" IOSTANDARD = PCI33_5;NET "FRAME" IOSTANDARD = PCI33_5;NET "GNT" IOSTANDARD = PCI33_5;NET "RST" IOSTANDARD = PCI33_5;NET "INTA" IOSTANDARD = PCI33_5;NET "IRDY" IOSTANDARD = PCI33_5;NET "PAR" IOSTANDARD = PCI33_5;NET "PERR" IOSTANDARD = PCI33_5;NET "REQ" IOSTANDARD = PCI33_5;NET "SERR" IOSTANDARD = PCI33_5;NET "STOP" IOSTANDARD = PCI33_5;NET "TRDY" IOSTANDARD = PCI33_5;NET "IDSEL" IOSTANDARD = PCI33_5;