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[/] [xulalx25soc/] [trunk/] [bench/] [cpp/] [sdramsim.cpp] - Blame information for rev 4

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#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
 
#include "sdramsim.h"
 
short   SDRAMSIM::operator()(int clk, int cke, int cs_n, int ras_n, int cas_n, int we_n,
                int bs, unsigned addr, int driv, short data) {
        short   result = 0;
 
        if (driv)
                result = data;
        else if (!clk)
                return m_last_value;
        if (!cke) {
                fprintf(stderr, "This simulation only supports CKE high!\n");
                fprintf(stderr, "\tCKE   = %d\n", cke);
                fprintf(stderr, "\tCS_n  = %d\n", cs_n);
                fprintf(stderr, "\tRAS_n = %d\n", ras_n);
                fprintf(stderr, "\tCAS_n = %d\n", cas_n);
                fprintf(stderr, "\tWE_n  = %d\n", we_n);
                assert(cke);
        }
 
        if (m_pwrup < POWERED_UP_STATE) {
                if (m_clocks_till_idle > 0)
                        m_clocks_till_idle--;
                if (m_pwrup == 0) {
                        assert((ras_n)&&(cas_n)&&(we_n));
                        if (m_clocks_till_idle == 0) {
                                m_pwrup++;
                                printf("Successful power up wait, moving to state #1\n");
                        }
                } else if (m_pwrup == 1) {
                        if ((!cs_n)&&(!ras_n)&&(cas_n)&&(!we_n)&&(addr&0x0400)) {
                                // Wait until a precharge all banks command
                                m_pwrup++;
                                printf("Successful precharge command, moving to state #2\n");
                                m_clocks_till_idle = 8;
                        }
                } else if (m_pwrup == 2) {
                        // Need 8 auto refresh cycles before or after the mode
                        // set command.  We'll insist they be before.
                        if (m_clocks_till_idle == 0) {
                                m_pwrup++;
                                printf("Successful initial auto-refresh, waiting for mode-set\n");
                                for(int i=0; i<m_nrefresh; i++)
                                        m_refresh_time[i] = MAX_REFRESH_TIME;
                        } else
                                assert((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n));
                } else if (m_pwrup == 3) {
                        const int tRSC = 2;
                        if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(!we_n)){
                                // mode set
                                printf("Mode set: %08x\n", addr);
                                assert(addr == 0x021);
                                m_pwrup++;
                                printf("Successful mode set, moving to state #3, tRSC = %d\n", tRSC);
                                m_clocks_till_idle=tRSC;
                        }
                } else if (m_pwrup == 4) {
                        assert(cs_n);
                        if (m_clocks_till_idle == 0) {
                                m_pwrup = POWERED_UP_STATE;
                                m_clocks_till_idle = 0;
                                printf("Successful settup!  SDRAM switching to operational\n");
                        } else if (m_clocks_till_idle == 1) {
                                ;
                        } else assert(0 && "Should never get here!");
                } else if (m_pwrup == 5) {
                        if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n)) {
                                if (m_clocks_till_idle == 0) {
                                        m_pwrup = POWERED_UP_STATE;
                                        m_clocks_till_idle = 0;
 
                                        for(int i=0; i<m_nrefresh; i++)
                                                m_refresh_time[i] = MAX_REFRESH_TIME;
                                }
                        } else {
                                assert(0);
                        }
                }
                m_next_wr = false;
        } else { // In operation ...
                for(int i=0; i<m_nrefresh; i++)
                        m_refresh_time[i]--;
                if (m_refresh_time[m_refresh_loc] < 0) {
                        assert(0 && "Failed refresh requirement");
                } for(int i=0; i<NBANKS; i++) {
                        m_bank_status[i] >>= 1;
                        if (m_bank_status[i]&2)
                                m_bank_status[i] |= 4;
                        if (m_bank_status[i]&1) { // Bank is open
                                m_bank_open_time[i] --;
                                if (m_bank_open_time[i] < 0) {
                                        assert(0 && "Bank held open too long");
                                }
                        }
                }
 
                if (m_clocks_till_idle)
                        m_clocks_till_idle--;
 
                if (m_fail > 0) {
                        m_fail--;
                        if (m_fail == 0) {
                                fprintf(stderr, "Failing on schedule\n");
                                exit(-3);
                        }
                }
 
                if ((m_clocks_till_idle > 0)&&(m_next_wr)) {
                        printf("SDRAM[%08x] <= %04x\n", m_wr_addr, data & 0x0ffff);
                        m_mem[m_wr_addr++] = data;
                        result = data;
                        m_next_wr = false;
                } else {
                        result = (driv)?data:m_qdata[m_qloc];
                }
                m_qloc = (m_qloc + 1)&m_qmask;
 
                if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n)) {
                        // Auto-refresh command
                        m_refresh_time[m_refresh_loc] = MAX_REFRESH_TIME;
                        m_refresh_loc++;
                        if (m_refresh_loc >= m_nrefresh)
                                m_refresh_loc = 0;
                        assert((m_bank_status[0]&6) == 0);
                        assert((m_bank_status[1]&6) == 0);
                        assert((m_bank_status[2]&6) == 0);
                        assert((m_bank_status[3]&6) == 0);
                } else if ((!cs_n)&&(!ras_n)&&(cas_n)&&(!we_n)) {
                        if (addr&0x0400) {
                                // Bank/Precharge All CMD
                                for(int i=0; i<NBANKS; i++)
                                        m_bank_status[i] &= 0x03;
                        } else {
                                // Precharge/close single bank
                                assert(0 == (bs & (~3))); // Assert w/in bounds
                                m_bank_status[bs] &= 0x03; // Close the bank
 
                                printf("Precharging bank %d\n", bs);
                        }
                } else if ((!cs_n)&&(!ras_n)&&(cas_n)&&(we_n)) {
                        printf("Activating bank %d\n", bs);
                        // Activate a bank!
                        if (0 != (bs & (~3))) {
                                m_fail = 2;
                                fprintf(stderr, "ERR: Activating a bank w/ more than 2 bits\n");
                                // assert(0 == (bs & (~3))); // Assert w/in bounds
                        } else if (m_bank_status[bs] != 0) {
                                fprintf(stderr, "ERR: Status of bank [bs=%d] = %d != 0\n",
                                        bs, m_bank_status[bs]);
                                m_fail = 4;
                                // assert(m_bank_status[bs]==0); // Assert bank was closed
                        }
                        m_bank_status[bs] |= 4;
                        m_bank_open_time[bs] = MAX_BANKOPEN_TIME;
                        m_bank_row[bs] = addr;
                } else if ((!cs_n)&&(ras_n)&&(!cas_n)) {
                        printf("R/W Op\n");
                        if (!we_n) {
                                // Initiate a write
                                assert(0 == (bs & (~3))); // Assert w/in bounds
                                assert(m_bank_status[bs]&1); // Assert bank is open
 
                                m_wr_addr = m_bank_row[bs];
                                m_wr_addr <<= 2;
                                m_wr_addr |= bs;
                                m_wr_addr <<= 9;
                                m_wr_addr |= (addr & 0x01ff);
 
                                assert(driv);
                                printf("SDRAM[%08x] <= %04x\n", m_wr_addr, data & 0x0ffff);
                                m_mem[m_wr_addr++] = data;
                                m_clocks_till_idle = 2;
                                m_next_wr = true;
 
                                if (addr & 0x0400) { // Auto precharge
                                        m_bank_status[bs] &= 3;
                                        m_bank_open_time[bs] = MAX_BANKOPEN_TIME;
                                }
                        } else { // Initiate a read
                                assert(0 == (bs & (~3))); // Assert w/in bounds
                                assert(m_bank_status[bs]&1); // Assert bank is open
 
                                unsigned        rd_addr;
 
                                rd_addr = m_bank_row[bs] & 0x01fff;
                                rd_addr <<= 2;
                                rd_addr |= bs;
                                rd_addr <<= 9;
                                rd_addr |= (addr & 0x01ff);
 
                                assert(!driv);
                                printf("SDRAM.Q %04x <= SDRAM[%08x]\n",
                                        m_mem[rd_addr] & 0x0ffff, rd_addr);
                                m_qdata[(m_qloc+1)&m_qmask] = m_mem[rd_addr++];
                                printf("SDRAM.Q %04x <= SDRAM[%08x]\n",
                                        m_mem[rd_addr] & 0x0ffff, rd_addr);
                                m_qdata[(m_qloc+2)&m_qmask] = m_mem[rd_addr++];
                                m_clocks_till_idle = 2;
 
                                if (addr & 0x0400) { // Auto precharge
                                        m_bank_status[bs] &= 3;
                                        m_bank_open_time[bs] = MAX_BANKOPEN_TIME;
                                }
                        }
                } else if (cs_n) {
                        // Chips not asserted, DESELECT CMD equivalent of a NOOP
                } else if ((ras_n)&&(cas_n)&&(we_n)) {
                        // NOOP command
                } else {
                        fprintf(stderr, "Unrecognized memory command!\n");
                        fprintf(stderr, "\tCS_n  = %d\n", cs_n);
                        fprintf(stderr, "\tRAS_n = %d\n", ras_n);
                        fprintf(stderr, "\tCAS_n = %d\n", cas_n);
                        fprintf(stderr, "\tWE_n  = %d\n", we_n);
                        assert(0 && "Unrecognizned command");
                }
        }
 
        return result & 0x0ffff;
}
 
 

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[/] [xulalx25soc/] [trunk/] [bench/] [cpp/] [sdramsim.cpp] - Blame information for rev 4

Line No.	Rev	Author	Line
1	4	dgisselq	`#include <stdio.h>`
2			`#include <stdlib.h>`
3			`#include <assert.h>`
4
5			`#include "sdramsim.h"`
6
7			`short SDRAMSIM::operator()(int clk, int cke, int cs_n, int ras_n, int cas_n, int we_n,`
8			`int bs, unsigned addr, int driv, short data) {`
9			`short result = 0;`
10
11			`if (driv)`
12			`result = data;`
13			`else if (!clk)`
14			`return m_last_value;`
15			`if (!cke) {`
16			`fprintf(stderr, "This simulation only supports CKE high!\n");`
17			`fprintf(stderr, "\tCKE = %d\n", cke);`
18			`fprintf(stderr, "\tCS_n = %d\n", cs_n);`
19			`fprintf(stderr, "\tRAS_n = %d\n", ras_n);`
20			`fprintf(stderr, "\tCAS_n = %d\n", cas_n);`
21			`fprintf(stderr, "\tWE_n = %d\n", we_n);`
22			`assert(cke);`
23			`}`
24
25			`if (m_pwrup < POWERED_UP_STATE) {`
26			`if (m_clocks_till_idle > 0)`
27			`m_clocks_till_idle--;`
28			`if (m_pwrup == 0) {`
29			`assert((ras_n)&&(cas_n)&&(we_n));`
30			`if (m_clocks_till_idle == 0) {`
31			`m_pwrup++;`
32			`printf("Successful power up wait, moving to state #1\n");`
33			`}`
34			`} else if (m_pwrup == 1) {`
35			`if ((!cs_n)&&(!ras_n)&&(cas_n)&&(!we_n)&&(addr&0x0400)) {`
36			`// Wait until a precharge all banks command`
37			`m_pwrup++;`
38			`printf("Successful precharge command, moving to state #2\n");`
39			`m_clocks_till_idle = 8;`
40			`}`
41			`} else if (m_pwrup == 2) {`
42			`// Need 8 auto refresh cycles before or after the mode`
43			`// set command. We'll insist they be before.`
44			`if (m_clocks_till_idle == 0) {`
45			`m_pwrup++;`
46			`printf("Successful initial auto-refresh, waiting for mode-set\n");`
47			`for(int i=0; i<m_nrefresh; i++)`
48			`m_refresh_time[i] = MAX_REFRESH_TIME;`
49			`} else`
50			`assert((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n));`
51			`} else if (m_pwrup == 3) {`
52			`const int tRSC = 2;`
53			`if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(!we_n)){`
54			`// mode set`
55			`printf("Mode set: %08x\n", addr);`
56			`assert(addr == 0x021);`
57			`m_pwrup++;`
58			`printf("Successful mode set, moving to state #3, tRSC = %d\n", tRSC);`
59			`m_clocks_till_idle=tRSC;`
60			`}`
61			`} else if (m_pwrup == 4) {`
62			`assert(cs_n);`
63			`if (m_clocks_till_idle == 0) {`
64			`m_pwrup = POWERED_UP_STATE;`
65			`m_clocks_till_idle = 0;`
66			`printf("Successful settup! SDRAM switching to operational\n");`
67			`} else if (m_clocks_till_idle == 1) {`
68			`;`
69			`} else assert(0 && "Should never get here!");`
70			`} else if (m_pwrup == 5) {`
71			`if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n)) {`
72			`if (m_clocks_till_idle == 0) {`
73			`m_pwrup = POWERED_UP_STATE;`
74			`m_clocks_till_idle = 0;`
75
76			`for(int i=0; i<m_nrefresh; i++)`
77			`m_refresh_time[i] = MAX_REFRESH_TIME;`
78			`}`
79			`} else {`
80			`assert(0);`
81			`}`
82			`}`
83			`m_next_wr = false;`
84			`} else { // In operation ...`
85			`for(int i=0; i<m_nrefresh; i++)`
86			`m_refresh_time[i]--;`
87			`if (m_refresh_time[m_refresh_loc] < 0) {`
88			`assert(0 && "Failed refresh requirement");`
89			`} for(int i=0; i<NBANKS; i++) {`
90			`m_bank_status[i] >>= 1;`
91			`if (m_bank_status[i]&2)`
92			`m_bank_status[i] \|= 4;`
93			`if (m_bank_status[i]&1) { // Bank is open`
94			`m_bank_open_time[i] --;`
95			`if (m_bank_open_time[i] < 0) {`
96			`assert(0 && "Bank held open too long");`
97			`}`
98			`}`
99			`}`
100
101			`if (m_clocks_till_idle)`
102			`m_clocks_till_idle--;`
103
104			`if (m_fail > 0) {`
105			`m_fail--;`
106			`if (m_fail == 0) {`
107			`fprintf(stderr, "Failing on schedule\n");`
108			`exit(-3);`
109			`}`
110			`}`
111
112			`if ((m_clocks_till_idle > 0)&&(m_next_wr)) {`
113			`printf("SDRAM[%08x] <= %04x\n", m_wr_addr, data & 0x0ffff);`
114			`m_mem[m_wr_addr++] = data;`
115			`result = data;`
116			`m_next_wr = false;`
117			`} else {`
118			`result = (driv)?data:m_qdata[m_qloc];`
119			`}`
120			`m_qloc = (m_qloc + 1)&m_qmask;`
121
122			`if ((!cs_n)&&(!ras_n)&&(!cas_n)&&(we_n)) {`
123			`// Auto-refresh command`
124			`m_refresh_time[m_refresh_loc] = MAX_REFRESH_TIME;`
125			`m_refresh_loc++;`
126			`if (m_refresh_loc >= m_nrefresh)`
127			`m_refresh_loc = 0;`
128			`assert((m_bank_status[0]&6) == 0);`
129			`assert((m_bank_status[1]&6) == 0);`
130			`assert((m_bank_status[2]&6) == 0);`
131			`assert((m_bank_status[3]&6) == 0);`
132			`} else if ((!cs_n)&&(!ras_n)&&(cas_n)&&(!we_n)) {`
133			`if (addr&0x0400) {`
134			`// Bank/Precharge All CMD`
135			`for(int i=0; i<NBANKS; i++)`
136			`m_bank_status[i] &= 0x03;`
137			`} else {`
138			`// Precharge/close single bank`
139			`assert(0 == (bs & (~3))); // Assert w/in bounds`
140			`m_bank_status[bs] &= 0x03; // Close the bank`
141
142			`printf("Precharging bank %d\n", bs);`
143			`}`
144			`} else if ((!cs_n)&&(!ras_n)&&(cas_n)&&(we_n)) {`
145			`printf("Activating bank %d\n", bs);`
146			`// Activate a bank!`
147			`if (0 != (bs & (~3))) {`
148			`m_fail = 2;`
149			`fprintf(stderr, "ERR: Activating a bank w/ more than 2 bits\n");`
150			`// assert(0 == (bs & (~3))); // Assert w/in bounds`
151			`} else if (m_bank_status[bs] != 0) {`
152			`fprintf(stderr, "ERR: Status of bank [bs=%d] = %d != 0\n",`
153			`bs, m_bank_status[bs]);`
154			`m_fail = 4;`
155			`// assert(m_bank_status[bs]==0); // Assert bank was closed`
156			`}`
157			`m_bank_status[bs] \|= 4;`
158			`m_bank_open_time[bs] = MAX_BANKOPEN_TIME;`
159			`m_bank_row[bs] = addr;`
160			`} else if ((!cs_n)&&(ras_n)&&(!cas_n)) {`
161			`printf("R/W Op\n");`
162			`if (!we_n) {`
163			`// Initiate a write`
164			`assert(0 == (bs & (~3))); // Assert w/in bounds`
165			`assert(m_bank_status[bs]&1); // Assert bank is open`
166
167			`m_wr_addr = m_bank_row[bs];`
168			`m_wr_addr <<= 2;`
169			`m_wr_addr \|= bs;`
170			`m_wr_addr <<= 9;`
171			`m_wr_addr \|= (addr & 0x01ff);`
172
173			`assert(driv);`
174			`printf("SDRAM[%08x] <= %04x\n", m_wr_addr, data & 0x0ffff);`
175			`m_mem[m_wr_addr++] = data;`
176			`m_clocks_till_idle = 2;`
177			`m_next_wr = true;`
178
179			`if (addr & 0x0400) { // Auto precharge`
180			`m_bank_status[bs] &= 3;`
181			`m_bank_open_time[bs] = MAX_BANKOPEN_TIME;`
182			`}`
183			`} else { // Initiate a read`
184			`assert(0 == (bs & (~3))); // Assert w/in bounds`
185			`assert(m_bank_status[bs]&1); // Assert bank is open`
186
187			`unsigned rd_addr;`
188
189			`rd_addr = m_bank_row[bs] & 0x01fff;`
190			`rd_addr <<= 2;`
191			`rd_addr \|= bs;`
192			`rd_addr <<= 9;`
193			`rd_addr \|= (addr & 0x01ff);`
194
195			`assert(!driv);`
196			`printf("SDRAM.Q %04x <= SDRAM[%08x]\n",`
197			`m_mem[rd_addr] & 0x0ffff, rd_addr);`
198			`m_qdata[(m_qloc+1)&m_qmask] = m_mem[rd_addr++];`
199			`printf("SDRAM.Q %04x <= SDRAM[%08x]\n",`
200			`m_mem[rd_addr] & 0x0ffff, rd_addr);`
201			`m_qdata[(m_qloc+2)&m_qmask] = m_mem[rd_addr++];`
202			`m_clocks_till_idle = 2;`
203
204			`if (addr & 0x0400) { // Auto precharge`
205			`m_bank_status[bs] &= 3;`
206			`m_bank_open_time[bs] = MAX_BANKOPEN_TIME;`
207			`}`
208			`}`
209			`} else if (cs_n) {`
210			`// Chips not asserted, DESELECT CMD equivalent of a NOOP`
211			`} else if ((ras_n)&&(cas_n)&&(we_n)) {`
212			`// NOOP command`
213			`} else {`
214			`fprintf(stderr, "Unrecognized memory command!\n");`
215			`fprintf(stderr, "\tCS_n = %d\n", cs_n);`
216			`fprintf(stderr, "\tRAS_n = %d\n", ras_n);`
217			`fprintf(stderr, "\tCAS_n = %d\n", cas_n);`
218			`fprintf(stderr, "\tWE_n = %d\n", we_n);`
219			`assert(0 && "Unrecognizned command");`
220			`}`
221			`}`
222
223			`return result & 0x0ffff;`
224			`}`
225
226